BRANCHED RECEPTOR BINDING MULTI-SUBUNIT PROTEIN COMPLEXES FOR USE IN BACTERIAL DELIVERY VEHICLES

Abstract
The present disclosure relates generally to bacterial delivery vehicles for use in efficient transfer of a desired payload into a target bacterial cell. More specifically, the present disclosure relates to bacterial delivery vehicles with desired host ranges based on the presence of a chimeric receptor binding protein (RBP) composed of a fusion between the N-terminal region of a RBP derived from a lambda-like bacteriophage and the C-terminal region of a different RBP, and/or the presence of an engineered branched receptor binding multi-subunit polypeptides (“branched-RBP”).
Description
REFERENCE TO SEQUENCE LISTING SUBMITTED VIA EFS-WEB

This application includes an electronically submitted sequence listing in .txt format. The .txt file contains a sequence listing entitled “EB2018-02USreg_ST25.txt” is 1.1 MB in size. The sequence listing contained in this .txt file is part of the specification and is hereby incorporated by reference herein in its entirety.


TECHNICAL FIELD

The present disclosure relates generally to bacterial delivery vehicles for use in efficient transfer of a desired payload into a target bacterial cell.


BACKGROUND

Bacteriophages are parasites that infect and multiply in bacteria. In general, the infection process can be divided in several stages: (i) adsorption corresponding to recognition and binding to the bacterial cell; (ii) injection of the DNA genome into the bacterial cell cytoplasm; (iii) production of a set of viral proteins that can lead to insertion in the host target genome (lysogenic phages) or to the production of infective particles (lytic phages) and (iv) release of mature virions from the infected cell, usually by controlled lysis [1].


Being the first step necessary for a successful infection, recognition and binding to the target cell is an essential process in the bacteriophage life cycle. Bacteriophages can in some cases recognize several strains of the same species, having a “broad host range”, but very commonly are able to recognize a specific antigen present only on some strains of the same species [2]. It is thus not surprising that this step of the infection process is central in the competition between bacteriophage and bacteria for successful infection.


As a general mechanism, a bacteriophage encodes two main sets of proteins that are involved in the recognition process. The first set is able to attach to the bacteriophage's primary receptor on the cell surface, an event that triggers DNA ejection into the cytoplasm and is usually viewed as an “irreversible” binding process [3]. Different bacteriophage genera differ in the organization of this set of proteins, and hence the naming can be different. In some Siphovirus, for example, they are called the “central tail fiber” or “tail tip”, which binds irreversibly to the LamB receptor in Escherichia coli. In the siphoviridae lambda, the “central tail fiber” or “tail tip” is composed of the protein gpJ [4]. In some other Siphovirus, like T5, a protein located at the very tip of the tail mediates this process. In the case of T5, a protein called pb5 recognizes the FhuA receptor [5]. This type of protein can be found in many other bacteriophages. In Myoviruses, like T4, the irreversible binding to the primary receptor or to the cell surface in general is mediated by the “short tail fibers”, which are also located at the end of the tail tube [5].


The second set of proteins in the bacteriophage (herein referred to as “receptor binding proteins”) encodes recognition and binding activities to the so-called “secondary receptor” on the bacterium. This secondary receptor allows for transient binding of the phage particle on the cell surface in order to scan the surface and position the first set of proteins in contact with the primary receptor. Since this binding is reversible, it allows the phage to “walk” on the cell surface until a primary receptor is found and the infection process starts. These protein complexes are sometimes referred to as “L-shape fibers”, such as in T5, “side tail fibers” such as in lambda, “long tail fibers” as in T4, or tailspikes such as in phage P22 [5]-[8]. For some phages, the presence of this second set of proteins is necessary for the infection process to occur, such as T4 [5]. In some other phages, like lambda, this second set of proteins is not strictly necessary for the infection process to happen, but it may allow for a more efficient binding to the target cell [7].


Since the adsorption process is strictly necessary for a successful infection to happen, bacteria can develop multiple ways to avoid being recognized by a bacteriophage. For example, they can mutate the primary or secondary receptor to which the bacteriophage binds; they can mask this receptor by attaching proteins to it (receptor masking); or they can grow physical barriers around them in the form of bacterial capsules, thus blocking any access to the cell surface [9]. Bacteria can produce many different types of extracellular polymeric capsules [10]. In turn, bacteriophages have evolved different strategies to bypass these defense mechanisms. For instance, mutating the tail tip proteins allows them to use a different receptor [11]. However, the presence of a polymeric capsule around the bacterium requires a different approach, as it blocks all contact to any receptors on the cell surface. In these cases, bacteriophages have evolved specific proteins that can enzymatically degrade this capsule to gain access to the cells. These depolymerase activities are encoded in protein complexes that are distinct to the primary receptor recognition machinery, in the form of side tail fibers, long tail fibers or tailspikes [12], [13], [14].


The concept of a bacteriophage's host range needs to be redefined when only the adsorption and injection processes are taken into account. Since all incompatibilities or defense mechanisms related to the phage replication cycle are left out of the picture, the “adsorption host range” of a given phage is usually larger than the “classical host range” in which the infectious cycle leads to newly produced mature virions. The concept of host range becomes even more different to the classical definition when packaged phagemids based on a given bacteriophage capsid is used. Packaged phagemids do not contain the information necessary to replicate the viral particles, because they do not package their cognate viral genome. Thus, the host range of a packaged phagemid tends to be larger than that of the parental bacteriophage it derives from. Therefore, for development of novel bacterial delivery vehicles, designed for the efficient delivery of exogenous DNA payload into target strains, it is of utmost importance to be able to engineer delivery vehicles with desired host ranges as well as the ability to bypass bacterial mechanisms that can lead to unsuccessful binding of the packaged phagemid to the bacterial cell surface.


SUMMARY

As a general mechanism, a bacteriophage encodes sets of proteins that are involved in the bacterial cell recognition process. Described herein are novel approaches to engineering synthetic bacterial delivery vehicles with desired target host ranges.


In some aspects, synthetic bacterial delivery vehicles are provided that are characterized by a chimeric receptor binding protein (RBP), wherein the chimeric RBP comprises a fusion between an N-terminal domain of a RBP from a lambda-like bacteriophage, or lambda bacteriophage, and a C-terminal domain of a different bacteriophage RBP. Such bacteriophage RBPs, from which the chimeric RBP are derived, include, for example, and depending on phages families, “L-shape fibers”, “side tail fibers (stfs)”, “long tail fibers” or “tailspikes.” As disclosed herein, it has been demonstrated that a significant portion of a lambda-like bacteriophage receptor binding protein (RBP), such as a stf protein, can be exchanged with a portion of a different RBP. Moreover, specific fusion positions in the RBPs have been identified which allow one to obtain functional chimeric RBPs.


In additional aspects, the disclosure relates to bacterial delivery vehicles with desired host ranges based on the presence of an engineered branched receptor binding multi-subunit protein complex (“branched-RBP”). The branched-RBP comprises two or more associated receptor binding proteins derived from bacteriophages, wherein said RBPs contain “interaction domains” (IDs) that mediate association of the different subunits. The association of one subunit to another can be non-covalent or covalent. The two or more associated RBPs include, but are not limited to, the chimeric receptor binding proteins (RBPs) described herein that comprise a fusion between the N-terminal domain of a RBP derived from a lambda-like, or lambda bacteriophage and the C-terminal domain of a different RBP.


The chimeric receptor binding protein (RBP) is one wherein the chimeric RBP comprises a fusion between an N-terminal domain of a RBP derived from a lambda-like bacteriophage, or lambda bacteriophage, and a C-terminal domain of a different RBP wherein said N-terminal domain of the RBP is fused to said C-terminal domain of a different RBP within one of the amino acids regions selected from positions 1-150, 320-460, or 495-560 of the N-terminal RBP with reference to the lambda stf sequence (SEQ ID NO: 1) or a similar region of a RBP having homology with one or more of three amino acid regions ranging from positions 1-150, 320-460, and 495-560 of the RBP with reference to the lambda stf sequence. In one specific aspect of the invention, the different RBP domain of the chimeric receptor binding protein (RBP) is derived from any bacteriophage or from any bacteriocin. In one specific aspect, the RBP from the lambda-like bacteriophage, or the lambda bacteriophage, or the different RBP contains homology in one or more of three amino acid regions ranging from positions 1-150, 320-460, or 495-560 of the N-terminal RBP with reference to the lambda bacteriophage stf sequence (SEQ ID NO: 1). In certain aspects, the homology between the lambda-like bacteriophage, the lambda bacteriophage, or the different RBP and the one or more of three amino acids regions is around 35% identity for 45 amino acids or more, around 50% identify for 30 amino acids or more, and around 90% identity for 18 amino acids or more with reference to the lambda bacteriophage stf sequence (SEQ ID NO:1). Determination of homology can be performed using alignment tools such as the Smith-Waterman algorithm (Smith et al., 1981, J. Mol. Biol 147:195-197) or EMBOSS Matcher (Rice, Longden, Bleasby 2000 EMBOSS Trends in Genetics 16: 276-277).


In one aspect of the invention, the chimeric RBP comprises the N-terminal domain of a RBP fused to the C-terminal domain of a different RBP within one of the amino acid regions selected from positions 80-150, 320-460, or 495-560 of the N-terminal RBP with reference to the lambda bacteriophage stf sequence (SEQ ID NO:1). In another embodiment of the invention, the chimeric RBP comprises an N-terminal domain and a C-terminal domain fused within one of the amino acids regions selected from positions 1-150, 320-460 or 495-560 at an insertion site having at least 80%, preferably at least 85%, at least 90%, at least 95%, at least 98% or at least 99%, identity with an insertion site selected from the group consisting of amino acids SAGDAS (SEQ ID NO:190), ADAKKS (SEQ ID NO:191), MDETNR (SEQ ID NO:192), SASAAA (SEQ ID NO:193), GAGENS (SEQ ID NO.194), ATLKQI (SEQ ID NO:195), IIQLED (SEQ ID NO:196), GNIIDL (SEQ ID NO: 197), IATRV (SEQ ID NO:198), TPGEL (SEQ ID NO: 199), GAIIN (SEQ ID NO:200), NQIID (SEQ ID NO:201), GQIVN (SEQ ID NO:202), and VDRAV (SEQ ID NO:203). In a more specific embodiment of the invention, the chimeric RBP comprises an N-terminal domain and a C-terminal domain fused within one of the amino acids regions selected from positions 1-150, 320-460 or 495-560 at an insertion site having at least 80%, preferably at least 85%, at least 90%, at least 95%, at least 98% or at least 99%, identity with an insertion site selected from the group consisting of amino acids SAGDAS (SEQ ID NO:190), ADAKKS (SEQ ID NO:191), MDETNR (SEQ ID NO:192), SASAAA (SEQ ID NO:193) and GAGENS (SEQ ID NO 194).


In another aspect, the chimeric RBP comprises the N-terminal domain of a RBP fused to the C-terminal domain of different RBP wherein the different RBP is a protein or group a different proteins that confers an altered host range. In one embodiment, the different RBP is a T4-like or T4 long tail fiber composed of a proximal tail fiber and a distal tail fiber (DTF), and the C-terminal domain of a T4-like or T4 RBP is the distal tail fiber (DTF). In another embodiment, the N-terminal domain of a RBP is fused to the T4-like or T4 distal tail fiber at an insertion site within the T4-like or T4 DTF having at least 80%, preferably at least 85%, at least 90%, at least 95%, at least 98% or at least 99%, identity with an insertion site selected from the group consisting of amino acids ATLKQI (SEQ ID NO:195), IIQLED (SEQ ID NO:196), GNIIDL (SEQ ID NO:197), IATRV (SEQ ID NO:198), TPGEL (SEQ ID NO:199), GAIIN (SEQ ID NO:200), NQIID (SEQ ID NO:201), GQIVN (SEQ ID NO:202), and VDRAV (SEQ ID NO:203). In a specific embodiment, the N-terminal domain of a RBP is fused to the T4-like or T4 distal tail fiber within a region from amino acid 1 to 90, with a preferred region from amino acid 40 to 50 of the DTF.


In specific embodiments, the disclosure provides specific chimeric RBPs. SEQ ID NOS 2-61, 135-165, 215-242, 271, 273, 282 and 283 disclose the amino acid sequences of such chimeric RBPs as well as, in some instances, their corresponding natural chaperone proteins (designated “AP”). Such AP proteins assist in the folding of the chimeric RBPs. In a specific embodiment, the RBP comprises the amino acid sequence of SEQ ID NO. 2, 4, 7, 9, 12, 15, 17, 20, 23, 24, 25, 27, 29, 31, 33, 35, 37, 39, 41, 42, 44, 46, 47, 48, 49, 50, 51, 52, 53, 56, 59, 135 to 144, 147, 150, 151, 154, 157, 160, 163, 215, 216, 219, 221, 223, 225, 227, 229, 232, 325, 237, 239, 241, 282 or 283. In a more specific embodiment, the RBP comprises the amino acid sequence of SEQ ID NO: 2, 4, 7, 9, 12, 15, 17, 20, 23, 24, 25, 27, 29, 31, 33, 35, 37, 39, 41, 42, 44, 46, 47, 48, 49, 50, 51, 52, 53, 56 or 59.


In another aspect, the present disclosure provides nucleotide sequences encoding for the chimeric RBPs disclosed herein. In a specific embodiment, nucleic acids encoding such chimeric RBPs, as well as their corresponding AP proteins, are depicted in SEQ ID NOS 62-120, 166-189, 206-212, 243-270, 272, 274 and 284. In a specific embodiment, the nucleic acids encoding such chimeric RBPs comprise the nucleotide sequence of SEQ ID NO: 62, 64, 67, 69, 72, 75, 77, 80, 83, 84, 85, 87, 89, 91, 93, 95, 97, 99, 101, 102, 104, 106, 107, 108, 109, 110, 111, 112, 113, 116, 119, 166, 167, 168, 171, 174, 175, 178, 181, 184, 187, 206, 207, 208, 209, 210, 211, 212, 243, 244, 247, 249, 251, 253, 255, 257, 260, 263, 265, 267, 269 or 284. In a more specific embodiment, the nucleic acids encoding such chimeric RBPs comprise the nucleotide sequence of SEQ ID NO: 62, 64, 67, 69, 72, 75, 77, 80, 83, 84, 85, 87, 89, 91, 93, 95, 97, 99, 101, 102, 104, 106, 107, 108, 109, 110, 111, 112, 113, 116 or 119.


In one specific non-limiting aspect of the invention, it has been demonstrated that engineering the chimeric RBP to encode enzymatic activity such as depolymerase activity can dramatically increase the delivery efficiency of the provided bacterial delivery vehicles comprising the chimeric RBP disclosed herein. In an embodiment of the invention, the different RBP domain of the chimeric RBP comprises enzymatic activity such as depolymerase activity against an encapsulated bacterial strain. In a specific embodiment, the depolymerase is an endosialidase such as, for example, a K1F or K5 endosialidase.


In another aspect, the present disclosure provides for engineered branched-RBPs, as well as bacterial delivery vehicles, with desired host ranges and/or specific biological functions, based on the presence of an engineered branched receptor binding multi-subunit protein complex (“branched-RBP”). The engineered branched-RBP comprises two or more associated receptor binding proteins, derived from bacteriophages that associated with one another based on the presence of interaction domains (IDs). Each of the protein complex subunits contain IDs that function as “anchors” for association of one subunit RBP with another. The association of one subunit with another can be non-covalent or covalent. The engineered branched RBP may comprise non-covalent association of the different subunits; in some instance, the engineered branched RBP may comprise covalent association of the different subunits; and in further instances, the engineered branched RBP may comprise both covalent and non-covalent associations of the different subunits. In instances where the association is non-covalent, the protein subunits are assembled into the engineered branched-RBP as separate protein subunits each having their own ID. In a non-limiting example, where the interaction is covalent, the engineered branched-RBP may exist as a single fusion protein comprising different protein domains of interest fused to two or more ID domains. In specific embodiments, the branched-RBP may comprise multiple RBP subunits, including, for example, two, three, four, etc. subunits. Each of the RBP subunits may bring different biological functions to the overall branched-RBP. Such functions include, but are not limited to, host recognition and enzymatic activity. Such enzymatic activity includes depolymerase activity.


Disclosed herein are amino acid sequences that are able to function as interaction domains (IDs). Such IDs, for purposes of the present invention, are those amino acid sequences that provide for association of one subunit to another thereby providing for assembly of the engineered branched-RBPs. The IDs may be naturally occurring bacteriophage IDs, IDs derived from non-bacteriophage polypeptides, or recombinantly derived IDs. The two or more of the associated receptor binding proteins of the engineered branched-RBP may be any bacteriophage RBP, or a functional domain of a bacteriophage RBP, e.g. a domain that provides desired host range or biological activity, wherein said RBP, or the domain of an RBP, are fused to an ID. The associated receptor binding proteins may include, but are not limited to, chimeric receptor binding proteins (RBPs) described herein that comprise of a fusion between the N-terminal domain of a RBP derived from a lambda-like, or lambda bacteriophage and the C-terminal domain of a different RBP wherein said chimeric RBP also comprises an ID.


In an embodiment of the invention, nucleic acid molecules encoding the chimeric RBPs disclosed herein, as well as the two or more subunit RBPs of the engineered branched-RBP, are provided. Such nucleic acids may be included in vectors such as bacteriophages, plasmids, phagemids, viruses, and other vehicles which enable transfer and expression of the chimeric RBP encoding nucleic acids. In instances where the subunits of a branched-RBP are to be expressed, it may be advantageous to express the subunits from a polycistronic expression unit containing multiple ribosomal binding sites (RBSs). The use of such an expression unit can be used to regulate the expression of each of the RBP subunits so that equal quantities of expression of each subunit are achieved.


Bacterial delivery vehicles are provided which enable transfer of a nucleic acid payload, encoding a protein or nucleic acid of interest, into a desired target bacterial host cell. Such bacterial delivery vehicles are characterized by having a chimeric RBP comprising a fusion between the N-terminal domain of a RBP from a lambda-like bacteriophage, or lambda bacteriophage, and the C-terminal domain of a different RBP. In an embodiment of the invention, the bacterial delivery vehicles contain a chimeric RBP comprising a fusion between an N-terminal domain of a RBP derived from a lambda-like bacteriophage, or lambda bacteriophage, and a C-terminal domain of a different RBP wherein said N-terminal domain of the chimeric RBP is fused to said C-terminal domain of a different RBP within one of the amino acids regions selected from positions 1-150, 320-460, or 495-560 of the N-terminal domain with reference to the lambda stf sequence (SEQ ID NO: 1). In one aspect, the RBP from the lambda-like bacteriophage, the lambda bacteriophage, and the different RBP contain homology in one or more of three amino acids regions ranging from positions 1-150, 320-460, and 495-560 of the RBP with reference to the lambda bacteriophage stf sequence (SEQ ID NO: 1). In certain aspects, the homology is around 35% identity for 45 amino acids or more, around 50% identify for 30 amino acids or more, or around 90% identity for 18 amino acids or more within the one or more of three amino acids regions ranging from positions 1-150, 320-460, and 495-560 of the RBP with reference to the lambda bacteriophage stf sequence (SEQ ID NO:1). In one specific aspect of the invention, the different RBP domain of the chimeric receptor binding protein (RBP) is derived from a bacteriophage or a bacteriocin. In one aspect of the invention, the chimeric RBP comprises an N-terminal domain of a RBP fused to a C-terminal domain of a RBP within one of the amino acids regions selected from positions 80-150, 320-460, or 495-560 of the N-terminal RBP domain with reference to the lambda stf sequence (SEQ ID NO:1). In another embodiment of the invention, the chimeric RBP comprises an N-terminal domain of a RBP and a C-terminal domain of a RBP fused within a site of the N-terminal RBP domain having at least 80%, preferably at least 85%, at least 90%, at least 95%, at least 98% or at least 99%, identity with a site selected from the group consisting of amino acids SAGDAS (SEQ ID NO:190), ADAKKS (SEQ ID N0:191), MDETNR (SEQ ID NO: 192), SASAAA (SEQ ID NO:193), GAGENS (SEQ ID NO:194), ATLKQI (SEQ ID NO:195), IIQLED (SEQ ID NO:196), GNIIDL (SEQ ID NO 197), IATRV (SEQ ID NO:198), TPGEL (SEQ ID NO 199), GAIN (SEQ ID NO:200), NQIID (SEQ ID NO:201), GQIVN (SEQ ID NO:202), and VDRAV (SEQ ID NO:203), preferably with a site selected from the group consisting of amino acids SAGDAS (SEQ ID NO:190), ADAKKS (SEQ ID NO:191), MDETNR (SEQ ID NO:192), SASAAA (SEQ ID NO:193) and GAGENS (SEQ ID NO:194).


In specific embodiments, the disclosure provides a bacterial delivery vehicle comprising a chimeric RBP. SEQ ID NOS 2-61, 135-165, 215-242, 271, 273, 282 and 283 disclose the amino acid sequences of such chimeric RBPs and in addition, in some instances, their corresponding natural chaperone proteins (designated “AP”). Such AP proteins assist in the folding of the chimeric PBPs. In a specific embodiment, the RBP comprises the amino acid sequence of SEQ ID NO: 2, 4, 7, 9, 12, 15, 17, 20, 23, 24, 25, 27, 29, 31, 33, 35, 37, 39, 41, 42, 44, 46, 47, 48, 49, 50, 51, 52, 53, 56, 59, 135 to 144, 147, 150, 151, 154, 157, 160, 163, 215, 216, 219, 221, 223, 225, 227, 229, 232, 325, 237, 239, 241, 282 or 283. In a more specific embodiment, the RBP comprises the amino acid sequence of SEQ ID NO: 2, 4, 7, 9, 12, 15, 17, 20, 23, 24, 25, 27, 29, 31, 33, 35, 37, 39, 41, 42, 44, 46, 47, 48, 49, 50, 51, 52, 53, 56 or 59.


In one aspect, the present disclosure also provides nucleotide sequences encoding for the chimeric RBPs disclosed herein. In a specific embodiment, nucleic acids encoding such chimeric RBPs, as well as corresponding AP proteins, are depicted in SEQ ID NOS 62-120, 166-189, 206-212, 243-270, 272, 274 and 284. In a specific embodiment, the nucleic acids encoding such chimeric RBPs comprise the nucleotide sequence of SEQ ID NO: 62, 64, 67, 69, 72, 75, 77, 80, 83, 84, 85, 87, 89, 91, 93, 95, 97, 99, 101, 102, 104, 106, 107, 108, 109, 110, 111, 112, 113, 116, 119, 166, 167, 168, 171, 174, 175, 178, 181, 184, 187, 206, 207, 208, 209, 210, 211, 212, 243, 244, 247, 249, 251, 253, 255, 257, 260, 263, 265, 267, 269 or 284. In a more specific embodiment, the nucleic acids encoding such chimeric RBPs comprise the nucleotide sequence of SEQ ID NO: 62, 64, 67, 69, 72, 75, 77, 80, 83, 84, 85, 87, 89, 91, 93, 95, 97, 99, 101, 102, 104, 106, 107, 108, 109, 110, 111, 112, 113, 116, or 119.


In other specific embodiments and to increase the delivery efficiency of the bacterial delivery vehicles disclosed herein the different RBP domain of the chimeric RBP comprises a domain having depolymerase activity against an encapsulated bacterial strain. In a specific embodiment, the depolymerase is an endosialidase, such as for example, a K1F or K5 endosialidase.


In another aspect of the invention, bacterial delivery vehicles are provided which enable transfer of a nucleic acid payload, encoding a protein or nucleic acid of interest, into a desired target bacterial host cell wherein said bacterial delivery vehicles are characterized by having a branched-RBP as disclosed herein.


The bacterial delivery vehicles provided herein enable transfer of a nucleic acid payload, encoding a protein or nucleic acid of interest, into a desired target bacterial host cell. In certain embodiments of the invention, the nucleic acid of interest is selected from the group consisting of a Cas nuclease gene, a Cas9 nuclease gene, a guide RNA, a CRISPR locus, a toxin gene, a gene expressing an enzyme such as a nuclease or a kinase, a TALEN, a ZFN, a meganuclease, a recombinase, a bacterial receptor, a membrane protein, a structural protein, a secreted protein, a gene expressing resistance to an antibiotic or to a drug in general, a gene expressing a toxic protein or a toxic factor, and a gene expressing a virulence protein or a virulence factor, or any of their combination. In an embodiment of the invention, the nucleic acid payload encodes a therapeutic protein. In another embodiment, the nucleic acid payload encodes an anti-sense nucleic acid molecule.


In one aspect, the bacterial delivery vehicle enables the transfer of a nucleic acid payload that encodes a nuclease that targets cleavage of a host bacterial cell genome or a host bacterial cell plasmid. In some aspects, the cleavage occurs in an antibiotic resistant gene. In another embodiment of the invention, the nuclease mediated cleavage of the host bacterial cell genome is designed to stimulate a homologous recombination event for insertion of a nucleic acid of interest into the genome of the bacterial cell.


The present invention also provides pharmaceutical or veterinary compositions comprising one or more of the bacterial delivery vehicles disclosed herein and a pharmaceutically-acceptable carrier. Also provided is a method for treating a disease or disorder caused by bacteria, preferably a bacterial infection, comprising administering to a subject having a disease or disorder caused by bacteria, preferably a bacterial infection, in need of treatment the provided pharmaceutical or veterinary composition. The present invention also relates to a pharmaceutical or veterinary composition as disclosed herein for use in the treatment of a disease or disorder caused by bacteria, preferably a bacterial infection. It further relates to the use of a pharmaceutical or veterinary composition as disclosed herein for the manufacture of a medicament for treating a disease or disorder caused by bacteria, preferably a bacterial infection. A method for reducing the amount of virulent and/or antibiotic resistant bacteria in a bacterial population is provided comprising contacting the bacterial population with the bacterial delivery vehicles disclosed herein. The method may be an in vivo or in vitro method. The present invention also relates to a pharmaceutical or veterinary composition as disclosed herein for use in reducing the amount of virulent and/or antibiotic resistant bacteria in a bacterial population, in particular in a subject having a bacterial infection. It further relates to the use of a pharmaceutical or veterinary composition as disclosed herein for the manufacture of a medicament for reducing the amount of virulent and/or antibiotic resistant bacteria in a bacterial population, in particular in a subject having a bacterial infection.





BRIEF DESCRIPTION OF FIGURES

In order to better understand the subject matter that is disclosed herein and to exemplify how it may be carried out in practice, embodiments will now be described, by way of non-limiting example, with reference to the accompanying drawings. With specific reference to the drawings, it is stressed that the particulars shown are by way of example and for purposes of illustrative discussion of embodiments of the invention.



FIG. 1 demonstrates delivery in wild-type E. coli strains with lambda and OMPF-lambda packaged phagemids. Lambda packaged phagemids were diluted 1:5 in LB plus 5 mM CaCl2) and 10 μL added in each well. 90 μL of cells grown to an OD600 of around 0.5 were then added to each phagemid-containing well, incubated for 30 min at 37° C. and 10 μL spotted on LB-agar supplemented with chloramphenicol. Left panel, wild type lambda packaged phagemids; right panel, OMPF-lambda variant. Circles show strains with modified delivery as compared to lambda wild-type.



FIG. 2 depicts wild-type lambda and lambda-stf-K1F chimeric delivery vehicles on K1+ strains. Lambda packaged phagemids were sequentially diluted 10× in LB plus 5 mM CaCl2) and 10 μL added in each well. Cells grown to an OD600 of around 0.5 were then added to each phagemid dilution, incubated for 30 min at 37° C. and 10 μL plated on LB supplemented with chloramphenicol. Top panel, strain UTI89; bottom panel, strain S88. Left plates, wild type lambda packaged phagemids; right plates, stf-K1F lambda packaged phagemids.



FIG. 3 depicts wild-type lambda and lambda-stf-K5 chimeric delivery vehicles on a K5+ strain. Lambda packaged phagemids were sequentially diluted 10× in LB plus 5 mM CaCl2 and 10 μL added in each well. ECOR55 grown to an OD600 of around 0.5 were then added to each phagemid dilution, incubated for 30 min at 37° C. and 10 μL plated on LB supplemented with chloramphenicol. Left panel, wild type lambda packaged phagemids; right panel, stf-K15 lambda packaged phagemids.



FIG. 4 depicts wild-type lambda, lambda-stf-AG22 and lambda-stf-SIEA11 chimeric delivery vehicles on a variety of encapsulated strains (O and K capsules). Lambda phagemids were diluted 1:5 in LB plus 5 mM CaCl2) and 10 μL added in each well. 90 μL of cells grown to an OD600 of around 0.5 were then added to each phagemid-containing well, incubated for 30 min at 37° C. and 10 μL spotted on LB-agar supplemented with chloramphenicol. Left panel, wild type lambda phagemids; middle panel, lambda stf-SIEA11 variant; right panel, lambda-stf-AG22 variant. Circles show strains with modified delivery as compared to lambda wild-type.



FIG. 5A-C demonstrates delivery of wild-type lambda and stf chimeras with different insertion sites on a variety of encapsulated strains (O and K capsules). Lambda packaged phagemids were diluted 1:5 in LB plus 5 mM CaCl2) and 10 μL added in each well. 90 μL of cells grown to an OD600 of around 0.5 were then added to each phagemid-containing well, incubated for 30 min at 37° C. and 10 μL spotted on LB-agar supplemented with chloramphenicol. FIG. 5A. Left panel, wild type lambda packaged phagemids; rest of panels, three different ADAKKS (SEQ ID NO:191)-stf variants. FIG. 5B Left panel, wild type lambda packaged phagemids; rest of panels, three different SASAAA (SEQ ID NO: 193)-stf variants. FIG. 5C Left panel, wild type lambda packaged phagemids; rest of panels, three different MDETNR (SEQ ID NO:192)-stf variants. For all panels, red circles show strains with improved delivery efficiency as compared to lambda wild-type.



FIG. 6 depicts a phmmer search that was performed with a 50aa sliding window (step 10) on the representative proteome database (rp75). The number of significant hits (E-value<0.01) is reported.



FIG. 7A-B depicts branched stf architectures with 2 subunits. FIG. 7A is a schematic view of a delivery vehicle with a 2 subunits branched stf architecture. ID: “Interaction Domain”. FIG. 7B is a schematic view of the genetic architecture of an engineered lambda stf construct.



FIG. 8 demonstrates delivery of branched lambda stf packaged phagemids. Lambda packaged lambda-stf-WW11.1 stf, lambda-stf-K1F or the branched construct shown in FIG. 7 (WW11.1-K1F) were produced and titrated against O57 and K1 strains.



FIG. 9A-B depicts branched stf architectures with 4 subunits. FIG. 9A is a schematic view of a delivery vehicle with a 4 subunits branched stf architecture. Actual interactions among different ID may be different in the biological assembly from the graph depicted here. FIG. 9B depicts a genetic circuit encoding the 4 subunits branched stf under the control of an inducible promoter.



FIG. 10. depicts architecture of the engineered lambda stf-T4-like DTF chimera. The semicircles denote RBS sites; the T sign, a transcriptional terminator; the arrow, a promoter.



FIG. 11. shows screening of phagemid particles with chimeric lambda stf-T4-like DTFs. A collection of 96 different wild type E. coli strains, encompassing different serotypes, was transduced with lambda-based phagemids and plated on Cm LB agar. Left panel, wild-type lambda stf; middle panel, chimeric lambda-stf-WW13; right panel, chimeric lambda-stf-PP-1.



FIG. 12. demonstrates screening of phagemid particles with chimeric lambda stf-T4-like DTFs. A collection of 96 different wild type E. coli strains, encompassing different serotypes, was transduced with lambda-based phagemids and plated on Cm LB agar. Left panel, wild-type lambda stf; middle panel, chimeric lambda-stf-WW55; right panel, chimeric lambda-stf-WW34.



FIG. 13. depicts screening of phagemid particles with chimeric lambda stf-T4-like DTFs. All points shown refer to the universal insertion site of the DTF, located within amino acid range from position 1 to 90 with reference to WW13 amino acid sequence. A collection of 96 different wild type E. coli strains, encompassing different serotypes, was transduced with lambda-based phagemids and plated on Cm LB agar (names on top).



FIG. 14. depicts dot scoring system to quantify delivery efficiency. Density 0, 5 or fewer colonies; density 1, more than 5 colonies but not enough to define a clear circular drop; density 2, several colonies, but the background is clearly visible and some colonies are still separated; density 3, many colonies, the background is still visible but the colonies are hardly discernible as separate; density 4, spot almost completely dense, the background can only be seen faintly in some parts of the drop; density 5, spot looks completely dense, background cannot be seen.



FIG. 15-1, FIG. 15-2, FIG. 15-3 depicts raw dot titrations of delivery particles with chimeric stf in 40 human strains of the ECOR collection. Below each panel, the name of the chimeric stf. Above each dot, the 1-2 letter code used to identify strains.



FIG. 16-1, FIG. 16-2 represents bar-formatted delivery data of FIG. 15-1, FIG. 15-2, FIG. 15-3. From 0 (no entry, grey background) to 5 (maximum delivery). The bar length is proportional to the entry score from 1 (smallest bars) to 5 (longest bars).





DETAILED DESCRIPTION

Disclosed herein are novel approaches to engineering synthetic bacterial delivery vehicles with desired target host ranges. The synthetic bacterial delivery vehicles are characterized by a chimeric receptor binding protein (RBP), wherein the chimeric RBP comprises a fusion between the N-terminal domain of a RBP from a lambda-like bacteriophage, or lambda bacteriophage, and the C-terminal domain of a different RBP. It has been demonstrated herein that a significant portion of a lambda-like RBP, such as a stf protein, can be exchanged with a portion of a different RBP. Moreover, specific fusion positions of the receptor binding protein have been identified which allow one to obtain a functional chimeric RBP.


Additionally, disclosed herein are synthetic bacterial delivery vehicles that are characterized by the presence of an engineered branched receptor binding multi-subunit protein complex (“branched-RBP”). The engineered branched-RBP comprises two or more associated receptor binding proteins, derived from bacteriophages, which associate with one another based on the presence of interaction domains (IDs). Each of the polypeptide subunits are engineered to contain IDs that function as “anchors” for association of one subunit RBP with another. The association of one subunit with another can be non-covalent or covalent. In specific embodiments the branched-RBP may comprise multiple RBP subunits, including, for example, two, three, four, etc. subunits.


As used herein, a receptor binding protein or RBP is a polypeptide that recognizes, and optionally binds and/or modifies or degrades a substrate located on the bacterial outer envelope, such as, without limitation, bacterial outer membrane, LPS, capsule, protein receptor, channel, structure such as the flagellum, pili, secretion system. The substrate can be, without limitation, any carbohydrate or modified carbohydrate, any lipid or modified lipid, any protein or modified protein, any amino acid sequence, and any combination thereof. As used herein, a lambda-like bacteriophage refers to any bacteriophage encoding a RBP having amino acids sequence homology of around 35% identity for 45 amino acids or more, around 50% identify for 30 amino acids or more, or around 90% identity for 18 amino acids or more in one or more of three amino acids regions ranging from positions 1-150, 320-460, and 495-560 with reference to the lambda bacteriophage stf sequence of SEQ ID NO: 1, independently of other amino acids sequences encoded by said bacteriophage.


The present disclosure provides a chimeric receptor binding protein (RBP), wherein the chimeric RBP comprises a fusion between an N-terminal domain of a RBP from a lambda-like bacteriophage, or lambda bacteriophage, and a C-terminal domain of a different bacteriophage RBP. Such bacteriophage RBPs, from which the chimeric RBP are derived, include, for example, “L-shape fibers”, “side tail fibers (stfs)”, “long tail fibers” or “tailspikes.” As disclosed herein, it has been demonstrated that a significant portion of a lambda-like bacteriophage receptor binding protein (RBP), such as a stf protein, can be exchanged with a portion of a different RBP. Moreover, specific fusion positions in the RBPs have been identified which allow one to obtain a functional chimeric RBP. Such chimeric RBPs include those having an altered host range and/or biological activity such as, for example, depolymerase activity.


The chimeric receptor binding protein (RBP) is one wherein the chimeric RBP comprises a fusion between an N-terminal domain of a RBP derived from a lambda-like bacteriophage, or lambda bacteriophage, and a C-terminal domain of a different RBP wherein said N-terminal domain of the RBP is fused to said C-terminal domain of a different RBP within one of the amino acids regions selected from positions 1-150, 320-460, or 495-560 of the N-terminal RBP with reference to the lambda stf sequence (SEQ ID NO: 1) or a similar region of a RBP having homology with one or more of three amino acids regions ranging from positions 1-150, 320-460, and 495-560 of the RBP with reference to the lambda stf sequence (SEQ ID NO:1). In one specific aspect of the invention, the different RBP of the chimeric receptor binding protein (RBP) is derived from any bacteriophage or from any bacteriocin.


In one specific aspect, the RBP from the lambda-like bacteriophage, the lambda bacteriophage, or the different RBP contain homology with one or more of three amino acids regions ranging from positions 1-150, 320-460, and 495-560 of the RBP with reference to the lambda bacteriophage stf sequence (SEQ ID NO:1). In certain aspects, the homology between the lambda-like bacteriophage, the lambda bacteriophage, or the different RBP and the one or more amino acids regions is around 35% identity for 45 amino acids or more, around 50% identify for 30 amino acids or more, and around 90% identity for 18 amino acids or more. Determination of homology can be performed using alignment tools such as the Smith-Waterman algorithm (Smith et al., 1981, J. Mol. Biol 147:195-197) or EMBOSS Matcher (Rice, Longden, Bleasby 2000 EMBOSS Trends in Genetics 16: 276-277). In one aspect of the invention, the chimeric RBP comprises the N-terminal domain of the chimeric RBP fused to the C-terminal domain of the chimeric RBP within one of the amino acids regions selected from positions 80-150, 320-460, or 495-560 with reference to the lambda bacteriophage stf sequence (SEQ ID NO: 1). In another embodiment of the invention, the chimeric RBP comprises an N-terminal domain and a C-terminal domain fused within one of the three amino acids regions at an insertion site having at least 80%, preferably at least 85%, at least 90%, at least 95%, at least 98% or at least 99%, identity with an insertion site selected from the group consisting of amino acids SAGDAS (SEQ ID NO:190), ADAKKS (SEQ ID NO:191), MDETNR (SEQ ID NO:192), SASAAA (SEQ ID NO:193), GAGENS (SEQ ID NO:194), ATLKQI (SEQ ID NO:195), IIQLED (SEQ ID NO:196), GNIIDL (SEQ ID NO:197), IATRV (SEQ ID NO:198), TPGEL (SEQ ID NO:199), GAIIN (SEQ ID NO:200), NQIID (SEQ ID NO:201), GQIVN (SEQ ID NO:202), and VDRAV (SEQ ID NO:203), preferably from the group consisting of amino acids SAGDAS (SEQ ID NO:190), ADAKKS (SEQ ID NO:191), MDETNR (SEQ ID NO:192), SASAAA (SEQ ID NO:193), GAGENS (SEQ ID NO:194. In a specific embodiment, where branched-RBPs comprise such chimeric RBPs, IDs may be inserted at such insertion sites thereby acting to fuse the N-terminal domain to the C-terminal domain.


In some instances, an ID domain may be fused to either an N-terminal domain, or C-terminal domain, of a bacteriophage RBP, to provide a non-chimeric protein subunit of an engineered branched RBP. The N-terminal domain, or C-terminal domain, may be chosen depending on the desired function of the domain, e.g. host range or biological function. Where such non-chimeric protein subunits are utilized for production of an engineered branched-RBP, the ID domain may be fused at the preferred insertion sites disclosed herein, or alternatively, at insertion sites that permit maintenance of the function of the chosen domain.


In specific embodiments, the disclosure provides chimeric RBPs. Such chimeric RBPs may function as protein subunits of an engineered branched-RBP protein complex. SEQ ID NOS 2-61, 135-165, 215-242, 271, 273, 282 and 283 disclose the amino acid sequences of such chimeric RBPs and in addition, in some instances, their corresponding natural chaperone proteins (designated “AP”). Such AP proteins assist in the folding of the chimeric RBPs. In a specific embodiment, the RBP comprises the amino acid sequence of SEQ ID NO: 2, 4, 7, 9, 12, 15, 17, 20, 23, 24, 25, 27, 29, 31, 33, 35, 37, 39, 41, 42, 44, 46, 47, 48, 49, 50, 51, 52, 53, 56, 59, 135 to 144, 147, 150, 151, 154, 157, 160, 163, 215, 216, 219, 221, 223, 225, 227, 229, 232, 325, 237, 239, 241, 282 or 283. In a more specific embodiment, the RBP comprises the amino acid sequence of SEQ ID NO: 2, 4, 7, 9, 12, 15, 17, 20, 23, 24, 25, 27, 29, 31, 33, 35, 37, 39, 41, 42, 44, 46, 47, 48, 49, 50, 51, 52, 53, 56 or 59.


In one aspect, the present disclosure also provides nucleotide sequences encoding for the chimeric RBPs disclosed herein. In a specific embodiment, nucleic acids encoding such chimeric RBPs, as well as corresponding AP proteins, are depicted in SEQ ID NOS 62-120, 166-189, 206-212, 243-270, 272, 274 and 284. In a specific embodiment, the nucleic acids encoding the chimeric RBP comprise the nucleotide sequence of SEQ ID NO: 62, 64, 67, 69, 72, 75, 77, 80, 83, 84, 85, 87, 89, 91, 93, 95, 97, 99, 101, 102, 104, 106, 107, 108, 109, 110, 111, 112, 113, 116, 119, 166, 167, 168, 171, 174, 175, 178, 181, 184, 187, 206, 207, 208, 209, 210, 211, 212, 243, 244, 247, 249, 251, 253, 255, 257, 260, 263, 265, 267, 269 or 284. In a more specific embodiment, the nucleic acids encoding such chimeric RBPs comprise the nucleotide sequence of SEQ ID NO: 62, 64, 67, 69, 72, 75, 77, 80, 83, 84, 85, 87, 89, 91, 93, 95, 97, 99, 101, 102, 104, 106, 107, 108, 109, 110, 111, 112, 113, 116, or 119.


In aspects where the above described chimeric RBPs are utilized as subunits for production of branched RBP protein complexes, said chimeric RBPs may be further engineered to contain ID domains that act to mediate the association of the various engineered branched-RBP protein subunits with one another.


In one specific non-limiting aspect of the disclosure, it has been demonstrated that engineering the chimeric RBP to encode depolymerase activity can dramatically increase the delivery efficiency of the provided bacterial delivery vehicles comprising the chimeric RBP disclosed herein. In an embodiment of the disclosure, the different RBP domain of the chimeric RBP comprises depolymerase activity against an encapsulated bacterial strain. In a specific embodiment, the depolymerase is an endosialidase such as, for example, a K1F or K5 endosialidase


With regard to the engineered branched-RBPs disclosed herein, any of the chimeric RBPs disclosed herein may be used as RBP subunits, wherein said RBPs may be further engineered to contain IDs. As disclosed in the Examples section, it has been demonstrated that engineering branched-RBPs can alter the host range of the resulting delivery particle.


Nucleic acid molecules encoding the chimeric RBPs and branched-RBPs, disclosed herein are provided. Such nucleic acids may be included in vectors such as bacteriophages, plasmids, phagemids, viruses, and other vehicles which enable transfer and expression of the chimeric RBP encoding nucleic acids.


Bacterial delivery vehicles are provided which enable transfer of a nucleic acid payload, encoding a protein or nucleic acid of interest, into a desired target bacterial host cell. Such bacterial delivery vehicles are characterized by having a chimeric RBP comprising a fusion between the N-terminal domain of a RBP from a lambda-like bacteriophage, or lambda bacteriophage, and the C-terminal domain of a different RBP. In an embodiment of the invention, the bacterial delivery vehicles contain a chimeric RBP comprising a fusion between an N-terminal domain of a RBP derived from a lambda-like bacteriophage, or lambda bacteriophage, and a C-terminal domain of a different RBP wherein said N-terminal domain of the chimeric RBP is fused to said C-terminal domain of a different RBP within one of the amino acids regions selected from positions 1-150, 320-460, or 495-560 of the N-terminal domain RBP with reference to the lambda stf sequence (SEQ ID NO: 1). In one aspect, the RBP from the lambda-like bacteriophage, the lambda bacteriophage, and the different RBP contain homology in one or more of three amino acids regions ranging from positions 1-150, 320-460, and 495-560 of the N-terminal RBP with reference to the lambda bacteriophage stf sequence. In certain aspects, the homology is around 35% identity for 45 amino acids or more, around 50% identify for 30 amino acids or more, or around 90% identity for 18 amino acids or more within the one or more of three amino acids regions ranging from positions 1-150, 320-460, and 495-560 of the N-terminal RBP with reference to the lambda bacteriophage stf sequence (SEQ ID NO: 1). In one specific aspect of the invention, the different RBP domain of the chimeric receptor binding protein (RBP) is derived from a bacteriophage or a bacteriocin. In one aspect of the invention, the chimeric RBP comprises an N-terminal domain of a RBP fused to a C-terminal domain of a RBP within one of the amino acids regions selected from 80-150, 320-460, or 495-560 of the RBPs with reference to the lambda stf sequence (SEQ ID NO: 1). In another embodiment of the invention, the chimeric RBP comprises an N-terminal domain of a RBP and a C-terminal domain of a RBP fused within a site of the N-terminal RBPs having at least 80/6, preferably at least 85%, at least 90%, at least 95%, at least 98% or at least 99%, identity with a site selected from the group consisting of amino acids SAGDAS (SEQ ID NO:190), ADAKKS (SEQ ID NO:191), MDETNR (SEQ ID NO:192), SASAAA (SEQ ID NO:193), GAGENS (SEQ ID NO:194), ATLKQI (SEQ ID NO:195), IIQLED (SEQ ID NO:196), GNIIDL (SEQ ID NO:197), IATRV (SEQ ID NO:198), TPGEL (SEQ ID NO:199), GAIIN (SEQ ID NO:200), NQIID (SEQ ID NO:201), GQIVN (SEQ ID NO:202), and VDRAV (SEQ ID NO:203), preferably selected from the group consisting of amino acids SAGDAS (SEQ ID NO:190), ADAKKS (SEQ ID NO:191), MDETNR (SEQ ID NO:192), SASAAA (SEQ ID NO:193), and GAGENS (SEQ ID NO:194).


In specific embodiments, the disclosure provides a bacterial delivery vehicle comprising a chimeric RBP. SEQ ID NOS 2-61, 135-165, 215-242, 271, 273, 282 and 283 disclose the amino acid sequences of such chimeric RBPs and in addition, in some instances, their corresponding natural chaperone proteins (designated “AP”). Such AP proteins assist in the folding of the chimeric RBPs. In a specific embodiment, the RBP comprises the amino acid sequence of SEQ ID NO: 2, 4, 7, 9, 12, 15, 17, 20, 23, 24, 25, 27, 29, 31, 33, 35, 37, 39, 41, 42, 44, 46, 47, 48, 49, 50, 51, 52, 53, 56, 59, 135 to 144, 147, 150, 151, 154, 157, 160, 163, 215, 216, 219, 221, 223, 225, 227, 229, 232, 325, 237, 239, 241, 282 or 283. In a more specific embodiment, the RBP comprises the amino acid sequence of SEQ ID NO: 2, 4, 7, 9, 12, 15, 17, 20, 23, 24, 25, 27, 29, 31, 33, 35, 37, 39, 41, 42, 44, 46, 47, 48, 49, 50, 51, 52, 53, 56 or 59.


In one aspect, the present disclosure also provides nucleotide sequences encoding for the chimeric RBPs disclosed herein. In a specific embodiment, nucleic acids encoding such chimeric RBPs, as well as corresponding AP proteins, are depicted in SEQ ID NOS 62-120, 166-189, 206-212, 243-270, 272, 274 and 284. In a specific embodiment, the nucleic acids encoding the chimeric RBPs comprise the nucleotide sequence of SEQ ID NO: 62, 64, 67, 69, 72, 75, 77, 80, 83, 84, 85, 87, 89, 91, 93, 95, 97, 99, 101, 102, 104, 106, 107, 108, 109, 110, 111, 112, 113, 116, 119, 166, 167, 168, 171, 174, 175, 178, 181, 184, 187, 206, 207, 208, 209, 210, 211, 212, 243, 244, 247, 249, 251, 253, 255, 257, 260, 263, 265, 267, 269 or 284. In a more specific embodiment, the nucleic acids encoding such chimeric RBPs comprise the nucleotide sequence of SEQ ID NO: 62, 64, 67, 69, 72, 75, 77, 80, 83, 84, 85, 87, 89, 91, 93, 95, 97, 99, 101, 102, 104, 106, 107, 108, 109, 110, 111, 112, 113, 116, or 119


In other specific embodiments and to increase the delivery efficiency of the bacterial delivery vehicles disclosed herein the different RBP domain of the chimeric RBP comprises a domain having depolymerase activity against an encapsulated bacterial strain. In a specific embodiment, the depolymerase is an endosialidase, such as for example, a K1F or K5 endosialidase.


The present disclosure provides synthetic bacterial delivery vehicles that are characterized by the presence of an engineered branched receptor binding multi-subunit protein complex (“branched-RBP”). The engineered branched-RBP comprises two or more associated receptor binding proteins, derived from bacteriophages, which associate with one another based on the presence of interaction domains (IDs). The association of one subunit with another can be non-covalent or covalent. Each of the polypeptide subunits contain IDs that function as “anchors” for association of one subunit RBP with another. In specific embodiments the branched-RBP may comprise multiple RBP subunits, including, for example, two, three, four, etc. subunits.


The individual RBP subunit may bring different biological functions to the overall engineered branched-RBP. Such functions include, but are not limited to host recognition and enzymatic activity. Such enzymatic activity includes depolymerase activity.


Disclosed herein are amino acid sequences that are able to function as ID polypeptides. Such IDs, for purposes of the present invention, are those amino acid sequences that provide for non-covalent or covalent association of one receptor binding protein to another. An interaction domain is a polypeptide whose function mediates the association of one biological molecule, e.g., a protein, to another biological molecule. As a non limitating example, the biological molecule can be a protein, a part of a protein, a carbohydrate, a lipid and a nucleic acid.


The IDs may be naturally occurring bacteriophage IDs, IDs derived from non-bacteriophage polypeptides that naturally associate with one another, or recombinantly derived IDs that function to mediate non-covalent or covalent association of two proteins or polypeptide domains.


The two or more associated receptor binding proteins of the branched-RBP include, but are not limited to, chimeric receptor binding proteins (RBPs) described herein that comprise a fusion between the N-terminal domain of a RBP derived from a lambda-like, or lambda bacteriophage and the C-terminal domain of a different RBP wherein said chimeric RBP further comprises an ID domain.


With regard to IDs, such sequences are linked to receptor binding proteins (RBPs), e.g. can be fusion, can be coiled coil, can be a non-covalent interaction or can be natural sequence of the RBP. An RBP subunit of the branched-RBP may be a polypeptide that recognizes, and optionally binds and/or modifies or degrades a substrate located on the bacterial outer envelope, such as, without limitation, bacterial outer membrane, LPS, capsule, protein receptor, channel, structure such as the flagellum, pili, secretion system. The substrate can be, without limitation, any carbohydrate or modified carbohydrate, any lipid or modified lipid.


The bacterial delivery vehicles provided herein enable transfer of a nucleic acid payload, encoding a protein or nucleic acid of interest, into a desired target bacterial host cell. As used herein, the term “delivery vehicle” refers to any means that allows the transfer of a payload into a bacterium. There are several types of delivery vehicles encompassed by the present invention including, without limitation, bacteriophage scaffold, virus scaffold, chemical based delivery vehicle (e.g., cyclodextrin, calcium phosphate, cationic polymers, cationic liposomes), protein-based or peptide-based delivery vehicle, lipid-based delivery vehicle, nanoparticle-based delivery vehicles, non-chemical-based delivery vehicles (e.g., transformation, electroporation, sonoporation, optical transfection), particle-based delivery vehicles (e.g., gene gun, magnetofection, impalefection, particle bombardment, cell-penetrating peptides) or donor bacteria (conjugation). Any combination of delivery vehicles is also encompassed by the present invention. The delivery vehicle can refer to a bacteriophage derived scaffold and can be obtained from a natural, evolved or engineered capsid. In some embodiments, the delivery vehicle is the payload as bacteria are naturally competent to take up a payload from the environment on their own.


Delivery vehicles as disclosed herein include packaged phagemids, as well as bacteriophage, comprising the chimeric and/or branched-RBPs disclosed herein. The engineering of such delivery vehicles are well known to those skilled in the art. Such engineering techniques may employ production cell lines engineered to express the chimeric RBPs or branched-RBP disclosed herein. Generation of packaged phagemids and bacteriophage particles are routine techniques well-known to one skilled in the art. A satellite phage and/or helper phage may be used to promote the packaging of the payload in delivery vehicles of the present invention. Helper phages provide functions in trans and are well known to the man skilled in the art. The helper phage comprises all the genes coding for the structural and functional proteins that are indispensable for the payload to be packaged, according to the invention (i.e. the helper phage provides all the necessary gene products for the assembly of the delivery vehicle). The helper phage may contain a defective origin of replication or packaging signal, or completely lack the latter, and hence it is uncapable of self-packaging, thus only bacterial delivery particles carrying the payload or plasmid will be produced. Helper phages may be chosen so that they cannot induce lysis of the host used for the delivery particle production. One skilled in the art would understand that some bacteriophages are defective and need a helper phage for payload packaging. Thus, depending on the bacteriophage chosen in connection with the present invention to prepare the bacterial delivery particles, the person skilled in the art would know if a helper phage is required. Sequences coding for one or more proteins or regulatory processes necessary for the assembly or production of packaged payloads may be supplied in trans. For example, the RBPs of the present disclosure may be provided in a plasmid under the control of an inducible promoter or expressed constitutively. In this case, the phage wild-type sequence may or not contain a deletion of the gene or sequence supplied in trans. Additionally, chimeric or modified phage sequences encoding a new function, like a RBP, may be directly inserted into the desired position in the genome of the helper phage, hence bypassing the necessity of providing the modified sequence in trans. Methods for both supplying a sequence or protein in trans in the form of a plasmid, as well as methods to generate direct genomic insertions, modifications and mutations are well known to those skilled in the art.


As used herein, the term “payload” refers to any nucleic acid sequence or amino acid sequence, or a combination of both (such as, without limitation, peptide nucleic acid or peptide-oligonucleotide conjugate) transferred into a bacterium with a delivery vehicle. The term “payload” may also refer to a plasmid, a vector or a cargo. The payload can be a phagemid or phasmid obtained from natural, evolved or engineered bacteriophage genome. The payload can also be composed only in part of phagemid or phasmid obtained from natural, evolved or engineered bacteriophage genome.


As used herein, the term “nucleic acid” refers to a sequence of at least two nucleotides covalently linked together which can be single-stranded or double-stranded or contains portion of both single-stranded and double-stranded sequence. Nucleic acids of the present invention can be naturally occurring, recombinant or synthetic. The nucleic acid can be in the form of a circular sequence or a linear sequence or a combination of both forms. The nucleic acid can be DNA, both genomic or cDNA, or RNA or a combination of both. The nucleic acid may contain any combination of deoxyribonucleotides and ribonucleotides, and any combination of bases, including uracil, adenine, thymine, cytosine, guanine, inosine, xathanine, hypoxathanine, isocytosine, 5-hydroxymethylcytosine and isoguanine. Other examples of modified bases that can be used in the present invention are detailed in Chemical Reviews 2016, 116 (20) 12655-12687. The term “nucleic acid” also encompasses any nucleic acid analogs which may contain other backbones comprising, without limitation, phosphoramide, phosphorothioate, phosphorodithioate, O-methylphophoroamidite linkage and/or deoxyribonucleotides and ribonucleotides nucleic acids. Any combination of the above features of a nucleic acid is also encompassed by the present invention.


Origins of replication known in the art have been identified from species-specific plasmid DNAs (e.g. CoIE1, Rl, pT181, pSC101, pMB1, R6K, RK2, p15a and the like), from bacterial virus (e.g. φX174, M13, F1 and P4) and from bacterial chromosomal origins of replication (e.g. oriC). In one embodiment, the phagemid according to the disclosure comprises a bacterial origin of replication that is functional in the targeted bacteria.


Alternatively, the plasmid according to the disclosure does not comprise any functional bacterial origin of replication or contain an origin of replication that is inactive in the targeted bacteria. Thus, the plasmid of the disclosure cannot replicate by itself once it has been introduced into a bacterium by the bacterial virus particle.


In one embodiment, the origin of replication on the plasmid to be packaged is inactive in the targeted bacteria, meaning that this origin of replication is not functional in the bacteria targeted by the bacterial virus particles, thus preventing unwanted plasmid replication.


In one embodiment, the plasmid comprises a bacterial origin of replication that is functional in the bacteria used for the production of the bacterial virus particles.


Plasmid replication depends on host enzymes and on plasmid-controlled cis and trans determinants. For example, some plasmids have determinants that are recognized in almost all gram-negative bacteria and act correctly in each host during replication initiation and regulation. Other plasmids possess this ability only in some bacteria (Kues, U and Stahl, U 1989 Microbiol Rev 53:491-516).


Plasmids are replicated by three general mechanisms, namely theta type, strand displacement, and rolling circle (reviewed by Del Solar et al. 1998 Microhio and Molec Biol. Rev 62:434-464) that start at the origin of replication. These replication origins contain sites that are required for interactions of plasmid and/or host encoded proteins.


Origins of replication used on the plasmid of the disclosure may be of moderate copy number, such as colE1 on from pBR322 (15-20 copies per cell) or the R6K plasmid (15-20 copies per cell) or may be high copy number, e.g. pUC oris (500-700 copies per cell), pGEM oris (300-400 copies per cell), pTZ oris (>1000 copies per cell) or pBluescript oris (300-500 copies per cell).


In one embodiment, the bacterial origin of replication is selected in the group consisting of ColE1, pMB1 and variants (pBR322, pET, pUC, etc), p15a, Col A, ColE2, pOSAK, pSC101, R6K, IncW (pSa etc), IncFII, pT181, P1, F IncP, IncC, IncJ, IncN, IncP1, IncP4, IncQ, IncH11, RSF1010, CloDF13, NTP16, R1, f5, pPS10, pC194, pE194, BBR1, pBC1, pEP2, pWVO1, pLF1311, pAP1, pWKS1, pLS1, pLS11, pUB6060, pJD4, pIJ101, pSN22, pAMbeta1, pIP501, pIP407, ZM6100(Sa), pCU1, RA3, pMOL98, RK2/RP4/RP1/R68, pB10, R300B, pRO1614, pRO1600, pECB2, pCM1, pFA3, RepFIA, RepFIB, RepFIC, pYVE439-80, R387, phasyl, RA1, TF-FC2, pMV158 and pUB113.


More preferably, the bacterial origin of replication is a E. coli origin of replication selected in the group consisting of ColE1, pMB1 and variants (pBR322, pET, pUC, etc), p15a, ColA, ColE2, pOSAK, pSC101, R6K, IncW (pSa etc), IncFII, pT181, P1, F IncP, IncC, IncJ, IncN, IncP1, IncP4, IncQ, IncH11, RSF1010, CloDF13, NTP16, R1, f5 and pPS10.


More preferably, the bacterial origin of replication is selected in the group consisting of pC194, pE194, BBR1, pBC1, pEP2, pWVO1, pLF1311, pAP1, pWKS1, pLS1, pLS11, pUB6060, pJD4, pLJ101, pSN22, pAMbeta1, pIP501, pIP407, ZM6100(Sa), pCU1, RA3, pMOL98, RK2/RP4/RP1/R68, pB10, R300B, pRO1614, pRO1600, pECB2, pCM1, pFA3, RepFIA, RepFIB, RepFIC, pYVE439-80, R387, phasyl, RA1, TF-FC2, pMV158 and pUB113.


Even more preferably, the bacterial origin of replication is ColE1.


The delivered nucleic acid sequence according to the disclosure may comprise a phage replication origin which can initiate, with complementation of a complete phage genome, the replication of the delivered nucleic acid sequence for later encapsulation into the different capsids.


A phage origin of replication comprised in the delivered nucleic acid sequence of the disclosure can be any origin of replication found in a phage.


Preferably, the phage origin of replication can be the wild-type or non-wildtype sequence of the M13, f1, φX174, P4, lambda, P2, lambda-like, HK022, mEP237, HK97, HK629, HK630, mEP043, mEP213, mEP234, mEP390, mEP460, mEPx1, mEPx2, phi80, mEP234, T2, T4, T5, T7, RB49, phiX174, R17, PRD1 P1-like, P2-like, P22, P22-like, N15 and N15-like bacteriophages.


More preferably, the phage origin of replication is selected in the group consisting of phage origins of replication of M13, f1, φX174, P4, and lambda.


In a particular embodiment, the phage origin of replication is the lambda or P4 origin of replication.


The delivered nucleic acid of interest comprises a nucleic acid sequence under the control of a promoter. In certain embodiments of the invention, the nucleic acid of interest is selected from the group consisting of a Cas nuclease gene, a Cas9 nuclease gene, a guide RNA, a CRISPR locus, a toxin gene, a gene expressing an enzyme such as a nuclease or a kinase, a TALEN, a ZFN, a meganuclease, a recombinase, a bacterial receptor, a membrane protein, a structural protein, a secreted protein, a gene expressing resistance to an antibiotic or to a drug in general, a gene expressing a toxic protein or a toxic factor, and a gene expressing a virulence protein or a virulence factor, or any of their combination. In an embodiment of the invention, the nucleic acid payload encodes a therapeutic protein. In another embodiment, the nucleic acid payload encodes an anti-sense nucleic acid molecule. 1911 In one embodiment, the sequence of interest is a programmable nuclease circuit to be delivered to the targeted bacteria. This programmable nuclease circuit is able to mediate in vivo sequence-specific elimination of bacteria that contain a target gene of interest (e.g. a gene that is harmful to humans). Some embodiments of the present disclosure relate to engineered variants of the Type II CRISPR-Cas (Clustered Regularly Interspaced Short Palindromic Repeats-CRISPR-associated) system of Streptococcus pyogenes. Other programmable nucleases that can be used include other CRISPR-Cas systems, engineered TALEN (Transcription Activator-Like Effector Nuclease) variants, engineered zinc finger nuclease (ZFN) variants, natural, evolved or engineered meganuclease or recombinase variants, and any combination or hybrids of programmable nucleases. Thus, the engineered autonomously distributed nuclease circuits provided herein may be used to selectively cleave DNA encoding a gene of interest such as, for example, a toxin gene, a virulence factor gene, an antibiotic resistance gene, a remodeling gene or a modulatory gene (cf. WO2014124226).


Other sequences of interest, preferably programmable, can be added to the delivered nucleic acid sequence so as to be delivered to targeted bacteria. Preferably, the sequence of interest added to the delivered nucleic acid sequence leads to cell death of the targeted bacteria. For example, the nucleic acid sequence of interest added to the plasmid may encode holins or toxins.


Alternatively, the sequence of interest circuit added to the delivered nucleic acid sequence does not lead to bacteria death. For example, the sequence of interest may encode reporter genes leading to a luminescence or fluorescence signal. Alternatively, the sequence of interest may comprise proteins and enzymes achieving a useful function such as modifying the metabolism of the bacteria or the composition of its environment.


In a particular embodiment, the nucleic sequence of interest is selected in the group consisting of Cas9, a single guide RNA (sgRNA), a CRISPR locus, a gene expressing an enzyme such as a nuclease or a kinase, a TALEN, a ZFN, a meganuclease, a recombinase, a bacterial receptor, a membrane protein, a structural protein, a secreted protein, resistance to an antibiotic or to a drug in general, a gene expressing a toxic protein or a toxic factor and a gene expressing a virulence protein or a virulence factor.


In a particular embodiment, the delivered nucleic acid sequence according to the disclosure comprises a nucleic acid sequence of interest that encodes a bacteriocin, which can be a proteinaceous toxin produced by bacteria to kill or inhibit growth of other bacteria. Bacteriocins are categorized in several ways, including producing strain, common resistance mechanisms, and mechanism of killing. Such bacteriocin had been described from gram negative bacteria (e.g. microcins, colicin-like bacteriocins and tailocins) and from gram positive bacteria (e.g. Class I, Class II, Class III or Class IV bacteriocins).


In one embodiment, the delivered nucleic acid sequence according to the disclosure further comprises a sequence of interest encoding a toxin selected in the group consisting of microcins, colicin-like bacteriocins, tailocins, Class I, Class II, Class III and Class IV bacteriocins.


In a particular embodiment, the corresponding immunity polypeptide (i.e. anti-toxin) may be used to protect bacterial cells (Cotter et al., Nature Reviews Microbiology 11: 95, 2013) for delivered nucleic acid sequence production and encapsidation purpose but is absent in the pharmaceutical composition and in the targeted bacteria in which the delivered nucleic acid sequence of the disclosure is delivered.


In one aspect of the disclosure, the CRISPR system is included in the delivered nucleic acid sequence. The CRISPR system contains two distinct elements, i.e. i) an endonuclease, in this case the CRISPR associated nuclease (Cas or “CRISPR associated protein”) and ii) a guide RNA. The guide RNA is in the form of a chimeric RNA which consists of the combination of a CRISPR (RNAcr) bacterial RNA and a RNAtracr (trans-activating RNA CRISPR) (Jinek et al., 2012, Science 337: 816-821). The guide RNA combines the targeting specificity of the RNAcr corresponding to the “spacing sequences” that serve as guides to the Cas proteins, and the conformational properties of the RNAtracr in a single transcript. When the guide RNA and the Cas protein are expressed simultaneously in the cell, the target genomic sequence can be permanently modified or interrupted. The modification is advantageously guided by a repair matrix. In general, the CRISPR system includes two main classes depending on the nuclease mechanism of action. Class 1 is made of multi-subunit effector complexes and includes type I, III and IV. Class 2 is made of single-unit effector modules, like Cas9 nuclease, and includes type II (II-A, II-B, II-C, II-C variant), V (V-A, V-B, V-C, V-D, V-E, V-U1, V-U2, V-U3, V-U4, V-U5) and VI (VI-A, VI-B1, VI-B2, VI-C, VI-D)


The sequence of interest according to the present disclosure comprises a nucleic acid sequence encoding Cas protein. A variety of CRISPR enzymes are available for use as a sequence of interest on the plasmid. In some embodiments, the CRISPR enzyme is a Type II CRISPR enzyme. In some embodiments, the CRISPR enzyme catalyzes DNA cleavage. In some other embodiments, the CRISPR enzyme catalyzes RNA cleavage. In one embodiment, the CRISPR enzymes may be coupled to a sgRNA. In certain embodiments, the sgRNA targets a gene selected in the group consisting of an antibiotic resistance gene, virulence protein or factor gene, toxin protein or factor gene, a bacterial receptor gene, a membrane protein gene, a structural protein gene, a secreted protein gene and a gene expressing resistance to a drug in general.


Non-limiting examples of Cas proteins as part of a multi-subunit effector or as a single-unit effector include Cas1, Cas1B, Cas2, Cas3, Cas4, Cas5, Cas6, Cas7, Cas8, Cas9 (also known as Csn1 and Csx12), Cas10, Cas11 (SS), Cas12a (Cpf1), Cas12b (C2cl), Cas12c (C2c3), Cas12d (CasY), Cas12e (CasX), C2c4, C2c8, C2c5, C2c10, C2c9, Cas13a (C2c2), Cas13b (C2c6), Cas13c (C2c7), Cas13d, Csa5, Csc1, Csc2, Cse1, Cse2, Csy1, Csy2, Csy3, Csf1, Csf2, Csf3, Csf4, Csm2, Csm3, Csm4, Csm5, Csm6, Cmr1, Cmr3, Cmr4, Cmr5, Cmr6, Csn2, Csb1, Csb2, Csb3, Csx17, Csx14, Csx10, Csx16, CsaX, Csx13, Csx1, Csx15, SdCpf1, CmtCpf1, TsCpf1, CmaCpf1, PcCpf1, ErCpf1, FbCpf1, UbcCpf1, AsCpf1, LbCpf1, homologues thereof, orthologues thereof, variants thereof, or modified versions thereof. In some embodiments, the CRISPR enzyme cleaves both strands of the target nucleic acid at the Protospacer Adjacent Motif (PAM) site.


In a particular embodiment, the CRISPR enzyme is any Cas9 protein, for instance any naturally-occurring bacterial Cas9 as well as any variants, homologs or orthologs thereof.


By “Cas9” is meant a protein Cas9 (also called Csn1 or Csx12) or a functional protein, peptide or polypeptide fragment thereof, i.e. capable of interacting with the guide RNA(s) and of exerting the enzymatic activity (nuclease) which allows it to perform the double-strand cleavage of the DNA of the target genome. “Cas9” can thus denote a modified protein, for example truncated to remove domains of the protein that are not essential for the predefined functions of the protein, in particular the domains that are not necessary for interaction with the gRNA(s).


The sequence encoding Cas9 (the entire protein or a fragment thereof) as used in the context of the disclosure can be obtained from any known Cas9 protein (Fonfara et al., Nucleic Acids Res 42 (4), 2014; Koonin et al., Nat Rev Microbiol 15(3), 2017). Examples of Cas9 proteins useful in the present disclosure include, but are not limited to, Cas9 proteins of Streptococcus pyogenes (SpCas9), Streptococcus thermophilus (St1Cas9, St3Cas9), Streptococcus mutans, Staphylococcus aureus (SaCas9), Campylobacter jejuni (CjCas9), Francisella novicida (FnCas9) and Neisseria meningitides (NmCas9).


The sequence encoding Cpf1 (Cas12a) (the entire protein or a fragment thereof) as used in the context of the disclosure can be obtained from any known Cpf1 (Cas12a) protein (Koonin et al., Nat Rev Microbiol 15(3), 2017). Examples of Cpf1(Cas12a) proteins useful in the present disclosure include, but are not limited to, Cpf1(Cas12a) proteins of Acidaminococcus sp, Lachnospiraceae bacteriu and Francisella novicida.


The sequence encoding Cas13a (the entire protein or a fragment thereof) can be obtained from any known Cas13a (C2c2) protein (Abudayyeh et al., 2017, Nature 550: 280-284). Examples of Cas13a (C2c2) proteins useful in the present disclosure include, but are not limited to, Cas13a (C2c2) proteins of Leptotrichia wadei (LwaCas13a).


The sequence encoding Cas13d (the entire protein or a fragment thereof) can be obtained from any known Cas13d protein (Yan et al., 2018, Mol Cell 70: 327-339). Examples of Cas13d proteins useful in the present disclosure include, but are not limited to, Cas13d proteins of Eubacterium siraeum and Ruminococcus sp.


In a particular embodiment, the nucleic sequence of interest is a CRISPR/Cas9 system for the reduction of gene expression or inactivation of a gene selected in the group consisting of an antibiotic resistance gene, virulence factor or protein gene, toxin factor or protein gene, a gene expressing a bacterial receptor, a membrane protein, a structural protein, a secreted protein, and a gene expressing resistance to a drug in general.


In one embodiment, the CRISPR system is used to target and inactivate a virulence factor. A virulence factor can be any substance produced by a pathogen that alter host-pathogen interaction by increasing the degree of damage done to the host. Virulence factors are used by pathogens in many ways, including, for example, in cell adhesion or colonization of a niche in the host, to evade the host's immune response, to facilitate entry to and egress from host cells, to obtain nutrition from the host, or to inhibit other physiological processes in the host. Virulence factors can include enzymes, endotoxins, adhesion factors, motility factors, factors involved in complement evasion, and factors that promote biofilm formation. For example, such targeted virulence factor gene can be E. coli virulence factor gene such as, without limitation, EHEC-HlyA, Stx1 (VT1), Stx2 (VT2), Stx2a (VT2a), Stx2b (VT2b), Stx2c (VT2c), Stx2d (VT2d), Stx2e (VT2e) and Stx2f (VT2f), Stx2h (VT2h), fimA, fimF, fimH, neuC, kpsE, sfa, foc, iroN, aer, iha, papC, papGI, papGII, papGIII, hlyC, cnf1, hra, sat, ireA, usp ompT, ibeA, malX, fyuA, irp2, traT, afaD, ipaH, eltB, estA, bfpA, eaeA, espA, aaiC, aatA, TEM, CTX, SHV, csgA, csgB, csgC, csgD, csgE, csgF, csgG, csgH, T1SS, T2SS, T3SS, T4SS, T5SS, T6SS (secretion systems). For example, such targeted virulence factor gene can be Shigella dysenteriae virulence factor gene such as, without limitation, stx1 and stx2. For example, such targeted virulence factor gene can be Yersinia pestis virulence factor gene such as, without limitation, yscF (plasmid-borne (pCDl) T3SS external needle subunit). For example, such targeted virulence factor gene can be Francisella tularensis virulence factor gene such as, without limitation, fslA. For example, such targeted virulence factor gene can be Bacillus anthracis virulence factor gene such as, without limitation, pag (Anthrax toxin, cell-binding protective antigen). For example, such targeted virulence factor gene can be Vibrio cholera virulence factor gene such as, without limitation, ctxA and ctxB (cholera toxin), tcpA (toxin co-regulated pilus), and toxT (master virulence regulator). For example, such targeted virulence factor gene can be Pseudomonas aeruginosa virulence factor genes such as, without limitation, pyoverdine (e.g., sigma factor pvdS, biosynthetic genes pvdL, pvdl, pvdJ, pvdH, pvdA, pvdF, pvdQ, pvdN, pvdM, pvdO, pvdP, transporter genes pvdE, pvdR, pvdT, opmQ), siderophore pyochelin (e.g., pchD, pchC, pchB, pchA, pchE, pchF and pchG, and toxins (e.g., exoU, exoS and exoT). For example, such targeted virulence factor gene can be Klebsiella pneumoniae virulence factor genes such as, without limitation, fimA (adherence, type I fimbriae major subunit), and cps (capsular polysaccharide). For example, such targeted virulence factor gene can be Acinetobacter baumannii virulence factor genes such as, without limitation, ptk (capsule polymerization) and epsA (assembly). For example, such targeted virulence factor gene can be Salmonella enterica Typhi virulence factor genes such as, without limitation, MIA (invasion, SPI-1 regulator), ssrB (SPI-2 regulator), and those associated with bile tolerance, including efflux pump genes acrA, acrB and toiC. For example, such targeted virulence factor gene can be Fusobacterium nucleatum virulence factor genes such as, without limitation, FadA and TIGIT. For example, such targeted virulence factor gene can be Bacteroides fragilis virulence factor genes such as, without limitation, bft.


In another embodiment, the CRISPR/Cas9 system is used to target and inactivate an antibiotic resistance gene such as, without limitation, GyrB, ParE, ParY, AAC(1), AAC(2′), AAC(3), AAC(6′), ANT(2″), ANT(3″), ANT(4′), ANT(6), ANT(9), APH(2″), APH(3″), APH(3′), APH(4), APH(6), APH(7″), APH(9), ArmA, RmtA, RmtB, RmtC, Sgm, AER, BLA1, CTX-M, KPC, SHV, TEM, BlaB, CcrA, IMP, NDM, VIM, ACT, AmpC, CMY, LAT, PDC, OXA β-lactamase, mecA, Omp36, OmpF, PIB, bla (blaI, blaR1) and mec (mecl, mecR1) operons, Chloramphenicol acetyltransferase (CAT), Chloramphenicol phosphotransferase, Ethambutol-resistant arabinosyltransferase (EmbB), MupA, MupB, Integral membrane protein MprF, Cfr 23S rRNA methyltransferase, Rifampin ADP-ribosyltransferase (Arr), Rifampin glycosyltransferase, Rifampin monooxygenase, Rifampin phosphotransferase, DnaA, RbpA, Rifampin-resistant beta-subunit of RNA polymerase (RpoB), Erm 23S rRNA methyltransferases, Lsa, MsrA, Vga, VgaB, Streptogramin Vgb lyase, Vat acetyltransferase, Fluoroquinolone acetyltransferase, Fluoroquinolone-resistant DNA topoisomerases, Fluoroquinolone-resistant GyrA, GyrB, ParC, Quinolone resistance protein (Qnr), FomA, FomB, FosC, FosA, FosB, FosX, VanA, VanB, VanD, VanR, VanS, Lincosamide nucleotidyltransferase (Lin), EreA, EreB, GimA, Mgt, Ole, Macrolide phosphotransferases (MPH), MefA, MefE, Mel, Streptothricin acetyltransferase (sat), Sul1, Sul2, Sul3, sulfonamide-resistant FolP, Tetracycline inactivation enzyme TetX, TetA, TetB, TetC, Tet30, Tet31, TetM, TetO, TetQ, Tet32, Tet36, MacAB-TolC, MsbA, MsrA, VgaB, EmrD, EmrAB-TolC, NorB, GepA, MepA, AdeABC, AcrD, MexAB-OprM, mtrCDE, EmrE, adeR, acrR, baeSR, mexR, phoPQ, mtrR, or any antibiotic resistance gene described in the Comprehensive Antibiotic Resistance Database (CARD https://card.mcmaster.ca/).


In another embodiment, the CRISPR/Cas9 system is used to target and inactivate a bacterial toxin gene. Bacterial toxin can be classified as either exotoxins or endotoxins. Exotoxins are generated and actively secreted; endotoxins remain part of the bacteria. The response to a bacterial toxin can involve severe inflammation and can lead to sepsis. Such toxin can be for example Botulinum neurotoxin, Tetanus toxin, Staphylococus toxins, Diphteria toxin, Anthrax toxin, Alpha toxin, Pertussis toxin, Shiga toxin, Heat-stable enterotoxin (E. coli ST), colibactin, BFT (B. fragilis toxin) or any toxin described in Henkel et al., (Toxins from Bacteria in EXS. 2010; 100: 1-29).


The bacteria targeted by bacterial delivery vehicles disclosed herein can be any bacteria present in a mammal organism. In a certain aspect, the bacteria are targeted through interaction of the chimeric RBPs and/or the branched-RBPs expressed by the delivery vehicles with the bacterial cell. It can be any commensal, symbiotic or pathogenic bacteria of the microbiota or microbiome.


A microbiome may comprise of a variety of endogenous bacterial species, any of which may be targeted in accordance with the present disclosure. In some embodiments, the genus and/or species of targeted endogenous bacterial cells may depend on the type of bacteriophages being used for preparing the bacterial delivery vehicles. For example, some bacteriophages exhibit tropism for, or preferentially target, specific host species of bacteria. Other bacteriophages do not exhibit such tropism and may be used to target a number of different genus and/or species of endogenous bacterial cells.


Examples of bacterial cells include, without limitation, cells from bacteria of the genus Yersinia spp., Escherichia spp., Klebsiella spp., Acinetobacter spp., Bordetella spp., Neisseria spp., Aeromonas spp., Franciesella spp., Corynebacterium spp., Citrobacter spp., Chlamydia spp., Hemophilus spp., Brucella spp., Mycobacterium spp., Legionella spp., Rhodococcus spp., Pseudomonas spp., Helicobacter spp., Vibrio spp., Bacillus spp., Erysipelothrix spp., Salmonella spp., Streptomyces spp., Streptococcus spp., Staphylococcus spp., Bacteroides spp., Prevotella spp., Clostridium spp., Bifidobacterium spp., Clostridium spp., Brevibacterium spp., Lactococcus spp., Leuconostoc spp., Actinobacillus spp., Selnomonas spp., Shigella spp., Zymonas spp., Mycoplasma spp., Treponema spp., Leuconostoc spp., Corynebacterium spp., Enterococcus spp., Enterobacter spp., Pyrococcus spp., Serratia spp., Morganella spp., Parvimonas spp., Fusobacterium spp., Actinomyces spp., Porphyromonas spp., Micrococcus spp., Bartonella spp., Borrelia spp., Brucelia spp., Campylobacter spp., Chlamydophilia spp., Cutibacterium (formerly Propionibacterium) spp., Ehrlichia spp., Haemophilus spp., Leptospira spp., Listeria spp., Mycoplasma spp., Nocardia spp., Rickettsia spp., Ureaplasma spp., and Lactobacillus spp, and a mixture thereof.


Thus, bacterial delivery vehicles may target (e.g., specifically target) a bacterial cell from any one or more of the foregoing genus of bacteria to specifically deliver the payload of interest according to the disclosure.


Preferably, the targeted bacteria can be selected from the group consisting of Yersinia spp., Escherichia spp., Klebsiella spp., Acinetobacter spp., Pseudomonas spp., Helicobacter spp., Vibrio spp, Salmonella spp., Streptococcus spp., Staphylococcus spp., Bacteroides spp., Clostridium spp., Shigella spp., Enterococcus spp., Enterobacter spp., and Listeria spp.


In some embodiments, bacterial cells of the present disclosure are anaerobic bacterial cells (e.g., cells that do not require oxygen for growth). Anaerobic bacterial cells include facultative anaerobic cells such as but not limited to Escherichia coli, Shewanella oneidensis and Listeria. Anaerobic bacterial cells also include obligate anaerobic cells such as, for example, Bacteroides and Clostridium species. In humans, anaerobic bacteria are most commonly found in the gastrointestinal tract. In some particular embodiment, the targeted bacteria are thus bacteria most commonly found in the gastrointestinal tract. Bacteriophages used for preparing the bacterial virus particles, and then the bacterial virus particles, may target (e.g., to specifically target) anaerobic bacterial cells according to their specific spectra known by the person skilled in the art to specifically deliver the plasmid.


In some embodiments, the targeted bacterial cells are, without limitation, Bacteroides thetaiolaomicron, Bacteroides fragilis, Bacteroides distasonis, Bacteroides vulgatus, Clostridium leptum, Clostridium coccoides, Staphylococcus aureus, Bacillus subtilis, Clostridium butyricum, Brevibacterium lactofermentum. Streptococcus agalactiae, Lactococcus lactis, Leuconostoc lactis, Actinobacillus actinobycetemcomitans, cyanobacteria, Escherichia coli, Helicobacter pylori, Sehnomonas ruminatiurn, Shigella sonnei. Zymomonas mobilis, Mycoplasma mycoides, Ireponema denticola, Bacillus thuringiensis, Staphilococcus lugdunensis, Leuconostoc oenos, Corynebacterium xerosis, Lactobacillus plantarum, Lactobacillus rhamnosus, Lactobacillus casei. Lactobacillus acidophilus. Enterococcus faecalis, Bacillus coagulans, Bacillus cereus, Bacillus popillae, Synechocystis strain PCC6803, Bacillus liquefaciens, Pyrococcus abyssi, Selenomonas nominantium, Lactobacillus hilgardii. Streptococcus ferus, Lactobacillus pentosus, Bacteroides fragilis, Staphylococcus epidermidis, Streptomyces phaechromogenes, Streptomyces ghanaenis, Klebsiella pneumoniae. Enterobacter cloacae, Enterobacter aerogenes, Serratia marcescens, Morganella morganii, Citrobacter freundii, Pseudononas aerigunosa, Parvinonas micra, Prevotella intermedia, Fusobacterium nucleatum. Prevotella nigrescens, Acitinomyces israelii, Porphyromonas endodontalis, Porphyromonas gingivalis Micrococcus luteus, Bacillus megaterium, Aeromonas hydrophila, Aeromonas caviae, Bacillus anthracis, Barlonella henselae, Bartonella Quintana. Bordetella pertussis, Borrelia burgdorferi, Borrelia garinii, Borrelia afzelii, Borrelia recurrentis, Brucella abortus. Brucella canis, Brucella melitensis, Brucella suis, Campylobacter jejuni, Campylobacter coli, Campylobacter fetus, Chlamydia pneumoniae, Chlamydia trachomatis, Chlamydophila psittaci. Clostridium botulinum, Clostridium difficile, Clostridium perfringens. Clostridium tetani, (Corynebacterium diphtheria, Cutibacterium acnes (formerly Propionibacterium acnes), Ehrlichia canis, Ehrlichia chaffeensis. Enterococcus faecium, Francisella tularensis, Haemophilus influenza, Legionella pneumophila, Leptospira interrogans, Leptospira santarosai, Leptospira welii, Leptospira noguchii, Listeria monocylogenes, Mycobacterium leprae, Mycobacterium tuberculosis, Mycohacterium ulcerans, Mycoplasma pneumonia, Neisseria gonorrhoeae, Neisseria meningitides, Nocardia asteroids, Rickettsia rickettsia, Salmonella enteritidis, Salmonella typhi, Salmonella paratyphi, Salmonella typhimurium, Shigella flexnerii, Shigella dysenteriae, Staphylococcus saprophyticus, Streptococcus pneumoniae, Streptococcus pyogenes, Streptococcus viridans, Treponema pallidum, Ureaplasma urealyticum, Vibrio cholera, Vibrio parahaemolyticus, Yersinia pestis, Yersinia enterocolitica, Yersinia pseudotuberculosis, Actinobacter baumanii, Pseudomonas aerigunosa, and a mixture thereof, preferably the bacteria of interest are selected from the group consisting of Escherichia coli. Enterococcus faecium, Staphylococcus aureus, Klebsiella pneumoniae, Acinetobacter baumanii, Pseudomonas aeruginosa, Enterobacter cloacae, and Enterobacter aerogenes, and a mixture thereof.


In one embodiment, the targeted bacteria are Escherichia coli.


Thus, bacteriophages used for preparing the bacterial delivery vehicles, and then the bacterial delivery vehicles, may target (e.g., specifically target) a bacterial cell from any one or more of the foregoing genus and/or species of bacteria to specifically deliver the payload of interest.


In one embodiment, the targeted bacteria are pathogenic bacteria. The targeted bacteria can be virulent bacteria.


The targeted bacteria can be antibacterial resistance bacteria, preferably selected from the group consisting of extended-spectrum beta-lactamase-producing (ESBL) Escherichia coli, ESBL Klebsiella pneumoniae, vancomycin-resistant Enterococcus (VRE), methicillin-resistant Staphylococcus aureus (MRSA), multidrug-resistant (MDR) Acinetobacter baumannii, MDR Enterobacter spp., and a combination thereof. Preferably, the targeted bacteria can be selected from the group consisting of extended-spectrum beta-lactamase-producing (ESBL) Escherichia coli strains.


Alternatively, the targeted bacterium can be a bacterium of the microbiome of a given species, preferably a bacterium of the human microbiota.


The present disclosure is directed to bacterial delivery vehicle containing the payload as described herein. The bacterial delivery vehicles are prepared from bacterial virus. The bacterial delivery vehicles are chosen in order to be able to introduce the payload into the targeted bacteria.


Bacterial viruses, from which the bacterial delivery vehicles having chimeric receptor binding proteins and/or branched-RBPs may be derived, are preferably bacteriophages. Optionally, the bacteriophage is selected from the Order Caudovirales consisting of, based on the taxonomy of Krupovic et al, 2015, Arch Virol, 161(1): 233-247:


Bacteriophages may be selected from the family Myoviridae (such as, without limitation, genus Cp220virus, Cp8virus, Ea214virus, Felixolvirus, Mooglevirus, Suspvirus, Hp1virus, P2virus, Kayvirus, P100virus, Silviavirus, Spolvirus, Tsarbombavirus, Twortvirus, Cc31virus, Jd18virus, Js98virus, Kp15virus, Moonvirus, Rb49virus, Rb69virus, S16virus, Schizot4virus, Sp18virus, T4virus, Cr3virus, Selvirus, V5virus, Abouovirus, Agatevirus, Agrican357virus, Ap22virus, Arvlvirus, B4virus, Bastillevirus, Bc431virus, Bcep78virus, Bcepmuvirus, Biquartavirus, Bxzlvirus, Cd119virus, Cp51virus, Cvm10virus, Eah2virus, Elvirus, Hapunavirus, Jimmervirus, Kpp10virus, M12virus, Machinavirus, Marthavirus, Msw3virus, Muvirus, Myohalovirus, Nitivirus, Plvirus, Pakpunavirus, Pbunavirus, Phikzvirus, Rheph4virus, Rsl2virus, Rslunavirus, Secunda5virus, Seplvirus, Spn3virus, Svunavirus, Tglvirus, Vhmlvirus and Wphvirus)


Bacteriophages may be selected from the family Podoviridae (such as, without limitation, genus Fri1virus, Kp32virus, Kp34virus, Phikmvvirus, Pradovirus, Sp6virus, T7virus, Cplvirus, P68virus, Phi29virus, Nona33virus, Pocjvirus, Tl2011virus, Bcep22virus, Bpplvirus, Cba41virus, Dfl12virus, Ea92virus, Epsilon15virus, F116virus, G7cvirus, Jwalphavirus, Kflvirus, Kpp25virus, Litivirus, Luz24virus, Luz7virus, N4virus, Nonanavirus, P22virus, Pagevirus, Phieco32virus, Prtbvirus, Sp58virus, Una961virus and Vp5virus)

    • Bacteriophages may be selected from the family Siphoviridae (such as, without limitation, genus Camvirus, Likavirus, R4virus, Acadianvirus, Coopervirus, Pglvirus, Pipefishvirus, Rosebushvirus, Brujitavirus, Che9cvirus, Hawkeyevirus, Plotvirus, Jerseyvirus, Klgvirus, Sp31virus, Lmdlvirus, Una4virus, Bongovirus, Reyvirus, Buttersvirus, Charlievirus, Redivirus, Baxtervirus, Nymphadoravirus, Bignuzvirus, Fishburnevirus, Phayoncevirus, Kp36virus, Roguelvirus, Rtpvirus, Tlvirus, Tlsvirus, Ab18virus, Amigovirus, Anatolevirus, Andromedavirus, Attisvirus, Barnyardvirus, Bernal13virus, Biseptimavirus, Bronvirus, C2virus, C5virus, Cba181virus, Cbastvirus, Cecivirus, Che8virus, Chivirus, Cjwlvirus, Corndogvirus, Cronusvirus, D3112virus, D3virus, Decurrovirus, Demosthenesvirus, Doucettevirus, E125virus, Eiauvirus, Ff47virus, Gaiavirus, Gilesvirus, Gordonvirus, Gordtnkvirus, Harrisonvirus, Hk578virus, Hk97virus, Jenstvirus, Jwxvirus, Kelleziovirus, Korravirus, L5virus, lambdavirus, Laroyevirus, Liefievirus, Marvinvirus, Mudcatvirus, N15virus, Nonagvirus, Nplvirus, Omegavirus, P12002virus, P12024virus, P23virus, P70virus, Pa6virus, Pamx74virus, Patiencevirus, Pbilvirus, Pepy6virus, Pfrlvirus, Phic31virus, Phicbkvirus, Phietavirus, Phifelvirus, Phijllvirus, Pis4avirus, Psavirus, Psimunavirus, Rdjlvirus, Rer2virus, Sap6virus, Send513virus, Septima3virus, Seuratvirus, Sextaecvirus, Sfi11virus, Sfi21dt1virus, Sitaravirus, Sklvirus, Slashvirus, Smoothievirus, Soupsvirus, Spbetavirus, Ssp2virus, T5virus, Tankvirus, Tin2virus, Titanvirus, Tm4virus, Tp21virus, Tp84virus, Triavirus, Trigintaduovirus, Vegasvirus, Vendettavirus, Wbetavirus, Wildcatvirus, Wizardvirus, Woesvirus, Xp10virus, Ydnl2virus and Yuavirus)


Bacteriophages may be selected from the family Ackermannviridae (such as, without limitation, genus Ag3virus, Limestonevirus, Cba120virus and Vi1virus)


Optionally, the bacteriophage is not part of the order Caudovirales but from families with unassigned order such as, without limitation, family Tectiviridae (such as genus Alphatectivirus, Betatectivirus), family Corticoviridae (such as genus Corticovirus), family Inoviridae (such as genus Fibrovirus, Habenivirus, Inovirus, Lineavirus, Plectrovirus, Saetivirus, Vespertiliovirus), family Cystoviridae (such as genus Cystovirus), family Leviviridae (such as genus Allolevivirus, Levivirus), family Microviridae (such as genus Alpha3microvirus, G4microvirus, Phixl74microvirus, Bdellomicrovirus, Chlamydiamicrovirus, Spiromicrovirus) and family Plasmaviridae (such as genus Plasmavirus).


Optionally, the bacteriophage is targeting Archea not part of the Order Caudovirales but from families with Unassigned order such as, without limitation, Ampullaviridae, FuselloViridae, Globuloviridae, Guttaviridae, Lipothrixviridae, Pleolipoviridae, Rudiviridae, Salterprovirus and Bicaudaviridae.


A non-exhaustive listing of bacterial genera and their known host-specific bacteria viruses is presented in the following paragraphs. The chimeric RBPs and/or the branched RBPs and the bacterial delivery vehicles disclosed herein may be engineered, as non-limiting examples, from the following phages. Synonyms and spelling variants are indicated in parentheses. Homonyms are repeated as often as they occur (e.g., D, D, d). Unnamed phages are indicated by “NN” beside their genus and their numbers are given in parentheses.


Bacteria of the genus Actinomyces can be infected by the following phages: Av-I, Av-2, Av-3, BF307, CTl, CT2, CT3, CT4, CT6, CT7, CT8 and 1281.


Bacteria of the genus Aeromonas can be infected by the following phages: AA-I, Aeh2, N, PMl, TP446, 3, 4, 11, 13, 29, 31, 32, 37, 43, 43-10T, 51, 54, 55R.1, 56, 56RR2, 57, 58, 59.1, 60, 63, Aehl, F, PM2, 1, 25, 31, 40RR2.8t, (syn=44R), (syn=44RR2.8t), 65, PM3, PM4, PM5 and PM6.


Bacteria of the genus Bacillus can be infected by the following phages: A, aizl, A1-K-I, B, BCJA1, BCl, BC2, BLLI, BLl, BP142, BSLl, BSL2, BSl, BS3, BS8, BS15, BS18, BS22, BS26, BS28, BS31, BS104, BS105, BS106, BTB, B1715V1, C, CK-I, Coll, Corl, CP-53, CS-I, CSi, D, D, D, D5, entl, FP8, FP9, FSi, FS2, FS3, FS5, FS8, FS9, G, GH8, GT8, GV-I, GV-2, GT-4, g3, gl2, gl3, gl4, gl6, gl7, g21, g23, g24, g29, H2, kenl, KK-88, Kuml, Kyul, J7W-1, LP52, (syn=LP-52), L7, Mexl, MJ-I, mor2, MP-7, MIPlO, MP12, MPI4, MP15, Neol, No 2, N5, N6P, PBCI, PBLA, PBPl, P2, S-a, SF2, SF6, Shal, Sill, SP02, (syn=ΦSPP1), SPP, STI, STi, SU-II, t, TbI, Tb2, Tb5, TbIO, Tb26, Tb51, Tb53, Tb55, Tb77, Tb97, Tb99, Tb560, Tb595, Td8, Td6, Tdl5, TgI, Tg4, Tg6, Tg7, Tg9, TgIO, TgIl, Tgl3, Tgl5, Tg21, Tinl, Tin7, Tin8, Tinl3, Tm3, Tocl, Togl, toll, TP-1, TP-10vir, TP-15c, TP-16c, TP-17c, TP-19, TP35, TP51, TP-84, Tt4, Tt6, type A, type B, type C, type D, type E, Tφ3, VA-9, W, wx23, wx26, Yunl, α, γ, pl 1, φmed-2, φT, φμ-4, φ3T, φ75, φlO5, (syn=φlO5), IA, IB, 1-97A, 1-97B, 2, 2, 3, 3, 3, 5, 12, 14, 20, 30, 35, 36, 37, 38, 41C, 51, 63, 64, 138D, I, II, IV, NN-Bacillus (13), alel, ARl, AR2, AR3, AR7, AR9, Bace-11, (syn=11), Bastille, BLI, BL2, BL3, BL4, BL5, BL6, BL8, BL9, BP124, BS28, BS80, Ch, CP-51, CP-54, D-5, darl, denl, DP-7, entl, FoSi, FoS2, FS4, FS6, FS7, G, gall, gamma, GEl, GF-2, GSi, GT-I, GT-2, GT-3, GT-4, GT-5, GT-6, GT-7, GV-6, gl5, 19, 110, ISi, K, MP9, MP13, MP21, MP23, MP24, MP28, MP29, MP30, MP32, MP34, MP36, MP37, MP39, MP40, MP41, MP43, MP44, MP45, MP47, MP50, NLP-I, No.1, N17, N19, PBSI, PKl, PMB1, PMB12, PMJl, S, SPOl, SP3, SP5, SP6, SP7, SP8, SP9, SPlO, SP-15, SP50, (syn=SP-50), SP82, SST, subl, SW, Tg8, Tgl2, Tgl3, Tgl4, thul, thuA, thuS, Tin4, Tin23, TP-13, TP33, TP50, TSP-I, type V, type VI, V, Vx, β22, φe, φNR2, φ25, φ63, 1, 1, 2, 2C, 3NT, 4, 5, 6, 7, 8, 9, 10, 12, 12, 17, 18, 19, 21, 138, III, 4 (B. megateriwn), 4 (B. sphaericus), AR13, BPP-IO, BS32, BS107, Bl, B2, GA-I, GP-IO, GV-3, GV-5, g8, MP20, MP27, MP49, Nf, PP5, PP6, SF5, Tgl8, TP-I, Versailles, φl5, φ29, 1-97, 837/IV, mi-Bacillus (1), BatlO, BSLlO, BSLI1, BS6, BS11, BS16, BS23, BSlOl, BS102, gl8, morl, PBLl, SN45, thu2, thu3, TmI, Tm2, TP-20, TP21, TP52, type F, type G, type IV, HN-BacMus (3), BLE, (syn=θc), BS2, BS4, BS5, BS7, BlO, B12, BS20, BS21, F, MJ-4, PBA12, AP50, AP50-04, AP50-11, AP50-23, AP50-26, AP50-27 and Bam35. The following Bacillus-specific phages are defective: DLP10716, DLP-11946, DPB5, DPB12, DPB21, DPB22, DPB23, GA-2, M, No. IM, PBLB, PBSH, PBSV, PBSW, PBSX, PBSY, PBSZ, phi, SPa, type 1 and μ.


Bacteria of the genus Bacteroides can be infected by the following phages: ad I2, Baf-44, Baf-48B, Baf-64, Bf-1, Bf-52, B40-8, Fl, βl, φAl, φBrOl, φBrO2, 11, 67.1, 67.3, 68.1, mt-Bacteroides (3), Bf42, Bf71, HN-Bdellovibrio (1) and BF-41.


Bacteria of the genus Bordetella can be infected by the following phages: 134 and NN-Bordetella (3).


Bacteria of the genus Borrellia can be infected by the following phages: NN-Borrelia (1) and NN-Borrelia (2).


Bacteria of the genus Brucella can be infected by the following phages: A422, Bk, (syn=Berkeley), BM29, FOi, (syn=FOI), (syn=FQI), D, FP2, (syn=FP2), (syn=FD2), Fz, (syn=Fz75/13), (syn=Firenze 75/13), (syn=Fi), Fi, (syn=F1), Fim, (syn=FIM), (syn=Fim), FiU, (syn=FlU), (syn=FiU), F2, (syn=F2), F3, (syn=F3), F4, (syn=F4), F5, (syn=F5), F6, F7, (syn=F7), F25, (syn=F25), (syn=£25), F25U, (syn=F25u), (syn=F25U), (syn=F25V), F44, (syn-F44), F45, (syn=F45), F48, (syn=F48), I, Im, M, MC/75, M51, (syn=M85), P, (syn=D), S708, R, Tb, (syn=TB), (syn=Tbilisi), W, (syn=Wb), (syn=Weybridge), X, 3, 6, 7, 10/1, (syn=10), (syn=F8), (syn=F8), 12m, 24/11, (syn=24), (syn=F9), (syn=F9), 45/111, (syn=45), 75, 84, 212/XV, (syn=212), (syn=Fi0), (syn=FlO), 371/XXIX, (syn=371), (syn=Fn), (syn=Fl1) and 513.


Bacteria of the genus Burkholderia can be infected by the following phages: CP75, NN-Burkholderia (1) and 42.


Bacteria of the genus Campylobacter can be infected by the following phages: C type, NTCC12669, NTCC12670, NTCC12671, NTCC12672, NTCC12673, NTCC12674, NTCC12675, NTCC12676, NTCC12677, NTCC12678, NTCC12679, NTCC12680, NTCC12681, NTCC12682, NTCC12683, NTCC12684, 32f, 111c, 191, NN-Campylobacter (2), Vfi-6, (syn=V19), VfV-3, V2, V3, V8, V16, (syn=Vfi-1), V19, V20(V45), V45, (syn=V-45) and NN-Campylobacter (1).


Bacteria of the genus Chlamydia can be infected by the following phage: Chpl.


Bacteria of the genus Closiridium can be infected by the following phages: CAKl, CA5, Ca7, CEβ, (syn=1C), CEγ, Cidl, c-n71, c-203 Tox−, DEβ, (syn=ID), (syn=IDtOX+), HM3, KMl, KT, Ms, NAl, (syn=Naltox+), PA1350e, Pfó, PL73, PL78, PL81, Pl, P50, P5771, P19402, ICt0X+, 2Ct0X\2D3 (syn=2DtOX+), 3C, (syn=3Ctox+), 4C, (syn=4Ct0X+), 56, III-1, NN-Clostridium (61), NBlt0X+, αl, CAl, HMT, HM2, PFl5 P-23, P-46, Q-05, Q-oe, Q-16, Q-21, Q-26, Q-40, Q-46, S111, SA02, WA01, WA03, Wm, W523, 80, C, CA2, CA3, CPTI, CPT4, cl, c4, c5, HM7, H11/A1, H18/Ax, FWS23, Hi58ZA1, K2ZA1, K21ZS23, ML, NA2t0X; Pf2, Pf3, Pf4, S9ZS3, S41ZA1, S44ZS23, a2, 41, 112ZS23, 214/S23, 233/Ai, 234/S23, 235/S23, 11-1, 11-2, 11-3, NN-Clostridium (12), CAl, Fl, K, S2, 1, 5 and NN-Clostridium (8).


Bacteria of the genus Corynebacterium can be infected by the following phages: CGKl (defective), A, A2, A3, AlOl, A128, A133, A137, A139, A155, A182, B, BF, B17, B18, B51, B271, B275, B276, B277, B279, B282, C, capi, CCl, CGl, CG2, CG33, CL31, Cog, (syn=CG5), D, E, F, H, H-I, hqi, hq2, 11ZH33, Ii/31, J, K, K, (syn=Ktox″), L, L, (syn=Ltox+), M, MC-1, MC-2, MC-3, MC-4, MLMa, N, 0, ovi, ov2, ov3, P, P, R, RP6, RS29, S, T, U, UB1, ub2, UH1, UH3, uh3, uh5, uh6, β, (syn=βtox+), βhv64, βvir, γ, (syn=γtoχ−), γl9, δ, (syn=δ′ox+), p, (syn=ptoχ−), Φ9, φ984, ω, IA, 1/1180, 2, 2/1180, 5/1180, 5ad/9717, 7/4465, 8/4465, 8ad/10269, 10/9253, 13Z9253, 15/3148, 21/9253, 28, 29, 55, 2747, 2893, 4498 and 5848.


Bacteria of the genus Enterococcus can be infected by the following phages: DF78, F1, F2, 1, 2, 4, 14, 41, 867, Dl, SB24, 2BV, 182, 225, C2, C2F, E3, E62, DS96, H24, M35, P3, P9, SBlOl, S2, 2BII, 5, 182a, 705, 873, 881, 940, 1051, 1057, 21096C, NN-Enterococcus (1), PEI, Fl, F3, F4, VD13, 1, 200, 235 and 341.


Bacteria of the genus Erysipelothrix can be infected by the following phage: NN-Eiysipelothrix (1).


Bacteria of the genus Escherichia can be infected by the following phages: BW73, B278, D6, D108, E, El, E24, E41, FI-2, FI-4, FI-5, HI8A, Ffl8B, i, MM, Mu, (syn=mu), (syn=MuI), (syn=Mu-I), (syn=MU-I), (syn=MuI), (syn=p), 025, PhI-5, Pk, PSP3, Pl, PlD, P2, P4 (defective), Sl, Wφ, φK13, φR73 (defective), φ1, φ2, φ7, φ92, ψ (defective), 7 A, 8φ, 9φ, 15 (defective), 18, 28-1, 186, 299, HH-Escherichia (2), AB48, CM, C4, C16, DD-VI, (syn=Dd-Vi), (syn=DDVI), (syn=DDVi), E4, E7, E28, FII, F13, H, HI, H3, H8, K3, M, N, ND-2, ND-3, ND4, ND-5, ND6, ND-7, Ox-I (syn=OXl), (syn=HF), Ox-2 (syn=0x2), (syn=0X2), Ox-3, Ox-4, Ox-5, (syn=0X5), Ox-6, (syn=φ66F), (syn=φ66t), (syn=φ66t−)5 0111, PhI-I, RB42, RB43, RB49, RB69, S, SaI-I, Sal-2, Sal-3, Sal-4, Sal-5, Sal-6, TC23, TC45, TuII*-6, (syn=TuII*), TuIP-24, TuII*46, TuIP-60, T2, (syn=ganuTia), (syn=γ), (syn=PC), (syn=P.C.), (syn=T-2), (syn=T2), (syn=P4), T4, (syn=T4), (syn=T-4), T6, T35, αl, 1, IA, 3, (syn=Ac3), 3A, 3T+, (syn=3), (syn=Ml), 5φ, (syn=φ5), 9266Q, CFO103, HK620, J, K, K1F, m59, no. A, no. E, no. 3, no. 9, N4, sd, (syn=Sd), (syn=SD), (syn=Sa)3 (syn=sd), (syn=SD), (syn=CD), T3, (syn=T-3), (syn=T3), T7, (syn=T-7), (syn=T7), WPK, W31, ΔH, φC3888, φK3, φK7, φK12, φV-1, Φ04-CF, Φ05, Φ06, Φ07, φl, φl.2, φ20, φ95, φ263, φlO92, φl, φll, (syn=φW), Ω8, 1, 3, 7, 8, 26, 27, 28-2, 29, 30, 31, 32, 38, 39, 42, 933W, NN-Escherichia (1), Esc-7-11, AC30, CVX-5, C1, DDUP, ECI, EC2, E21, E29, F1, F26S, F27S, Hi, HK022, HK97, (syn=ΦHK97), HK139, HK253, HK256, K7, ND-I, no. D, PA-2, q, S2, Tl, (syn=α), (syn=P28), (syn=T-I), (syn=Tx), T3C, T5, (syn=T-5), (syn=T5), UC-I, w, β4, γ2, λ (syn=lambda), (syn=Φλ), ΦD326, φγ, Φ06, Φ7, Φ10, φ80, χ, (syn=χi), (syn=φχ), (syn=φχi), 2, 4, 4A, 6, 8A, 102, 150, 168, 174, 3000, AC6, AC7, AC28, AC43, AC50, AC57, AC81, AC95, HK243, K10, ZG/3A, 5, 5A, 21EL, H19-J and 933H.


Bacteria of the genus Fusobacterium can be infected by the following phages: NN-Fusobacterium (2), fv83-554/3, fv88-531/2, 227, fv2377, fv2527 and fv8501.


Bacteria of the genus Haemophilus can be infected by the following phages: HPl, S2 and N3.


Bacteria of the genus Helicobacter can be infected by the following phages. HPl and {circumflex over ( )}{circumflex over ( )}-Helicobacter (1).


Bacteria of the genus Klebsiella can be infected by the following phages: AIO-2, KI4B, K16B, K19, (syn=K19), K114, K115, K121, K128, K129, K132, K133, K135, K1106B, K1171B, K1181B, K1832B, AIO-I, AO-I, AO-2, AO-3, FC3-10, K, K11, (syn=KII), K12, (syn=K12), K13, (syn=K13), (syn=KI 70/11), K14, (syn=K14), K15, (syn=K15), K16, (syn=K16), K17, (syn=K17), K18, (syn=K18), K119, (syn=K19), K127, (syn=K127), K131, (syn=K131), K135, KI171B, II, VI, IX, CI-I, K14B, K18, K111, K112, K113, K116, K117, K118, K120, K122, K123, K124, K126, K130, K134, K1106B, KIi65B, K1328B, KLXI, K328, P5046, 11, 380, II, IV, VII, VIII, FC3-11, K12B, (syn=K12B), K125, (syn=K125), K142B, (syn=K142), (syn=K142B), K1181B, (syn=KIl 81), (syn=K1181B), K1765/!, (syn=K1765/1), K1842B, (syn=K1832B), K1937B, (syn=K1937B), LI, φ28, 7, 231, 483, 490, 632 and 864/100.


Bacteria of the genus Lepilospira can be infected by the following phages: LEl, LE3, LE4 and -NN-Leptospira (1).


Bacteria of the genus Listeria can be infected by the following phages: A511, 01761, 4211, 4286, (syn=B054), A005, A006, A020, A500, A502, A511, Al 18, A620, A640, B012, B021, B024, B025, B035, B051, B053, B054, B055, B056, B11, B110, B545, B604, B653, C707, D441, HSO47, HlOG, H8/73, H19, H21, H43, H46, H107, H108, HI lO, H163/84, H312, H340, H387, H391/73, H684/74, H924A, PSA, U153, φMLUP5, (syn=P35), 00241, 00611, 02971A, 02971C, 5/476, 5/911, 5/939, 5/11302, 5/11605, 5/11704, 184, 575, 633, 699/694, 744, 900, 1090, 1317, 1444, 1652, 1806, 1807, 1921/959, 1921/11367, 1921/11500, 1921/11566, 1921/12460, 1921/12582, 1967, 2389, 2425, 2671, 2685, 3274, 3550, 3551, 3552, 4276, 4277, 4292, 4477, 5337, 5348/11363, 5348/11646, 5348/12430, 5348/12434, 10072, 11355C, 11711 A, 12029, 12981, 13441, 90666, 90816, 93253, 907515, 910716 and NN-Lisferia (15).


Bacteria of the genus Morganella can be infected by the following phage: 47.


Bacteria of the genus Mycobacterium can be infected by the following phages: 13, AGI, ALi, ATCC 11759, A2, B.C3, BG2, BKI, BK5, butyricum, B-I, B5, B7, B30, B35, Clark, C1, C2, DNAIII, DSP1, D4, D29, GS4E, (syn=GS4E), GS7, (syn=GS-7), (syn=GS7), IPa, lacticola, Legendre, Leo, L5, (syn=ΦL-5), MC-I, MC-3, MC-4, minetti, MTPH11, Mx4, MyF3P/59a, phlei, (syn=phlei 1), phlei 4, Polonus II, rabinovitschi, smegmatis, TM4, TM9, TMIO, TM20, Y7, YlO, p630, IB, IF, IH, 1/1, 67, 106, 1430, B1, (syn=Bol), B24, D, D29, F-K, F-S, HP, Polonus I, Roy, Rl, (syn=Rl-Myb), (syn=Ri), 11, 31, 40, 50, 103a, 103b, 128, 3111-D, 3215-D and NN-Mycobacterium (1).


Bacteria of the genus Neisseria can be infected by the following phages: Group I, group II and NPl.


Bacteria of the genus Nocardia can be infected by the following phages: MNP8, NJ-L, NS-8, N5 and TtiN-Nocardia.


Bacteria of the genus Proteus can be infected by the following phages: Pm5, 13vir, 2/44, 4/545, 6/1004, 13/807, 20/826, 57, 67b, 78, 107/69, 121, 9/0, 22/608, 30/680, PmI, Pm3, Pm4, Pm6, Pm7, Pm9, PmIO, Pm11, Pv2, al, (pm, 7/549, 9B/2, 10A/31, 12/55, 14, 15, 16/789, 17/971, 19A/653, 23/532, 25/909, 26/219, 27/953, 32A/909, 33/971, 34/13, 65, 5006M, 7480b, VI, 13/3a, Clichy 12, n2600, eX7, 1/1004, 5/742, 9, 12, 14, 22, 24/860, 2600/D52, Pm8 and 24/2514.


Bacteria of the genus Providencia can be infected by the following phages: PL25, PL26, PL37, 9211/9295, 9213/921 Ib, 9248, 7/R49, 7476/322, 7478/325, 7479, 7480, 9000/9402 and 9213/921 Ia.


Bacteria of the genus Pseudomonas can be infected by the following phages: PfI, (syn=Pf-I), Pf2, Pf3, PP7, PRRI, 7s, im-Pseudomonas (1), AI-I, AI-2, B 17, B89, CB3, Col 2, Col 11, Col 18, Col 21, C154, C163, C167, C2121, E79, F8, ga, gb, H22, K1, M4, N2, Nu, PB-I, (syn=PBl), pfl6, PMN17, PPl, PP8, Psal, PsPl, PsP2, PsP3, PsP4, PsP5, PS3, PS17, PTB80, PX4, PX7, PYOl, PYO2, PYO5, PYO6, PYO9, PYOlO, PYO13, PYO14, PYO16, PYO18, PYO19, PYO20, PYO29, PYO32, PYO33, PYO35, PYO36, PYO37, PYO38, PYO39, PYO41, PYO42, PYO45, PYO47, PYO48, PYO64, PYO69, PYO103, PIK, SLP1, SL2, S2, UNL-I, wy, Yai, Ya4, Yan, φBE, φCTX, φC17, φKZ, (syn=ΦKZ), φ-LT, Φmu78, φNZ, φPLS-1, φST-1, φW-14, φ-2, 1/72, 2/79, 3, 3/DO, 4/237, 5/406, 6C, 6/6660, 7, 7v, 7/184, 8/280, 9/95, 10/502, 11/DE, 12/100, 12S, 16, 21, 24, 25F, 27, 31, 44, 68, 71, 95, 109, 188, 337, 352, 1214, HN-Pseudomonas (23), A856, B26, CI-I, CI-2, C5, D, gh-1, Fl 16, HF, H90, K5, K6, Kl 04, K109, K166, K267, N4, N5, O6N-25P, PE69, Pf, PPN25, PPN35, PPN89, PPN91, PP2, PP3, PP4, PP6, PP7, PP8, PP56, PP87, PP114, PP206, PP207, PP306, PP651, Psp231a, Pssy401, Pssy9220, psi, PTB2, PTB20, PTB42, PXI, PX3, PXIO, PX12, PX14, PYO70, PYO71, R, SH6, SH133, tf, Ya5, Ya7, (eBS, ΦKf77, φ-MC, ΦmnF82, φPLS27, φPLS743, φS-1, 1, 2, 2, 3, 4, 5, 6, 7, 7, 8, 9, 10, 11, 12, 12B, 13, 14, 15, 14, 15, 16, 17, 18, 19, 20, 20, 21, 21, 22, 23, 23, 24, 25, 31, 53, 73, 119x, 145, 147, 170, 267, 284, 308, 525, NN-Pseudomonas (5), af, A7, B3, B33, B39, BI-I, C22, D3, D37, D40, D62, D3112, F7, FlO, g, gd, ge, gξ Hwl2, Jb 19, KFI, L°, OXN-32P, 06N-52P, PCH-I, PC13-1, PC35-1, PH2, PH51, PH93, PH132, PMW, PM13, PM57, PM61, PM62, PM63, PM69, PM105, PMl 13, PM681, PM682, P04, PPl, PP4, PP5, PP64, PP65, PP66, PP71, PP86, PP88, PP92, PP401, PP711, PP891, Pssy41, Pssy42, Pssy403, Pssy404, Pssy420, Pssy923, PS4, PS-IO, Pz, SDl, SLl, SL3, SL5, SM, φC5, φC11, φCl 1-1, φC13, φC15, φMO, φX, φO4, φ11, φ240, 2, 2F, 5, 7m, 11, 13, 13/441, 14, 20, 24, 40, 45, 49, 61, 73, 148, 160, 198, 218, 222, 236, 242, 246, 249, 258, 269, 295, 297, 309, 318, 342, 350, 351, 357-1, 400-1, HN-Pseudomonas (6), GlOl, M6, M6a, LI, PB2, Pssy15, Pssy4210, Pssy4220, PYO12, PYO34, PYO49, PYO50, PYO51, PYO52, PYO53, PYO57, PYO59, PYO200, PX2, PX5, SL4, φ03, φ06 and 1214.


Bacteria of the genus Rickettsia can be infected by the following phage: NN-Rickettsia.


Bacteria of the genus Salmonella can be infected by the following phages: b, Beccles, CT, d, Dundee, f, Fels 2, GI, GUI, GVI, GVIII, k, K, i, j, L, 01, (syn=0-1), (syn=01), (syn=0-I), (syn=7), 02, 03, P3, P9a, PlO, Sab3, Sab5, SaniS, Sanl7, SI, Taunton, ViI, (syn=ViI), 9, imSalmonella (1), N-I, N-5, N-10, N-17, N-22, 11, 12, 16-19, 20.2, 36, 449C/C178, 966A/C259, a, B.A.O.R., e, G4, GUI, L, LP7, M, MG40, N-18, PSA68, P4, P9c, P22, (syn=P22), (syn=PLT22), (syn=PLT22), P22al, P22-4, P22-7, P22-11, SNT-I, SNT-2, SP6, Villi, ViIV, ViV, ViVI, ViVII, Worksop, Sj5, ε34, 1, 37, 1(40), (syn=φl[40]), 1,422, 2, 2.5, 3b, 4, 5, 6,14(18), 8, 14(6,7), 10, 27, 28B, 30, 31, 32, 33, 34, 36, 37, 39, 1412, SNT-3, 7-11, 40.3, c, C236, C557, C625, C966N, g, GV, G5, GI 73, h, IRA, Jersey, MB78, P22-1, P22-3, P22-12, Sabl, Sab2, Sab2, Sab4, Sanl, San2, San3, San4, San6, San7, San8, San9, Sanl3, Sanl4, Sanl6, Sanl8, Sanl9, San20, San21, San22, San23, San24, San25, San26, SasLI, SasL2, SasL3, SasL4, SasL5, SIBL, SII, Vill, yl, 1, 2, 3a, 3al, 1010, Ym-Salmonella (1), N-4, SasL6 and 27.


Bacteria of the genus Serratia can be infected by the following phages: A2P, PS20, SMB3, SMP, SMP5, SM2, V40, V56, ic, ΦCP-3, ΦCP-6, 3M, 10/la, 20A, 34CC, 34H, 38T, 345G, 345P, 501B, SMB2, SMP2, BC, BT, CW2, CW3, CW4, CW5, Lt232, L2232, L34, L.228, SLP, SMPA, V.43, σ, φCWI, ΦCP6-1, ΦCP6-2, ΦCP6-5, 3T, 5, 8, 9F, 10/1, 20E, 32/6, 34B, 34CT, 34P, 37, 41, 56, 56D, 56P, 60P, 61/6, 74/6, 76/4, 101/8900, 226, 227, 228, 229F, 286, 289, 290F, 512, 764a, 2847/10, 2847/1Oa, L.359 and SMBI.


Bacteria of the genus Shigella can be infected by the following phages: Fsa, (syn=a), FSD2d, (syn=D2d), (syn=W2d), FSD2E, (syn=W2e), fv, F6, f7.8, H-Sh, PE5, P90, Sf11, Sh, SHm, SHrv, (syn=HIV), SHvi, (syn=HVI), SHVvm, (syn=HVIII), SKy66, (syn=gamma 66), (syn=yββ), (syn=766b), SKm, (syn=SIIIb)5 (syn=UI), SKw, (syn=Siva), (syn=IV), SIC™, (syn=SIVA.), (syn=IVA), SKvi, (syn=KVI), (syn=Svi), (syn=VI), SKvm, (syn=Svm), (syn=VIII), SKVTIIA, (syn=SvmA), (syn=VIIIA), STvi, STK, STx1, STxn, S66, W2, (syn=D2c), (syn=D20), φl, φIVb 3-SO-R, 8368-SO-R, F7, (syn=FS7), (syn=K29), FlO, (syn=FSlO), (syn=K31), I1, (syn=alfa), (syn=FSa), (syn=Kl 8), (syn=α), 12, (syn=a), (syn=K19), SG33, (syn=G35), (syn=SO-35/G), SG35, (syn=SO-55/G), SG3201, (syn=SO-3201/G), SHn, (syn=HII), SHv, (syn=SHV), SHx, SHX, SKn, (syn=K2), (syn=KII), (syn=Sn), (syn=SsII), (syn=II), SKrv, (syn=Sm), (syn=SsIV), (syn=IV), SK1Va, (syn=Swab), (syn=SsIVa), (syn=IVa), SKV, (syn=K4), (syn=KV), (syn=SV), (syn=SsV), (syn=V), SKx, (syn=K9), (syn=KX), (syn=SX), (syn=SsX), (syn=X), STV, (syn=T35), (syn=35-50-R), STvm, (syn=T8345), (syn=8345-SO—S-R), W1, (syn=D8), (syn=FSD8), W2a, (syn=D2A), (syn=FS2a), DD-2, Sf6, FSi, (syn=F1), SF6, (syn=F6), SG42, (syn=SO-42/G), SG3203, (syn=SO-3203/G), SKF12, (syn=SsF12), (syn=F12), (syn=F12), STn, (syn=1881-SO-R), γ66, (syn=gamma 66a), (syn=Ssγ66), φ2, BII, DDVII, (syn=DD7), FSD2b, (syn=W2B), FS2, (syn=F2), (syn=F2), FS4, (syn=F4), (syn=F4), FS5, (syn=F5), (syn=F5), FS9, (syn=F9), (syn=F9), F11, P2-SO-S, SG36, (syn=SO-36/G), (syn=G36), SG3204, (syn=SO-3204/G), SG3244, (syn=SO-3244/G), SHi, (syn=HI), SHvn, (syn=HVII), SHK, (syn=HIX), SHx1, SHxn, (syn=HXn), SKI, KI, (syn=S1), (syn=SsI), SKVII, (syn=KVII), (syn=Svn), (syn=SsVH), SKIX, (syn=KIX), (syn=Slx), (syn=SsIX), SKXII, (syn=KXII), (syn=Sxn), (syn=SsXII), STi, STff1, STrv, STVi, STvπ, S70, S206, U2-SO-S, 3210-SO-S, 3859-SO-S, 4020-SO-S, φ3, φ5, φ7, φ8, φ9, φlO, φl 1, φ13, φ14, φ18, SHm, (syn=Hπi), SHχi, (syn=HXt) and SKxI, (syn=KXI), (syn=Sχi), (syn=SsXI), (syn=XI).


Bacteria of the genus Staphylococcus can be infected by the following phages: A, EW, K, Ph5, Ph9, PhIO, Phl3, Pl, P2, P3, P4, P8, P9, PlO, RG, SB-i, (syn=Sb-I), S3K, Twort, ΦSK311, φ812, 06, 40, 58, 119, 130, 131, 200, 1623, STCI, (syn=stcl), STC2, (syn=stc2), 44AHJD, 68, ACI, AC2, A6“C”, A9“C”, b581, CA-I, CA-2, CA-3, CA-4, CA-5, DI1, L39x35, L54a, M42, N1, N2, N3, N4, N5, N7, N8, NlO, Ni 1, N12, N13, N14, N16, Ph6, Phl2, Phl4, UC-18, U4, U15, SI, S2, S3, S4, S5, X2, Z1, φB5-2, φD, ω, 11, (syn=φl 1), (syn=P11-M15), 15, 28, 28A, 29, 31, 31B, 37, 42D, (syn=P42D), 44A, 48, 51, 52, 52A, (syn=P52A), 52B, 53, 55, 69, 71, (syn=P71), 71A, 72, 75, 76, 77, 79, 80, 80a, 82, 82A, 83 A, 84, 85, 86, 88, 88A, 89, 90, 92, 95, 96, 102, 107, 108, 111, 129-26, 130, 130A, 155, 157, 157A, 165, 187, 275, 275A, 275B, 356, 456, 459, 471, 471A, 489, 581, 676, 898, 1139, 1154A, 1259, 1314, 1380, 1405, 1563, 2148, 2638A, 2638B, 2638C, 2731, 2792A, 2792B, 2818, 2835, 2848A, 3619, 5841, 12100, AC3, A8, AO, A13, b594n, D, HK2, N9, N15, P52, P87, S1, S6, Z4, φRE, 3A, 3B, 3C, 6, 7, 16, 21, 42B, 42C, 42E, 44, 47, 47A5 47C, 51, 54, 54x1, 70, 73, 75, 78, 81, 82, 88, 93, 94, 101, 105, 110, 115, 129/16, 174, 594n, 1363/14, 2460 and mS-Staphylococcus (1).


Bacteria of the genus Streptococcus can be infected by the following phages: EJ-I, NN-Streptococais (1), a, C1, FL0Ths, H39, Cp-I, Cρ-5, Cp-7, Cp-9, Cp-IO, AT298, A5, alO/Jl, alO/J2, alO/J5, alO/J9, A25, BT11, b6, CAl, c20-l, c20-2, DP-I, Dp-4, DTI, ET42, elO, FA101, FEThs, Fu, FKKIOI, FKLIO, FKP74, FKH, FLOThs, FyIOl, f1, F10, F20140/76, g, GT-234, HB3, (syn=HB-3), HB-623, HB-746, M102, 01205, p01205, PST, PO, Pl, P2, P3, P5, P6, P8, P9, P9, P12, P13, P14, P49, P50, P51, P52, P53, P54, P55, P56, P57, P58, P59, P64, P67, P69, P71, P73, P75, P76, P77, P82, P83, P88, sc, sch, sf, SfIl 1, (syn=SFiI l), (syn=PSFill), (syn=ΦSfil 1), (syn=φSfil 1), sfil9, (syn=SFil9), (syn=φSFil9), (syn=(φSfil9), Sfi21, (syn=SFi21), (syn=φSFi21), (syn=φSfi21), ST0, STX, st2, ST2, ST4, S3, (syn=φS3), s265, Φ17, φ42, Φ57, φ80, φ81, φ82, φ83, φ84, φ85, φ86, φ87, φ88, φ89, φ90, φ91, φ92, φ93, φ94, φ95, φ96, φ97, φ98, φ99, φlOO, φlOl, φlO2, φ227, Φ7201, ω1, ω2, ω3, ω4, ω5, ω6, ω8, ωlO, 1, 6, 9, IOF, 12/12, 14, 17SR, 19S, 24, 50/33, 50/34, 55/14, 55/15, 70/35, 70/36, 71/ST15, 71/45, 71/46, 74F, 79/37, 79/38, 80/J4, 80/J9, 80/ST16, 80/15, 80/47, 80/48, 101, 103/39, 103/40, 121/41, 121/42, 123/43, 123/44, 124/44, 337/ST17 and mStreptococcus (34).


Bacteria of the genus Treponema can be infected by the following phage: NN-Treponema (1).


Bacteria of the genus Vibrio can be infected by the following phages: CTXΦ, fs, (syn=si), fs2, Ivpf5, Vfl2, Vf33, VPIΦ, VSK, v6, 493, CP-Tl, ET25, kappa, K139, Labol, XN-69P, OXN-86, 06N-21P, PB-I, P147, rp-1, SE3, VA-I, (syn=VcA-I), VcA-2, VPl, VP2, VP4, VP7, VP8, VP9, VPlO, VP17, VP18, VP19, X29, (syn=29 d'Herelle), t, ΦHAWI-1, ΦHAWI-2, ΦHAWI-3, ΦHAWI-4, ΦHAWI-5, ΦHAWI-6, ΦHAWI-7, XHAWI-8, ΦHAWI-9, ΦHAWI-10, ΦDHC1-1, ΦDHC1-2, ΦDHC1-3, ΦHCl-4, ΦHC2-1, ΦHC2-2, ΦHC2-3, ΦHC2-4, ΦDHC3-1, ΦHC3- 2, ΦHC3-3, ΦHD1S-1, ΦHDIS-2, ΦHD2S-1, ΦHD2S-2, ΦHD2S-3, ΦHD2S-4, ΦHD2S-5, ΦHDO-1, ΦHDO-2, ΦHDO-3, ΦHDO-4, ΦHDO-5, ΦHDO-6, ΦKL-33, ΦKL-34, ΦKL-35, ΦKL-36, ΦKWH-2, ΦKWH-3, ΦKWH-4, ΦMARQ-1, ΦMARQ-2, ΦMARQ-3, ΦMOAT-1, ΦO139, ΦPEL1A-1, ΦPEL1A-2, ΦPEL8A-1, ΦPEL8A-2, ΦPEL8A-3, ΦPEL8C-1, ΦPEL8C-2, ΦPEL13A-1, ΦPEL13B-1, ΦPEL13B-2, ΦPEL13B-3, ΦPEL13B-4, ΦPEL13B-5, ΦPEL13B-6, ΦPEL13B-7, ΦPEL13B-8, ΦPEL13B-9, ΦPEL13B-10, φVP143, φVP253, Φ16, φ138, 1-II, 5, 13, 14, 16, 24, 32, 493, 6214, 7050, 7227, II, (syn=group II), (syn==(2), V, VIII, ˜m-Vibrio (13), KVP20, KVP40, nt-1, 06N-22P, P68, e1, e2, e3, e4, e5, FK, G, I, K, nt-6, NI, N2, N3, N4, N5, 06N-34P, OXN-72P, OXN-85P, OXN-100P, P, Ph-I, PL163/10, Q, S, T, p92, 1-9, 37, 51, 57, 70A-8, 72A-4, 72A-10, 110A-4, 333, 4996, I (syn=group I), III (syn=group III), VI, (syn=A-Saratov), VII, IX, X, HN-Vibrio (6), pAl, 7, 7-8, 70A-2, 71A-6, 72A-5, 72A-8, 108A-10, 109A-6, 109A-8, 1 lOA-1, 110A-5, 110A-7, hv-1, OXN-52P, P13, P38, P53, P65, P108, Pill, TPl3 VP3, VP6, VP12, VP13, 70A-3, 70A-4, 70A-10, 72A-1, 108A-3, 109-B1, 110A-2, 149, (syn=φl49), IV, (syn=group IV), NN-Vibrio (22), VP5, VPIl, VP15, VP16, α1, α2, α3a, α3b, 353B and HN-Vibrio (7).


Bacteria of the genus Yersinia can be infected by the following phages: H, H-1, H-2, H-3, H4, Lucas 110, Lucas 303, Lucas 404, YerA3, YerA7, YerA20, YerA41, 3/M64-76, 5/G394-76, 6/C753-76, 8/C239-76, 9/F18167, 1701, 1710, PST, 1/F2852-76, D'Herelle, EV, H, Kotljarova, PTB, R, Y, YerA41, φYerO3-12, 3, 4/C1324-76, 7/F783-76, 903, 1/M6176 and Yer2AT.


More preferably, the bacteriophage is selected in the group consisting of Salmonella virus SKML39, Shigella virus AG3, Dickeya virus Limestone, Dickeya virus RC2014, Escherichia virus CBA 120, Escherichia virus PhaxI, Salmonella virus 38, Salmonella virus Det7, Salmonella virus GG32, Salmonella virus PM10, Salmonella virus SFP10, Salmonella virus SH19, Salmonella virus SJ3, Escherichia virus ECML4, Salmonella virus Marshall, Salmonella virus Maynard, Salmonella virus SJ2, Salmonella virus STML131, Salmonella virus ViI, Erwinia virus Ea2809, Klebsiella virus 0507KN21, Serratia virus IME250, Serratia virus MAM1, Campylobacter virus CP21, Campylobacter virus CP220, Campylobacter virus CPt10, Campylobacter virus IBB35, Campylobacter virus CP81, Campylobacter virus CP30A, Campylobacter virus CPX, Campylobacter virus NCTC12673, Erwinia virus Ea214, Erwinia virus M7, Escherichia virus AYO145A, Escherichia virus EC6, Escherichia virus HYO2, Escherichia virus JH2, Escherichia virus TP1, Escherichia virus VpaE1, Escherichia virus wV8, Salmonella virus FelixO1, Salmonella virus HB2014, Salmonella virus Mushroom, Salmonella virus UAB87, Citrobacter virus Moogle, Citrobacter virus Mordin, Escherichia virus SUSP1, Escherichia virus SUSP2, Aeromonas virus phiO18P, Haemophilus virus HPl, Haemophilus virus HP2, Pasteurella virus F108, Vibrio virus K139, Vibrio virus Kappa, Burkholderia virus phi52237, Burkholderia virus phiE122, Burkholderia virus phiE202, Escherichia virus 186, Escherichia virus P4, Escherichia virus P2, Escherichia virus Wphi, Mannheimia virus PHL101, Pseudomonas virus phiCTX, Ralstonia virus RSAI, Salmonella virus Fels2, Salmonella virus PsP3, Salmonella virus SopEphi, Yersinia virus L413C, Staphylococcus virus G1, Staphylococcus virus G15, Staphylococcus virus JD7, Staphylococcus virus K, Staphylococcus virus MCE2014, Staphylococcus virus P108, Staphylococcus virus Rodi, Staphylococcus virus S253, Staphylococcus virus S25-4, Staphylococcus virus SA12, Listeria virus A511, Listeria virus P100, Staphylococcus virus Remus, Staphylococcus virus SA11, Staphylococcus virus Stau2, Bacillus virus Camphawk, Bacillus virus SPO1, Bacillus virus BCP78, Bacillus virus TsarBomba, Staphylococcus virus Twort, Enterococcus virus phiEC24C, Lactobacillus virus Lb338-1, Lactobacillus virus LP65, Enterobacter virus PG7, Escherichia virus CC31, Klebsiella virus JD18, Klebsiella virus PKO111, Escherichia virus Bp7, Escherichia virus IME08, Escherichia virus JS10, Escherichia virus JS98, Escherichia virus QLO1, Escherichia virus VR5, Enterobacter virus Eap3, Klebsiella virus KP15, Klebsiella virus KP27, Klebsiella virus Matisse, Klebsiella virus Miro, Citrobacter virus Merlin, Citrobacter virus Moon, Escherichia virus JSE, Escherichia virus phi1, Escherichia virus RB49, Escherichia virus HXO1, Escherichia virus JSO9, Escherichia virus RB69, Shigella virus UTAM, Salmonella virus S16, Salmonella virus STML198, Vibrio virus KVP40, Vibrio virus ntl, Vibrio virus VaIKK3, Escherichia virus VR7, Escherichia virus VR20, Escherichia virus VR25, Escherichia virus VR26, Shigella virus SP18, Escherichia virus AR1, Escherichia virus C40, Escherichia virus E112, Escherichia virus ECML134, Escherichia virus HY01, Escherichia virus Ime09, Escherichia virus RB3, Escherichia virus RB14, Escherichia virus T4, Shigella virus Pss1, Shigella virus Shfl2, Yersinia virus D1, Yersinia virus PST, Acinetobacter virus 133, Aeromonas virus 65, Aeromonas virus Aeh1, Escherichia virus RB16, Escherichia virus RB32, Escherichia virus RB43, Pseudomonas virus 42, Cronobacter virus CR3, Cronobacter virus CR8, Cronobacter virus CR9, Cronobacter virus PBESO2, Pectobacterium virus phiTE, Cronobacter virus GAP31, Escherichia virus 4MG, Salmonella virus SE1, Salmonella virus SSE121, Escherichia virus FFH2, Escherichia virus FV3, Escherichia virus JES2013, Escherichia virus V5, Brevibacillus virus Abouo, Brevibacillus virus Davies, Bacillus virus Agate, Bacillus virus Bobb, Bacillus virus Bp8pC, Erwinia virus Deimos, Erwinia virus Ea35-70, Erwinia virus RAY, Erwinia virus Simmy50, Erwinia virus SpecialG, Acinetobacter virus AB1, Acinetobacter virus AB2, Acinetobacter virus AbC62, Acinetobacter virus AP22, Arthrobacter virus ArV1, Arthrobacter virus Trina, Bacillus virus AvesoBmore, Bacillus virus B4, Bacillus virus Bigbertha, Bacillus virus Riley, Bacillus virus Spock, Bacillus virus Troll, Bacillus virus Bastille, Bacillus virus CAM003, Bacillus virus Bc431, Bacillus virus Bcp1, Bacillus virus BCP82, Bacillus virus BM15, Bacillus virus Deepblue, Bacillus virus JBP901, Burkholderia virus Bcep1, Burkholderia virus Bcep43, Burkholderia virus Bcep781, Burkholderia virus BcepNY3, Xanthomonas virus OP2, Burkholderia virus BcepMu, Burkholderia virus phiE255, Aeromonas virus 44RR2, Mycobacterium virus Alice, Mycobacterium virus Bxz1, Mycobacterium virus Dandelion, Mycobacterium virus HyRo, Mycobacterium virus 13, Mycobacterium virus Nappy, Mycobacterium virus Sebata, Clostridium virus phiC2, Clostridium virus phiCD27, Clostridium virus phiCD119, Bacillus virus CP51, Bacillus virus JL, Bacillus virus Shanette, Escherichia virus CVM10, Escherichia virus ep3, Erwinia virus Asesino, Erwinia virus EaH2, Pseudomonas virus EL, Halomonas virus HAP1, Vibrio virus VP882, Brevibacillus virus Jimmer, Brevibacillus virus Osiris, Pseudomonas virus Ab03, Pseudomonas virus KPP10, Pseudomonas virus PAKP3, Sinorhizobium virus M7, Sinorhizobium virus M12, Sinorhizobium virus N3, Erwinia virus Machina, Arthrobacter virus Brent, Arthrobacter virus Jawnski, Arthrobacter virus Martha, Arthrobacter virus Sonny, Edwardsiella virus MSW3, Edwardsiella virus PEi21, Escherichia virus Mu, Shigella virus SfMu, Halobacterium virus phiH, Bacillus virus Grass, Bacillus virus NIT1, Bacillus virus SPG24, Aeromonas virus 43, Escherichia virus P1, Pseudomonas virus CAbI, Pseudomonas virus CAb02, Pseudomonas virus JG004, Pseudomonas virus PAKPl, Pseudomonas virus PAKP4, Pseudomonas virus PaPl, Burkholderia virus BcepF1, Pseudomonas virus 141, Pseudomonas virus Ab28, Pseudomonas virus DL60, Pseudomonas virus DL68, Pseudomonas virus F8, Pseudomonas virus JG024, Pseudomonas virus KPP12, Pseudomonas virus LBL3, Pseudomonas virus LMA2, Pseudomonas virus PB1, Pseudomonas virus SN, Pseudomonas virus PA7, Pseudomonas virus phiKZ, Rhizobium virus RHEph4, Ralstonia virus RSF1, Ralstonia virus RSL2, Ralstonia virus RSL1, Aeromonas virus 25, Aeromonas virus 31, Aeromonas virus Aesl2, Aeromonas virus Aes508, Aeromonas virus AS4, Stenotrophomonas virus IME13, Staphylococcus virus IPLAC1C, Staphylococcus virus SEP1, Salmonella virus SPN3US, Bacillus virus 1, Geobacillus virus GBSV1, Yersinia virus R1RT, Yersinia virus TG1, Bacillus virus G, Bacillus virus PBS1, Microcystis virus Ma-LMMO1, Vibrio virus MAR, Vibrio virus VHML, Vibrio virus VP585, Bacillus virus BPS13, Bacillus virus Hakuna, Bacillus virus Megatron, Bacillus virus WPh, Acinetobacter virus AB3, Acinetobacter virus Abp1, Acinetobacter virus Fri1, Acinetobacter virus IME200, Acinetobacter virus PD6A3, Acinetobacter virus PDAB9, Acinetobacter virus phiABI, Escherichia virus K30, Klebsiella virus K5, Klebsiella virus K11, Klebsiella virus Kpl, Klebsiella virus KP32, Klebsiella virus KpV289, Klebsiella virus F19, Klebsiella virus K244, Klebsiella virus Kp2, Klebsiella virus KP34, Klebsiella virus KpV41, Klebsiella virus KpV71, Klebsiella virus KpV475, Klebsiella virus SU503, Klebsiella virus SU552A, Pantoea virus Limelight, Pantoea virus Limezero, Pseudomonas virus LKA1, Pseudomonas virus phiKMV, Xanthomonas virus f20, Xanthomonas virus 30, Xylella virus Prado, Erwinia virus Era103, Escherichia virus K5, Escherichia virus K1-5, Escherichia virus K1E, Salmonella virus SP6, Escherichia virus T7, Kluyvera virus Kvp1, Pseudomonas virus gh1, Prochlorococcus virus PSSP7, Synechococcus virus P60, Synechococcus virus Syn5, Streptococcus virus Cp1, Streptococcus virus Cp7, Staphylococcus virus 44AHJD, Streptococcus virus C1, Bacillus virus B103, Bacillus virus GAI, Bacillus virus phi29, Kurthia virus 6, Actinomyces virus Av1, Mycoplasma virus P1, Escherichia virus 24B, Escherichia virus 933W, Escherichia virus Min27, Escherichia virus PA28, Escherichia virus Stx2 II, Shigella virus 7502Stx, Shigella virus POCJ13, Escherichia virus 191, Escherichia virus PA2, Escherichia virus TL2011, Shigella virus VASD, Burkholderia virus Bcep22, Burkholderia virus Bcepil02, Burkholderia virus Bcepmigl, Burkholderia virus DC1, Bordetella virus BPP1, Burkholderia virus BcepC6B, Cellulophaga virus Cba41, Cellulophaga virus Cba172, Dinoroseobacter virus DFL12, Erwinia virus Ea9-2, Erwinia virus Frozen, Escherichia virus phiV10, Salmonella virus Epsilon15, Salmonella virus SPN1S, Pseudomonas virus F116, Pseudomonas virus H66, Escherichia virus APEC5, Escherichia virus APEC7, Escherichia virus Bp4, Escherichia virus EC1UPM, Escherichia virus ECBP1, Escherichia virus G7C, Escherichia virus IMEl 1, Shigella virus Sbl, Achromobacter virus Axp3, Achromobacter virus JWAlpha, Edwardsiella virus KF1, Pseudomonas virus KPP25, Pseudomonas virus R18, Pseudomonas virus Ab09, Pseudomonas virus LIT1, Pseudomonas virus PA26, Pseudomonas virus Ab22, Pseudomonas virus CHU, Pseudomonas virus LUZ24, Pseudomonas virus PAA2, Pseudomonas virus PaP3, Pseudomonas virus PaP4, Pseudomonas virus TL, Pseudomonas virus KPP21, Pseudomonas virus LUZ7, Escherichia virus N4, Salmonella virus 9NA, Salmonella virus SP069, Salmonella virus BTP1, Salmonella virus HK620, Salmonella virus P22, Salmonella virus ST64T, Shigella virus Sf6, Bacillus virus Page, Bacillus virus Palmer, Bacillus virus Pascal, Bacillus virus Pony, Bacillus virus Pookie, Escherichia virus 172-1, Escherichia virus ECB2, Escherichia virus NJO1, Escherichia virus phiEco32, Escherichia virus Septimal 1, Escherichia virus SUl0, Brucella virus Pr, Brucella virus Tb, Escherichia virus Pollock, Salmonella virus FSL SP-058, Salmonella virus FSL SP-076, Helicobacter virus 1961P, Helicobacter virus KHP30, Helicobacter virus KHP40, Hamiltonella virus APSE1, Lactococcus virus KSY1, Phormidium virus WMP3, Phormidium virus WMP4, Pseudomonas virus 119X, Roseobacter virus SIO1, Vibrio virus VpV262, Vibrio virus VC8, Vibrio virus VP2, Vibrio virus VP5, Streptomyces virus Amela, Streptomyces virus phiCAM, Streptomyces virus Aaronocolus, Streptomyces virus Caliburn, Streptomyces virus Danzina, Streptomyces virus Hydra, Streptomyces virus Izzy, Streptomyces virus Lannister, Streptomyces virus Lika, Streptomyces virus Sujidade, Streptomyces virus Zemlya, Streptomyces virus ELB20, Streptomyces virus R4, Streptomyces virus phiHau3, Mycobacterium virus Acadian, Mycobacterium virus Baee, Mycobacterium virus Reprobate, Mycobacterium virus Adawi, Mycobacterium virus Bane1, Mycobacterium virus BrownCNA, Mycobacterium virus Chrisnmich, Mycobacterium virus Cooper, Mycobacterium virus JAMaL, Mycobacterium virus Nigel, Mycobacterium virus Stinger, Mycobacterium virus Vincenzo, Mycobacterium virus Zemanar, Mycobacterium virus Apizium, Mycobacterium virus Manad, Mycobacterium virus Oline, Mycobacterium virus Osmaximus, Mycobacterium virus Pg1, Mycobacterium virus Soto, Mycobacterium virus Suffolk, Mycobacterium virus Athena, Mycobacterium virus Bernardo, Mycobacterium virus Gadjet, Mycobacterium virus Pipefish, Mycobacterium virus Godines, Mycobacterium virus Rosebush, Mycobacterium virus Babsiella, Mycobacterium virus Brujita, Mycobacterium virus Che9c, Mycobacterium virus Sbash, Mycobacterium virus Hawkeye, Mycobacterium virus Plot, Salmonella virus AG11, Salmonella virus Ent1, Salmonella virus f18SE, Salmonella virus Jersey, Salmonella virus L13, Salmonella virus LSPA 1, Salmonella virus SE2, Salmonella virus SETP3, Salmonella virus SETP7, Salmonella virus SETP13, Salmonella virus SP101, Salmonella virus SS3e, Salmonella virus wksl3, Escherichia virus K1G, Escherichia virus K1H, Escherichia virus Klind1, Escherichia virus Klind2, Salmonella virus SP31, Leuconostoc virus Lmd1, Leuconostoc virus LNO3, Leuconostoc virus LNO4, Leuconostoc virus LN12, Leuconostoc virus LN6B, Leuconostoc virus P793, Leuconostoc virus 1 A4, Leuconostoc virus Ln8, Leuconostoc virus Ln9, Leuconostoc virus LN25, Leuconostoc virus LN34, Leuconostoc virus LNTR3, Mycobacterium virus Bongo, Mycobacterium virus Rey, Mycobacterium virus Butters, Mycobacterium virus Michelle, Mycobacterium virus Charlie, Mycobacterium virus Pipsqueaks, Mycobacterium virus Xeno, Mycobacterium virus Panchino, Mycobacterium virus Phrann, Mycobacterium virus Redi, Mycobacterium virus Skinnyp, Gordonia virus BaxterFox, Gordonia virus Yeezy, Gordonia virus Kita, Gordonia virus Zirinka, Gorrdonia virus Nymphadora, Mycobacterium virus Bignuz, Mycobacterium virus Brusacoram, Mycobacterium virus Donovan, Mycobacterium virus Fishburne, Mycobacterium virus Jebeks, Mycobacterium virus Malithi, Mycobacterium virus Phayonce, Enterobacter virus F20, Klebsiella virus 1513, Klebsiella virus KLPN1, Klebsiella virus KP36, Klebsiella virus PKP126, Klebsiella virus Sushi, Escherichia virus AHP42, Escherichia virus AHS24, Escherichia virus AKS96, Escherichia virus C119, Escherichia virus E41c, Escherichia virus Eb49, Escherichia virus Jk06, Escherichia virus KP26, Escherichia virus Rogue1, Escherichia virus ACGM12, Escherichia virus Rtp, Escherichia virus ADB2, Escherichia virus JMPW1, Escherichia virus JMPW2, Escherichia virus T1, Shigella virus PSf2, Shigella virus Shfl1, Citrobacter virus Stevie, Escherichia virus TLS, Salmonella virus SP126, Cronobacter virus Esp2949-1, Pseudomonas virus Ab18, Pseudomonas virus Ab19, Pseudomonas virus PaMx11, Arthrobacter virus Amigo, Propionibacterium virus Anatole, Propionibacterium virus B3, Bacillus virus Andromeda, Bacillus virus Blastoid, Bacillus virus Curly, Bacillus virus Eoghan, Bacillus virus Finn, Bacillus virus Glittering, Bacillus virus Riggi, Bacillus virus Taylor, Gordonia virus Attis, Mycobacterium virus Barnyard, Mycobacterium virus Konstantine, Mycobacterium virus Predator, Mycobacterium virus Bernall3, Staphylococcus virus 13, Staphylococcus virus 77, Staphylococcus virus 108PVL, Mycobacterium virus Bron, Mycobacterium virus Faith1, Mycobacterium virus Joedirt, Mycobacterium virus Rumpelstiltskin, Lactococcus virus bLL67, Lactococcus virus c2, Lactobacillus virus c5, Lactobacillus virus Ld3, Lactobacillus virus Ldl7, Lactobacillus virus Ld25A, Lactobacillus virus LLKu, Lactobacillus virus phiLdb, Cellulophaga virus Cbal21, Cellulophaga virus Cba171, Cellulophaga virus Cba181, Cellulophaga virus ST, Bacillus virus 250, Bacillus virus IEBH, Mycobacterium virus Ardmore, Mycobacterium virus Avani, Mycobacterium virus Boomer, Mycobacterium virus Che8, Mycobacterium virus Che9d, Mycobacterium virus Deadp, Mycobacterium virus Dlane, Mycobacterium virus Dorothy, Mycobacterium virus Dotproduct, Mycobacterium virus Drago, Mycobacterium virus Fruitloop, Mycobacterium virus Gumbie, Mycobacterium virus Ibhubesi, Mycobacterium virus Llij, Mycobacterium virus Mozy, Mycobacterium virus Mutaformal3, Mycobacterium virus Pacc40, Mycobacterium virus PMC, Mycobacterium virus Ramsey, Mycobacterium virus Rockyhorror, Mycobacterium virus SG4, Mycobacterium virus Shaunal, Mycobacterium virus Shilan, Mycobacterium virus Spartacus, Mycobacterium virus Taj, Mycobacterium virus Tweety, Mycobacterium virus Wee, Mycobacterium virus Yoshi, Salmonella virus Chi, Salmonella virus FSLSPO30, Salmonella virus FSLSP088, Salmonella virus iEPS5, Salmonella virus SPN19, Mycobacterium virus 244, Mycobacterium virus Bask21, Mycobacterium virus CJW1, Mycobacterium virus Eureka, Mycobacterium virus Kostya, Mycobacterium virus Porky, Mycobacterium virus Pumpkin, Mycobacterium virus Sirduracell, Mycobacterium virus Toto, Mycobacterium virus Corndog, Mycobacterium virus Firecracker, Rhodobacter virus RcCronus, Pseudomonas virus D3112, Pseudomonas virus DMS3, Pseudomonas virus FHA0480, Pseudomonas virus LPB1, Pseudomonas virus MP22, Pseudomonas virus MP29, Pseudomonas virus MP38, Pseudomonas virus PAIKOR, Pseudomonas virus D3, Pseudomonas virus PMG1, Arthrobacter virus Decurro, Gordonia virus Demosthenes, Gordonia virus Katyusha, Gordonia virus Kvothe, Propionibacterium virus B22, Propionibacterium virus Doucette, Propionibacterium virus E6, Propionibacterium virus G4, Burkholderia virus phi6442, Burkholderia virus phil026b, Burkholderia virus phiE125, Edwardsiella virus eiAU, Mycobacterium virus Ff47, Mycobacterium virus Muddy, Mycobacterium virus Gaia, Mycobacterium virus Giles, Arthrobacter virus Captnmurica, Arthrobacter virus Gordon, Gordonia virus GordTnk2, Paenibacillus virus Harrison, Escherichia virus EK99P1, Escherichia virus HK578, Escherichia virus JL1, Escherichia virus SSL2009a, Escherichia virus YD2008s, Shigella virus EP23, Sodalis virus SOl, Escherichia virus HK022, Escherichia virus HK75, Escherichia virus HK97, Escherichia virus HK106, Escherichia virus HK446, Escherichia virus HK542, Escherichia virus HK544, Escherichia virus HK633, Escherichia virus mEp234, Escherichia virus mEp235, Escherichia virus mEpXl, Escherichia virus mEpX2, Escherichia virus mEp043, Escherichia virus mEp213, Escherichia virus mEp237, Escherichia virus mEp390, Escherichia virus mEp460, Escherichia virus mEp505, Escherichia virus mEp506, Brevibacillus virus Jenst, Achromobacter virus 83-24, Achromobacter virus JWX, Arthrobacter virus Kellezzio, Arthrobacter virus Kitkat, Arthrobacter virus Bennie, Arthrobacter virus DrRobert, Arthrobacter virus Glenn, Arthrobacter virus HunterDalle, Arthrobacter virus Joann, Arthrobacter virus Korra, Arthrobacter virus Preamble, Arthrobacter virus Pumancara, Arthrobacter virus Wayne, Mycobacterium virus Alma, Mycobacterium virus Arturo, Mycobacterium virus Astro, Mycobacterium virus Backyardigan, Mycobacterium virus BBPiebs31, Mycobacterium virus Benedict, Mycobacterium virus Bethlehem, Mycobacterium virus Billknuckles, Mycobacterium virus Bruns, Mycobacterium virus Bxbl, Mycobacterium virus Bxz2, Mycobacterium virus Che12, Mycobacterium virus Cuco, Mycobacterium virus D29, Mycobacterium virus Doom, Mycobacterium virus Ericb, Mycobacterium virus Euphoria, Mycobacterium virus George, Mycobacterium virus Gladiator, Mycobacterium virus Goose, Mycobacterium virus Hammer, Mycobacterium virus Heldan, Mycobacterium virus Jasper, Mycobacterium virus JC27, Mycobacterium virus Jeffabunny, Mycobacterium virus JHC117, Mycobacterium virus KBG, Mycobacterium virus Kssjeb, Mycobacterium virus Kugel, Mycobacterium virus L5, Mycobacterium virus Lesedi, Mycobacterium virus LHTSCC, Mycobacterium virus lockley, Mycobacterium virus Marcell, Mycobacterium virus Microwolf, Mycobacterium virus Mrgordo, Mycobacterium virus Museum, Mycobacterium virus Nepal, Mycobacterium virus Packman, Mycobacterium virus Peaches, Mycobacterium virus Perseus, Mycobacterium virus Pukovnik, Mycobacterium virus Rebeuca, Mycobacterium virus Redrock, Mycobacterium virus Ridgecb, Mycobacterium virus Rockstar, Mycobacterium virus Saintus, Mycobacterium virus Skipole, Mycobacterium virus Solon, Mycobacterium virus Switzer, Mycobacterium virus SWUl, Mycobacterium virus Tal7a, Mycobacterium virus Tiger, Mycobacterium virus Timshel, Mycobacterium virus Trixie, Mycobacterium virus Turbido, Mycobacterium virus Twister, Mycobacterium virus U2, Mycobacterium virus Violet, Mycobacterium virus Wonder, Escherichia virus DE3, Escherichia virus HK629, Escherichia virus HK630, Escherichia virus lambda, Arthrobacter virus Laroye, Mycobacterium virus Halo, Mycobacterium virus Liefie, Mycobacterium virus Marvin, Mycobacterium virus Mosmoris, Arthrobacter virus Circum, Arthrobacter virus Mudcat, Escherichia virus N15, Escherichia virus 9g, Escherichia virus JenKi, Escherichia virus JenP1, Escherichia virus JenP2, Pseudomonas virus NP1, Pseudomonas virus PaMx25, Mycobacterium virus Baka, Mycobacterium virus Courthouse, Mycobacterium virus Littlee, Mycobacterium virus Omega, Mycobacterium virus Optimus, Mycobacterium virus Thibault, Polaribacter virus P12002L, Polaribacter virus P12002S, Nonlabens virus P12024L, Nonlabens virus P12024S, Thermus virus P23-45, Thermus virus P74-26, Listeria virus LP26, Listeria virus LP37, Listeria virus LPI10, Listeria virus LP114, Listeria virus P70, Propionibacterium virus ATCC29399BC, Propionibacterium virus ATCC29399BT, Propionibacterium virus Attacne, Propionibacterium virus Keiki, Propionibacterium virus Kubed, Propionibacterium virus Lauchelly, Propionibacterium virus MrAK, Propionibacterium virus Ouroboros, Propionibacterium virus P91, Propionibacterium virus P105, Propionibacterium virus P144, Propionibacterium virus P1001, Propionibacterium virus P1.1, Propionibacterium virus P100A, Propionibacterium virus P100D, Propionibacterium virus P101A, Propionibacterium virus P104A, Propionibacterium virus PA6, Propionibacterium virus Pacnes201215, Propionibacterium virus PAD20, Propionibacterium virus PAS50, Propionibacterium virus PHL009M11, Propionibacterium virus PHL025M00, Propionibacterium virus PHL037M02, Propionibacterium virus PHL041M10, Propionibacterium virus PHL060L00, Propionibacterium virus PHL067M01, Propionibacterium virus PHL070N00, Propionibacterium virus PHL071N05, Propionibacterium virus PHL082M03, Propionibacterium virus PHL092M00, Propionibacterium virus PHL095N00, Propionibacterium virus PHL11IM01, Propionibacterium virus PHIL 112N00, Propionibacterium virus PHIL 113M01, Propionibacterium virus PHL114L00, Propionibacterium virus PHL116M00, Propionibacterium virus PHL117M00, Propionibacterium virus PHL117M01, Propionibacterium virus PHL132N00, Propionibacterium virus PHL141N00, Propionibacterium virus PHL151MOO, Propionibacterium virus PHL151N00, Propionibacterium virus PHL152M00, Propionibacterium virus PHL163M00, Propionibacterium virus PHL 171M01, Propionibacterium virus PHL 179M00, Propionibacterium virus PHL194M00, Propionibacterium virus PHL199M00, Propionibacterium virus PHL301M00, Propionibacterium virus PHL308M00, Propionibacterium virus Pirate, Propionibacterium virus Procrassl, Propionibacterium virus SKKY, Propionibacterium virus Solid, Propionibacterium virus Stormborn, Propionibacterium virus Wizzo, Pseudomonas virus PaMx28, Pseudomonas virus PaMx74, Mycobacterium virus Patience, Mycobacterium virus PBI1, Rhodococcus virus Pepy6, Rhodococcus virus Poco6, Propionibacterium virus PFR1, Streptomyces virus phiBTI, Streptomyces virus phiC31, Streptomyces virus TG1, Caulobacter virus Karma, Caulobacter virus Magneto, Caulobacter virus phiCbK, Caulobacter virus Rogue, Caulobacter virus Swift, Staphylococcus virus 11, Staphylococcus virus 29, Staphylococcus virus 37, Staphylococcus virus 53, Staphylococcus virus 55, Staphylococcus virus 69, Staphylococcus virus 71, Staphylococcus virus 80, Staphylococcus virus 85, Staphylococcus virus 88, Staphylococcus virus 92, Staphylococcus virus 96, Staphylococcus virus 187, Staphylococcus virus 52a, Staphylococcus virus 80alpha, Staphylococcus virus CNPH82, Staphylococcus virus EW, Staphylococcus virus IPLA5, Staphylococcus virus IPLA7, Staphylococcus virus IPLA88, Staphylococcus virus PH15, Staphylococcus virus phiETA, Staphylococcus virus phiETA2, Staphylococcus virus phiETA3, Staphylococcus virus phiMR11, Staphylococcus virus phiMR25, Staphylococcus virus phiNM1, Staphylococcus virus phiNM2, Staphylococcus virus phiNM4, Staphylococcus virus SAP26, Staphylococcus virus X2, Enterococcus virus FL 1, Enterococcus virus FL2, Enterococcus virus FL3, Lactobacillus virus ATCC8014, Lactobacillus virus phiJLI, Pediococcus virus cIPl, Aeromonas virus pIS4A, Listeria virus LP302, Listeria virus PSA, Methanobacterium virus psiM1, Roseobacter virus RDJL 1, Roseobacter virus RDJL2, Rhodococcus virus RER2, Enterococcus virus BC611, Enterococcus virus IMEEFI, Enterococcus virus SAP6, Enterococcus virus VD13, Streptococcus virus SPQS1, Mycobacterium virus Papyrus, Mycobacterium virus Send513, Burkholderia virus KL1, Pseudomonas virus 73, Pseudomonas virus Ab26, Pseudomonas virus Kakheti25, Escherichia virus Cajan, Escherichia virus Seurat, Staphylococcus virus SEP9, Staphylococcus virus Sextaec, Streptococcus virus 858, Streptococcus virus 2972, Streptococcus virus ALQ132, Streptococcus virus O1205, Streptococcus virus Sfi11, Streptococcus virus 7201, Streptococcus virus DT1, Streptococcus virus phiAbc2, Streptococcus virus Sfi19, Streptococcus virus Sfi21, Paenibacillus virus Diva, Paenibacillus virus Hb10c2, Paenibacillus virus Rani, Paenibacillus virus Shelly, Paenibacillus virus Sitara, Paenibacillus virus Willow, Lactococcus virus 712, Lactococcus virus ASCC191, Lactococcus virus ASCC273, Lactococcus virus ASCC281, Lactococcus virus ASCC465, Lactococcus virus ASCC532, Lactococcus virus Bibb29, Lactococcus virus bIL170, Lactococcus virus CB13, Lactococcus virus CB14, Lactococcus virus CB19, Lactococcus virus CB20, Lactococcus virus jj50, Lactococcus virus P2, Lactococcus virus P008, Lactococcus virus skl, Lactococcus virus S14, Bacillus virus Slash, Bacillus virus Stahl, Bacillus virus Staley, Bacillus virus Stills, Gordonia virus Bachita, Gordonia virus ClubL, Gordonia virus OneUp, Gordonia virus Smoothie, Gordonia virus Soups, Bacillus virus SPbeta, Vibrio virus MARIO, Vibrio virus SSP002, Escherichia virus AKFV33, Escherichia virus BF23, Escherichia virus DT57C, Escherichia virus EPS7, Escherichia virus FFH1, Escherichia virus H8, Escherichia virus slur09, Escherichia virus T5, Salmonella virus 118970sa12, Salmonella virus Shivani, Salmonella virus SPC35, Salmonella virus Stitch, Arthrobacter virus Tank, Tsukamurella virus TIN2, Tsukamurella virus TIN3, Tsukamurella virus TIN4, Rhodobacter virus RcSpartan, Rhodobacter virus RcTitan, Mycobacterium virus Anaya, Mycobacterium virus Angelica, Mycobacterium virus Crimd, Mycobacterium virus Fionnbarth, Mycobacterium virus Jaws, Mycobacterium virus Larva, Mycobacterium virus Macncheese, Mycobacterium virus Pixie, Mycobacterium virus TM4, Bacillus virus BMBtp2, Bacillus virus TP21, Geobacillus virus Tp84, Staphylococcus virus 47, Staphylococcus virus 3a, Staphylococcus virus 42e, Staphylococcus virus IPLA35, Staphylococcus virus phi12, Staphylococcus virus phiSLT, Mycobacterium virus 32HC, Rhodococcus virus RGL3, Paenibacillus virus Vegas, Gordonia virus Vendetta, Bacillus virus Wbeta, Mycobacterium virus Wildcat, Gordonia virus Twister6, Gordonia virus Wizard, Gordonia virus Hotorobo, Gordonia virus Monty, Gordonia virus Woes, Xanthomonas virus CP1, Xanthomonas virus OP1, Xanthomonas virus phil7, Xanthomonas virus Xop411, Xanthomonas virus Xp10, Streptomyces virus TP1604, Streptomyces virus YDN12, Alphaproteobacteria virus phiJl001, Pseudomonas virus LKO4, Pseudomonas virus M6, Pseudomonas virus MP1412, Pseudomonas virus PAE1, Pseudomonas virus Yua, Pseudoalteromonas virus PM2, Pseudomonas virus phi6, Pseudomonas virus phi8, Pseudomonas virus phi12, Pseudomonas virus phi13, Pseudomonas virus phi2954, Pseudomonas virus phiNN, Pseudomonas virus phiYY, Vibrio virus fsl, Vibrio virus VGJ, Ralstonia virus RS603, Ralstonia virus RSM1, Ralstonia virus RSM3, Escherichia virus M13, Escherichia virus 122, Salmonella virus IKe, Acholeplasma virus L51, Vibrio virus fs2, Vibrio virus VFJ, Escherichia virus If1, Propionibacterium virus B5, Pseudomonas virus Pf1, Pseudomonas virus Pf3, Ralstonia virus PE226, Ralstonia virus RSS1, Spiroplasma virus SVTS2, Stenotrophomonas virus PSH1, Stenotrophomonas virus SMA6, Stenotrophomonas virus SMA7, Stenotrophomonas virus SMA9, Vibrio virus CTXphi, Vibrio virus KSF1, Vibrio virus VCY, Vibrio virus Vf33, Vibrio virus Vf03K6, Xanthomonas virus Cflc, Spiroplasma virus C74, Spiroplasma virus R8A2B, Spiroplasma virus SkV1CR23x, Escherichia virus FI, Escherichia virus Qbeta, Escherichia virus BZ13, Escherichia virus MS2, Escherichia virus alpha3, Escherichia virus ID21, Escherichia virus ID32, Escherichia virus ID62, Escherichia virus NC28, Escherichia virus NC29, Escherichia virus NC35, Escherichia virus phiK, Escherichia virus Stl, Escherichia virus WA45, Escherichia virus G4, Escherichia virus ID52, Escherichia virus Talmos, Escherichia virus phiX174, Bdellovibrio virus MAC1, Bdellovibrio virus MH2K, Chlamydia virus Chpl, Chlamydia virus Chp2, Chlamydia virus CPAR39, Chlamydia virus CPG1, Spiroplasma virus SpV4, Acholeplasma virus L2, Pseudomonas virus PR4, Pseudomonas virus PRD1, Bacillus virus AP50, Bacillus virus Bam35, Bacillus virus GIL16, Bacillus virus Wip1, Escherichia virus phi80, Escherichia virus RB42, Escherichia virus T2, Escherichia virus T3, Escherichia virus T6, Escherichia virus VT2-Sa, Escherichia virus VT1-Sakai, Escherichia virus VT2-Sakai, Escherichia virus CP-933V, Escherichia virus P27, Escherichia virus Stx2phi-I, Escherichia virus Stxlphi, Escherichia virus Stx2phi-II, Escherichia virus CP-1639, based on the Escherichia virus BP-4795, Escherichia virus 86, Escherichia virus Min27, Escherichia virus 2851, Escherichia virus 1717, Escherichia virus YYZ-2008, Escherichia virus EC026_P06, Escherichia virus ECO103_P15, Escherichia virus ECO103_P12, Escherichia virus ECO111_P16, Escherichia virus ECOl11_P11, Escherichia virus VT2phi_272, Escherichia virus TL-201 ic, Escherichia virus P13374, Escherichia virus Sp5.


In one embodiment, the bacterial virus particles target E. coli and includes the capsid of a bacteriophage selected in the group consisting of BW73, B278, D6, D108, E, El, E24, E41, FI-2, FI-4, F1-5, H18A, Ffl8B, i, MM, Mu, 025, PhI-5, Pk, PSP3, Pl, PID, P2, P4, S1, Wφ, φK13, φl, φ2, φ7, φ92, 7 A, 8φ, 9φ, 18, 28-1, 186, 299, HH-Escherichia (2), AB48, CM, C4, C16, DD-VI, E4, E7, E28, Fll, FI3, H, Hl, H3, H8, K3, M, N, ND-2, ND-3, ND4, ND-5, ND6, ND-7, Ox-I, Ox-2, Ox-3, Ox-4, Ox-5, Ox-6, PhI-I, RB42, RB43, RB49, RB69, S, SaI-I, Sal-2, Sal-3, Sal-4, Sal-5, Sal-6, TC23, TC45, Tull*-6, TuIP-24, TuII*46, TulP-60, T2, T4, T6, T35, al, 1, IA, 3, 3A, 3T+, 5φ, 9266Q, CF0103, HK620, J, K, KiF, m59, no. A, no. E, no. 3, no. 9, N4, sd, T3, T7, WPK, W31, ΔH, φC3888, φK3, φK7, φK12, φV-1, Φ04-CF, Φ05, Φ06, Φ07, φ1, φ1.2, φ20, φ95, φ263, φ1092, φ1, φ11, Ω8, 1, 3, 7, 8, 26, 27, 28-2, 29, 30, 31, 32, 38, 39, 42, 933W, NN-Escherichia (1), Esc-7-11, AC30, CVX-5, C1, DDUP, ECI, EC2, E21, E29, F1, F26S, F27S, Hi, HK022, HK97, HK139, HK253, HK256, K7, ND-I, PA-2, q, S2, TI, ), T3C, T5, UC-I, w, p4, γ2, λ, ΦD326, φγ, Φ06, Φ7, Φ10, φ80, χ, 2, 4, 4A, 6, 8A, 102, 150, 168, 174, 3000, AC6, AC7, AC28, AC43, AC50, AC57, AC81, AC95, HK243, KlO, ZG/3A, 5, 5A, 21EL, H19-J and 933H.


As used herein, a “prebiotic” refers to an ingredient that allows specific changes, both in the composition and/or activity in the gastrointestinal microbiota that may confer benefits upon the host. A prebiotic can be a comestible food or beverage or ingredient thereof. A prebiotic may be a selectively fermented ingredient. Prebiotics may include complex carbohydrates, amino acids, peptides, minerals, or other essential nutritional components for the survival of the bacterial composition. Prebiotics include, but are not limited to, amino acids, biotin, fructo-oligosaccharide, galacto-oligosaccharides, hemicelluloses (e.g., arabinoxylan, xylan, xyloglucan, and glucomannan), inulin, chitin, lactulose, mannan oligosaccharides, oligofructose-enriched inulin, gums (e.g., guar gum, gum arabic and carregenaan), oligofructose, oligodextrose, tagatose, resistant maltodextrins (e.g., resistant starch), trans-galactooligosaccharide, pectins (e.g., xylogalactouronan, citrus pectin, apple pectin, and rhamnogalacturonan-I), dietary fibers (e.g., soy fiber, sugarbeet fiber, pea fiber, corn bran, and oat fiber) and xylooligosaccharides.


As use herein, a “probiotic” refers to a dietary supplement based on living microbes which, when taken in adequate quantities, has a beneficial effect on the host organism by strengthening the intestinal ecosystem. Probiotic can comprise a non-pathogenic bacterial or fungal population, e.g., an immunomodulatory bacterial population, such as an anti-inflammatory bacterial population, with or without one or more prebiotics. They contain a sufficiently high number of living and active probiotic microorganisms that can exert a balancing action on gut flora by direct colonisation. It must be noted that, for the purposes of the present description, the term “probiotic” is taken to mean any biologically active form of probiotic, preferably but not limited to lactobacilli, bifidobacteria, streptococci, enterococci, propionibacteria or saccharomycetes but even other microorganisms making up the normal gut flora, or also fragments of the bacterial wall or of the DNA of these microorganisms. These compositions are advantageous in being suitable for safe administration to humans and other mammalian subjects and are efficacious for the treatment, prevention, of a bacterial infection. Probiotics include, but are not limited to lactobacilli, bifidobacteria, streptococci, enterococci, propionibacteria, saccharomycetes, lactobacilli, bifidobacteria, or proteobacteria.


The antibiotic can be selected from the group consisting in penicillins such as penicillin G, penicillin K, penicillin N, penicillin O, penicillin V, methicillin, benzylpenicillin, nafcillin, oxacillin, cloxacillin, dicloxacillin, ampicillin, amoxicillin, pivampicillin, hetacillin, bacampicillin, metampicillin, talampicillin, epicillin, carbenicillin, ticarcillin, temocillin, mezlocillin, and piperacillin; cephalosporins such as cefacetrile, cefadroxil, cephalexin, cefaloglycin, cefalonium, cefaloridine, cefalotin, cefapirin, cefatrizine, cefazaflur, cefazedone, cefazolin, cefradine, cefroxadine, ceftezole, cefaclor, cefonicid, cefprozil, cefuroxime, cefuzonam, cefmetazole, cefotetan, cefoxitin, loracarbef, cefbuperazone, cefminox, cefotetan, cefoxitin, cefotiam, cefcapene, cefdaloxime, cefdinir, cefditoren, cefetamet, cefixime, cefmenoxime, cefodizime, cefotaxime, cefovecin, cefpimizole, cefpodoxime, cefteram, ceftamere, ceftibuten, ceftiofur, ceftiolene, ceftizoxime, ceftriaxone, cefoperazone, ceftazidime, latamoxef, cefclidine, cefepime, cefluprenam, cefoselis, cefozopran, cefpirome, cefquinome, flomoxef, ceftobiprole, ceftaroline, ceftolozane, cefaloram, cefaparole, cefcanel, cefedrolor, cefempidone, cefetrizole, cefivitril, cefmatilen, cefmepidium, cefoxazole, cefrotil, cefsumide, ceftioxide, cefuracetime, and nitrocefin; polymyxins such as polysporin, neosporin, polymyxin B, and polymyxin E, rifampicins such as rifampicin, rifapentine, and rifaximin; Fidaxomicin; quinolones such as cinoxacin, nalidixic acid, oxolinic acid, piromidic acid, pipemidic acid, rosoxacin, ciprofloxacin, enoxacin, fleroxacin, lomefloxacin, nadifloxacin, norfloxacin, ofloxacin, pefloxacin, rufloxacin, balofloxacin, grepafloxacin, levofloxacin, pazufloxacin, temafloxacin, tosufloxacin, clinafloxacin, gatifloxacin, gemifloxacin, moxifloxacin, sitafloxacin, trovafloxacin, prulifloxacin, delafloxacin, nemonoxacin, and zabofloxacin; sulfonamides such as sulfafurazole, sulfacetamide, sulfadiazine, sulfadimidine, sulfafurazole, sulfisomidine, sulfadoxine, sulfamethoxazole, sulfamoxole, sulfanitran, sulfadimethoxine, sulfametho-xypyridazine, sulfametoxydiazine, sulfadoxine, sulfametopyrazine, and terephtyl; macrolides such as azithromycin, clarithromycin, erythromycin, fidaxomicin, telithromycin, carbomycin A, josamycin, kitasamycin, midecamycin, oleandomycin, solithromycin, spiramycin, troleandomycin, tylosin, and roxithromycin; ketolides such as telithromycin, and cethromycin; lluoroketolides such as solithromycin; lincosamides such as lincomycin, clindamycin, and pirlimycin; tetracyclines such as demeclocycline, doxycycline, minocycline, oxytetracycline, and tetracycline; aminoglycosides such as amikacin, dibekacin, gentamicin, kanamycin, neomycin, netilmicin, sisomicin, tobramycin, paromomycin, and streptomycin; ansamycins such as geldanamycin, herbimycin, and rifaximin; carbacephems such as loracarbef; carbapenems such as ertapenem, doripenem, imipenem (or cilastatin), and meropenem; glycopeptides such as teicoplanin, vancomycin, telavancin, dalbavancin, and oritavancin; lincosamides such as clindamycin and lincomycin; lipopeptides such as daptomycin; monobactams such as aztreonam; nitrofurans such as furazolidone, and nitrofurantoin; oxazolidinones such as linezolid, posizolid, radezolid, and torezolid; teixobactin, clofazimine, dapsone, capreomycin, cycloserine, ethambutol, ethionamide, isoniazid, pyrazinamide, rifabutin, arsphenamine, chloramphenicol, fosfomycin, fusidic acid, metronidazole, mupirocin, platensimycin, quinupristin (or dalfopristin), thiamphenicol, tigecycline, tinidazole, trimethoprim, alatrofloxacin, fidaxomycin, nalidixice acide, rifampin, derivatives and combination thereof.


The present invention provides pharmaceutical or veterinary compositions comprising one or more of the bacterial delivery vehicles disclosed herein and a pharmaceutically-acceptable carrier. Generally, for pharmaceutical use, the bacterial delivery vehicles may be formulated as a pharmaceutical preparation or compositions comprising at least one bacterial delivery vehicles and at least one pharmaceutically acceptable carrier, diluent or excipient, and optionally one or more further pharmaceutically active compounds. Such a formulation may be in a form suitable for oral administration, for parenteral administration (such as by intravenous, intramuscular or subcutaneous injection or intravenous infusion), for topical administration, for administration by inhalation, by a skin patch, by an implant, by a suppository, etc. Such administration forms may be solid, semi-solid or liquid, depending on the manner and route of administration. For example, formulations for oral administration may be provided with an enteric coating that will allow the synthetic bacterial delivery vehicles in the formulation to resist the gastric environment and pass into the intestines. More generally, synthetic bacterial delivery vehicle formulations for oral administration may be suitably formulated for delivery into any desired part of the gastrointestinal tract. In addition, suitable suppositories may be used for delivery into the gastrointestinal tract. Various pharmaceutically acceptable carriers, diluents and excipients useful in bacterial delivery vehicle compositions are known to the skilled person.


Also provided are methods for treating a bacterial infection using the synthetic bacterial delivery vehicles disclosed herein. The methods include administering the synthetic bacterial delivery vehicles or compositions disclosed herein to a subject having a bacterial infection in need of treatment. In some embodiments, the subject is a mammal. In some embodiments, the subject is a human.


The pharmaceutical or veterinary composition according to the disclosure may further comprise a pharmaceutically acceptable vehicle. A solid pharmaceutically acceptable vehicle may include one or more substances which may also act as flavouring agents, lubricants, solubilisers, suspending agents, dyes, fillers, glidants, compression aids, inert binders, sweeteners, preservatives, dyes, coatings, or tablet-disintegrating agents. Suitable solid vehicles include, for example calcium phosphate, magnesium stearate, talc, sugars, lactose, dextrin, starch, gelatin, cellulose, polyvinylpyrrolidine, low melting waxes and ion exchange resins.


The pharmaceutical or veterinary composition may be prepared as a sterile solid composition that may be suspended at the time of administration using sterile water, saline, or other appropriate sterile injectable medium. The pharmaceutical or veterinary compositions of the disclosure may be administered orally in the form of a sterile solution or suspension containing other solutes or suspending agents (for example, enough saline or glucose to make the solution isotonic), bile salts, acacia, gelatin, sorbitan monoleate, polysorbate 8o (oleate esters of sorbitol and its anhydrides copolymerized with ethylene oxide) and the like. The particles according to the disclosure can also be administered orally either in liquid or solid composition form. Compositions suitable for oral administration include solid forms, such as pills, capsules, granules, tablets, and powders, and liquid forms, such as solutions, syrups, elixirs, and suspensions. Forms useful for enteral administration include sterile solutions, emulsions, and suspensions.


The bacterial delivery vehicles according to the disclosure may be dissolved or suspended in a pharmaceutically acceptable liquid vehicle such as water, an organic solvent, a mixture of both or pharmaceutically acceptable oils or fats. The liquid vehicle can contain other suitable pharmaceutical additives such as solubilisers, emulsifiers, buffers, preservatives, sweeteners, flavouring agents, suspending agents, thickening agents, colours, viscosity regulators, stabilizers or osmo-regulators. Suitable examples of liquid vehicles for oral and enteral administration include water (partially containing additives as above, e.g. cellulose derivatives, preferably sodium carboxymethyl cellulose solution), alcohols (including monohydric alcohols and polyhydric alcohols, e.g. glycols) and their derivatives, and oils (e.g. fractionated coconut oil and arachis oil). For parenteral administration, the vehicle can also be an oily ester such as ethyl oleate and isopropyl myristate. Sterile liquid vehicles are useful in sterile liquid form compositions for enteral administration. The liquid vehicle for pressurized compositions can be a halogenated hydrocarbon or other pharmaceutically acceptable propellant.


For transdermal administration, the pharmaceutical or veterinary composition can be formulated into ointment, cream or gel form and appropriate penetrants or detergents could be used to facilitate permeation, such as dimethyl sulfoxide, dimethyl acetamide and dimethylformamide.


For transmucosal administration, nasal sprays, rectal or vaginal suppositories can be used. The active compounds can be incorporated into any of the known suppository bases by methods known in the art. Examples of such bases include cocoa butter, polyethylene glycols (carbowaxes), polyethylene sorbitan monostearate, and mixtures of these with other compatible materials to modify the melting point or dissolution rate.


The present invention relates to a method for treating a disease or disorder caused by bacteria comprising administering a therapeutically amount of the pharmaceutical or veterinary composition as disclosed herein to a subject having such disease or disorder and in need of treatment. It also relates to the pharmaceutical or veterinary composition as disclosed herein for use in the treatment of a disease or disorder caused by bacteria. It further relates to the use of a pharmaceutical or veterinary composition as disclosed herein for the manufacture of a medicament for treating a disease or disorder caused by bacteria.


The diseases or disorders caused by bacteria may be selected from the group consisting of abdominal cramps, acne vulgaris, acute epiglottitis, arthritis, bacteraemia, bloody diarrhea, botulism, Brucellosis, brain abscess, chancroid venereal disease, Chlamydia, Crohn's disease, conjunctivitis, cholecystitis, colorectal cancer, polyposis, dysbiosis, Lyme disease, diarrhea, diphtheria, duodenal ulcers, endocarditis, erysipelothricosis, enteric fever, fever, glomerulonephritis, gastroenteritis, gastric ulcers, Guillain-Barre syndrome tetanus, gonorrhoea, gingivitis, inflammatory bowel diseases, irritable bowel syndrome, leptospirosis, leprosy, listeriosis, tuberculosis, Lady Widermere syndrome, Legionaire's disease, meningitis, mucopurulent conjunctivitis, multi-drug resistant bacterial infections, multi-drug resistant bacterial carriage, myonecrosis-gas gangrene, Mycobacterium avium complex, neonatal necrotizing enterocolitis, nocardiosis, nosocomial infection, otitis, periodontitis, phalyngitis, pneumonia, peritonitis, purpuric fever, Rocky Mountain spotted fever, shigellosis, syphilis, sinusitis, sigmoiditis, septicaemia, subcutaneous abscesses, tularaemia, tracheobronchitis, tonsillitis, typhoid fever, ulcerative colitis, urinary infection and whooping cough.


The disease or disorder caused by bacteria may be a bacterial infection selected from the group consisting of skin infections such as acne, intestinal infections such as esophagitis, gastritis, enteritis, colitis, sigmoiditis, rectitis, and peritonitis, urinary tract infections, vaginal infections, female upper genital tract infections such as salpingitis, endometritis, oophoritis, myometritis, parametritis and infection in the pelvic peritoneum, respiratory tract infections such as pneumonia, intra-amniotic infections, odontogenic infections, endodontic infections, fibrosis, meningitis, bloodstream infections, nosocomial infection such as catheter-related infections, hospital acquired pneumonia, post-partum infection, hospital acquired gastroenteritis, hospital acquired urinary tract infections, and a combination thereof. Preferably, the infection according to the disclosure is caused by a bacterium presenting an antibiotic resistance. In a particular embodiment, the infection is caused by a bacterium as listed above in the targeted bacteria.


The disease or disorder caused by bacteria may also be a metabolic disorder, for example, obesity and diabetes. The disclosure thus also concerns a pharmaceutical or veterinary composition as disclosed herein for use in the treatment of metabolic disorder including, for example, obesity and diabetes. It further concerns a method for treating a metabolic disorder comprising administering a therapeutically amount of the pharmaceutical or veterinary composition as disclosed herein, and the use of a pharmaceutical or veterinary composition as disclosed herein for the manufacture of a medicament for treating a metabolic disorder.


The disease or disorder caused by bacteria may also be a pathology involving bacteria of the human microbiome. Thus, in a particular embodiment, the disclosure concerns a pharmaceutical or veterinary composition as disclosed herein for use in the treatment of pathologies involving bacteria of the human microbiome, such as inflammatory and auto-immune diseases, cancers, infections or brain disorders. It further concerns a method for treating a pathology involving bacteria of the human microbiome comprising administering a therapeutically amount of the pharmaceutical or veterinary composition as disclosed herein, and the use of a pharmaceutical or veterinary composition as disclosed herein for the manufacture of a medicament for treating a pathology involving bacteria of the human microbiome. Indeed, some bacteria of the microbiome, without triggering any infection, can secrete molecules that will induce and/or enhance inflammatory or auto-immune diseases or cancer development. More specifically, the present disclosure relates also to modulating microbiome composition to improve the efficacy of immunotherapies based, for example, on CAR-T (Chimeric Antigen Receptor T) cells, TIL (Tumor Infiltrating Lymphocytes) and Tregs (Regulatory T cells) also known as suppressor T cells. Modulation of the microbiome composition to improve the efficacy of immunotherapies may also include the use of immune checkpoint inhibitors well known in the art such as, without limitation, PD-1 (programmed cell death protein 1) inhibitor, PD-L1 (programmed death ligand 1) inhibitor and CTLA-4 (cytotoxic T lymphocyte associated protein 4).


Some bacteria of the microbiome can also secrete molecules that will affect the brain.


Therefore, a further object of the disclosure is a method for controlling the microbiome of a subject, comprising administering an effective amount of the pharmaceutical composition as disclosed herein in said subject.


In a particular embodiment, the disclosure also relates to a method for personalized treatment for an individual in need of treatment for a bacterial infection comprising: i) obtaining a biological sample from the individual and determining a group of bacterial DNA sequences from the sample; ii) based on the determining of the sequences, identifying one or more pathogenic bacterial strains or species that were in the sample; and iii) administering to the individual a pharmaceutical composition according to the disclosure capable of recognizing each pathogenic bacterial strain or species identified in the sample and to deliver the packaged plasmid.


Preferably, the biological sample comprises pathological and non-pathological bacterial species, and subsequent to administering the pharmaceutical or veterinary composition according to the disclosure to the individual, the amount of pathogenic bacteria on or in the individual are reduced, but the amount of non-pathogenic bacteria is not reduced.


In another particular embodiment, the disclosure concerns a pharmaceutical or veterinary composition according to the disclosure for use in order to improve the effectiveness of drugs. Indeed, some bacteria of the microbiome, without being pathogenic by themselves, are known to be able to metabolize drugs and to modify them in ineffective or harmful molecules.


In another particular embodiment, the disclosure concerns a composition according to the invention that may further comprise at least one additional active ingredient, for instance a prebiotic and/or a probiotic and/or an antibiotic, and/or another antibacterial or antibiofilm agent, and/or any agent enhancing the targeting of the bacterial delivery vehicle to a bacteria and/or the delivery of the payload into a bacteria.


In another particular embodiment, the disclosure concerns the in-situ bacterial production of any compound of interest, including therapeutic compound such as prophylactic and therapeutic vaccine for mammals. The compound of interest can be produced inside the targeted bacteria, secreted from the targeted bacteria or expressed on the surface of the targeted bacteria. In a more particular embodiment, an antigen is expressed on the surface of the targeted bacteria for prophylactic and/or therapeutic vaccination.


The present disclosure also relates to a non-therapeutic use of the bacterial delivery particles. For instance, the non-therapeutic use can be a cosmetic use or a use for improving the well-being of a subject, in particular a subject who does not suffer from a disease, and in particular from a disease or disorder caused by bacteria. Accordingly, the present disclosure also relates to a cosmetic composition or a non-therapeutic composition comprising the bacterial delivery particles of the disclosure.


Example 1

The example below demonstrates that a significative portion of a lambda receptor binding protein (RBP), e.g. the stf protein, can be exchanged with a portion of a different RBP. More particularly, specific fusion positions in the lambda RBP have been identified which allow one to obtain a functional chimeric RBP. Specifically, the data demonstrate in a non-limiting embodiment that in the case of packaged phagemids derived from bacteriophage lambda, modifying the side tail fiber protein results in an expanded host range. The addition of chimeric stf proteins to lambdoid packaged phagemids, is demonstrated to be a very powerful approach to modify and increase their host range, and in some cases is more efficient than the modification of the gpJ gene. In addition, modification of the side tail fiber protein to encode enzymatic activity such as depolymerase activities can dramatically increase the delivery efficiency. In some cases, the addition of this enzymatic activity allows for 100% delivery efficiency while the wild-type lambda packaged phagemid showed no entry at all. These two approaches can be combined to generate packaged phagemid variants with different specificities and delivery efficiencies to many strains of bacterial species.


Materials and Methods

Tests were conducted to determine whether the modification of the tail tip gene (gpJ) would have an impact in the host range of lambda packaged phagemids. The lambda tail tip was modified to include the mutations described in [11] to generate OMPF-lambda. This packaged phagemid should now use OmpF instead of LamB as a primary receptor in the cell surface. Next, the delivery efficiency was tested in a collection of E. coli strains that spans a variety of O and K serotypes, as shown in FIG. 1.


As can be seen in FIG. 1, using packaged phagemids that recognize a different cell surface receptor has a minimal impact on efficiency delivery and host range. Only 3 strains show a marginal improvement in the number of colonies after treatment with the modified packaged phagemid. This result may be due to the presence of a capsule around the majority of the cells that forms a physical barrier to the packaged phagemids, thus rendering this approach unsuccessful. In view of these results, the lambda stf gene was modified to include enzymatic activities against bacterial capsules.


The sequence of lambda stf (SEQ ID NO:1) is:









MAVKISGVLKDGTGKPVQNCTIQLKARRNSTTVVVNTVGSENPDEAGRY





SMDVEYGQYSVILQVDGFPPSHAGTITVYEDSQPGTLNDFLCAMTEDDA





RPEVLRRLELMVEEVARNASVVAQSTADAKKSAGDASASAAQVAALVTD





ATDSARAASTSAGQAASSAQEASSGAEAASAKATEAEKSAAAAESSKNA





AATSAGAAKTSETNAAASQQAATSASTAATKASEAATSARDAVASKEAA





KSSETNASSSAGRAASSATAAENSARAAKTSETNARSSETAAERSASAA





ADAKTAAAGSASTASTKATEAAGSAVSASQSKSAAEAAAIRAKNSAKRA





EDIASAVALEDADTTRKGIVQLSSATNSTSETLAATPKAVKVVMDETNR





KAPLDSPALTGTPTAPTALRGTNNTQIANTAFVLAAIADVIDASPDALN





TLNELAAALGNDPDFATTMTNALAGKQPKNATLTALAGLSTAKNKLPYF





AENDAASLTELTQVGRDILAKNSVADVLEYLGAGENSAFPAGAPIPWPS







DIVPSGYVLMQGQAFDKSAYPKLAVAYPSGVLPDMRGWTIKGKPASGRA









VLSQEQDGIKSHTHSASASGTDLGTKTTSSFDYGTKTTGSFDYGTKSTN









NTGAHAHSLSGSTGAAGAHAHTSGLRMNSSGWSQYGTATITGSLSTVKG









TSTQGIAYLSKTDSQGSHSHSLSGTAVSAGAHAHTVGIGAQHPVVIGAH









AHSFSIGSHGHTITVNAAGNAENTVKNIAFNYIVRLA








The bold and underlined sequence represents the part of the protein that was introduced in the T4 phage (Montag et al. J Bacteriol. 1989 August; 171(8): 4378-4384). Experiments were conducted to investigate if it was possible to exchange the C-terminus of the lambda stf with a tail fiber from a different phage to yield chimeric side tail fibers with an enzymatic activity against encapsulated E. coli. The tail fiber from the K1F phage which has been studied in depth and its structure solved [19], [20] was chosen. K1F encodes an enzyme with endosialidase activity, which is active against polymer of sialic acid secreted by K1-encapsulated E. coli. In fact, K1+ strains are immune to T7 infection because the capsule forms a physical barrier that prevents attachment of the phage, but if purified K1F enzyme is added to the cells before infection, T7 is able to lyse them [21], confirming that the presence of bacterial capsules is a powerful mechanism to avoid recognition by bacteriophages. Thus, by testing delivery of modified lambda-stf-K1 packaged phagemids in K1+ strains it was possible to verify whether the lambda-stf chimeric proteins retain its enzymatic activity.


The sequence of K1F tail fiber (SEQ ID NO:121) is:









MSTITQFPSGNTQYRIEFDYLARTFVVVTLVNSSNPTLNRVLEVGRDYR





FLNPTMIEMLVDQSGFDIVRIHRQTGTDLVVDFRNGSVLTASDLTTAEL





QAIHIAEEGRDQTVDLAKEYADAAGSSAGNAKDSEDEARRIAESIRAAG





LIGYMTRRSFEKGYNVTTWSEVLLWEEDGDYYRWDGTLPKNVPAGSTPE





TSGGIGLGAWVSVGDAALRSQISNPEGAILVPELHRARWLDEKDARGWG







AKGDGVTDDTAALTSALNDTPVGQKINGNGKTYKVTSLPSISRFINTRF









VYERIPGQPLVYASEEFVQGKLFKITDTPYYNAWPQDKAFVVENVIYAP









YMGSDRHGVSRLHVSWVKSGDDGQTWSTPEWLTDLHPDYPTVNYHCMSM









GVCRNRLFAMIETRTLAKNALTNCALWDRPMSRSLHLTGGITKAANQRY









ATIHVPDHGLFVGDFVNFSNSAVTCVSGDMTVATVIDKDNFTVLTPNQQ









TSDLNNAGKNWHMGTSFHKSPWRKTDLGLIPSVTEVHSFATIDNNGFAM









GYHQGDVAPREVGLFYEPDAFNSPSNYVRRQIPSEYEPDASEPCIKYYD









GVLYLITRGTRGDRLGSSLHRSRDIGQTWESLRFPHNVHHTTLPFAKVG









DDLIMFGSERAENEWEAGAPDDRYKASYPRTFYARLNVNNWNADDIEWV









NITDQIYQGGIVNSGVGVGSVVVKDNYIYYMFGGEDHFNPWTYGDNSAK









DPFKSDGHPSDLYCYKMKIGPDNRVSRDFRYGAVPNRAVPVFFDTNGVR









TVPAPMEFTGDLGLGHVTIRASTSSNIRSEVLMEGEYGFIGKSIPTDNP









AGQRIIFCGGEGTSSTTGAQITLYGANNTDSRRIVYNGDEHLFQSADVK









PYNDNVTALGGPSNRFTTAYLGSNPIVTSNGERKTEPVVFDDAFLDAWG









DVHYIMYQWLDAVQLKGNDARIHFGVIAQQIRDVFIAHGLMDENSTNCR









YAVLCYDKYPRMTDTVFSHNEIVEHTDEEGNVTTTEEPVYTEVVIHEEG









EEWGVRPDGIFFAEAAYQRRKLERIEARLSALEQK








The bold and underlined sequence represents the part of the protein that has been crystalized and has been shown to retain its endosialidase activity. Since there is no identity between the lambda stf protein and the KiF tail fiber, the insertion site was made based on conclusions extracted from different sources of information, including literature and crystal structures.


The stf gene was modified to include the K1F endosialidase at its C-terminus using a Cas9-mediated gene exchange protocol [22] and resulted in a lambda-K1F chimeric stf of nucleotide sequence SEQ ID NO. 106 and amino acid sequence SEQ ID NO: 46. Lambda-K1F phagemids were produced as in [23] and titrated against some K1+ strains, specifically E. coli UTI89 and S88. The results were striking; in these strains, there is no delivery if lambda wild-type stf is used, but the addition of the lambda-K1F variant of SEQ ID NO: 46 to the packaged phagemid gives 100% delivery (FIG. 2).


The same principle was followed to create a different variant of lambda-stf, this time with K5-capsule degrading activity (K5 lyase tail fiber from phage K5A). As in the case of K1F, there is no homology between lambda-stf and K5 lyase, but its crystal structure has been published [24]. Hence, the same approach as for K1F was used to generate lambda-K5 chimeric side tail fibers of nucleotide sequence SEQ ID NO: 107 and amino acid sequence SEQ ID NO. 47 and tested the produced packaged phagemids against a K5-encapsulated strain of E. coli (ECOR 55). In this case, however, a de/ta-stf lambda production strain was produced with the lambda-K5 stf fusion gene expressed in trans under the control of an inducible promoter. As depicted in FIG. 3, there was some residual delivery using the wild-type lambda-stf, probably due to the presence of some cells with a thinner K5 capsule. However, the addition of lambda-stf-K5 chimeras allows for an improvement in delivery of more than 106 fold.


In some other cases, side tail fibers can be found that have some degree of homology to lambda stf, although no crystal structure is available. In these cases, the insertion site was designed as the last stretch of amino acids with identity to lambda stf. For example, in two in-house sequenced phages, the predicted side tail fiber proteins are as follows:









Phage AG22 stf:


(SEQ ID NO: 204)


MAIYRQGQASMDAQGYVTGYGTKWRELQLTLIRPGATIFFLAQPLQAAV





ITEVISDTSIRAITTGGAVVQKTNYLILLHDSLTVDGLAQDVAETLRYY





QGKESEFAGFIEIIKDFDWDKLQKIQEDVKTNADAAAASQQAAKTSENN





AKTSATNAANSKKGADTAKAAAESARDAANTAKTGAEAAKSGAESARDA





ANTAKAGAESARDQAEEYAKQAAEPYKDLLQPLPDVWIPFNDSLDMITG





FSPSYKKIVIGDDEITMPGDKIVKRKRASTATYINKSGVLTNAAIDEPR





FEKDGLLIEGQRTNLLINSTNPSKWNKSSNMILDRSGVDDFGFQYAKFT





LKPEMVGQTSSINIVTVSGSRGFDVTGNEKYVTISCRAQSGTPNLRCRL





RFENYDGSAYASLGDAYVNLTDLSIEKTGGAANRITARAVKDEASKWIF





FEATIKALDTENMIGAMVQYAPAKDGGGTGADDYIYIATPQVEGGVCAS





SFIITEATPVTRASDMVTIPIKNNLYNLPFTVLCEVHKNWYITPNAAPR





VFDTGGHQSGAAIILAFGSADGDNDGFPYCDIGKSNRRVNENAKLKKMI





IGMRVKSDYNTCCVSNARISSETKTEWRYIVSTATIRIGGQTSTGERHL





FGHVRNFRIWHKALTDHQLGEIV


and





corresponding nucleotide sequence of SEQ ID NO:


213.






Its alignment to lambda stf is as follows:












Lambda
156
STSAGQAASSAQEASSGAPAASAKATPAEKSAAAAESSKNAAATSAGAAKTSETNAAASQ



AG22
 92
ETLRYYQGKESEFAGFIEIIKDFDWDKLQKIQEDVKTNADAAAASQQAAKTSENNAKTSA




 *           *               *          *** *  ****** **  * 






The sequence of the stf of a second in-house phage is as follows:









Phage SIEA11 stf:


(SEQ ID NO: 205)


MSTKFKTVITTAGAAKLAAATVPGGKKNTTLSAMAVGDGNGKLPVPDAG





QTKLVHEVWRHALNKVSVDNKNKNYIVAELVVPPEVGGFWMRELGLYDD





AGTLIAVSNMAESYKPELAEGSGRAQTCRMVIIVSNVASVELSIDASTV





MATQDYVDDKIAEHEQSRRHPDATLTEKGFTQLSSATNSTSESLAATPK





AVKAANDNANSRLAKNQNGADIQDKSAFLDNVGYTSLTFMKNNGEMPVD





ADLNTFGSVKAYSGIWSKATSTNATLEKNFPEDNAVGVLEVFTGGNFAG





TQRYTTRDGNLYIRKLIGTWNGNDGPWGAWRHVQAVTRALSTTIDLNSL





GGAEHLGLWRNSSSAIASFERHYPEQGGDAQGILEIFEGGLYGRTQRYT





TRNGTMYIRGLTAKWDAENPQWEDWNQIGYQTSSTFYEDDLDDLMSPGI





YSVTGKATHTPIQGQSGFLEVIRRKDGVYVLQRYTTTGTSAATKDRLYE





RVFLGGSFNAWGEWRQIYNSNSLPLELGIGGAVAKLTSLDWQTYDFVPG





SLITVRLDNMTNIPDGMDWGVIDGNLINISVGPSDDSGSGRSMHVWRST





VSKANYRFFMVRISGNPGSRTITTRRVPIIDEAQTWGAKQTFSAGLSGE





LSGNAATATKLKTARKINNVSFDGTSDINLTPKNIGAFASGKTGDTVAN





DKAVGWNWSSGAYNATIGGASTLILHFNIGEGSCPAAQFRVNYKNGGIF





YRSARDGYGFEADWSEFYTTTRKPTAGDVGALPLSGGQLNGALGIGTSS





ALGGNSIVLGDNDTGFKQNGDGNLDVYANSVHVMRFVSGSVQSNKTINI





TGRVNPSDYGNFDSRYVRDVRELGTRVVQTMQKGVMYEKAGHVITGLGI





VGEVDGDDPAVFRPIQKYINGTWYNVAQV


and





corresponding nucleotide sequence of SEQ ID NO:


214.






Its alignment to lambda stf is as follows:












Lambda
367
SSATNSTSETLAATPKAVKVVMDETNRKAPLDSPALTGTPTAPTALRGTNNTQIANTAFV



SIEA11
180
SSATNSTSESLAATPKAVKAANDNANSRL---AKNQNGADIQDKSAP-LDNVGVTSLTFM




********* *********   *  *           *            *       *






In these two specific cases, it was unknown which antigen these side tail fibers were able to recognize, so lambda packaged phagemids with the chimeric side tail fibers lambda-AG22 and lambda-SIEA11 engineered based respectively on SEQ ID NO: 1 and SEQ ID NO: 213, and SEQ ID NO: 1 and SEQ ID NO: 214 were produced and their delivery efficiency was tested in a E. coli collection that contains a very diverse group of O and K serotypes.


As shown in FIG. 4, the addition of a chimeric stf allows the lambda-based packaged phagemid to show increased delivery efficiency in 25 out of 96 strains tested (more than 25% of the collection). In some cases, the increase is modest; in others, it allows for very good delivery efficiency in strains that had no or very low entry with wild-type lambda packaged phagemids. It is also worth noting that AG22 belongs to the Siphovirus_family, like lambda, but SIEA11 is a P2-like phage. This highlights the significant observation that stf modules can be exchanged across bacteriophage genera.


Other side tail fiber genes have been analyzed as shown in FIG. 4 and several insertion sites into the lambda stf gene have been identified that give chimeric variants with differential entry in the E. coli collection as shown previously. These insertion sites are based on the results for the non-homologous tail fiber variants (such as in the cases for K1F and K5 above) or on varying degrees of homology between lambda stf and the variant to be tested. This homology can be short, about 5-10 aminoacids, or substantially similar. The insertion sites tested are shown in bold and underlined below:









lambda stf


(SEQ ID NO: 1)


MAVKISGVLKDGTGKPVQNCTIQLKARRNSTFVVVNTVGSENPDEAGRY





SMDVEYGQYSVILQVDGFPPSHAGTITVYEDSQPGTLNDFLCAMTEDDA





RPEVLRRLELMVEEVARNASVVAQSTADAKKSAGDASASAAQVAALVTD





ATDSARAASTSAGQAASSAQEASSGAEAASAKATEAEKSAAAAESSKNA





AATSAGAAKTSETNAAASQQSAATSASTAATKASEAATSARDAVASKEA





AKSSETNASSSAGRAASSATAAENSARAAKTSETNARSSETAAERSASA







AA
DAKTAAAGSASTASTKATEAAGSAVSASQSKSAAEAAAIRAKNSAKR






AEDIASAVALEDADTTRKGIVQLSSATNSTSETLAATPKAVKVVMDETN







R
KAPLDSPALTGTPTAPTALRGTNNTQIANTAFVLAAIADVIDASPDAL






NTLNELAAALGNDPDFATTMTNALAGKQPKNATLTALAGLSTAKNKLPY





FAENDAASLTELTQVGRDILAKNSVADVLEYLGAGENSAFPAGAPIPWP





SDIVPSGYVLMQGQAFDKSAYPKLAVAYPSGVLPDMRGWTIKGKPASGR





AVLSQEQDGIKSHTHSASASGTDLGTKTTSSFDYGTKTTGSFDYGTKST





NNTGAHAHSLSGSTGAAGAHAHTSGLRMNSSGWSQYGTATITGSLSTVK





GTSTQGIAYLSKTDSQGSHSHSLSGTAVSAGAHAHTVGIGAHQHPVVIG





AHAHSFSIGSHGHTITVNAAGNAENTVKNIAFNYIVRLA







The lambda stf protein consists of 774 aminoacids. The insertion sites can be found closer to the N-terminus (amino acid 131, insertion point ADAKKS (SEQ ID NO:191)) or closer to the C-terminus (amino acid 529, insertion point GAGENS (SEQ ID NO:194)). Stf chimeras with amino acid sequences of SEQ ID NO: 2-45 and 48-61 and corresponding nucleotide sequences of SEQ ID NO: 62-105 and 108-120 were engineered using these insertion sites. FIG. 5 depicts some selected examples for the insertion points ADAKKS (SEQ ID NO:191), SASAAA (SEQ ID NO:193) and MDETNR (SEQ ID NO:192). The results described herein show that it is possible to build chimeric tail fibers that combine the part of one tail fiber that attaches to the capsid of one phage (usually the N-terminus of the protein) with the part of another fiber that interacts with the bacterium (usually the C-terminus of the protein). Stretches of homology between the sequences of different tail fibers can be considered as preferable recombination sites. In order to identify such sites for the stf protein of phage lambda a scan of the Stf sequence was performed with a 50aa window and a phmmer search [25] was performed on each window to identify homologous sequences in the representative proteome 75 database (FIG. 6).


Example 2

Many phages contain a single stf protein, which is a very important factor determining their host specificity. However, there are also several examples of phages encoding more than one stf gene, which is a beneficial trait since, presumably, each of them recognizes a different host. These phages have found different solutions to achieve this feature: some of them, like phi92, encode up to 6 stfs that bind to different parts of the baseplate/viral particle, and probably to other stfs [29]; others, like CBA120 [30], encode 4 stfs that form a tetrameric structure in which one of the stfs attaches to the phage particle while the other three attach to the first one through interaction; and others, like DT57C, contain an stf that binds the particle and a second one that attaches to the first through an interaction domain (branched stfs) [32] (FIG. 7A). In terms of engineering, having a particle that is able to recognize different hosts could have a great impact in terms of production costs and host range expansion.


As a proof of concept, an engineered lambda stf was constructed based on a branched architecture. A phage, referred to as WW11, contains two stfs of SEQ ID NO: 124 and 125 that follow the same order and contain homology to phage DT57C, which has been suggested to have branched stfs. The interaction domains of stf-I and stf-2 in phage WW11 have been identified and used as modules to attach to the Lambda stf. The final construct contains the N-terminal part of the lambda stf of SEQ ID NO: 1 up to the GAGENS insertion site SEQ ID NO: 194 fused to WW11 stf-1 interaction domain ID1 of SEQ ID NO: 280 and WW11 stf-1 proper; after this, a synthetic RBS was inserted and immediately after, the stf-2 interaction domain ID2 of SEQ ID NO: 281 was fused to the C-terminal part of the K1F tail fiber of SEQ ID NO: 121 (see bold sequence of section [198] (FIG. 7B). The GAGENS insertion site of SEQ ID NO: 194 was chosen as the insertion site. Both chimeric proteins were transcribed from a polycistronic mRNA. This construction resulted in a final branched stf WW11-K1F of amino acid sequence SEQ ID NO: 282 and SEQ ID NO: 283 expressed from nucleotide sequence of SEQ ID NO: 284.


The original host range of WW11 phage is 0157 strains, while that of K1F phage is K1 strains. As demonstrated in FIG. 8, when producing packaged phagemids containing the branched chimeric stf of SEQ ID NO: 282 and SEQ ID NO: 283, it can be seen that the host range of the branched stf is now the combination of each single stf, i.e. a combination of both single stf activities (O157 and K1). Although the K1F stf in the branched architecture seems to be less efficient than in the particle containing only one stf, further engineering such as, for example, (i) choosing a more efficient RBS between both stfs, (ii) increasing the length or (iii) introducing flexible linkers between the interaction domains and the fusion stfs and/or (iv) increasing the translation rate of the first stf in the polycistron (since this is known to affect the translation rate of the second CDS in a polycistronic message). An advantage of this approach is also that the stfs are present in the phagemid particle in a 1:1 ratio, assuming proper expression of both components, which may be important for regulatory purposes.


Following a similar approach to the “dimeric” branched stf (Lambda-IDI-WW11 ID2-K1F), a lambda particle whose stf carried 4 different activities was designed. CBA120 is a phage with 4 fibers (called stf; See, FIG. 9). Their sequences are below: Stf4 (also called TSP4) of FIG. 9 (orf213, protein ID YP_004957867.1) (SEQ ID NO:127), stf3 (also called TSP3) of FIG. 9 (orf212, protein ID YP_004957866.1) (SEQ ID NO:128), stf2 (also called TSP2) of FIG. 9 (orf211, protein ID YP_004957865.1) (SEQ ID NO:129), and stf1 (also called TSP1) of FIG. 9 (orf210, protein ID YP_004957864.1) (SEQ ID NO: 130). During analysis of these 4 TSPs, it was noticed that the N-termini have homology to phages G7C/WW11/DT57C, which is a strong indication that these stfs associate to form a tetrameric complex. The first stf to be translated, according to the TSP operon in the CBA120 genome, is TSP4, then TSP3, then TSP2, then TSP1. From this information, it was assumed that the main stf is TSP4, since it's the one to be expressed first. It may encode an ID domain to which more than one TSP attaches. The N-terminal domains also share homology to one another, which helps in the identification of the presumable ID domains. The following interaction domains (ID) were found with probable branching/association activities, making BLAST analysis to the phages mentioned above: TSP4 ID4 Of FIG. 9 (SEQ ID NO: 131) (ID4 seems to have an extra domain at the N-terminus that may be involved in capsid binding, so it will be left out of the final construct), TSP3 ID3 of FIG. 9 (SEQ ID NO: 132), TSP2 ID2 of FIG. 9 (SEQ ID NO: 133), and TSP1 ID1 of FIG. 9 (SEQ ID NO:134).


The following describes the assembly process to be used to construct the tetrameric branched RBP. First, the domains were recoded and two gene blocks were ordered. Recoding is a very common process, and the objective is two-fold. First recoding is done to avoid codon bias based on the fact that the codons used for a given amino acid vary depending on the organism. Accordingly, to avoid expression problems, which can lead to truncated, mutated or misfolded proteins, sequences were recoded with the codon usage of the host organism (in this case E. coli). Second, removal of unknown layers of regulation may be advantageous. This is especially true for operons, phages and in general any other sequences with high “density information”, like a phage genome; they have a limited amount of DNA that can be packaged, so several signals and functions may be encoded within a region, and this may impact the ability to use a genetic part in the desired way.


Plasmid pPhlF-Tetra STF BsaI cloning (pSC101 37C, KanR) has been cloned, containing a fusion to Lambda stf GAGENS of SEQ ID NO: 194 with TSP4 interaction domain (SEQ ID NO:131). The other TSP interaction domains are preceded by a synthetic RBS to avoid including unknown layers of regulation from the phage. This plasmid allows the TypeIIS cloning (BSaI) of 4 stfs fused to each of the TSP interaction domains. Four stfs and 4 strains were identified for readout of each stf activity: (i)—V10: strain V10; (ii)—K1F: strain K1F; (iii)—K5: strain K5; and—stf48: strain 48. These four stfs will be cloned as fusions with ID4 of SEQ ID NO: 131, ID3 of SEQ ID NO: 132, ID2 of SEQ ID NO: 133 and ID1 of SEQ ID NO: 134, respectively. ID4 is fused to the N-terminus of Lambda stf at the GAGENS SEQ ID NO: 194 insertion site (FIG. 9A-B). The final architecture for expression of the tetrameric is depicted in FIG. 9B, although such an expression scheme may be modified, since the plasmid will be large (>16 kb) and the length of the transcribed mRNA is >9kb.


Example 3

T4-like phages are a very diverse family of bacteriophages that share a common long tail fiber architecture: a proximal tail fiber that attaches to the phage particle and a distal tail fiber (DTF) that encodes host specificity linked by proteins acting as “hinge connectors” (Desplats and Krisch, 2003, Res. Microbiol. 154:259-267; Bartual et al. 2010, Proc. Natl. Acad. Sci. 107: 20287-20292). It is thought that the main host range determinants of the tail fiber reside in the distal part. Hence, it is very important to understand if it is possible to translate the host range of a given T4-like phage, which are known to be very broad, to any other phage or packaged phagemid of interest. The distal tail fiber (C-terminal domain of the T4-like long tail fiber) of several T4-like phages were screened for possible functional insertion sites, several fusions with the Lambda stf gene were generated and their host range screened.


Possible insertion sites in the DTF that, when fused to a heterologous tail fiber (the lambda phage stf), will give a functional chimera were searched. The DTF of the phage (WW13) was used as a testbed. This phage possesses a classical T4-like architecture, with a proximal and a distal tail fiber separated by hinge connectors, a gp38 chaperone/adhesin (to assist folding of the tail fiber and recognition of the host (Trojet et al., 2011, Genome Biol. Evol. 3:674-686) and a gp57A chaperone known to be needed for proper folding of the tail fiber (Matsui et al., 1997, J. Bacteriol. 179:1846-1851). Since the endogenous genomic regulation of T4-like phages is complex and may include unknown layers of regulation (Miller et al., 2003, Microbio. Mol. Biol. Rev. 67:86-156), a synthetic linker encoding a RBS was designed to replace the natural DNA linker between the DTF gene and the adhesin; immediately downstream, another synthetic RBS preceding the chaperone gp57A was added, hence creating a polycistronic mRNA encoding for all the functions needed for the proper folding of the DTF (FIG. 10). This construct was built in a plasmid under the control of an inducible promoter and complemented in trans in a strain producing lambda-based phagemids.



FIG. 10. depicts the architecture of an engineered lambda stf-T4-like DTF chimera. The semicircles denote RBS sites; the T sign, a transcriptional terminator; the arrow, a promoter. Several parts of the C-terminus of the DTF were screened and fused to the lambda stf gene at the GAGENS (SEQ ID NO: 194) insertion site. Several variants of the chimera lambda stf-WW13 were functional, as assessed by production of phagemid particles and transduction of a chloramphenicol marker in a collection of E. coli strains. The functional chimeras shown in FIG. 11 were obtained with fusion at the IIQLED (SEQ ID NO:196) insertion site in WW13. Additional functional chimeras were obtained by fusion at the lambda stf MDETNR (SEQ ID NO:192) insertion site and at the WW13 DTF GNIIDL (SEQ ID NO:197), VDRAV (SEQ ID NO:203) and IIQLED (SEQ ID NO:196) insertion sites (FIG. 13)


Other T4-like phages, like PP-1, sharing sequence homology with WW13 were also tested and verified to produce functional chimeras (FIG. 11). These functional chimeras show a IATRV (SEQ ID NO:198) insertion site at the beginning of PP-1 DTF part.



FIG. 11 depicts screening of phagemid particles with chimeric lambda stf-T4-like DTFs and in particular chimeric lambda stf-WW13 and chimeric lambda stf-PP1 of aminoacids sequences SEQ ID NO: 142 to 149 and nucleotide sequences of SEQ ID NO: 166 to 173 including their respective chaperones proteins. A collection of 96 different wild type E. coli strains, encompassing different serotypes, was transduced with lambda-based packaged phagemids and plated on Cm LB agar. Left panel represents wild-type lambda stf; the middle panel represents chimeric lambda-stf-WW13; and the right panel, represents chimeric lambda-stf-PP-1.


The insertion sites found for WW13 do not always exist in a given T4-like DTF, thereby complicating the analysis. Another functional insertion site without homology to WW13 was discovered for a second phage (WW55, FIG. 12). The same TPGEL (SEQ ID NO:199) insertion site could be found in a subset of T4-like phages and proven to yield functional chimeras with at least one of them, WW34 (FIG. 12), and at MDETNR (SEQ ID NO:192) insertion site in lambda stf.



FIG. 12. shows screening of phagemid particles with chimeric lambda stf-T4-like DTFs and in particular chimeric lambda stf-WW55 and chimeric lambda stf-WW34 of aminoacids sequences SEQ ID NO: 150 to 156 and nucleotide sequences of SEQ ID NO: 174 to 180 including their respective chaperones proteins. A collection of 96 different wild type E. coli strains, encompassing different serotypes, was transduced with lambda-based phagemids and plated on Cm LB agar. The left panel represents wild-type lambda stf; the middle panel represents chimeric lambda-stf-WW55; and the right panel represents chimeric lambda-stf-WW34.


Since T4-like DTF proteins may or may not share common sites for insertion, attempts were made to identify a universal insertion site that exists in all T4-like DTFs. When several T4-like DTFs are aligned, no homology along the whole DTF gene present in all the sequences exists, except for the N-terminus which is well conserved. The N-terminus of the DTF is thought to interact with the hinge connectors for attachment to the main phage particle.


Although the classic view is that the host range determinants reside in the C-terminal part of the DTF, recent studies have proven that the N-terminus may also be involved in this process (Chen et al., 2017, Appl. Environ. Microbiol. VI. 83 No. 23). The N-terminus of the DTF was then scanned to look for an insertion site that exists in all T4-like phages and that is able to yield functional chimeras. Phage WW13 DTF and insertion site MDETNR (SEQ ID NO:192) in lambda stf were used. While the direct fusion of the complete DTF gene (starting at amino acid 2) gives particles with some activity, a region from amino acid 1 to 90, with a preferred region from amino acid 40 to 50 of the DTF, that recapitulates the behavior of the DTF fusion was identified and is shown in FIG. 13. Importantly, this region exists in all T4-like phages screened and could be very rapidly used to generate chimeras with a diverse set of DTFs, including WW55 (FIG. 13) and in particular chimeric lambda stf-WW14, chimeric lambda stf-WW170 and chimeric lambda stf-202 of aminoacids sequences SEQ ID NO: 157 to 165 and nucleotide sequences of SEQ ID NO: 181 to 189 including their respective chaperones proteins.


Accordingly, the present disclosure is useful for the generation of phage and phagemid particles with altered host ranges, since it provides a practical framework for the construction of chimeras using the DTFs from any T4-like phage, highlighting its modularity and translatability.


Example 4

The human microbiome comprises different zones of the body, including gut, skin, vagina and mouth [29]. The microbiota in these areas is composed of different communities of microorganisms, such as bacteria, archaea and fungi [29]-[31]. While numerous studies have been made that try to elucidate the specific composition of these communities, it is becoming clear that while there may exist a “core microbiome”, there are many variations in the relative content of each microorganism depending on several factors, such as geographical location, diet or age [32]-[35].


Specifically, in the case of the human gut microbiota, it is not possible to know apriori what are the bacterial species that a given person possesses without running a diagnostic method. In the case of Escherichia coli, some studies have been made that point out to the prevalence of some serotypes and phylogenetic groups in the majority of humans; however, there are significant changes in the composition of the samples depending on the geographic distribution as well as the time of sampling: for example, samples isolated from Europe, Africa, Asia and South America in the 1980s show a prevalence for phylogroups A and B1 (55% and 21%, respectively); but samples obtained in the 2000s in Europe, North America, Asia and Australia belong mainly to the B2 group (43%), followed by the A (24%), D (21%), and B1 (12%) [36]. It is also thought that phylogenetic groups B2 and D are usually more commonly associated with pathogenic strains than with commensal strains [37], but there are studies showing a number of human- and non-human-specific strains belonging to phylogenetic group B2 that are commensals and belong to different serotypes [38].


The intrinsic variability of the human microbiome, and specifically that of Escherichia coli subtypes, makes it difficult to design targeted therapeutic approaches. In the case of phage therapy aimed at killing a target bacterial population, for instance, two possible approaches are possible. first, the use of narrow host range particles that are able to recognize and target a specific E. coli serotype or second the use of broad host range phages that are able to recognize many different strains, sometimes even from different genera [39]. This difficulty is exacerbated if one takes into account strategies that do not aim to kill the target bacterial population, but that seek to add a function to them (i.e. delivery of a factor that will have an effect in the host and that will be expressed by the targeted microbiota). In this specific case, the use of packaged phagemids is of great interest, since they do not kill the host (unless their payload carries genes aimed at killing the host), payload does not replicate and expand and does not contain any endogenous phage genes. However, as in the case of phages, a diagnostic study would be needed to identify the specific serotypes/variants of bacteria that exist in the patient before the treatment in order to find or design a packaged phagemid that allows for delivery of a payload adding a function to the target bacteria without killing them.


By combining these two approaches, it was proposed to use engineered delivery vehicles that are able to recognize a large number of strains belonging to different serotypes and phylogenetic groups (i.e., engineered particles having a “broad host range”), with a focus on Escherichia co/i. As opposed to a killing-oriented approach, where the targeted bacterial population needs to be as close as possible to 100% to reduce their numbers, a therapeutic delivery approach does not need a priori to reach a large percentage of bacteria; the delivery needs to be high enough for the therapeutic payload to be expressed at the correct levels, which may be highly variable depending on the application. Additionally, the payload can be expressed by different serotypes or phylogenetic groups. This approach increases the chance that the particle will deliver a payload expressed in vivo in the majority of patients.


To achieve the delivery in bacterial communities composed of unknown serotypes/variants of target strains, delivery vehicles were engineered to contain chimeric side tail fibers (stf) that have been selected due to their ability to recognize a large variety of target strains. There are many phages that have been described as having a broad host range in E. coli and many of these belong to the T4 family, although in general, phages against E. coli and related bacteria have a restricted host range.


However, according to [41], there is no consensus as to how many strains need to be targeted by a phage to be considered as a “broad host range”.


In the case of Escherichia coli, the ECOR collection is a set of strains isolated from different sources that is thought to represent the variability of this bacterium in Nature [42]. Some phage have been shown to have a broad host range against this collection (for instance, about 53% of the ECOR strains can be lysed with phage AR1 [43] and about 60% with phage SU16 [44]). As opposed to this, a single phage is able to infect 95% of Staphylococcus aureus strains [40].


It was decided to use human strains of this collection to test engineered delivery vehicles with chimeric stf and assess their host range in an attempt to identify variants that are able to recognize as many hosts as possible, as has been described in the literature [45]. The difference is that the present assays measure delivery efficiency as opposed to lysis.


Strains from an overnight culture were diluted 1:100 in 600 uL of LB supplemented with 5 mM CaCl2 in deep 96 well plates and grown for 2 hours at 37° C. at 900 rpm. 10 μL of packaged phagemids, containing a DNA payload p7.3 of SEQ ID NO: 277, produced at an average of 106/μL were then added to 90 uL of the bacterial cultures, incubated 30 minutes at 37° C. and 10 μL of the mixtures plated on LB agar supplemented with 24 pg/mL chloramphenicol and incubated overnight at 37° C. The next day, the density of the dots was scored from 0 to 5, with 0 being no transductants and 5 being a spot with very high density [FIG. 14]. The density of the spots is directly related to the delivery efficiency of the packaged phagemids, since it corresponds to the number of bacteria that have received a payload containing a chloramphenicol acetyltransferase gene.


Several stf chimeras were tested and screened in 40 human strains of the ECOR collection. As a control, the delivery efficiency of the wild-type lambda stf of SEQ ID NO: 1 was tested. The packaged phagemid variant used for the delivery experiments was modified so that its tail tip gpJ now recognizes a receptor other than LamB (pgJ A2 variant of amino acid sequence SEQ ID NO: 278 and nucleotide sequence SEQ ID NO: 279). In FIG. 15-1, FIG. 15-2, FIG. 15-3, the raw dot titrations for 18 chimeric stf of amino acid sequence of SEQ ID NO: 215 to 242 and nucleotide sequences of SEQ ID NO: 243 to 270 including their respective chaperones proteins are shown and in FIG. 16-1, FIG. 16-2 a bar-formatted table is shown with the delivery efficiencies scored by dot density as well as the delivery statistics.


Taking only into account dots with density scores of 3 and higher (considered as medium to high delivery efficiency), some stf s can be considered as broad host range because the delivery efficiency in the selected ECOR strains is significantly higher than when using the wild type stf. For example, for stf EB6 or stf 68B, about 50% of the strains show medium to high delivery efficiencies, as compared to 17.5% of the strains with the wild type stf. These stf are good candidates for in vivo delivery, since they are able to deliver in different phylogenetic groups as well as serotypes. At the bottom of the Table in FIG. 16-1, FIG. 16-2, a bar-formatted representation for density scores higher than 3 is shown, where the threshold for a broad host range stf is set at an increase of at least 2× compared to the basal line of the wild type stf; this is, stf that are able to deliver with scores of 3 and higher in at least 35% of the strains. Other stf also show an increased delivery as compared to the wild type stf, so a less stringent threshold was set for stf able to deliver with scores 3 or higher with at least a 50% increase compared to the number of strains delivered with the wild-type stf (this is, delivery with scores of 3 and higher in at least 26.25% of the strains). As a comparison, data for stf K1 and stf 66D is shown: these stf seem to be delivering efficiently in a small number of strains (for instance, strains B and AB for stf K1; and strains E and AF for stf 66D), which means that they probably have a narrow host range, this is to be expected, since in the case of the K1 stf the cognate receptor is the KI capsule [46]. Additionally, data are shown for a chimera with a stf originating in a T4-like phage; as the literature suggests, this chimera shows a broad host range although it does not seem to be the best candidate.


Taken together, these results suggest that the stf of a delivery vehicle can be engineered to recognize a wide number of target E. coli strains, hence rendering it “broad host range”. This type of particles can be very useful to deliver payloads adding a function to the target bacteria without having to engineer a specific variant that recognizes a given bacterial strain.


LIST OF REFERENCES CITED

Each of the reference cited within the specification and those listed below are hereby incorporated by reference in their entirety.

  • [1] G. P. C. Salmond and P. C. Fineran, “A century of the phage: past, present and future,” Nat. Rev. Microbiol., vol. 13, no. 12, pp. 777-786, December 2015.
  • [2] P. Hyman and S. T. Abedon, “Bacteriophage host range and bacterial resistance,” Adv. Appl. Microbiol., vol. 70, pp. 217-248, 2010.
  • [3] S. Chatterjee and E. Rothenberg, “Interaction of Bacteriophage h with Its E. coli Receptor, LamB,” Viruses, vol. 4, no. 11, pp. 3162-3178, November 2012.
  • [4] Nobrega et al, Nat Rev, 2018 “Targeting mechanisms of tailed bacteriophages”
  • [5] A. Flayhan, F. Wien, M. Paternostre, P. Boulanger, and C. Breyton, “New insights into pb5, the receptor binding protein of bacteriophage T5, and its interaction with its Escherichia coli receptor FhuA,” Biochimie, vol. 94, no. 9, pp. 1982-1989, September 2012.
  • [5] M. G. Rossmann, V. V. Mesyanzhinov, F. Arisaka, and P. G. Leiman, “The bacteriophage T4 DNA injection machine,” Curr. Opin. Struct. Biol., vol. 14, no. 2, pp. 171-180, April 2004.
  • [6] Y. Zivanovic et al., “Insights into Bacteriophage T5 Structure from Analysis of Its Morphogenesis Genes and Protein Components,” J. Virol., vol. 88, no. 2, pp. 1162-1174, January 2014.
  • [7] R. W. Hendrix and R. L. Duda, “Bacteriophage lambda PaPa: not the mother of all lambda phages,” Science, vol. 258, no. 5085, pp. 1145-1148, November 1992.
  • [8] M. A. Speed, T. Morshead, D. I. Wang, and J. King, “Conformation of P22 tailspike folding and aggregation intermediates probed by monoclonal antibodies,” Protein Sci. Publ. Protein Soc., vol. 6, no. 1, pp. 99-108, January 1997.
  • [9] S. J. Labrie, J. E. Samson, and S. Moineau, “Bacteriophage resistance mechanisms,” Nat. Rev. Microbiol., vol. 8, no. 5, pp. 317-327, March 2010.
  • [10] C. Whitfield, “Biosynthesis and assembly of capsular polysaccharides in Escherichia coli,” Annu. Rev. Biochem., vol. 75, pp. 39-68, 2006.
  • [11] J. R. Meyer, D. T. Dobias, J. S. Weitz, J. E. Barrick, R. T. Quick, and R. E. Lenski, “Repeatability and contingency in the evolution of a key innovation in phage lambda,” Science, vol. 335, no. 6067, pp. 428-432, January 2012.
  • [12] D. S. Gupta et al., “Coliphage K5, specific for E. coli exhibiting the capsular K5 antigen,” FEMS Microbiol. Lett., vol. 14, no. 1, pp. 75-78, May 1982.
  • [13] R. J. Gross, T. Cheasty, and B. Rowe, “Isolation of bacteriophages specific for the K1 polysaccharide antigen of Escherichia coli,” J. Clin. Microbiol., vol. 6, no. 6, pp. 548-550, December 1977.
  • [14] D. Schwarzer et al., “A Multivalent Adsorption Apparatus Explains the Broad Host Range of Phage phi92: a Comprehensive Genomic and Structural Analysis,”J. Virol., vol. 86, no. 19, pp. 10384-10398, October 2012.
  • [15] F. Tétart, F. Repoila, C. Monod, and H. M. Krisch, “Bacteriophage T4 host range is expanded by duplications of a small domain of the tail fiber adhesin,” J. Mol. Biol., vol. 258, no. 5, pp. 726-731, May 1996.
  • [16] E. Haggård-Ljungquist, C. Hailing, and R. Calendar, “DNA sequences of the tail fiber genes of bacteriophage P2: evidence for horizontal transfer of tail fiber genes among unrelated bacteriophages.,” J. Bacteriol., vol. 174, no. 5, pp. 1462-1477, March 1992.
  • [17] L.-T. Wu, S.-Y. Chang, M.-R. Yen, T.-C. Yang, and Y.-H. Tseng, “Characterization of Extended-Host-Range Pseudo-T-Even Bacteriophage Kpp95 Isolated on Klebsiella pneumoniae,” Appl. Environ. Microbiol., vol. 73, no. 8, pp. 2532-2540, April 2007.
  • [18] D. Montag, H. Schwarz, and U. Henning, “A component of the side tail fiber of Escherichia coli bacteriophage lambda can functionally replace the receptor-recognizing part of a long tail fiber protein of the unrelated bacteriophage T4,”J. Bacteriol., vol. 171, no. 8, pp. 4378-4384, August 1989.
  • [19] E. R. Vimr, R. D. McCoy, H. F. Vollger, N. C. Wilkison, and F. A. Troy, “Use of prokaryotic-derived probes to identify poly(sialic acid) in neonatal neuronal membranes,” Proc. Natl. Acad. Sci., vol. 81, no. 7, pp. 1971-1975, April 1984.
  • [20] K. Stummeyer, A. Dickmanns, M. Mühlenhoff, R. Gerardy-Schahn, and R. Ficner, “Crystal structure of the polysialic acid-degrading endosialidase of bacteriophage K1F,” Nat. Struct. Mol. Biol., vol. 12, no. 1, pp. 90-96, January 2005.
  • [21] D. Scholl, S. Adhya, and C. Merril, “Escherichia coli K1's Capsule Is a Barrier to Bacteriophage T7,” Appl. Environ. Microbiol., vol. 71, no. 8, pp. 4872-4874, August 2005.
  • [22] Y. Jiang, B. Chen, C. Duan, B. Sun, J. Yang, and S. Yang, “Multigene Editing in the Escherichia coli Genome via the CRISPR-Cas9 System,” Appl. Environ. Microbiol., vol. 81, no. 7, pp. 2506-2514, April 2015.
  • [23] J. E. Cronan, “Improved Plasmid-Based System for Fully Regulated Off-To-On Gene Expression in Escherichia coli: Application to Production of Toxic Proteins,” Plasmid, vol. 69, no. 1, pp. 81-89, January 2013.
  • [24] J. E. Thompson et al., “The K5 Lyase KflA Combines a Viral Tail Spike Structure with a Bacterial Polysaccharide Lyase Mechanism,”.J. Biol. Chem., vol. 285, no. 31, pp. 23963-23969, July 2010.
  • [25] S. C. Potter, A. Luciani, S. R. Eddy, Y. Park, R. Lopez, and R. D. Finn, “HMMER web server: 2018 update,” Nucleic Acids Res., vol. 46, no. W1, pp. W200-W204, July 2018.
  • [26] E. I. Marusich, L. P. Kurochkina, and V. V. Mesyanzhinov, “Chaperones in bacteriophage T4 assembly,” Biochem. Biokhimiia, vol. 63, no. 4, pp. 399-406, April 1998.
  • [27] J. Xu, R. W. Hendrix, and R. L. Duda, “Chaperone-protein interactions that mediate assembly of the bacteriophage lambda tail to the correct length,” J. Mol. Biol., vol. 426, no. 5, pp. 1004-1018, March 2014.
  • [28] D. Schwarzer et al., “Proteolytic Release of the Intramolecular Chaperone Domain Confers Processivity to Endosialidase F,” J. Biol. Chem., vol. 284, no. 14, pp. 9465-9474, April 2009.
  • [29] D. Schwarzer et al., “A Multivalent Adsorption Apparatus Explains the Broad Host Range of Phage phi92: a Comprehensive Genomic and Structural Analysis,” J. Virol., vol. 86, no. 19, pp. 10384-10398, October 2012.
  • [30] “Characterization of a ViI-like phage specific to Escherichia coli O157:H7.—PubMed—NCBI.” [Online]. Available: https.//www.ncbi.nlm.nih.gov/pubmed/21899740. [Accessed. 10-Dec.-2018].
  • [31] C. Chen, P. Bales, J. Greenfield, R. D. Heselpoth, D. C. Nelson, and O. Herzberg, “Crystal structure of ORF210 from E. coli 0157:H1 phage CBA 120 (TSP1), a putative tailspike protein,” PloS One, vol. 9, no. 3, p. e93156, 2014.
  • [32] A. K. Golomidova et al., “Branched Lateral Tail Fiber Organization in T5-Like Bacteriophages DT57C and DT571/2 is Revealed by Genetic and Functional Analysis,” Viruses, vol. 8, no. 1, January 2016.












SEQUENCES











SEQ ID

Protein (PRT)




NO
Name
or DNA
Origin
Insertion site














1
lambda stf
PRT
lambda bacteriophage






2
STF-25
PRT
Artificial sequence
ADAKKS


3
STF25-AP1
PRT
Artificial sequence






4
STF-27
PRT
Artificial sequence
ADAKKS





5
STF27-AP1
PRT
Artificial sequence






6
STF27-AP2
PRT
Artificial sequence






7
STF-28
PRT
Artificial sequence
ADAKKS





8
STF28-AP1
PRT
Artificial sequence






9
STF-15
PRT
Artificial sequence
SASAAA





10
STF15-AP1
PRT
Artificial sequence






11
STF15-AP2
PRT
Artificial sequence






12
STF-16
PRT
Artificial sequence
SASAAA





13
STF16-AP1
PRT
Artificial sequence






14
STF16-AP2
PRT
Artificial sequence






15
STF-17
PRT
Artificial sequence
SASAAA





16
STF17-AP1
PRT
Artificial sequence






17
STF-13
PRT
Artificial sequence
SASAAA





18
STF13-AP1
PRT
Artificial sequence






19
STF13-AP2
PRT
Artificial sequence






20
STF-12
PRT
Artificial sequence
SASAAA





21
STF12-AP1
PRT
Artificial sequence






22
STF12-AP2
PRT
Artificial sequence






23
STF-63
PRT
Artificial sequence
SASAAA





24
STF-62
PRT
Artificial sequence
SASAAA





25
STF-71
PRT
Artificial sequence
SASAAA





26
STF71-AP1
PRT
Artificial sequence






27
STF-20
PRT
Artificial sequence
MDETNR





28
STF20-AP1
PRT
Artificial sequence






29
STF-23
PRT
Artificial sequence
MDETNR





30
STF23-AP1
PRT
Artificial sequence






31
STF-24
PRT
Artificial sequence
MDETNR





32
STF24-AP1
PRT
Artificial sequence






33
O111-2.0
PRT
Artificial sequence
MDETNR





34
O111 2.0-AP1
PRT
Artificial sequence






35
STF-74
PRT
Artificial sequence
MDETNR





36
STF74-AP1
PRT
Artificial sequence






37
STF-86
PRT
Artificial sequence
MDETNR





38
STF86-AP1
PRT
Artificial sequence






39
STF-84
PRT
Artificial sequence
MDETNR





40
STF84-AP1
PRT
Artificial sequence






41
STF-93
PRT
Artificial sequence
MDETNR





42
STF-95
PRT
Artificial sequence
MDETNR





43
STF95-AP1
PRT
Artificial sequence






44
STF-132
PRT
Artificial sequence
MDETNR





45
STF132-AP1
PRT
Artificial sequence






46
K1F
PRT
Artificial sequence
GAGENS





47
K5
PRT
Artificial sequence
GAGENS





48
STF-37
PRT
Artificial sequence
GAGENS





49
1JL
PRT
Artificial sequence
GAGENS





50
STF-48
PRT
Artificial sequence
GAGENS





51
STF-49
PRT
Artificial sequence
GAGENS





52
STF-52
PRT
Artificial sequence
GAGENS





53
1AR
PRT
Artificial sequence
GAGENS





54
1AR-AP1
PRT
Artificial sequence






55
1AR-AP2
PRT
Artificial sequence






56
13-13.0
PRT
Artificial sequence
GAGENS





57
13-13.0-AP1
PRT
Artificial sequence






58
13-13.0-AP2
PRT
Artificial sequence






59
13-14.3
PRT
Artificial sequence
SAGDAS





60
13-14.3-AP1
PRT
Artificial sequence






61
13-14.3-AP2
PRT
Artificial sequence






62
STF-25
DNA
Artificial sequence






63
STF25-AP1
DNA
Artificial sequence






64
STF-27
DNA
Artificial sequence






65
STF27-AP1
DNA
Artificial sequence






66
STF27-AP2
DNA
Artificial sequence






67
STF-28
DNA
Artificial sequence






68
STF28-AP1
DNA
Artificial sequence






69
STF-15
DNA
Artificial sequence






70
STF15-AP1
DNA
Artificial sequence






71
STF15-AP2
DNA
Artificial sequence






72
STF-16
DNA
Artificial sequence






73
STF16-AP1
DNA
Artificial sequence






74
STF16-AP2
DNA
Artificial sequence






75
STF-17
DNA
Artificial sequence






76
STF17-AP1
DNA
Artificial sequence






77
STF-13
DNA
Artificial sequence






78
STF13-AP1
DNA
Artificial sequence






79
STF13-AP2
DNA
Artificial sequence






80
STF-12
DNA
Artificial sequence






81
STF12-AP1
DNA
Artificial sequence






82
STF12-AP2
DNA
Artificial sequence






83
STF-63
DNA
Artificial sequence






84
STF-62
DNA
Artificial sequence






85
STF-71
DNA
Artificial sequence






86
STF71-AP1
DNA
Artificial sequence






87
STF-20
DNA
Artificial sequence






88
STF20-AP1
DNA
Artificial sequence






89
STF-23
DNA
Artificial sequence






90
STF23-AP1
DNA
Artificial sequence






91
STF-24
DNA
Artificial sequence






92
STF24-AP1
DNA
Artificial sequence






93
O111-2.0
DNA
Artificial sequence






94
O111 2.0-AP1
DNA
Artificial sequence






95
STF-74
DNA
Artificial sequence






96
STF74-AP1
DNA
Artificial sequence






97
STF-86
DNA
Artificial sequence






98
STF86-AP1
DNA
Artificial sequence






99
STF-84
DNA
Artificial sequence






100
STF84-AP1
DNA
Artificial sequence






101
STF-93
DNA
Artificial sequence






102
STF-95
DNA
Artificial sequence






103
STF95-AP1
DNA
Artificial sequence






104
STF-132
DNA
Artificial sequence






105
STF132-AP1
DNA
Artificial sequence






106
K1F
DNA
Artificial sequence






107
K5
DNA
Artificial sequence






108
STF-37
DNA
Artificial sequence






109
1JL
DNA
Artificial sequence






110
STF-48
DNA
Artificial sequence






111
STF-49
DNA
Artificial sequence






112
STF-52
DNA
Artificial sequence






113
1AR
DNA
Artificial sequence






114
1AR-AP1
DNA
Artificial sequence






115
1AR-AP2
DNA
Artificial sequence






116
13-13.0
DNA
Artificial sequence






117
13-13.0-AP1
DNA
Artificial sequence






118
13-13.0-AP2
DNA
Artificial sequence






119
13-14.3
DNA
Artificial sequence






120
13-14.3-AP1
DNA
Artificial sequence






121
K1F
PRT
K1F phage






122
13-14.3-AP2
DNA
Artificial sequence






123
lambda stf
PRT
lambda phage






124
WW11 stf1
PRT
WW11 phage






125
WW11 stf2
PRT
WW11 phage






126
K1F
PRT
K1F phage






127
TSP4 Branched
PRT
CBA120 phage






128
TSP3 Branched
PRT
CBA120 phage






129
TSP2 Branched
PRT
CBA120 phage






130
TSP1 Branched
PRT
CBA120 phage






131
ID4 Branched
PRT
CBA120 phage






132
ID3 Branched
PRT
CBA120 phase






133
ID2 Branched
PRT
CBA120 phage






134
ID1 branched
PRT
CBA120 phase






135
WW13
PRT
Artificial sequence
GNIIDL





136
PP-1
PRT
Artificial sequence
IATRV





137
WW55
PRT
Artificial sequence
TPGEL





138
WW34
PRT
Artificial sequence
TPGEL





139
WW14
PRT
Artificial sequence
NQIID





140
WW170
PRT
Artificial sequence
GAIIN





141
WW202
PRT
Artificial sequence
GQIVN





142
WW13 13.0
PRT
Artificial sequence
IIQLED





143
WW13 10.0
PRT
Artificial sequence
VDRAV





144
WW13-G8
PRT
Artificial sequence
GNIIDL





145
WW13 gp38
PRT
ww13 phase






146
WW13 gp57A
PRT
ww13 phase






147
PP-1
PRT
Artificial sequence
IATRV





148
PP-1 gp38
PRT
pp-1 phase






149
PP-1 gp57A
PRT
pp-1 phase






150
WW55 3.0
PRT
Artificial sequence
TPGEL





151
WW55-G8
PRT
Artificial sequence
GAIIN





152
WW55 gp38
PRT
ww55 phage






153
WW55 gp57A
PRT
ww55 phase






154
WW34 3.0
PRT
Artificial sequence
TPGEL





155
WW34 gp38
PRT
ww34 phase






156
WW34 gp57A
PRT
ww34 phase






157
WW14-G8
PRT
Artificial sequence
NQIID





158
WW14 gp38
PRT
ww14 phase






159
WW14 gp57A
PRT
ww14 phase






160
WW170-G8
PRT
Artificial sequence
GAIIN





161
WW170 gp38
PRT
ww170 phase






162
WW170 gp57A
PRT
ww170 phase






163
WW202-G8
PRT
Artificial sequence
GQIVN





164
WW202 gp38
PRT
ww202 phage






165
WW202 gp57A
PRT
ww202 phage






166
WW13 13.0
DNA
Artificial sequence






167
WW13 10.0
DNA
Artificial sequence






168
WW13-G8
DNA
Artificial sequence






169
WW13 GP38
DNA
ww13 phase






170
WW13 GP57A
DNA
ww13 phase






171
PP-1
DNA
Artificial sequence






172
PP-1 GP38
DNA
pp-1 phase






173
PP-1 GP57A
DNA
pp-1 phage






174
WW55 3.0
DNA
Artificial sequence






175
WW55-G8
DNA
Artificial sequence






176
WW55 GP38
DNA
ww55 phage






177
WW55 GP57A
DNA
ww55 phage






178
WW34 3.0
DNA
Artificial sequence






179
WW34 GP38
DNA
ww34 phage






180
WW34 GP57A
DNA
ww34 phage






181
WW14-G8
DNA
Artificial sequence






182
WW14 GP38
DNA
ww14 phage






183
WW14 GP57A
DNA
ww14 phage






184
WW170-G8
DNA
Artificial sequence






185
WW170 GP38
DNA
ww170 phae






186
WW170 GP57A
DNA
ww170 phage






187
WW170 GP57A
DNA
Artificial sequence






188
WW202 GP38
DNA
ww202 phage






189
WW202 GP57A
DNA
ww202 phage






190
insertion sequence
PRT
Artificial sequence






191
insertion sequence
PRT
Artificial sequence






192
insertion sequence
PRT
Artificial sequence






193
insertion sequence
PRT
Artificial sequence






194
insertion sequence
PRT
Artificial sequence






195
insertion sequence
PRT
Artificial sequence






196
insertion sequence
PRT
Artificial sequence






197
insertion sequence
PRT
Artificial sequence






198
insertion sequence
PRT
Artificial sequence






199
insertion sequence
PRT
Artificial sequence






200
insertion sequence
PRT
Artificial sequence






201
insertion sequence
PRT
Artificial sequence






202
insertion sequence
PRT
Artificial sequence






203
insertion sequence
PRT
Artificial sequence






204
AG22
PRT
AG22 phage






205
SIEA11
PRT
SIEA11 phase






206
WW13
DNA
WW13 phage






207
PP-1
DNA
PP-1 phage






208
WW55
DNA
WW55 phage






209
WW34
DNA
WW34 phage






210
WW14
DNA
WW14 phage






211
WW170
DNA
WW170 phage






212
WW202
DNA
WW202 phage






213
AG22
DNA
AG22 phage






214
SIEA11
DNA
SIEA11 phage






215
O111
PRT
Artificial sequence






216
SIED6
PRT
Artificial sequence






217
SIED6 AP1
PRT
Artificial sequence






218
SIED6 AP2
PRT
Artificial sequence






219
SIEA11
PRT
Artificial sequence






220
SIEA11 AP1
PRT
Artificial sequence






221
DC1
PRT
Artificial sequence






222
DC1 AP1
PRT
Artificial sequence






223
EB6
PRT
Artificial sequence






224
EB6 AP1
PRT
Artificial sequence






225
AH11L
PRT
Artificial sequence






226
AH11L AP1
PRT
Artificial sequence






227
STF-94A
PRT
Artificial sequence






228
STF-94A AP1
PRT
Artificial sequence






229
STF-69A
PRT
Artificial sequence






230
STF-69A AP1
PRT
Artificial sequence






231
STF-69A AP2
PRT
Artificial sequence






232
STF-68B
PRT
Artificial sequence






233
STF-68B AP1
PRT
Artificial sequence






234
STF-68B AP2
PRT
Artificial sequence






235
STF-118
PRT
Artificial sequence






236
STF-118 AP1
PRT
Artificial sequence






237
STF-90B
PRT
Artificial sequence






238
STF-90B AP1
PRT
Artificial sequence






239
STF-117
PRT
Artificial sequence






240
STF-117 AP1
PRT
Artificial sequence






241
STF-66D
PRT
Artificial sequence






242
STF-66D AP1
PRT
Artificial sequence






243
O111
DNA
Artificial sequence






244
SIED6
DNA
Artificial sequence






245
SIED6 AP1
DNA
Artificial sequence






246
SIED6 AP2
DNA
Artificial sequence






247
SIEA11
DNA
Artificial sequence






248
SIEA11 AP1
DNA
Artificial sequence






249
DC1
DNA
Artificial sequence






250
DC1 AP1
DNA
Artificial sequence






251
EB6
DNA
Artificial sequence






252
EB6 AP1
DNA
Artificial sequence






253
AH11L
DNA
Artificial sequence






254
AH11L AP1
DNA
Artificial sequence






255
STF-94A
DNA
Artificial sequence






256
STF-94A AP1
DNA
Artificial sequence






257
STF-69A
DNA
Artificial sequence






258
STF-69A AP1
DNA
Artificial sequence






250
STF-69A AP2
DNA
Artificial sequence






260
STF-68B
DNA
Artificial sequence






261
STF-68B AP1
DNA
Artificial sequence






262
STF-68B AP2
DNA
Artificial sequence






263
STF-118
DNA
Artificial sequence






264
STF-118 AP1
DNA
Artificial sequence






265
STF-90B
DNA
Artificial sequence






266
STF-90B AP1
DNA
Artificial sequence






267
STF-117
DNA
Artificial sequence






268
STF-117 AP1
DNA
Artificial sequence






269
STF-66D
DNA
Artificial sequence






270
STF-66D AP1
DNA
Artificial sequence






271
WW55 3.0 AP1
PRT
Artificial sequence






272
WW55 3.9 AP1
DNA
Artificial sequence






273
WW55 3.0 AP2
PRT
Artificial sequence






274
WW55 3.9 AP2
DNA
Artificial sequence






275
lambda stf AP1
PRT
Artificial sequence






276
lambda stf AP1
DNA
Artificial sequence






277
payload p7.3
DNA
Artificial sequence






278
1A2 gpJ variant
PRT
Artificial sequence






279
1A2 gpJ variant
DNA
Artificial sequence






280
WW11 ID1
DNA
Artificial sequence






281
WW11 ID2
DNA
Artificial sequence






282
WW11 K1F
PRT
Artificial sequence




chimeric stfa








283
WW11 KIF
PRT
Artificial sequence




chimeric stfb








284
WW11 K1F
DNA
Artificial sequence




chimeric stf








Claims
  • 1. An engineered branched receptor binding multi-subunit protein complex (branched-RBP) comprising two or more associated bacteriophage derived receptor binding proteins (RBP): wherein a first associated bacteriophage derived receptor binding protein comprises a first interaction domain (ID); andwherein a second associated bacteriophage derived receptor binding protein comprises a second interaction domain.
  • 2. The engineered branched-RBP of claim 1, wherein the association is a non-covalent association.
  • 3. The engineered branched-RBP of claim 1, wherein at least one of the two or more associated bacteriophage derived RBPs is a chimeric RBP having an ID domain.
  • 4. The engineered branched-RBP of claim 1, wherein at least one of the two or more receptor binding protein (RBP) comprises a chimeric RBP, wherein said chimeric RBP is selected from the group consisting of: (i) a fusion between the N-terminal domain of a RBP from a lamba or lambda-like bacteriophage and the C-terminal domain of a different RBPwherein said N-terminal domain is fused to said C-terminal domain within one of the amino acids regions selected from positions 1-150, 320-460 or 495-560 of the N-terminal RBP with reference to the lambda stf sequence (SEQ ID NO:1) andwherein said chimeric RBP contains an interaction domain, that may optionally be inserted between the N-terminal and C-terminal domain: and(ii) a fusion between the N-terminal domain of a RBP from a lambda or lambda-like bacteriophage and the C-terminal domain of a different RBP,wherein said RBP from a lambda or lambda-like bacteriophage and the other RBP have homology in one or more of three amino acids regions ranging from positions 1-150, 320-460 and 495-560 of the N-terminal RBP with reference to the lambda stf sequence (SEQ ID NO:1) andwherein said N-terminal domain is fused to said C-terminal domain within one of the amino acids regions selected from positions 1-150, 320-460 or 495-560 of the N-terminal RBP with reference to the lambda stf sequence (SEQ ID NO:1) andwherein said chimeric RBP contains an interaction domain, that may optionally be inserted between the N-terminal and C-terminal domain.
  • 5. The engineered branched-RBP of claim 1, wherein the first and/or second ID is selected from the group consisting of SEQ ID NOs: 131-134 and 280-281.
  • 6. The engineered branched-RBP of claim 4, wherein the chimeric RBP is selected from the group consisting of: (i) a chimeric RBP wherein said different RBP is derived from any bacteriophage or bacteriocin;(ii) a chimeric RBP, wherein the N-terminal domain of the chimeric RBP is fused to said C-terminal domain within one of the amino acids regions selected from positions 80-150, 320-460, or 495-560 of the N-terminal RBP with reference to the lambda bacteriophage stf sequence (SEQ ID NO:1) and wherein said chimeric RBP contains an interaction domain, that may optionally be inserted between the N-terminal and C-terminal domain; and(iii) a chimeric RBP, wherein the N-terminal domain and the C-terminal domain are fused within said region at an insertion site having at least 80% identity with insertion site selected from the group consisting of amino acids SAGDAS (SEQ ID NO:190), ADAKKS (SEQ ID NO:191), MDETNR (SEQ ID NO:192), SASAAA (SEQ ID NO: 193), GAGENS (SEQ ID NO:194), ATLKQI (SEQ ID NO:195), IIQLED (SEQ ID NO: 196), GNIIDL (SEQ ID NO: 197), IATRV (SEQ ID NO:198), TPGEL (SEQ ID NO:199), GAIIN (SEQ ID NO:200), NQIID (SEQ ID NO:201), GQIVN (SEQ ID NO:202), and VDRAV (SEQ ID NO:203) wherein said chimeric RBP contains an interaction domain that may optionally be inserted between the N-terminal and C-terminal domain.
  • 7. The engineered branched-RBP complex of claim 1, wherein the one or more receptor binding protein (RBP) comprises a chimeric RBP selected from the group consisting of: (i) a chimeric RBP comprising a fusion between the N-terminal domain of a RBP from a lambda bacteriophage and the C-terminal domain of a different RBP; andwherein said N-terminal domain is fused to said C-terminal domain within one of the amino acids regions selected from positions 1-150, 320-460 or 495-560 of the N-terminal RBP with reference to the lambda stf sequence (SEQ ID NO:1) and wherein said chimeric RBP contains an interaction domain that may optionally be inserted between the N-terminal and C-terminal domain; and(ii) a chimeric RBP comprising a fusion between the N-terminal domain of a RBP from a lambda bacteriophage and the C-terminal domain of a different RBP,wherein said RBP from a lambda bacteriophage and the other RBP have homology in one or more of three amino acids regions ranging from positions 1-150, 320460, and 495-560 of the N-terminal RBP with reference to the lambda stf sequence (SEQ ID NO:1); andwherein said N-terminal domain is fused to said C-terminal domain within one of the amino acids regions selected from positions 1-150, 320-460, or 495-560 of the N-terminal RBP with reference to the lambda stf sequence (SEQ ID NO:1); and wherein said chimeric RBP contains an interaction domain that may optionally be inserted between the N-terminal and C-terminal domain.
  • 8. The engineered branched-RBP of claim 7, wherein said different RBP is derived from any bacteriophage or bacteriocin.
  • 9. The engineered branched-RBP of claim 7, wherein said N-terminal domain of the chimeric RBP is fused to said C-terminal domain within one of the amino acids regions selected from positions 80-150, 320460, or 495-560 of the N-terminal RBP with reference to the lambda stf sequence (SEQ ID NO:1) and wherein said chimeric RBP contains an interaction domain, that may optionally be inserted between the N-terminal and C-terminal domain.
  • 10. The engineered branched-RBP of claim 7, wherein the N-terminal domain and the C-terminal domain are fused within said region at an insertion site having at least 80% identity with insertion site selected from the group consisting of amino acids SAGDAS (SEQ ID NO: 190), ADAKKS (SEQ ID NO:190), MDETNR (SEQ ID NO:191), SASAAA (SEQ ID NO.192), GAGENS (SEQ ID NO:193), ATLKQI (SEQ ID NO:195), IIQLED (SEQ ID NO:196), GNIIDL (SEQ ID NO:197), IATRV (SEQ ID NO:198), TPGEL (SEQ ID NO:199), GAIIN (SEQ ID N0:200), NQIID (SEQ ID NO:201), GQIVN (SEQ ID NO:202), and VDRAV (SEQ ID NO:203) wherein said chimeric RBP contains an interaction domain, that may optionally be inserted between the N-terminal and C-terminal domain.
  • 11. The engineered branched-RBP of claim 4, wherein the C-terminal domain of the different RBP has a depolymerase activity against an encapsulated bacterial strain.
  • 12. The engineered branched-RBP of claim 1, wherein at least one of the two or more associated receptor binding proteins (RBP) comprises a chimeric RBP comprising an amino acid sequence selected from the group consisting SEQ ID NO: 2, 4, 7, 9, 12, 15, 17, 20, 23, 24, 25, 27, 29, 31, 33, 35, 37, 39, 41, 42, 44, 46, 47, 48, 49, 50, 51, 52, 53, 56, 59, 135 to 144, 147, 150, 151, 154, 157, 160, 163, 215, 216, 219, 221, 223, 225, 227, 229, 232, 325, 237, 239, 241, 282and 283.
  • 13. A bacterial delivery vehicle comprising an engineered branched-RBP.
  • 14. The bacterial delivery vehicle of claim 13 wherein said bacterial delivery vehicle is a bacteriophage or is a packaged phagemid.
  • 15. The bacterial delivery vehicle of claim 13, wherein the engineered branched-RBP comprises a chimeric receptor binding protein having an interaction domain.
  • 16. The bacterial delivery vehicle of claim 15, wherein the chimeric RBP is selected from the group consisting of: (i) a chimeric RBP that comprises a fusion between the N-terminal domain of a RBP from a lambda or lambda-like bacteriophage and the C-terminal domain of a different RBP andwherein said N-terminal domain is fused to said C-terminal domain within one of amino acids regions selected from positions 1-150, 320-460 or 495-560 of the N-terminal RBP with reference to the lambda stf sequence (SEQ ID NO:1)wherein said chimeric RBP contains an interaction domain that may optionally be inserted between the N-terminal and C-terminal domain; and(ii) a chimeric RBP that comprises a fusion between the N-terminal domain of a RBP from a lambda or lambda-like bacteriophage and the C-terminal domain of a different RBP,wherein said RBP from a lambda or lambda-like bacteriophage, and the other RBP have homology in one or more of three amino acids regions ranging from positions 1-150, 320-460, and 495-560 of the N-terminal RBP with reference to the lambda stf sequence (SEQ ID NO:1) andwherein said N-terminal domain is fused to said C-terminal domain within one of the amino acids regions selected from 1-150, 320-460 or 495-560 of the N-terminal RBP with reference to the lambda stf sequence (SEQ ID NO:1); andwherein said chimeric RBP contains an interaction domain that may optionally be inserted between the N-terminal and C-terminal domain.
  • 17. The bacterial delivery vehicle of claim 16, wherein said different RBP is derived from any bacteriophage or bacteriocin.
  • 18. The bacterial delivery vehicle of claim 16, wherein said N-terminal domain of the chimeric RBP is fused to said C-terminal domain within one of the amino acids regions selected from positions 80-150, 320-460 or 495-560 of the N-terminal RBP with reference to the lambda stf sequence (SEQ ID NO:1); and wherein said chimeric RBP contains an interaction domain that may optionally be inserted between the N-terminal and C-terminal domain.
  • 19. The bacterial delivery vehicle of claim 16, wherein said N-terminal domain and the C-terminal domain are fused within said region at an insertion site having at least 80/0 identity with an insertion site selected from the group consisting of amino acids SAGDAS (SEQ ID NO:190), ADAKKS (SEQ ID NO:191), MDETNR (SEQ ID NO:192), SASAAA (SEQ ID NO:193), GAGENS (SEQ ID NO.194), ATLKQI (SEQ ID NO:195), IIQLED (SEQ ID NO:196), GNIIDL (SEQ ID NO:197), IATRV (SEQ ID NO:198), TPGEL (SEQ ID NO:199), GAIN (SEQ ID NO:200), NQIID (SEQ ID NO:201), GQIVN (SEQ ID NO:202) and VDRAV (SEQ ID NO:203) and wherein said chimeric RBP contains an interaction domain that may optionally be inserted between the N-terminal and C-terminal domain.
  • 20. The bacterial delivery vehicle of claim 16, wherein the C-terminal domain of the different RBP has a depolymerase activity against an encapsulated bacterial strain.
  • 21. The bacterial delivery vehicle of claim 16, wherein the chimeric RBP is selected from the group consisting of: (i) a chimeric RBP comprising a fusion between the N-terminal domain of a RBP from a lambda bacteriophage and the C-terminal domain of a different RBP andwherein said N-terminal domain is fused to said C-terminal domain within one amino acids regions 1-150, 320-460 or 495-560 of the N-terminal RBP with reference to the lambda stf sequence (SEQ ID NO:1); and wherein said chimeric RBP contains an interaction domain that may optionally be inserted between the N-terminal and C-terminal domain; and.
  • 22. The bacterial delivery vehicle of any claim 13 further comprising a nucleic acid payload comprising a nucleic acid of interest.
  • 23. The bacterial delivery vehicle of claim 22, wherein the nucleic acid of interest is selected from the group consisting of: a Cas nuclease gene, a Cas9 nuclease gene, a guide RNA, a CRISPR locus, a toxin gene, a gene expressing an enzyme such as a nuclease or a kinase, a TALEN, a ZFN, a meganuclease, a recombinase, a bacterial receptor, a membrane protein, a structural protein, a secreted protein, a gene expressing resistance to an antibiotic or to a drug in general, a gene expressing a toxic protein or a toxic factor and a gene expressing a virulence protein or a virulence factor, a gene encoding a protein of interest, a gene encoding a nuclease that targets cleavage of a host bacterial cell genome or a host bacterial cell plasmid wherein said cleavage optionally occurs in an antibiotic resistant gene, a gene encoding a therapeutic protein, encodes an anti-sense nucleic acid molecule and any combination thereof.
  • 24. A nucleic acid molecule encoding the branched-RBP of claim 1, wherein said nucleic acid is a polycistronic nucleic acid molecule.
  • 25. The nucleic acid of claim 24, wherein the polycistronic nucleic acid molecule comprises one or more ribosome binding sites.
  • 26. A pharmaceutical or veterinary composition comprising one or more of the bacterial delivery vehicles of claim 13 and a pharmaceutically-acceptable carrier.
  • 27. A method for treating a bacterial infection comprising administering to a subject in need of treatment the pharmaceutical or veterinary composition of claim 26, wherein said subject has a disease or disorder caused by bacteria, said disease or disorder selected from the group consisting of: a bacterial infection, a metabolic disorder, and a pathology involving bacteria of the human microbiome.
  • 28. The composition of claim 26 wherein said composition is for in-situ bacterial production of a compound of interest, preferably said compound of interest being produced inside the targeted bacteria, secreted from the targeted bacteria or expressed on the surface of the targeted bacteria.
  • 29. The engineered branched-RBP of claim 1, wherein the association is a covalent association.
CROSS-REFERENCE TO RELATED APPLICATION

This application is a continuation application of U.S. patent application Ser. No. 16/726,033, filed Dec. 23, 2019, which is a continuation-in-part of U.S. patent application Ser. No. 16/696,769, filed Nov. 26, 2019, which claims priority to U.S. Provisional Application No. 62/802,777 filed Feb. 8, 2019 and U.S. Provisional Application No. 62/783,258, filed Dec. 21, 2018, which are incorporated herein by reference in their entireties.

Provisional Applications (1)
Number Date Country
62802777 Feb 2019 US
Continuations (1)
Number Date Country
Parent 16726033 Dec 2019 US
Child 17527766 US
Continuation in Parts (1)
Number Date Country
Parent 16696769 Nov 2019 US
Child 16726033 US