Patent Application
20200268868
Described herein are genetically engineered Vibrio cholerae bacteria, pharmaceutical compositions including the bacteria, and methods of using the bacteria and/or a pharmaceutical composition including the bacteria to protect against disease caused by virulent strains of Vibrio cholerae through a combination of rapid probiotic protection and eliciting an adaptive immune response.
The instant application contains a Sequence Listing which has been filed electronically in ASCII format and is hereby incorporated by reference in its entirety. Said ASCII copy, created on Jul. 10, 2018, is named 29618-0175WO1_SL.txt and is 5.03 megabytes in size.
Cholera is a diarrheal disease caused by an infection with the Gram-negative bacterium Vibrio cholerae. The disease can be a rapidly fatal, and outbreaks often spread explosively. Efforts to fight the disease include oral rehydration and antibiotic therapy. However, the disease is a major public health hazard in developing and destabilized countries (see, e.g., Bohles et al. (2014) Hum. Vaccin. Immunother. 10(6): 1522-35). Vaccination campaigns deploying vaccines comprising killed Vibrio cholerae bacterial strains are currently underway. However, the utility of these vaccines for curtailing the spread of an ongoing epidemic (so-called ‘reactive vaccination’) depends on the time required for vaccinated subjects to become resistant to cholera. The protective immune responses elicited by current vaccines typically take days or weeks to manifest and often require multiple vaccine doses. Thus, there is a need for vaccines that can induce rapid protection against Vibrio cholerae after a single dose.
Described herein are attenuated V. cholerae bacterial strains that act, in an unprecedented manner, both as probiotic agents, to rapidly protect against cholera, and as traditional vaccines, to elicit the long-lived protective immunity to cholera observed of existing cholera vaccines. The attenuated V. cholerae bacterial strains described herein, as HaitiV, are derived from a recent clinical isolate, include multiple genetic modifications, and exhibit robust, multi-day occupancy of the intestine that is suggestive/predictive of their potential to engender long-lived immunity to cholera in humans. Surprisingly, a single dose of the attenuated bacterial strains is capable of conferring protection against a lethal challenge within 24 hours of HaitiV-administration in the infant rabbit model of cholera. The observation of such rapid protection in a neonatal model of infection is inconsistent with the protective immunity elicited by traditional vaccines. Instead, the ability of live HaitiV to rapidly mediate colonization resistance and disease protection against multiple challenge strains indicates that HaitiV, unlike existing vaccines, confers probiotic protection against cholera. Moreover, mathematical modeling indicates that the unprecedented speed of HaitiV-mediated protection could dramatically improve the public health impact of reactive vaccination. Thus, administration of the bacterial strains described herein can be used to reduce the risk of cholera infection, in particular during an ongoing epidemic, by engendering both rapid and long-lived protection.
Moreover, an attenuated V. cholerae bacterial strain may be induced to revert into a virulent strain by reacquiring virulence genes, and methods of preventing and/or mitigating the possibility of HaitiV's reversion to toxigenicity are also provided. Of particular concern are the genes encoding cholera toxin, the pathogen's principal diarrheagenic factor, which are deleted from live cholera vaccines. Any means of horizontal gene transfer, including re-infection by the cholera toxin encoding bacteriophage (CTXΦ) or natural transformation, may be sufficient to induce vaccine reversion. Applicants have developed attenuated V. cholerae bacterial strains modified to include RNA-guided endonuclease systems capable of specifically targeting the ctxA gene, which encodes the active subunit of cholera toxin. This strategy provides a biosafety mechanism to prevent V. cholerae bacteria from reacquiring ctxA, by any means, including infection with the CTXΦ prophage. Furthermore, this strategy can be generalized to other attenuated vaccine strains (e.g., Vaxchora and Peru-15) by engineering the strains to produce anti-virulence factor CRISPR systems from plasmid-encoded or chromosomally-integrated constructs.
In one aspect, the disclosure provides a genetically engineered Vibrio cholerae bacterium having a deletion in a nucleic acid sequence encoding a cholera toxin subunit A; a heterologous nucleic acid sequence encoding a Cas9 nuclease molecule; and a heterologous nucleic acid sequence encoding a guide RNA (gRNA), wherein the gRNA includes a targeting domain which is complementary with a target nucleic acid sequence of ctxA.
In some embodiments, a genetically engineered V. cholerae bacterium provided herein has a deletion in the nucleic acid sequence encoding the cholera toxin subunit A that is located in a ctxA gene that was integrated into the genome of the bacterium.
In some embodiments, a genetically engineered V. cholerae bacterium provided herein has a deletion in a nucleic acid sequence of the core region of a CTXΦ genome that was integrated into the genome of the bacterium.
In some embodiments, a genetically engineered V. cholerae bacterium provided herein has a deletion in a nucleic acid sequence of the RS2 region of a CTXΦ genome that was integrated into the genome of the bacterium.
In some embodiments, a genetically engineered V. cholerae bacterium provided herein has a complete deletion of a CTXΦ genome that was integrated into the genome of the bacterium.
In another aspect, the disclosure provides a genetically engineered Vibrio cholerae bacterium having a heterologous nucleic acid sequence encoding a Cas9 nuclease molecule; and a heterologous nucleic acid sequence encoding a guide RNA (gRNA), wherein the gRNA includes a targeting domain which is complementary with a target nucleic acid sequence of CTXΦ.
In some embodiments, target nucleic acid sequence of the CTXΦ genome is located in a gene selected from the group consisting of rstR, rstA, rstB, psh, cep, orfU, ace, zot, ctxA and ctxB. In some embodiments, the target nucleic acid sequence of the CTXΦ genome is located in a ctxA gene. In some embodiments, the gRNA comprises or consists of the nucleic acid sequence 5′-cctgatgaaataaagcagtcgttttagagctagaaatagc aagttaaaataaggctagtccgttatcaacttgaaaaagtggcaccgagtcggtgc-3′ (SEQ ID NO: 3).
In some embodiments, a genetically engineered V. cholerae bacterium provided herein has not previously had a copy of a CTXΦ genome integrated into the bacterial genome.
In some embodiments, a genetically engineered V. cholerae bacterium provided herein has a deletion in a nucleic acid sequence encoding a multifunctional-autoprocessing repeats-in-toxin (MARTX) toxin. In some embodiments, the nucleic acid sequence encoding the MARTX toxin is selected from the group consisting of rtxA, rtxB, rtxC, rtxD, and rtxE.
In some embodiments, a genetically engineered V. cholerae bacterium provided herein has a deletion in a nucleic acid sequence encoding a DNA-binding protein HU-beta. In some embodiments, the nucleic acid sequence encoding the DNA-binding protein HU-beta is a hupB gene.
In some embodiments, a genetically engineered V. cholerae bacterium provided herein has a deletion in a nucleic acid encoding a flagellin. In some embodiments, the nucleic acid sequence encoding a flagellin is selected from the group consisting of flaA, flaB, flaC, flaD, and FlaE.
In some embodiments, a genetically engineered V. cholerae bacterium provided herein includes a heterologous nucleic acid, wherein the heterologous nucleic acid includes a gene encoding cholera toxin subunit B that is operably-linked to a promoter. In some embodiments, the gene encoding cholera toxin subunit B is a ctxB gene. In some embodiments, the promoter is an inducible promoter. In some embodiments, the promoter is a Phtpg promoter. In some embodiments, the promoter is a constitutive promoter.
In some embodiments, a genetically engineered V. cholerae bacterium provided herein has a deletion in a nucleic acid sequence encoding a RecA protein. In some embodiments, the nucleic acid sequence encoding the RecA protein is a recA gene.
In another aspect, the disclosure provides a genetically engineered Vibrio cholerae bacterium having a deletion in one or more nucleic acid sequences encoding a MARTX toxin selected from the group consisting of rtxA, rtxB, rtxC, rtxD, rtxE and rtxH; a deletion in one or more flagellin genes selected from the group consisting of flaA, flaB, flaC, flaD, and FlaE; a deletion in a recA gene; and a heterologous nucleic acid, wherein the heterologous nucleic acid includes a ctxB gene operably linked to a promoter (e.g., a constitutive promoter or an inducible promoter). In some embodiments, the bacterium includes a complete deletion of a CTXΦ genome that was integrated into the genome of the bacterium. In some embodiments, the bacterium has not previously had a copy of a CTXΦ prophage genome integrated into the bacterial genome.
In some embodiments, a genetically engineered V. cholerae bacterium provided herein includes a heterologous nucleic acid sequence encoding a Cas9 nuclease molecule; and a heterologous nucleic acid sequence encoding a guide RNA (gRNA), wherein the gRNA includes a targeting domain which is complementary with a target nucleic acid sequence of ctxA. In some embodiments, the target nucleic acid sequence of CTXΦ is located in a ctxA gene. In some embodiments, the gRNA comprises or consists of the nucleic acid sequence 5′-cctgatgaaataaagcagtcgtttt agagctagaaatagcaagttaaaataaggct agtccgttatcaacttgaaaaagtggcaccgagtcggtgc-3′ (SEQ ID NO: 3).
In some embodiments, a genetically engineered V. cholerae bacterium provided herein has a deletion in one or more of: a nucleic acid sequence encoding a product that confers resistance to trimethoprim, a nucleic acid sequence encoding a product that confers resistance to sulfamethoxazole, a nucleic acid sequence encoding a product that confers resistance to streptomycin, and a nucleic acid sequence encoding a product that confers resistance to chloramphenicol. In some embodiments, the gene encoding a product that confers resistance to trimethoprim is dfrA. In some embodiments, the gene encoding a product that confers resistance to sulfamethoxazole is sul2. In some embodiments, the gene encoding a product that confers resistance to streptomycin is strAB. In some embodiments, the gene encoding a product that confers resistance to chloramphenicol is floR.
In some embodiments, a genetically engineered V. cholerae bacterium provided herein is derived from a parental strain belonging to the El Tor biotype.
In some embodiments, a genetically engineered V. cholerae bacterium provided herein is derived from a Haiti parental strain.
In some embodiments, a genetically engineered V. cholerae bacterium provided herein includes a first bacterial chromosome including or consisting of the nucleic acid sequence of SEQ ID NO: 7. In some embodiments, a genetically engineered V. cholerae bacterium provided herein includes a second bacterial chromosome including or consisting of the nucleic acid sequence of SEQ ID NO: 51.
In one aspect, the disclosure provides a genetically engineered Vibrio cholerae bacterium, wherein the bacterium has mutations in the same genes, relative to its parental strain (e.g., a virulent parental strain), as the strain having ATCC deposit number PTA-125138.
In another aspect, the disclosure provides a genetically engineered Vibrio cholerae bacterium, wherein the bacterium is a V. cholerae strain having ATCC deposit number PTA-125138.
The disclosure also provides pharmaceutical compositions including a genetically engineered Vibrio cholerae bacterium provided herein and a pharmaceutically acceptable excipient.
The disclosure further provides methods of inducing a protective response in a subject against a virulent strain of Vibrio cholerae, including administering to the subject a genetically engineered Vibrio cholerae bacterium provided herein, or a pharmaceutical composition including the bacterium, thereby inducing the protective response against the virulent strain of Vibrio cholerae in the subject (e.g., a human subject). In some embodiments, the protective response is induced within 24 hours of administering the genetically engineered Vibrio cholerae bacterium or of the pharmaceutical composition to the subject.
The disclosure also provides a genetically engineered Vibrio cholerae bacterium provided herein, for use in a method of inducing a protective response in a subject against a virulent strain of Vibrio cholera.
Also provided is a genetically engineered Vibrio cholerae bacterium provided herein, for use in a method of treating a subject who has a virulent strain of Vibrio cholerae.
In another aspect, the disclosure also provides a genetically engineered bacterium having a deletion of at least one virulence gene; a heterologous nucleic acid encoding a Cas9 nuclease molecule; and one or more heterologous nucleic acids encoding guide RNAs (gRNAs), wherein the gRNAs include a targeting domain that is complementary with a target nucleic acid sequence of the deleted virulence gene; wherein the Cas9 nuclease molecule is capable of binding to the gRNAs thereby forming a complex, and wherein the complex is capable of targeting and cleaving a nucleic acid sequence of the deleted virulence gene. In some embodiments, the bacterium is of a species selected from the group consisting of Vibrio cholerae, Salmonella enterica, Shigella flexneri, Shigella sonnei, Shigella dysenteriae, Bordetella pertussis, and Clostridioides difficile. In some embodiments, the virulence gene is selected from the group consisting of ctxA, aroA, aroQ, aroC, aroD, htrA, ssaV, cya, crp, phoP, phoQ, guaB, guaA, clpX, clpP, set, sen, virG/icsA, luc, aroA, msbB2, stxA, stxB, ampG, dnt, tcdA, and tcdB.
The disclosure also provides a pharmaceutical composition including a genetically engineered bacterium provided herein and a pharmaceutically acceptable excipient.
Also provided are methods of inducing a protective response in a subject against a virulent strain of bacterium described herein (e.g., Vibrio cholerae, Salmonella enterica, Shigella flexneri, Shigella sonnei, Shigella dysenteriae, Bordetella pertussis, and Clostridioides difficile), including administering to the subject a genetically engineered bacterium provided herein, or a pharmaceutical composition including the genetically engineered bacterium, thereby inducing the protective response against the virulent strain of bacterium in the subject (e.g., a human subject).
Unless otherwise defined, all technical and scientific terms used herein have the same meaning as commonly understood by one of ordinary skill in the art to which this invention belongs. Methods and materials are described herein for use in the present invention; other, suitable methods and materials known in the art can also be used. The materials, methods, and examples are illustrative only and not intended to be limiting. All publications, patent applications, patents, sequences, database entries, and other references mentioned herein are incorporated by reference in their entirety. In case of conflict, the present specification, including definitions, will control.
Other features and advantages of the invention will be apparent from the following detailed description and figures, and from the claims.
Provided herein is a genetically engineered Vibrio cholerae bacterium that may be used to induce protection from virulent V. cholerae within 24 hours of its administration to a subject. Vaccination with live attenuated V. cholerae bacterial strains is a promising strategy for inducing a protective immune response against the bacterium. The genes (ctxA and ctxB) encoding the main virulence factor in V. cholerae, cholera toxin (CT), are deleted from many live attenuated V. cholerae vaccine candidates but carried by CTX, a filamentous bacteriophage that infects V. cholerae, integrating its genome into the V. cholerae chromosome and/or replicating extra-chromosomally as a plasmid. Thus, there is a significant risk that CTXΦ infection of an attenuated strain of V. cholerae may induce the strain to revert to a virulent state; other means of gene acquisition, including natural transformation, can also mediate reversion. Methods of preventing and/or mitigating the possibility of acquisition of cholera toxin, e.g., by CTXΦ infection or transformation by attenuated V. cholerae bacterial strains are highly desirable to ensure the biosafety of vaccines including the attenuated V. cholerae strains.
In some embodiments, the bacterium is attenuated (i.e., has reduced virulence as compared to a parental strain from which it was derived). The bacterium may include one or more of the genetic modifications described herein in order to achieve attenuated state. The genetic modifications include, but are not limited to, a complete or partial deletion of a gene, and genetic modifications that alter the ability of the bacteria to express the gene (e.g., alterations to a promoter element that render it inoperable).
In some embodiments, the bacterium is of the genus Vibrio. In some embodiments, the bacterium is of the species Vibrio cholerae. Any V. cholerae strain, including clinical isolates, can be used as described herein. In some embodiments, the V. cholerae bacterium belongs to the O1 serogroup. In some embodiments, the V. cholerae bacterium belongs to the O1 serogroup and is of the classical biotype. In some embodiments, the V. cholerae bacterium belongs to the O1 serogroup and is of the El Tor biotype. In some embodiments, the V. cholerae bacterium belongs to the O1 serogroup and is of the variant El Tor biotype. In some embodiments, the V. cholerae bacterium belongs to the O139 serogroup. In some embodiments, the V. cholerae bacterium belongs to the Inaba serotype. In some embodiments, the V. cholerae bacterium belongs to the Ogawa serotype. In some embodiments, the V. cholerae bacterium belongs to the Hikojima serotype. In some embodiments, the V. cholerae bacterium is derived from a Haitian clinical isolate. In some embodiments, the V. cholerae bacterium is derived from a strain selected from the group consisting of O395, N16961, B33, D34122, D34642, and D34755. In some embodiments, the V. cholerae bacterium is derived from an H1 strain (also known as KW3 strain (see NCBI Ref. Seq. GCF_000275645.1 and Ref. Seq. GCF_001318185.1)). Virulent V. cholerae strains encode two major virulence factors: cholera toxin (CT) and the toxin co-regulated pilus (TCP) that are encoded by the lysogenic bacteriophage CTXΦ and a chromosomal pathogenicity island, respectively. The bacteriophage CTXΦ can convert a non-pathogenic strain of V. cholerae into a pathogenic strain through phage infection, a process by which the phage genome integrates into the host genome or is maintained as a plasmid, both of which provide the host bacterium with virulence genes.
The CTXΦ genome is approximately 6.9 kb in size and is organized into two functionally distinct regions (see e.g., McLeod et al. (2005) Mol. Microbiol. 57(2): 347-56; and Kim et al. (2014) J. Microbiol. Biotechnol. 24(6): 725-31). The first region, repeat sequence 2 (RS2) includes three genes: rstR, rstA and rstB. rstA and rstB encode the proteins RstA and RstB, respectively, which are required for CTX DNA replication and integration into the bacterial chromosome. rstR encodes the repressor protein RstR. The second region, referred to as the core region, includes the genes psh, cep, orfU (gill), ace, zot, and ctxAB. The psh, cep, orfU, ace, and zot genes encode the proteins Psh, Cep, OrfU (pIIICTX), Ace, and Zot, respectively, which are required for phage packaging and secretion. The ctxAB is an operon includes the ctxA and ctxB genes which encode the protein subunits of cholera toxin, CtxA and CtxB, respectively. Together, ctxA and ctxB encode the Cholera toxin (CT) virulence factor that consists of one CT-A subunit and five CT-B subunits.
In some embodiments, the V. cholerae bacterium described herein includes one or more genetic alterations in order to reduce, inhibit and/or alter the expression of one or more CTXΦ genome genes that are integrated in the bacterial genome in order to reduce the virulence of the bacterium. The genetic alterations include, but are not limited to a deletion, mutation, insertion in the open reading frame of a CTXΦ genome gene to alter the expression and function of the gene product, or in a promoter or transcriptional regulatory element in order to inhibit the expression of the gene. In some embodiments, the V. cholerae bacterium includes a deletion of all copies of the integrated CTXΦ genome and the adjacent (and related) RS1 element, a satellite phage that can be packaged by CTXΦ. In some embodiments, the V. cholerae bacterium includes a deletion in a nucleic acid sequence of an integrated CTXΦ genome gene. In some embodiments, the V. cholerae bacterium has been genetically modified to completely delete a nucleic acid sequence including or consisting of a CTXΦ genome that was incorporated into the bacterial chromosome. In some embodiments, the V. cholerae bacterium has been genetically modified to partially delete a nucleic acid sequence including a CTXΦ genome that was incorporated into the bacterial chromosome. In some embodiments, the V. cholerae bacterium has been genetically modified to delete a nucleic acid sequence including or consisting of the RS2 region of a CTXΦ genome that was incorporated into the bacterial chromosome. In some embodiments, the V. cholerae bacterium has been genetically modified to delete a nucleic acid sequence including or consisting of the core region of a CTXΦ genome that was incorporated into the bacterial chromosome. In some embodiments, the V. cholerae bacterium has been genetically modified to delete a nucleic acid sequence including or consisting of a gene selected from the group consisting of rstR, rstA, rstB, psh, cep, orfU (gill), ace, zot, ctxA and ctxB. In some embodiments, the V. cholerae bacterium has been genetically modified to delete a nucleic acid sequence including or consisting of a ctxA gene. In some embodiments, the V. cholerae bacterium has been genetically modified to delete a nucleic acid sequence including or consisting of a ctxB gene. In some embodiments, the V. cholerae bacterium has been genetically modified to delete a nucleic acid sequence including or consisting of a ctxAB operon. In some embodiments, the V. cholerae bacterium has been genetically modified to delete an attB (attachment) site where CTXΦ phage integrates.
In some embodiments, the V. cholerae bacterium includes one or more genetic alterations in order to reduce, inhibit and/or alter the expression of one or more RS1 satellite phage genes and/or one or more TCL satellite phage genes that are integrated in the bacterial genome. Integrated copies of the CTXΦ prophage genome are often flanked by copies of the RS1 satellite phage and the TLC satellite phage. The TLC satellite phage is involved in altering the V. cholerae genome to enhance the integration of the CTXΦ and RS1 phages, while the RS1 phage uses some of the CTXΦ-encoded proteins for packaging and secretion (see, e.g., Samruzzaman et al. (2014) Infect. Immun. 82(9): 3636-43. In some embodiments, the V. cholerae bacterium includes a partial deletion of an integrated copy of the RS1 phage genome. In some embodiments, the V. cholerae bacterium includes a complete deletion of an integrated copy of the RS1 phage genome. In some embodiments, the V. cholerae bacterium includes a partial deletion of an integrated copy of an RS1 phage gene. In some embodiments, the V. cholerae bacterium includes a complete deletion of an integrated copy of an RS1 phage gene. In some embodiments, the V. cholerae bacterium includes a partial deletion of an integrated copy of the TLC phage genome. In some embodiments, the V. cholerae bacterium includes a complete deletion of an integrated copy of the TLC phage genome. In some embodiments, the V. cholerae bacterium includes a partial deletion of an integrated copy of an TLC phage gene. In some embodiments, the V. cholerae bacterium includes a complete deletion of an integrated copy of an TLC phage gene.
In some embodiments, the V. cholerae bacterium includes a genetic modification that renders the bacterium incapable of facilitating the replication of CTX. For example, the DNA binding protein HUD promotes replication of the plasmid form of CTXΦ in V. cholerae (see, Martinez et al. (2015) PLoS Genetics 11(5): e1005256, the entire contents of which are expressly incorporated herein by reference). In V. cholerae, HUβ is encoded by hupB (also known as VC1919). Thus, in some embodiments, the V. cholerae bacterium includes a genetic alteration that alters the function and/or expression of hupB. In some embodiments, the V. cholerae bacterium includes a partial deletion of the hupB gene. In some embodiments, the V. cholerae bacterium includes a complete deletion of the hupB gene.
In some embodiments, the V. cholerae bacterium includes a genetic modification that renders the bacterium incapable of producing and/or secreting a multifunctional-autoprocessing repeats-in-toxin (MARTX) toxin. The MARTX toxin rtx gene loci in V. cholerae consists of two divergently transcribed operons rtxHCA and rtxBDE. In V. cholerae, the MARTX toxin, RtxA, is encoded by the gene rtxA, and facilitates bacterial colonization of the intestine (see, e.g., Satchell et al. (2015) Microbiol. Spectr. 3(3) and Fullner et al. (2002) J. Exp. Med. 195(11): 1455-62; and Olivier et al. (2009) PLoS One 4(10): e7352, the entire contents of each of which are incorporated herein by reference). Adjacent gene rtxC encodes the putative acytltransferase rtxC, while rtxH encodes a hypothetical protein with uncharacterized function (see Gavin and Satchell (2015) Pathog. Dis. 73(9): ftv092, the entire contents of which are incorporated herein by reference). The genes of the rtxBDE operon encode a dedicated MARTX toxin Type 1 secretion system (T1SS), whereby rtxB and rtxE encode the ATPase proteins RtxB and RtxE, respectively, and rtxD encodes the transmembrane protein RtxD which acts in concert with the outer membrane porin TolC to secrete RtxA from the bacterial cytoplasm to the extracellular environment (see Gavin and Satchell (2015)). In some embodiments, the V. cholerae bacterium includes a genetic alteration that alters the function of the MARTX toxin. In some embodiments, the V. cholerae bacterium includes a partial deletion of the rtxA gene. In some embodiments, the V. cholerae bacterium includes a complete deletion of the rtxA gene. In some embodiments, the V. cholerae bacterium includes a partial deletion of the rtxB gene. In some embodiments, the V. cholerae bacterium includes a complete deletion of the rtxB gene. In some embodiments, the V. cholerae bacterium includes a partial deletion of the rtxC gene. In some embodiments, the V. cholerae bacterium includes a complete deletion of the rtxC gene. In some embodiments, the V. cholerae bacterium includes a partial deletion of the rtxD gene. In some embodiments, the V. cholerae bacterium includes a complete deletion of the rtxD gene. In some embodiments, the V. cholerae bacterium includes a partial deletion of the rtxE gene. In some embodiments, the V. cholerae bacterium includes a complete deletion of the rtxE gene. In some embodiments, the V. cholerae bacterium includes a partial deletion of the rtxH gene. In some embodiments, the V. cholerae bacterium includes a complete deletion of the rtxH gene. In some embodiments, the V. cholerae bacterium includes a partial deletion of the rtxHCA operon. In some embodiments, the V. cholerae bacterium includes a complete deletion of the rtxHCA operon. In some embodiments, the V. cholerae bacterium includes a partial deletion of the rtxBDE operon. In some embodiments, the V. cholerae bacterium includes a complete deletion of the rtxBDE operon.
In some embodiments, the V. cholerae bacterium includes a genetic modification to reduce the reactogenicity of the bacterium after administration to a subject (e.g., a human subject). Some attenuated oral V. cholerae vaccine strains have induced reactogenicity symptoms that included noncholeric diarrhea and abdominal cramps; however, V. cholerae strains lacking flagellin-encoding genes have been demonstrated to exhibit reduced reactogenicity in animal models (see, e.g., Rui et al. (2010) Proc. Nat'l. Acad. Sci. USA 107(9): 4359-64, the entire contents of which are expressly incorporated herein by reference.) V. cholerae includes two operons, flaAC and flaDBE, which include five flagellin-encoding genes. In some embodiments, the V. cholerae bacterium includes a genetic alteration that alters the function of at least one gene encoding a flagellin. In some embodiments, the V. cholerae bacterium includes a partial deletion in a gene encoding a flagellin. In some embodiments, the V. cholerae bacterium includes a complete deletion in a gene encoding a flagellin. In some embodiments, the V. cholerae bacterium includes a complete or partial deletion in a flagellin gene selected from the group consisting of flaA, flaB, flaC, flaD, and flaE. In some embodiments, the V. cholerae bacterium includes a complete or partial deletion of the flaAC operon. In some embodiments, the V. cholerae bacterium includes a complete or partial deletion of the flaBDE operon. In some embodiments, the V. cholerae bacterium includes a complete or partial deletion of both the flaAC operon and the flaBDE operon.
In some embodiments, the V. cholerae bacterium includes a deletion in an antibiotic resistance gene to prevent the dispersal of the antibiotic resistance genes to other bacteria. In some embodiments, the V. cholerae bacterium includes a partial deletion in an antibiotic resistance gene. In some embodiments, the V. cholerae bacterium includes a complete deletion in an antibiotic resistance gene. In some embodiments, the antibiotic resistance gene is selected from the group consisting of floR (which confers resistance to chloramphenicol), strAB (which confers resistance to streptomycin), sul2 (which confers resistance to sulfisoxazole and sulfamethoxazole), and dfrA (which confers resistance to trimethoprim). In some embodiments, the V. cholerae bacterium includes a complete deletion of each of the following antibiotic resistance genes: floR, strAB, dfrA, and sul2.
In some embodiments, the V. cholerae bacterium includes a genetic modification that renders the bacterium incapable of producing RecA. The gene recA encodes the multifunctional protein RecA, which is involved in homologous recombination, DNA repair, and the SOS response (see, e.g., Thompson et al. (2004) Int. J. Syst. Evol. Microbiol. 54 (Pt. 3): 919-24, the entire contents of which are expressly incorporated herein by reference). In some embodiments, the V. cholerae bacterium includes a deletion in the recA gene. In some embodiments, the deletion is a partial deletion. In some embodiments, the deletion is a complete deletion. Without wishing to be bound by any particular theory, deletion of recA prevents homologous recombination-dependent gene acquisition by the V. cholerae bacterium and its ability to resolve mutations that arise from environmental exposure such as UV light.
In some embodiments, the V. cholerae bacterium includes a heterologous nucleic acid or a heterologous gene. The term “heterologous nucleic acid” or “heterologous gene” refers to a nucleic acid that is not normally found in a given cell in nature (e.g., a nucleic acid that is exogenously introduced into a given cell; or a nucleic acid that has been introduced into the host cell in a form that is different from the corresponding native nucleic acid). It will be readily understood by those of skill in the art that a heterologous nucleic acid may comprise a gene that is codon-optimized for use in a V. cholerae bacterium described herein.
In some embodiments, the V. cholerae bacterium includes a heterologous nucleic acid encoding an antigenic polypeptide. In some embodiments, the expression of the nucleic acid encoding the antigenic polypeptide is operably-linked to a constitutive promoter. In some embodiments, the nucleic acid encoding the antigenic polypeptide is operably-linked to an inducible promoter. In some embodiments, the heterologous nucleic acid encoding an antigenic polypeptide is integrated in the bacterial genome. In some embodiments, the heterologous nucleic acid encoding an antigenic polypeptide is present on a plasmid. In some embodiments, the antigenic polypeptide is the cholera toxin subunit CtxB. Expression of the cholera toxin CtxB subunit by the V. cholerae bacterium described herein may be particularly advantageous as it may promote the induction of an anti-CtxB immune response in a subject to whom the bacterium is administered, thereby resulting in immunoprotection against V. cholerae and enterotoxigenic E. coli (ETEC) (see, e.g., Kauffman et al. (2016) mBio 7(6): e02021-16, the entire contents of which are expressly incorporated herein by reference). Thus, in some embodiments, the V. cholerae bacterium includes a heterologous nucleic acid comprising the V. cholerae ctxB gene. In some embodiments, the V. cholerae bacterium includes a heterologous nucleic acid comprising the V. cholerae ctxB gene is operably linked to an inducible promoter (e.g., a Phtpg promoter). In some embodiments, the V. cholerae bacterium includes a heterologous nucleic acid comprising the V. cholerae ctxB gene is operably linked to an inducible promoter. In some embodiments, the heterologous nucleic acid comprising the V. cholerae ctxB gene is present on the bacterial chromosome. In some embodiments, the V. cholerae bacterium includes the mutation N900_11550::Phtpg-ctxB. In some embodiments, the V. cholerae bacterium includes a heterologous nucleic acid encoding CtxB integrated into the chromosome at a locus homologous to the N900_11550 locus of HaitiWT (Bioproject Accession No. PRJNA215281; Biosample Accession No. SAMN04191514). In some embodiments, the V. cholerae bacterium includes a heterologous nucleic acid encoding CtxB integrated into the chromosome at a locus homologous to the N900_RS07040 locus of HaitiWT. In some embodiments, the V. cholerae bacterium includes a heterologous nucleic acid encoding CtxB integrated into the chromosome at a locus homologous to the N900_RS07045 locus of HaitiWT.
In some embodiments, the V. cholerae bacterium includes a bacterial chromosome, wherein the bacterial chromosome includes or consists of the nucleic acid sequence of SEQ ID NO: 7. In some embodiments, the V. cholerae bacterium includes a bacterial chromosome, wherein the bacterial chromosome includes or consists of the nucleic acid sequence of SEQ ID NO: 51. In some embodiments, the V. cholerae bacterium includes a first bacterial chromosome and a second bacterial chromosome, wherein the first bacterial chromosome includes or consists of the nucleic acid sequence of SEQ ID NO: 7, and the second bacterial chromosome includes or consists of the nucleic acid sequence of SEQ ID NO: 51. In some embodiments, the V. cholerae bacterium has mutations in the same genes, relative to its parental strain, as the strain having ATCC deposit number PTA-125138. In some embodiments, the Vibrio cholerae bacterium is a V. cholerae strain having ATCC deposit number PTA-125138 (described herein as HaitiV).
The disclosure further provides recombinant bacterial strains comprising a programmable RNA-guided nuclease system that specifically targets a gene (e.g., a virulence gene) that was previously deleted from the bacterial strain. By targeting the gene that was deleted from the bacterial strain, reversion of a virulent phenotype by the recombinant bacterium may be prevented and/or ameliorated (e.g., by preventing re-acquisition of the gene). The use of programmable RNA-guided nuclease systems as described herein is particularly useful in live attenuated vaccine bacterial strains in order to maintain the attenuated phenotype of the strains.
Any attenuated bacterial strain can be modified to express a programmable RNA-guided nuclease system to prevent and/or ameliorate reversion to a virulent phenotype. For example, live attenuated bacterial strains of the species V. cholerae, Salmonella enterica, Shigella flexneri, Shigella sonnei, Shigella dysenteriae, Bordetella pertussis, and Clostridioides difficile (previously Clostridium difficile) can be genetically-manipulated to express a programmable RNA-guided nuclease system targeting a gene that is deleted in the strain (i.e., as compared to the strain from which the attenuated bacterial strain was derived). Exemplary live attenuated bacterial strains and a description of the virulence genes that are deleted in the strains are provided in Table 1. Exemplary sequences of the virulence genes that are deleted in these live attenuated bacterial strains are provided in Table 2. Each of the bacterial strains provided in Table 1 can be genetically modified as described herein to include a RNA-guided nuclease system that specifically targets at least one of the genes that has been deleted in the strain. For example, in some embodiments, the bacterial strain is a V. cholerae strain including a deletion in a ctxA gene, as well as a programmable RNA-guided nuclease system (e.g., a heterologous nucleic acid sequence encoding a Cas9 nuclease molecule and a heterologous nucleic acid sequence encoding a guide RNA (gRNA)) targeting a ctxA gene. In some embodiments, the bacterial strain is a S. enterica strain including a deletion in at least one virulence gene selected from aroC, aroD, htrA, ssaV, cya, crp, phoP, phoQ, guaB, guaA, clpX, and clpP, as well as a programmable RNA-guided nuclease system targeting at least one of the deleted virulence genes (e.g., aroC, aroD, htrA, ssaV, cya, crp, phoP, phoQ, guaB, guaA, clpX, and clpP). In some embodiments, the bacterial strain is a S. flexneri strain including a deletion in at least one virulence gene selected from guaB, guaA, set, sen, virG/icsA, luc, aroA, and msbB2, as well as a programmable RNA-guided nuclease system targeting at least one of the deleted virulence genes (e.g., guaB, guaA, set, sen, virG/icsA, luc, aroA, and msbB2). In some embodiments, the bacterial strain is a S. dysenteriae strain including a deletion in at least one virulence gene selected from guaB, guaA, sen, stxA, stxB, and msbB2, as well as a programmable RNA-guided nuclease system targeting at least one of the deleted virulence genes (e.g., guaB, guaA, sen, stxA, stxB, and msbB2). In some embodiments, the bacterial strain is a S. sonnei strain including a deletion in a stxA gene and/or a stxB gene, as well as a programmable RNA-guided nuclease system targeting the deleted virulence gene (e.g., stxA and/or stxB). In some embodiments, the bacterial strain is a B. pertussis strain including a deletion in a dnt gene, a aroA gene and/or an aroQ gene, as well as a programmable RNA-guided nuclease system targeting the deleted virulence gene (e.g., dnt, aroA and/or aroQ). In some embodiments, the bacterial strain is a C. difficile strain including a deletion in a tcdA gene and/or a tcdB gene, as well as a programmable RNA-guided nuclease system targeting the deleted virulence gene (e.g., tcdA and/or tcdB).
In some embodiments, the bacterium is a V. cholerae bacterium having a programmable RNA-guided nuclease system that specifically targets a CTXΦ nucleic acid, thereby preventing or interrupting one or more of the following processes: the insertion of CTXΦ genetic material into the bacterial genome, the replication of CTXΦ, the assembly of CTXΦ, and/or the release of CTXΦ from the bacterium; or killing the bacterium comprising an integrated copy of the CTXΦ genome. In some embodiments, the programmable RNA-guided nuclease system targets a ctxA gene.
Relevant nuclease systems that may be used include, but are not limited to: zinc finger nucleases, transcription activator-like effector nucleases (TALENs), CRISPR from Prevotella and Francisella 1 (Cpf1) nucleases, meganucleases, and CRISPR/Cas9 nuclease systems. As used herein, the term “edits” in reference to a programmable RNA-guided nuclease system includes mutations such as, a point mutation, an insertion, a deletion, a frameshift, or a missense mutation at a target nucleic acid. The RNA-guided nuclease system includes guide RNAs comprising a sequence that is complementary to the sequence of a nucleic acid (i.e., a targeting domain) in the virulence gene (e.g., a gene present in a CTXΦ genome such as ctxA), and a sequence (e.g., a PAM sequence or a direct repeat sequence) that is targetable by a nuclease molecule (e.g., a Cas9 nuclease molecule). The term guide RNA (“gRNA”), as used herein, includes any RNA molecule (e.g., gRNA, crRNA, tracrRNA, sgRNA, and others) guiding a nuclease molecule to a target nucleic acid. Upon successful targeting, the nuclease molecule cleaves the nucleic acid in the virulence gene (e.g., ctxA). By specifically targeting the virulence gene with a programmable RNA-guided nuclease system, the reversion of an attenuated bacterium (e.g., an attenuated Salmonella enterica or V. cholerae bacterium) to a virulent bacterium may be prevented and/or ameliorated. The term “prevention” refers to any reduction, no matter how slight (e.g., need not be 100% reduction), of the risk that an attenuated bacterium to revert to a virulent form.
In some embodiments, the bacterium includes a heterologous nucleic acid encoding a Cas9 nuclease molecule. Although the present examples exemplify the use of a Streptococcus pyogenes Cas9 nuclease molecule (SpCas9), other Cas9 nuclease molecules from other species can also be used (e.g., Staphylococcus aureus Cas9 nuclease molecule (SaCas9)), as discussed below. The sequences of multiple Cas9 nuclease molecules, as well as their respective PAM sequences, are known in the art (see, e.g., Kleinstiver et al. (2015) Nature 523 (7561): 481-5; Hou et al. (2013) Proc. Natl. Acad. Sci. U.S.A.; Fonfara et al. (2014) Nucleic Acids Res. 42: 2577-90; Esvelt et al. (2013) Nat. Methods 10: 1116-21; Cong et al. (2013) Science 339: 819-23; and Horvath et al. (2008)J Bacteriol. 190: 1401-12; PCT Publication Nos. WO 2016/141224, WO 2014/204578, and WO 2014/144761; U.S. Pat. No. 9,512,446; and US Publication No. 2014/0295557; the entire contents of each of which are incorporated herein by reference). Variants of the SpCas9 system can also be used (e.g., truncated sgRNAs (Tsai et al. (2015) Nat. Biotechnol. 33: 187-97; Fu et al. (2014) Nat. Biotechnol. 32: 279-84), nickase mutations (Mali et al. (2013) Nat. Biotechnol. 31: 833-8 (2013); Ran et al. (2013) Cell 154: 1380-9), FokI-dCas9 fusions (Guilinger et al. (2014) Nat. Biotechnol. 32: 577-82; Tsai et al. (2014) Nat. Biotechnol. 32: 569-76; and PCT Publication No. WO 2014/144288; the entire contents of each of which are incorporated herein by reference). The nucleases can include one or more of SpCas9 D1135E variant; SpCas9 VRER variant; SpCas9 EQR variant; SpCas9 VQR variant; Streptococcus thermophilus Cas9 nuclease molecule (StCas9); Treponema denticola Cas9 nuclease molecule (TdCas9); or Neisseria meningitidis Cas9 nuclease molecule (NmCas9), as well as variants thereof that are at least 80%, 85%, 90%, 95%, 96%, 97%, 98%, 99% or 100% identical thereto that retain at least one function of the enzyme from which they are derived, e.g., the ability to complex with a gRNA, bind to target DNA specified by the gRNA, and alter the sequence (e.g., cleave) of the target DNA.
In some embodiments, the bacterium (e.g., a V. cholerae bacterium) includes a heterologous nucleic acid encoding a Cpf1 nuclease molecule. Cpf1 is a Cas protein that can be programmed to cleave target DNA sequences (Zetsche et al. (2015) Cell 163: 759-71; Schunder et al. (2013) Int. J Med. Microbiol. 303: 51-60; Makarova et al. (2015) Nat. Rev. Microbiol. 13: 722-36; Fagerlund et al. (2015) Genome Biol. 16: 251). In some embodiments, the Cpf1 nuclease molecule is Acidaminococcus sp. BV3L6 (AsCpf1; NCBI Reference Sequence: WP 021736722.1), or a variant thereof. In some embodiments, the Cpf1 nuclease molecule is Lachnospiraceae bacterium ND2006 (LbCpf1; GenBank Acc No. WP_051666128.1) or a variant thereof. Unlike SpCas9, Cpf1 requires only a single 42-nt crRNA, which has 23 nt at its 3′ end that are complementary to the protospacer of the target DNA sequence (Zetsche et al. (2015)). Furthermore, whereas SpCas9 recognizes an NGG PAM sequence that is 3′ of the protospacer, AsCpf1 and LbCp1 recognize TTTN PAMs that are found 5′ of the protospacer (Zetsche et al. (2015)). In some embodiments, the Cpf1 nuclease molecule is a variant of a wild-type Cpf1 molecule that is at least 80%, 85%, 90%, 95%, 96%, 97%, 98%, 99% or 100% identical to a wild-type Cpf1 nuclease molecule, and retains at least one function of the enzyme from which it was derived, e.g., the ability to complex with a gRNA, bind to target DNA specified by the gRNA, and alter the sequence (e.g., cleave) of the target DNA
To determine the percent identity of two sequences, the sequences are aligned for optimal comparison purposes (gaps are introduced in one or both of a first and a second amino acid or nucleic acid sequence as required for optimal alignment, and non-homologous sequences can be disregarded for comparison purposes). The length of a reference sequence aligned for comparison purposes is at least 80% (in some embodiments, about 85%, 90%, 95%, or 100% of the length of the reference sequence) is aligned. The nucleotides or residues at corresponding positions are then compared. When a position in the first sequence is occupied by the same nucleotide or residue as the corresponding position in the second sequence, then the molecules are identical at that position. The percent identity between the two sequences is a function of the number of identical positions shared by the sequences, taking into account the number of gaps, and the length of each gap, which need to be introduced for optimal alignment of the two sequences.
The comparison of sequences and determination of percent identity between two sequences can be accomplished using a mathematical algorithm. For example, the percent identity between two amino acid sequences can be determined using the Needleman and Wunsch algorithm (see Needleman and Wunsch (1970) J Mol. Biol. 48: 444-53) which has been incorporated into the GAP program in the GCG software package, using a Blossum 62 scoring matrix with a gap penalty of 12, a gap extend penalty of 4, and a frameshift gap penalty of 5.
The amino acid sequence of wild type SpCas9 is as follows:
The amino acid sequence of wild type SaCas9 is as follows:
In some embodiments, the bacterium includes a heterologous nucleic acid sequence encoding a gRNA, wherein the gRNA includes a targeting domain which is complementary with a target nucleic acid sequence of a virulence gene (e.g., a CTXΦ genome gene such as ctxA). In some embodiments, the gRNA includes a targeting domain which is complementary with a target nucleic acid sequence present on a virulence gene listed in Table 2 (e.g., ctxA, aroD, or htrA). Methods of designing and making gRNAs with specificity for particular targets are known in the art and are described, for example, in Prykhozhij et al. (2015) PLos One 10(3):e0119372; Doench et al. (2014) Nat. Biotechnol. 32(12): 1262-7; and Graham et al. (2015) Genome Biol. 16: 260, each of which are expressly incorporated herein by reference.
V. cholerae Having Programmable RNA-Guided Nuclease Systems
In some embodiments, the virulence gene is a CTXΦ gene and the bacterium is an attenuated V. cholerae bacterium. Without wishing to be bound by any particular theory, by specifically targeting a nucleic acid sequence of the CTXΦ genome, it is possible to prevent integration of the CTXΦ genome into the V. cholerae bacterial genome and/or maintenance of the CTXΦ genome as a plasmid, either of which may cause the bacterium to adapt and/or revert to a virulent state. The gRNA may comprise a targeting domain complementary with a target nucleic acid sequence present in the CTXΦ genome; however, it is preferable that the gRNA specifically target the nucleic acid sequence of the CTXΦ genome and not a bacterial genome nucleic acid sequence. In some embodiments, the gRNA includes a targeting domain complementary with a target nucleic acid sequence present in a CTXΦ gene (e.g., rstR, rstA, rstB, psh, cep, orfU (gill), ace, zot, ctxA and ctxB). It is particularly desireable to target ctxA. In some embodiments, the gRNA includes a targeting domain complementary with a target nucleic acid sequence present in a ctxA gene. In some embodiments, the gRNA includes the nucleic acid sequence: 5′-cctgatgaaataaagcagtcgttttagagctagaaatagcaagttaaaataaggctagtccgttatcaacttgaaaaagtgg caccgagtcggtgc-3′ (SEQ ID NO: 3; targeting sequence specific for ctxA highlighted in bold). In some embodiments, the gRNA includes the nucleic acid sequence 5′-tttttgtcgattatcttgctgttctagagagcgggagctcaagttagaataaggctagtccgtattcagtgcgggagcacgg caccgattcggtgc-3′ (SEQ ID NO: 4; targeting sequence specific for rstA highlighted in bold). In some embodiments, the gRNA includes the nucleic acid sequence 5′-taaacaaagggagcattatagttggagaggcatgagaatgccaagttccaataaggctagtccgtacacacctaggaga ctaggggcaccgagtcggtgc-3′ (SEQ ID NO: 5; targeting sequence specific for ctxA highlighted in bold).
As described above, in some embodiments, the genetically engineered V. cholerae bacterium may include a heterologous nucleic acid, wherein the heterologous nucleic acid includes a ctxB gene. Without wishing to be bound by any particular theory, expression of CtxB may induce an anti-ctxB immune response in a subject. This anti-ctxB immune response may protect against diarrheal disease caused by either a virulent V. cholerae bacterial strain and/or enterotoxigenic E. coli (ETEC) (see, e.g., Kauffman et al. (2016) MBio. 7(6): e 02021-16). One of skill in the art will readily appreciate that if the bacterium includes a heterologous nucleic acid comprising a ctxB gene as well as a gRNA comprising a targeting domain complementary with a target nucleic acid sequence present in a ctxB gene, either the heterologous nucleic acid comprising the ctxB gene, or the nucleic acid encoding the gRNA may be genetically engineered such that the gRNA does not target the heterologous nucleic acid comprising the ctxB gene. For example, the heterologous nucleic acid comprising the ctxB gene may be modified to replace a codon sequence with a synonymous codon sequence such that it is not complementary to the gRNA targeting domain sequence.
Vibrio
cholerae
Vaccine
Vibrio
V.
cholerae
cholerae
Vibrio
cholerae
Salmonella
enterica
Typhi
Salmonella
enterica
Vaccine
Typhi
Salmonella
enterica
Typhi
Salmonella
enterica
Typhi
Salmonella
enterica
Typhi
Salmonella
enterica
Typhi
Salmonella
enterica
Typhi
Salmonella
enterica
Typhi
Salmonella
enterica
Paratyphi
A
Salmonella
enterica
Paratyphi
A
Salmonella
enterica
Paratyphi
B
Salmonella
enterica
Typhimurium
Salmonella
enterica
Typhimurium
Salmonella
enterica
Enteritidis
Salmonella
enterica
Enteritidis
Shigella
flexneri
Shigella
Vaccine
flexneri
Shigella
flexneri
Shigella
flexneri
Shigella
flexneri
Shigella
flexneri
Shigella
flexneri
Shigella
sonnei
Shigella
sonnei
Shigella
sonnei
Shigella
dysenteriae
Shigella
dysenteriae
Shigella
dysenteriae
Shigella
dysenteriae
Shigella
dysenteriae
Shigella
dysenteriae
Shigella
dysenteriae
Bordetella
pertussis
Bordetella
Vaccine
pertussis
Bordetella
pertussis
Bordetella
pertussis
Vibrio
cholerae O1
Vibrio
cholerae O395
Vibrio
cholerae O395
Vibrio
cholerae O395
Vibrio
cholerae O395
Salmonella
enterica
serovar
Typhi str.
Salmonella
enterica
Salmonella
enterica
serovar
Typhi str. P-
Salmonella
enterica
serovar
Typhi str.
Salmonella
enterica
serovar
Typhi str.
Salmonella
enterica
serovar
Typhi str.
Salmonella
enterica
serovar
Typhi str. Ty2
Salmonella
enterica
serovar
Typhi str. P-
Salmonella
enterica
Salmonella
enterica
serovar
Montevideo
Salmonella
enterica
serovar
Typhi str.
Salmonella
enterica
serovar
Typhi str. Ty2
Salmonella
enterica
serovar
Typhi str. P-
Salmonella
enterica
serovar
Typhi str.
Salmonella
enterica
serovar
Typhi str.
Salmonella
enterica
serovar
Typhi str.
Salmonella
enterica
serovar
Typhi str. Ty2
Salmonella
enterica
serovar
Typhi str. P-
Salmonella
enterica
serovar
Typhi str.
Salmonella
enterica
serovar
Typhi str.
Salmonella
enterica
serovar
Typhimurium
Salmonella
enterica
serovar
Typhi str.
Salmonella
enterica
serovar
Typhi str. Ty2
Salmonella
enterica
serovar
Paratyphi
B
Salmonella
enterica
serovar
Newport str.
Salmonella
enterica
serovar
Typhi str.
Salmonella
enterica
serovar
Typhi str. Ty2
Salmonella
enterica
Salmonella
enterica
serovar
Typhi str.
Salmonella
enterica
serovar
Typhi str.
Salmonella
enterica
serovar
Typhi str.
Salmonella
enterica
serovar
Typhi str. Ty2
Salmonella
enterica
serovar
Typhi str. P-
Salmonella
enterica
serovar
Typhi str.
Salmonella
enterica
serovar
Typhi str.
Salmonella
enterica
serovar
Typhi str.
Salmonella
enterica
serovar
Typhi str. Ty2
Salmonella
enterica
serovar
Typhi str. P-
Salmonella
enterica
serovar
Typhi str.
Salmonella
enterica
serovar
Typhi str.
Salmonella
enterica
serovar
Typhi str.
Salmonella
enterica
serovar
Heidelberg
Salmonella
enterica
serovar
Typhimurium
Salmonella
enterica
serovar
Dublin
Salmonella
enterica
serovar
Typhi str. Ty2
Salmonella
enterica
serovar
Typhi str.
Salmonella
enterica
serovar
Typhi str. Ty2
Salmonella
enterica
serovar
Heidelberg
Salmonella
enterica
serovar
Agona str.
Salmonella
enterica
serovar
Dublin str.
Salmonella
enterica
serovar
Typhi str.
Salmonella
enterica
serovar
Typhi str. Ty2
Salmonella
enterica
serovar
Typhi str. P-
Salmonella
enterica
serovar
Typhi str.
Salmonella
enterica
serovar
Typhi str.
Salmonella
enterica
serovar
Typhimurium
Salmonella
enterica
serovar
Typhi str.
Salmonella
enterica
serovar
Typhi str. Ty2
Salmonella
enterica
serovar
Choleraesuis
Salmonella
enterica
serovar
Paratyphi
B
Shigella
flexneri 2a
Shigella
flexneri 2a
Shigella
flexneri
Shigella
flexneri
Shigella
flexneri
Shigella
flexneri 2a
Shigella
flexneri 2a
Shigella
flexneri
Shigella
flexneri
Shigella
flexneri
Shigella
flexneri 4c
Shigella
flexneri 1a
Shigella
flexneri 1a
Shigella
flexneri 2a
Shigella
flexneri
2a
Shigella
flexneri
Shigella
flexneri 2a
Shigella
flexneri 2a
Shigella
flexneri
Shigella
flexneri 2a
Shigella
flexneri 4c
Shigella
flexneri 2a
Shigella
flexneri 2a
Shigella
flexneri 4c
Shigella
flexneri 2a
Shigella
flexneri 2a
Shigella
flexneri K-
Shigella
flexneri 2a
Shigella
flexneri 2a
Shigella
flexneri 5
Shigella
flexneri
Shigella
flexneri
Shigella
flexneri 5a
Shigella
flexneri 2a
Shigella
dysenteriae
Shigella
flexneri
Shigella
dysenteriae
Shigella
sonnei
Shigella
sonnei
Shigella
sonnei
Shigella
sonnei
Shigella
sonnei
Shigella
sonnei
Shigella
sonnei
Shigella
sonnei
Shigella
sonnei
Shigella
sonnei
Bordetella
pertussis
Bordetella
pertussis
Bordetella
pertussis
Bordetella
pertussis
Bordetella
pertussis
Bordetella
pertussis
Bordetella
pertussis
Bordetella
pertussis
Bordetella
pertussis
Bordetella
pertussis
Bordetella
pertussis
Bordetella
pertussis
Bordetella
pertussis
Bordetella
pertussis
Bordetella
pertussis
Bordetella
bronchiseptica RB50
Bordetella
parapertussis 12822
Bordetella
pertussis
Bordetella
pertussis
Bordetella
pertussis
A further aspect encompasses methods of using a genetically engineered bacterium provided herein (e.g., a genetically engineered V. cholerae bacterium). For instance, in some embodiments provided herein are methods for modulating a subject's immune system by administering a genetically engineered described herein to the subject (e.g., orally). The method includes administering to the subject (e.g., a human subject) an effective amount of a composition comprising a genetically engineered bacterium described herein. One of skill in the art will appreciate that an effective amount of a composition is an amount that will generate the desired response (e.g., a protective response, a mucosal response, a humoral response, or a cellular response). The response can be quantitated by methods known in the art.
In some embodiments, provided herein are methods of inducing a protective response against a virulent strain of Vibrio cholerae in a subject, the method comprising administering a genetically modified V. cholerae bacterium described herein, or a pharmaceutical composition comprising a genetically modified V. cholerae bacterium described herein. In some embodiments, the protective response is developed within about 12 hours, about 18 hours, about 24 hours, about 36 hours, about 48 hours, about 60 hours, about 72 hours, or about 84 hours after administration of the genetically modified bacterium of the pharmaceutical composition to the subject. In some embodiments, the protective immune response is developed within 12 hours, 18 hours, 24 hours, 36 hours, 48 hours, 60 hours, 72 hours, 84 hours, or more after administration of the genetically modified bacterium of the pharmaceutical composition to the subject.
In a further embodiment, the genetically engineered V. cholerae bacteria described herein may be used in a method for ameliorating one or more symptoms of cholera in a host in need thereof. Cholera symptoms include diarrhea, nausea, vomiting, and dehydration. The method includes administering an effective amount of a composition comprising a genetically engineered V. cholerae bacterium described herein.
The genetically engineered bacteria described herein and compositions comprising the bacteria may be administered to any subject. Exemplary vaccine composition formulations comprising the genetically engineered bacteria and methods of administration are detailed below.
Pharmaceutical compositions comprising a genetically engineered bacterium described herein may optionally comprise one or more possible pharmaceutically acceptable excipients, such as carriers, preservatives, cryoprotectants (e.g., sucrose and trehalose), stabilizers, adjuvants, and other substances. For example, when the composition includes genetically engineered bacteria that are alive, excipients are chosen such that the live bacterium is not killed, or such that the ability of the bacteria to effectively colonize a subject is not compromised by the use of excipients. Suitable pharmaceutical carriers are known in the art and, for example, include liquid carriers, such as normal saline and other non-toxic salts at or near physiological concentrations, and solid carriers, such as talc and sucrose. In some embodiments, the pharmaceutical composition includes an adjuvant. In some embodiments, the pharmaceutical composition may be a in a form suitable for aerosolized administration to a subject. In some embodiments, the pharmaceutical formulation is in a freeze-dried form (i.e., lyophilized form). In some embodiments, the pharmaceutical formulation is a gelatin capsule. Suitable pharmaceutical carriers and adjuvants and the preparation of dosage forms are described in, Remington's Pharmaceutical Sciences, 17th Edition, (Gennaro, Ed., Mack Publishing Co., Easton, Pa., 1985), which is herein incorporated by reference.
Administration of the genetically engineered bacteria described herein to a subject can be by any known technique, including, but not limited to oral administration, rectal administration, vaginal administration, or nasal administration.
The dosages of the genetically engineered bacteria that is administered to a subject can and will vary depending on the genetically engineered bacterium, the route of administration, and the intended subject, as will be appreciated by one of skill in the art. Generally speaking, the dosage need only be sufficient to elicit a protective host response in the subject. For example, typical dosages for oral administration could be about 1×107 to 1×1010 colony forming units (CFU) depending upon the age of the subject to whom the bacteria will be administered. Administering multiple dosages of the genetically engineered bacteria may also be used as needed to provide the desired level of protection.
Kits comprising a genetically engineered bacterium or a pharmaceutical composition described herein are also provided. In some embodiments, the kit further includes instructions for use. In some embodiments, the pharmaceutical composition is lyophilized such that addition of a hydrating agent (e.g., buffered saline) reconstitutes the composition to generate a pharmaceutical composition suitable for administration to a subject (e.g., orally).
The following examples are included to demonstrate preferred embodiments of the invention. It should be appreciated by those of skill in the art that the techniques disclosed in the examples that follow represent techniques discovered by the inventors to function well in the practice of the invention. Those of skill in the art should, however, in light of the present disclosure, appreciate that many changes can be made in the specific embodiments that are disclosed and still obtain a like or similar result without departing from the spirit and scope of the invention, therefore all matter set forth or shown in the accompanying drawings is to be interpreted as illustrative and not in a limiting sense.
The invention is further described in the following examples, which do not limit the scope of the invention described in the claims.
The massive and ongoing cholera epidemics in Yemen and Haiti illustrate that this ancient diarrheal disease remains a significant threat to public health (Balakrishnan (2017) Lancet Infect. Dis. 17, 700-1; and Ali et al. (2015) PLoS Negl. Trop Dis. 9, e0003832). Cholera results from ingesting water or food contaminated by Vibrio cholerae, a Gram-negative bacterial pathogen. V. cholerae colonizes the small intestine where it produces cholera toxin, which induces profuse watery diarrhea and consequent dehydration that can be rapidly fatal in the absence of rehydration therapy (Clemens et al. (2017) Lancet 390(10101): 1539-49). Public health interventions to limit cholera dissemination are critical because of the otherwise rampant spread of cholera epidemics, particularly in association with disruptions in sanitation infrastructure and water supplies. Oral cholera vaccines (OCVs) consisting of killed whole V. cholerae cells have modest protective efficacy in endemic regions (Qadri et al. (2015) Lancet 386(10001): 1362-71), and these vaccines were recently deployed during outbreaks in non-endemic areas as part of ‘reactive vaccination’ programs aimed at blocking the spread of cholera (see, e.g., Luquero et al. (2014) N Engl. J. Med. 370(22): 2111-20). However, optimal efficacy of killed OCVs requires 2 refrigerated doses administered 14 days apart (see, e.g., Kabir (2014) Clin. Vaccine Immunol. 21(9): 1195-1205), and these features may limit the capacity of the killed OCVs to rapidly constrain ongoing outbreaks in destabilized or resource-limited settings. Single dose live attenuated OCVs showed efficacy in challenge studies (see e.g., Chen et al. (2016) Clin. Infect. Dis. 62(11): 1329-35) and early phase clinical trials in endemic regions (Qadri et al. (2007) Vaccine 25(2): 231-8), and reactive vaccination with a live attenuated OCV may have contributed to a decrease in the incidence of cholera during an outbreak (see Calain et al. (2004) Vaccine 22(19): 2444-51). However, no live OCVs are based on globally predominant ‘variant’ El Tor strains, like that responsible for the 2010 Haitian cholera outbreak (see Chin et al. (2011) N Engl. J. Med. 364(1): 33-42). Furthermore, no killed or live attenuated OCV has been shown to mediate rapid (e.g., within 24 hours of administration) protection against cholera; instead current vaccines are thought to require the time necessary to elicit a protective adaptive immune response (a minimum of 1 week), to engender protection against cholera. This example describes the generation of a new live attenuated cholera vaccine based on the Haitian outbreak strain which was found to rapidly protect infant rabbits against lethal cholera-like illness within one day of administration.
The following materials and methods were used in this Example.
Study Design
The aim of this study was to design a new live attenuated cholera vaccine candidate, assess the strain's capacity to safely colonize the intestine, determine whether the strain could protect animals from cholera-like illness shortly after its administration, and quantify the potential impact of observed protection parameters on the incidence of cholera infection during an epidemic. The vaccine candidate was derived, from an isolate of the globally predominant V. cholerae strain, via sequential allelic exchange steps (see Genetic manipulations), and mutations were verified by whole genome sequencing (see Whole genome sequencing). Studies of intestinal colonization and cholera-like illness were conducted, in compliance with federal and institutional guidelines regarding the use of animals in research, using the infant rabbit model of infection (see Infant rabbit infection studies). 1-2 day old animals were allocated to treatment groups randomly, and within-litter (i.e., co-housed and age-matched) controls were used to minimize the impacts of litter-to-litter variation. For studies of disease progression, assessors were unaware of the treatment administered to each group, and animals found dead within 10 hours of challenge were excluded due to physical trauma consistent with maternal rejection. Transposon-insertion sequencing studies were conducted using the ARTIST pipeline, which models and compensates for experimental noise and offers recommendations for the imposition of effect size thresholds (see Transposon-insertion sequencing analysis). Lastly, modeling incorporating a variable time to vaccine protection into a set of previously published parameters for disease transmission was performed (see Modeling of cholera outbreaks).
Statistical Analysis
Comparisons of two samples were performed using two-sided testing (α=0.05) for a t test (fluid accumulation ratios), a Mann-Whitney U test for nonparametric data (bacterial burden), or a log-rank test (survival curve). Comparisons of three samples were performed using the Kruskall-Wallis test followed by Dunn's multiple comparisons test (bacterial burden).
Strains, Media, and Culture Conditions
Table 3 contains a list of strains used in this study. Unless otherwise noted, V. cholerae and E. coli were grown in lysogeny broth (LB: 10 g/L tryptone, 5 g/L yeast extract, 5 g/L NaCl) with shaking (250 RPM) at 37° C. Recipient strains in phage transduction assays were grown in AKI media (15 g/L peptone, 4 g/L yeast extract, 5 g/L NaCl, autoclaved, then supplemented with freshly made, sterile-filtered 0.3% NaHCO3).
Antibiotics and substrates were used in the following concentrations unless otherwise noted: streptomycin (Sm) (200 μg/mL), carbenicillin (50 μg/mL), chloramphenicol (20 μg/mL), SXT (160 μg/mL sulfamethoxazole, 32 μg/mL trimethoprim), kanamycin (Kn) (50 μg/mL) and 5-Bromo-4-Chloro-3-Indolyl 0-D-Galactopyranoside (X-Gal 60 mg/mL).
V.
cholerae
V.
cholerae
V.
cholerae
V.
cholerae
V.
cholerae
V.
cholerae
V.
cholerae
V.
cholerae
V.
cholerae
V.
cholerae
V.
cholerae
E. coli
E. coli
E. coli
E. coli
E. coli
E. coli
E. coli
E. coli
E. coli
E. coli
E. coli
E. coli
E. coli
E. coli
E. coli
Genetic Manipulations
All gene deletions and replacements were constructed via homologous recombination using the suicide vector pCVD442, DH5α-λpir and donor strains MFD-λpir (see Ferrieres et al. (2010) J. Bacteria 192(24): 6418-27) or SM10-λpir (Table 3). For all deletions, approximately 500-700 bp homology regions upstream and downstream of the respective ORF were amplified using the primer combinations described below and cloned into XbaI-digested pCVD442 using isothermal assembly.
For derivation of HaitiV from the HaitiWT strain, first, the CTXΦ prophage and surrounding sequences were deleted using primers TDPsCTX1/TDPsCTX2 and TDPsCTX3/TDPsCTX4 to amplify homology regions upstream of the rtx toxin transporter at the 5′ end and upstream of a putative dehydrogenase on the 3′ end of this region. This results in a deletion of a 42,650 bp fragment that includes the entire CTXΦ prophage, which includes ctxAB, the CTX attachment site, the RS1 and TLC satellite prophages and the MARTX toxin genes rtxABCDE. The knockout was validated via polymerase chain reaction (PCR) using primers TD1027/TDP1028.
Next, the flaBDE operon was deleted as previously described in Millet et al. (2014) PLoS Pathog. 10(10): e1004405. The flaAC operon deletion plasmid was constructed using primers TDP1172/1174 (upstream homology) and TDP1173a/TDP1173 (downstream homology). Subsequently, the SXT ICE-encoded antibiotic resistance loci, dfrA, sul2, strAB, and floR were deleted using primers TDP1193/TDP1194+TDP1195/1196 (dfrA, trimethoprim resistance) and TDP1287/TDP1288+TDP1291/TDP1292 (sulfamethoxazole, streptomycin and chloramphenicol resistance loci). Whole genome sequencing revealed that the second crossover in the allele exchange process occurred not between the homologous regions included in the suicide plasmid, but rather between duplicate sequences flanking the flor/sul region of the chromosome (N900_11210 and N900_11260). An SmR mutant of the vaccine precursor strain was isolated by plating on streptomycin (1000 μg/mL), and the rpsLK43R SNV was confirmed by Sanger sequencing.
For CtxB overexpression, the htpG promoter was amplified from Peru-15 (see Kenner et al. (1995) J. Infect. Dis. 172(4): 1126-9) using primers FD54/FD103 (adding the strong ribosome binding site AGGAGG (SEQ ID NO: 6)) and ctxB was amplified from HaitiWT, which contains the ctxB7 allele, using primers FD33/FD34. Homologous regions flanking the intergenic region of the validated neutral locus vc0610/N900_11550 (see Abel et al. (2015) Nat. Methods 12(3): 223-6) were amplified with primer pairs FD30/FD31 and FD73/FD74. These fragments were then cloned into pCVD442 in a one-step isothermal assembly reaction. CtxB overexpression was confirmed by Western blot on cell-free supernatants from cultures grown in AKI conditions described above. (Abcam ab123129, anti-cholera toxin;
Next, the hupB deletion plasmid was constructed using primer pairs Vc-hupB5-F1/Vc-hupB5-R1 and VC-hupB3-F1/Vc-hupB3-R1. The deletion was verified with primers VC-hupB-SF2/Bc-hupB-SR2.
For the cas9-sgRNA module, cas9 was amplified from plasmid DS_SpCas9 (addgene.org/48645/) with primers TDP1747/TDP1748. The sgRNA region was amplified from gBlock ‘VC_3x_sgRNAgBlock’ (Table 4) with primers TDP1761/TDP1762. Both fragments were combined and cloned in to the StuI site of pJLl (Butterton (1995) Infect Immun 63: 2689-96) via isothermal assembly. Sequencing revealed that a recombination event during assembly had removed 2 of 3 sgRNAs, leaving a single guide targeting ctxA. This suicide vector was introduced to the vaccine strain via triparental mating with the helper plasmid pRK600.
Finally, a recA deletion plasmid was constructed using primer pairs Vc-recA5-F1/Vc-recA5-R1 and Vc-recA3-F1/Vc-recA3-R1; the deletion was verified with primers Vc-recA-SF2/Vc-recA-SR2.
Whole Genome Sequencing
Genomic DNA from HaitiWT and HaitiV was prepared using the Nextera XT library preparation kit (ILLUMINA) and sequenced on a MiSeq (Reagent kit v2, 2×250). The genomic sequence of the bacterial chromosomes of HaitiV are provided herein as SEQ ID NOs: 7 and 51. The HaitiV strain was deposited with the American Type Culture Collection (ATCC), located at 10801 University Boulevard, Manassas, Va. 20110, USA on Jun. 22, 2018 under the terms of the Budapest Treaty and assigned ATCC Patent Deposit Designation PTA-125138. Each sample was mapped to its putative genome and variants identified using GATK3.6.
CTXΦ Transduction Assay
Supernatant from Vibrio cholerae 0395 strains harboring CTXΦ-IGKn (a phage whose genome includes ctxA (see, e.g., Lazar and Walder (1998) Infect. Immun. 66: 394-7) or CTX-KnΦ (a phage whose genome lacks ctxA (see, e.g., Waldor and Mekalanos (1996) Science 272(5270): 1910-4) (grown at 30° C. in LB to an OD600 of 1.0) was concentrated (approximately 50-fold; Ultracel-100K centrifugal filter, MILLIPORE) and filtered (0.22 μm filter, MILLIPORE) to get a cell-free phage supernatant. In order to induce expression of TCP (the phage receptor) in the strains being assayed for CTXΦ susceptibility, overnight LB cultures were back-diluted 1:100 into 10 mL AKI in 16×150 mm glass culture tubes and incubated without shaking for 4 hours at 37° C. All but 1 mL of the culture was then discarded, and the culture was moved to a shaker (250 rpm) for aerobic culture at 37° C. for an additional 2 hours. Recipient cultures were washed once by centrifugation, mixed 2:1 with phage supernatant, and incubated at room temperature for 20 minutes. Serial dilutions were then plated on LB and LB+Kanamycin (100 μg/mL) agar plates, and transduction efficiency was calculated as (CFU/mL)Kan100/(CFU/mL)LB.
Generation of HaitiWT-Tn Library
E. coli SM10λpir bearing the pir-dependent Himar transposon vector pSC189 (Chiang and Rubin (2002) Gene 296(1-2): 179-85) were conjugated with recipient HaitiWT to generate a transposon-insertion library. Overnight cultures of each strain were grown aerobically at 37° C. and then diluted 1:100 in media at 37° C. After 4 hours of outgrowth, 4 mL of each culture was pelleted and washed once with LB. Cultures were then mixed in a 1:1 ratio, pelleted and re-suspended in 800 μL LB. 50 μL of the mix was spotted onto 0.45 μm filters on LB agar plates for a total of 16 conjugation reactions. Reactions were incubated at 37° C. for 4 hours, after which filters were vortexed in LB (1 mL/filter) to re-suspend attached bacteria. Suspensions were plated onto 245 mm2 LB+Sm/Kan agar plates to select for V. cholerae trans-conjugants (2 mL suspension/plate). Plates were incubated at 30° C. overnight to enumerate bacterial colonies. The library consisted of ˜300,000 colonies and was scraped into LB+25% glycerol. The OD600 was adjusted to approximately 10 and aliquots were stored at −80° C. for downstream use.
Infant Rabbit Infection Studies
Infant rabbit studies were conducted according to protocols approved by the Brigham and Women's Hospital Committee on Animals (Institutional Animal Care and Use Committee protocol number 2016N000334, Animal Welfare Assurance of Compliance number A4752-01) and in accordance with the recommendations in the Guide for the Care and Use of Laboratory Animals of the National Institutes of Health and the Animal Welfare Act of the United States Department of Agriculture.
To prepare bacteria for inoculation, overnight cultures were diluted 1:100 in 100 mL LB and cultured with aeration at 37° C. until late-log phase (OD600 0.5 to 0.9). Approximately 2×1010 CFU were pelleted by centrifugation at 6,000 rpm, the supernatant was removed, and cell pellets were re-suspended in 10 mL of 2.5% sodium bicarbonate solution (2.5 g in 100 mL water; pH 9.0) to a final cell density of approximately 2×109 CFU/mL. For co-infection studies, approximately 1×1010 CFU were pelleted by centrifugation at 6,000 rpm, the supernatant was removed, cell pellets were re-suspended in 5 mL 2.5% sodium bicarbonate solution, and the resulting suspensions were combined to yield a 1:1 mixture at a cell density of approximately 2×109 CFU/mL. For studies using the HaitiWT transposon library, a 1 mL frozen stock of the library (OD600=10) was transferred to 100 mL LB to an initial OD600 of 0.1. The library was then cultured with aeration at 37° C. to OD600 0.8 (approximately 2 hours) and approximately 2×109 CFU/mL cell suspension in 2.5% sodium bicarbonate solution was prepared as described above. Preparation of formalin-killed vaccine required the following additional steps: cell pellets were re-suspended in 8 mL of 10% formalin, the formalin suspension was centrifuged at 6,000 rpm, the supernatant was removed, cells were re-suspended in 5 volumes of 1× phosphate buffered saline (40 mL 1×PBS) to wash away excess formalin, the PBS suspension was centrifuged at 6,000 rpm, the supernatant was removed, and cells were re-suspended in 10 mL of 2.5% sodium bicarbonate solution. This procedure eliminated all viable V. cholerae. For all experiments, the final cell suspension was serially diluted in 1×PBS and plated in triplicate on LB+Sm/X-Gal, and incubated at 30° C. overnight to enumerate the precise dose. For co-infection studies, the disruption of lacZ in HaitiV enabled enumeration of HaitiWT and HaitiV CFU, blue and white colonies, respectively. For studies using the HaitiWT transposon library, approximately 2×1010 CFU of the library inoculum were plated on LB+Sm200/Kan50 and incubated at 30° C. overnight to generate a representative sample of the library inoculum used for subsequent statistical comparisons.
Infant rabbit infections were performed as previously described (Ritchie et al. (2010) MBio. 1(1): e00047-10) with minor modifications detailed below. All experiments were conducted using 1-4 day old New Zealand White Rabbits, and animals were co-housed with littermates and a lactating dam for the duration of all studies, which varied in length based on the phenotypes assessed. Animals were obtained from either Pine Acre Rabbitry (Norton, Mass., USA) or Charles River Canada, and phenotypes were consistent across animals from both vendors. Animal studies were always conducted using within-litter controls to minimize the impacts of litter-to-litter variation. Initial studies of HaitiWT and HaitiV colonization (
At necropsy, the entire intestinal tract was removed, cecal fluid was extracted using a 26½ gauge needle and transferred to a pre-weighed Eppendorf tube. 2-3 cm sections of the distal small intestine, along with the entire cecum, were placed in pre-weighed homogenization tubes containing 1 mL sterile PBS and two 3.2 mm stainless steel beads (BioSpec Products Inc., Bartlesville, Okla., USA) and all filled tubes were weighed. The mass of fluid recovered from the cecum was divided by the mass of the cecum to obtain a fluid accumulation ratio (FAR). The tubes containing tissue were homogenized for 2 minutes on a mini-beadbeater-16 (BioSpec Products Inc., Bartlesville, Okla., USA), serially diluted in 1×PBS, and plated. Plates were incubated at 30° C. overnight and the number of observed colonies was divided by the appropriate dilution ratio and the mass of the corresponding tissue/fluid sample to yield a measure of CFU/g tissue. Homogenates were plated on LB+Sm200/X-Gal60 to enumerate total burden (i.e., HaitiWT+HaitiV) and on LB+SXT to enumerate HaitiWT burden alone. For co-inoculation or sequential inoculation studies, the absence of a HaitiV-specific selectable marker prevented the enumeration of HaitiV CFU unless the burden of HaitiV was comparable to HaitiWT (i.e., within 100-fold). Similarly, for studies utilizing the N16961 WT strain, which is sensitive to SXT, the number of blue colonies on LB+Sm200/X-Gal60 was used to enumerate WT burden. For co-inoculation studies, a competitive index was calculated as:
For studies using the HaitiWT transposon library, the terminal 10 cm of the distal small intestine were obtained at necropsy, weighed, and homogenized as described above. The homogenate was serially diluted in 1×PBS and plated on LB+Sm200/X-Gal60 to enumerate total burden and LB+Sm200/Kan50 to enumerate the burden of HaitiTn. The remaining 900 μL of undiluted tissue homogenate were plated on LB+Sm200/Kan50 to recover representative samples of the in vivo passaged HaitiTn library that were used for subsequent analyses of sites of transposon insertion.
Colonization data were not reported for animals that reached a moribund state of disease in studies of disease progression, because the interval between inoculation and euthanasia, which varies substantially in these studies, is likely to impact bacterial burden. Instead, animals were euthanized upon assessment of moribund status characterized by a combination of visible diarrhea (staining of the ventral surface), dehydration (skin tenting), weight loss, lethargy (minimal movement), and decreased body temperature (cold to the touch). These assessments were carried out in a blinded fashion as to whether animals received killed vaccine or live vaccine. One animal progressed to moribund status without developing visible diarrhea, explaining the differences in sample sizes between
Transposon-Insertion Sequencing Analysis
The transposon-insertion libraries were characterized by massively parallel sequencing; sequence data were processed and mapped to the V. cholerae H1 genome (see, e.g., Bashir et al. (2012) Nat. Biotechnol. 30(7): 701-7) as previously described (see Pritchard et al. (2014) PLoS Genet. 10(11): e1004782). Higher complexity libraries (>30,000 unique genotypes) were compared to the input libraries using the ARTIST pipeline. Data were corrected for origin proximity using a LOESS correction of 100,000 bp windows. The inoculum data sets were independently normalized relative to intestinal data sets using Con-ARTIST's multinomial distribution-based random samplings (n=100). A modified version of Con-ARTIST's Mann-Whitney U function was used to compare the intestinal data sets to their 100 simulated control data sets. Thresholds of mean informative sites>5|Log2(mean fold change)|>1, mean inverse P-value>100 were imposed to identify loci for which corresponding insertion mutants are significantly enriched or depleted in the intestinal data sets relative to the inoculum.
Modeling of Cholera Outbreaks
Our model, adapted from a previous study (Azman (2015) PLoS Med. 12: e1001867), is depicted schematically in
Generation of the Genetically Engineered Vibrio cholerae Bacterial Strain HaitiV for Use as a Live Attenuated Vaccine
Nine different modifications were generated to derive the new vaccine, HaitiV (Table 5), and whole genome sequencing was used to confirm that the mutations were present. Mutations were engineered to ensure biosafety, to a degree unprecedented among cholera vaccines, while maintaining HaitiV's capacity for intestinal colonization so that, like wild type V. cholerae and some previously tested live vaccine candidates (Cohen et al. (2002) Infect. Immun. 70: 1965-70; and Chen et al. (2016) Clin. Infect. Dis. 62(11): 1329-35), it would likely impart long-term immunity after a single oral dose. To ensure the safety of HaitiV, we removed the bacteriophage (CTXΦ 0) encoding cholera toxin (CT) (Waldor and Mekalanos (1996) Science 272(5270): 1910-4) (
Genet. 11(5): e1005256).
HaitiV is an Attenuated V. cholerae Bacterial Strain
Comparative studies of oro-gastrically inoculated HaitiV as compared to the wild type V. cholerae isolate from which it was derived (referred to herein as HaitiWT) were performed in infant rabbits, a small animal model that recapitulates many aspects of human cholera, including rapid mortality (see Ritchie et al. (2010) MBio. 1(1): e00047-10). All animals inoculated with HaitiWT progressed to a moribund state by 18 hours post-inoculation (18HPI). Upon necropsy, the ceca of these animals were filled with fluid (
The distinct responses to HaitiWT or HaitiV inoculation were not associated with differences between intestinal colonization by the two strains. At 18HPI, there was no significant difference in V. cholerae colonization of the distal small intestine between littermates inoculated with HaitiV or HaitiWT (
Inoculation with HaitiV Induces a Protective Response Against the Virulent V. cholerae Bacterial Strain HaitiWT
Given HaitiV's robust and prolonged occupancy of the intestine, experiments were performed to determine whether HaitiV-colonized animals might exhibit resistance to colonization by HaitiWT even prior to the development of an adaptive immune response, for example due to alteration of the pathogen's intestinal niche. Animals were inoculated either with HaitiV (live vaccine), formalin-killed HaitiV (killed vaccine), or a buffer control (mock), and then challenged 24 hours later with a lethal dose of HaitiWT. Animals in the buffer and formalin groups developed severe cholera-like illness following HaitiWT challenge, and intestinal burdens of HaitiWT in these animals resembled those without pretreatment (
To assess the specificity of colonization resistance, the vaccine study was repeated, challenging with V. cholerae N16961, an early El Tor strain administered to human volunteers in studies of cholera vaccine efficacy (see Chen et al. (2016) Clin. Infect. Dis. 62(11): 1329-35). Importantly, the Haitian and N16961 strains were isolated independently and are of distinct serotypes (see Chin et al. (2011) N. Engl. J. Med. 364(1): 33-42). Animals inoculated with live HaitiV, but not killed HaitiV, also exhibited colonization resistance against the N16961 WT challenge (
Given the low levels of HaitiWT burden in animals inoculated with HaitiV, it was possible that the vaccine's occupancy of the intestine interfered with processes required for colonization by the challenge strain. Therefore, a forward genetic screen to identify mutations that allow HaitiWT to resist or evade vaccine-mediated antagonism was performed. Such mutations could provide insight into the mechanism(s) by which HaitiV mediates colonization resistance, and were predicted to confer a fitness advantage to HaitiWT, specifically in the HaitiV-colonized intestine. Animals were challenged with a pooled HaitiWT transposon insertion library (HaitiTn) in the absence of pretreatment (single inoculation,
To identify enriched mutants, the transposon junctions from HaitiTn recovered from the distal small intestine were sequences and a genome-wide comparison of mutant abundance in animals subjected to HaitiTn challenge without pretreatment (
The genetic diversity intrinsic to the HaitiTn library utilized in the experiments described above allowed for an assessment as to whether HaitiV-mediated colonization resistance was associated with changes in the severity of the infection bottleneck that V. cholerae encounters in vivo (Abel et al. (2015) Nat. Methods 12: 223-6; Abel et al. (2015) PLoS Pathog. 11: e1004823). V. cholerae recovered from the intestine arise from a founding population of organisms that persist following a stochastic constriction of the bacterial inoculum (Abel et al. (2015) Nat. Methods 12: 223-6). The severity of this infection bottleneck can be estimated from the number of unique transposon insertion mutants recovered from the intestine (Chao et al. (2016) Nat. Rev. Microbiol. 14: 119-28). A subset of animals previously inoculated with live vaccine were colonized by relatively few unique insertion mutants and showed low HaitiTn burdens (
HaitiV Induces Protection Against the Virulent Vibrio cholerae Strain HaitiWT within 24 Hours of Administration
To quantify HaitiV-dependent protection from cholera-like disease, infant rabbits were inoculated with live or killed vaccine, challenged with HaitiWT 24 hours later, and monitored regularly to assess their status. All animals inoculated with killed vaccine developed diarrhea (median onset 15 hours) and progressed to a moribund state within 29 hours of HaitiWT inoculation (median 18.8 hours) (
To investigate how HaitiV's rapid protection might impact reactive vaccination campaigns, a previously-published mathematical model of a cholera outbreak in a susceptible population, an epidemic context prioritized for reactive OCV interventions, was modified (Azman (2015) PLoS Med. 12: e1001867; Reyburn et al. (2011) PLoS Negl. Trop. Dis. 5: e952). Modifications to the mathematical model (
Provided herein is the design and characterization of a new live attenuated cholera vaccine candidate, HaitiV. The studies above indicate that HaitiV is refractory to toxigenic reversion and that it colonizes an animal model of cholera without causing cholera-like disease or other untoward effects. The infant rabbit model is well-suited for the intestinal colonization and disease progression studies reported above. The study is limited by the poorly characterized intestinal microbiota and adaptive immune capacity of rabbit neonates, which restrict further investigation of HaitiV's mechanism(s) of action and immunogenicity in this system. There are no robust animal models to investigate adaptive immunity to cholera; as with previous cholera vaccines, evaluating the adaptive immune response elicited by HaitiV will require human volunteer studies. Encouragingly, HaitiV's colonization was comparable to that of strains closely related to Peru-15 in the same model (Rui et al. (2010) Proc. Nat'l. Acad. Sci. USA 107(9): 4359-64), an earlier live cholera vaccine candidate found to be safe in humans and to confer protection with a single dose (Cohen et al. (2002) Infect. Immun. 70: 1965-70) even in children under 5 who are not protected by killed OCVs (Qadri (2007) Vaccine 25: 231-8. Surprisingly, HaitiV was found to confer protection within 24 hours of administration, an interval that is not consistent with adaptive immunity and unprecedented among existing vaccines. Notably, these effects required use of viable HaitiV; formalin-killed HaitiV did not provide acute protection from disease, suggesting that rapid protection requires a probiotic effect that is unlikely to be elicited by killed OCVs. Human challenge studies are a well-established system for assessing the adaptive immune protection elicited by OCVs (Chen et al. (2016) Clin. Infect. Dis. 62(11): 1329-35 and Cohen et al. (2002) Infect. Immun. 70: 1965-70). Incorporating additional acute challenges (e.g., within 24 hours post-vaccination) will illuminate the onset and duration of OCV protection, thereby assessing whether HaitiV or other OCVs elicit protection prior to adaptive immune responses, as observed in the infant rabbit model.
Although the mechanisms underlying HaitiV's acute protection are likely complex and require further elucidation, the mathematical modeling described in this study indicates that the public health impacts of HaitiV's rapid protection could be transformative in the context of reactive vaccination during cholera epidemics. Relative to controls, HaitiV-inoculated animals challenged with a lethal dose of HaitiWT survived longer following the onset of diarrhea, displayed lower levels of HaitiWT colonization, and in some cases, were completely protected from cholera. HaitiV-induced delay of disease progression suggests that individuals who are infected with pathogenic V. cholerae after being inoculated with HaitiV may have more time to access life-saving treatment following the onset of symptoms. The time that elapses between onset of symptoms and administration of treatment is often the determinant of case fatality rates during cholera outbreaks, because re-hydration therapy is sufficient to prevent death in virtually all symptomatic individuals (Farmer et al. (2011) PLoS Negl. Trop. Dis. 5: e1145). Additionally, the colonization resistance mediated by HaitiV, but not formalin-killed HaitiV, suggests that inoculation with HaitiV may reduce shedding of toxigenic V. cholerae into the environment, the transmission route that perpetuates outbreaks. Although HaitiV's potential effects on transmission were not incorporated into the modeling studies, a reduction in transmission is likely to potentiate the already dramatic impact that HaitiV could have on outbreak control. Overall, the above studies suggest that probiotic vaccines, mediating rapid protection from disease while eliciting adaptive immunity, could constitute a new class of therapeutics with a transformative impact on outbreak control.
To determine whether inoculation with HaitiV induces a vibriocidal antibody response, C57BL/6 and Swiss-Webster mice were inoculated with either HaitiV or a spontaneous streptomycin resistant mutant derived from the V. cholerae bacterial strain CVD103-HgR, referred to herein as CVD103-HgR* (control). CVD-103HgR (Vaxchora™; PaxVax, Inc., Redwood City, Calif., USA) is currently approved for the prevention of cholera caused by V. cholerae O1 in adult travelers. Sera vibriocidal activity was analyzed using an in vitro microdilution assay to assess complement-mediated cell lysis of V. cholerae PIC018 (Inaba serotype) or PIC158 (Ogawa serotype). As shown in
Anti-OSP IgA and IgG Titers Increase Over Time in Mice Inoculated with HaitiV
To determine whether inoculation with HaitiV induces an antibody response against 0-antigen-specific polysaccharide (OSP), C57BL/6 and Swiss-Webster mice were inoculated with either HaitiV or CVD103-HgR* (control), and the abundance of anti-OSP IgA and anti-OSP IgG antibodies against either Ogawa-derived or Inaba-derived OSP was measured using ELISA. As shown in
Materials and Methods
The following materials and methods were used in this Example.
To generate a streptomycin resistant strain of CVD103-HgR (Vaxchora™; PaxVax, Inc., Redwood City, Calif., USA), the bacterial strain was inoculated into 5 mL of LB broth and cultured with aeration (250 rpm) at 37° C. overnight. 1 mL of the overnight culture was plated on LB agar+streptomycin (1000 μg/mL) and incubated at 37° C. overnight. Colonies that arose on LB agar+streptomycin (1000 μg/mL) were considered spontaneous streptomycin resistant mutants of CVD103-HgR, hereafter referred to as CVD103-HgR*.
HaitiV immunogenicity studies were conducted using female, germ-free C57BL/6 mice (n=7, Massachusetts Host-Microbiome Center) and female, germ-free Swiss-Webster mice (n=6, Taconic Farms) housed in a BL-2 animal facility for the duration of study. HaitiV or CVD103-HgR* bacteria were resuspended in 2.5% sodium bicarbonate solution (pH 9.0) to a final concentration of 1010 colony forming units per mL (CFU/mL). Mice were anesthetized via isoflurane inhalation and orally gavaged with 100 μL of the bacterial suspension (109 CFU per mouse). This procedure was repeated at 2, 4, 6, 14, 28, and 42 days following the initial immunization. Mice were monitored daily for signs of disease and weighed every 4-5 days and prior to each immunization. Fecal pellets were obtained at each weighing, and pellets were homogenized in 1× phosphate buffered saline (PBS) and serial dilutions were plated on LB+streptomycin (200 μg/mL) to enumerate fecal burdens of HaitiV. For the C57BL/6 cohort, blood samples were obtained via tail vein incision at 7, 14, 28, and 42 days post-immunization. For the Swiss-Webster cohort, blood samples were obtained via tail vein incision at 1, 7, 14, 28, and 42 days post-immunization. Blood was allowed to clot at room temperature for 1 hour, centrifuged at 13,000 rpm for 5 minutes, and the supernatant (serum) was collected and stored at −20° C. for subsequent analyses.
Vibriocidal antibody quantification was performed as previously described (Rollenhagen et al. (2009) Vaccine 27(36): 4917-22, and Tarique et al. (2012) Clin. Vaccine Immunol. 19(4): 594-60, each of which is incorporated herein by reference) via an in vitro microdilution assay of complement-mediated cell lysis of V. cholerae PIC018 (Inaba) or PIC158 (Ogawa). Vibriocidal responses are reported as titers (i.e., the dilution of serum) causing a 50% reduction in V. cholerae optical density compared to wells with no added serum. Antibody responses to either Inaba or Ogawa O-antigen-specific polysaccharide (OSP) were assessed via enzyme-linked immunosorbent assay (ELISA) as described in Aktar et al. (2016) Clin. Vaccine Immunol. 23(5): 427-35, incorporated herein by reference. Data are presented as normalized response, which is the ratio of ELISA signal for the test sample to a standardized pool of sera included on each plate.
It is to be understood that while the invention has been described in conjunction with the detailed description thereof, the foregoing description is intended to illustrate and not limit the scope of the invention, which is defined by the scope of the appended claims. Other aspects, advantages, and modifications are within the scope of the following claims.
This application claims the benefit of priority of U.S. Application No. 62/531,551, filed Jul. 12, 2017; and U.S. Application No. 62/680,286, filed Jun. 4, 2018. The content of each of the foregoing applications is hereby incorporated by reference in its entirety.
This invention was made with Government support under Grant Nos. AI042347 and AI-120665, awarded by the National Institutes of Health. The Government has certain rights in the invention.
| Filing Document | Filing Date | Country | Kind |
|---|---|---|---|
| PCT/US2018/041846 | 7/12/2018 | WO | 00 |
| Number | Date | Country | |
|---|---|---|---|
| 62680286 | Jun 2018 | US | |
| 62531551 | Jul 2017 | US |
