Identification and Attenuation of the Immunosuppressive Domains in Fusion Proteins of Enveloped RNA Viruses

Information

  • Patent Application
  • 20240150409
  • Publication Number
    20240150409
  • Date Filed
    April 28, 2023
    a year ago
  • Date Published
    May 09, 2024
    7 months ago
Abstract
The present invention relates to enveloped RNA viruses. The invention in particular relates to the generation of superior antigens for mounting an immune response by first identifying then mutating the immunosuppressive domains in fusion proteins of enveloped RNA viruses resulting in decreased immunosuppressive properties of viral envelope proteins from the viruses.
Description
FIELD OF THE INVENTION

The present invention relates to enveloped RNA viruses. In particular, the invention relates to the generation of superior antigens for mounting an immune response by first identifying then mutating the immunosuppressive domains in fusion proteins of enveloped RNA viruses resulting in decreased immunosuppressive properties of viral envelope proteins from said viruses.


BACKGROUND OF THE INVENTION
Classification of Viruses
ICTV Classification

The International Committee on Taxonomy of Viruses (ICTV) developed the current classification system and wrote guidelines that put a greater weight on certain virus properties to maintain family uniformity. A unified taxonomy (a universal system for classifying viruses) has been established. The 7th ICTV Report formalized for the first time the concept of the virus species as the lowest taxon (group) in a branching hierarchy of viral taxa. However, at present only a small part of the total diversity of viruses has been studied, with analyses of samples from humans finding that about 20% of the virus sequences recovered have not been seen before, and samples from the environment, such as from seawater and ocean sediments, finding that the large majority of sequences are completely novel.


The general taxonomic structure is as follows:

    • Order (-virales)
    • Family (-viridae)
    • Subfamily (-virinae)
    • Genus (-virus)
    • Species (-virus)


In the current (2008) ICTV taxonomy, five orders have been established, the Caudovirales, Herpesvirales, Mononegavirales, Nidovirales, and Picornavirales. The committee does not formally distinguish between subspecies, strains, and isolates. In total there are 5 orders, 82 families, 11 subfamilies, 307 genera, 2,083 species and about 3,000 types yet unclassified.


Baltimore Classification

The Baltimore Classification of viruses is based on the method of viral mRNA synthesis.


The ICTV classification system is used in conjunction with the Baltimore classification system in modern virus classification.


The Baltimore classification of viruses is based on the mechanism of mRNA production. Viruses must generate mRNAs from their genomes to produce proteins and replicate themselves, but different mechanisms are used to achieve this in each virus family. Viral genomes may be single-stranded (ss) or double-stranded (ds), RNA or DNA, and may or may not use reverse transcriptase (RT). Additionally, ssRNA viruses may be either sense (+) or antisense (−). This classification places viruses into seven groups:

    • I: dsDNA viruses (e.g. Adenoviruses, Herpesviruses, Poxviruses)
    • II: ssDNA viruses (+)sense DNA (e.g. Parvoviruses)
    • III: dsRNA viruses (e.g. Reoviruses)
    • IV: (+)ssRNA viruses (+)sense RNA (e.g. Picornaviruses, Togaviruses)
    • V: (−)ssRNA viruses (−)sense RNA (e.g. Orthomyxoviruses, Rhabdoviruses)
    • VI: ssRNA-RT viruses (+)sense RNA with DNA intermediate in life-cycle (e.g. Retroviruses)
    • VII: dsDNA-RT viruses (e.g. Hepadnaviruses)


As an example of viral classification, the chicken pox virus, varicella zoster (VZV), belongs to the order Herpesvirales, family Herpesviridae, subfamily Alphaherpesvirinae, and genus Varicellovirus. VZV is in Group I of the Baltimore Classification because it is a dsDNA virus that does not use reverse transcriptase.


Many viruses (e.g. influenza and many animal viruses) have viral envelopes covering their protein cores. The envelopes typically are derived from portions of the host cell membranes (phospholipids and proteins), but include some viral glycoproteins. Functionally, viral envelopes are used to enable viruses to enter host cells. Glycoproteins on the surface of the envelope serve to identify and bind to receptor sites on the host's membrane. Subsequently the viral envelope then fuses with that of the host's, allowing the viral capsid and viral genome to enter and infect the host.


Typically, in RNA viruses a single transmembrane glycoprotein, a fusion protein, undergoes a conformational transition triggered by receptor recognition or low pH, leading to the insertion of a fusion peptide into the plasma membrane or the membrane of an endocytic vesicle. For some RNA viruses, including members of the paramyxovirus family, separate envelope proteins mediate attachment and fusion.


Membrane fusion can occur either at the plasma membrane or at an intracellular location following internalization of virus by receptor-mediated endocytosis. Fusion is mediated by viral transmembrane proteins known as fusion proteins. Upon appropriate triggering, the fusion protein interacts with the target membrane through a hydrophobic fusion peptide and undergoes a conformational change that drives the membrane fusion reaction. There are a variety of fusion triggers, including various combinations of receptor binding, receptor/coreceptor binding, and exposure to the mildly acidic pH within the endocytic pathway. Fusion proteins from different viruses have different names in spite of the common functionality.


Based on important structural features, many virus membrane fusion proteins are currently annotated to either the “class I” membrane fusion proteins exemplified by the influenza hemagglutinin (HA) or HIV-1 gp41, or the “class II” proteins of the alphaviruses and flaviviruses. The alphaviruses and flaviviruses are members of the Togaviridae and Flaviviridae families, respectively. These small enveloped positive-sense RNA viruses are composed of a capsid protein that assembles with the RNA into the nucleocapsid, and a lipid bilayer containing the viral transmembrane (TM) proteins.


Class I fusion proteins are synthesized as single chain precursors, which then assemble into trimers. The polypeptides are then cleaved by host proteases, which is an essential step in rendering the proteins fusion competent. This proteolytic event occurs late in the biosynthetic process because the fusion proteins, once cleaved are metastable and readily activated. Once activated, the protein refolds into a highly stable conformation. The timing of this latter event is of crucial importance in the fusion process. Maintenance of the intact precursor polypeptide during folding and assembly of the oligomeric structure is essential if the free energy that is released during the refolding event is to be available to overcome the inherent barriers to membrane fusion. The new amino-terminal region that is created by the cleavage event contains a hydrophobic sequence, which is known as the fusion peptide. The authentic carboxy-terminal region of the precursor polypeptide contains the transmembrane anchor. In the carboxy-terminal polypeptide, there are sequences known as the heptad repeat that are predicted to have an alpha helical structure and to form a coiled coil structure. These sequences participate in the formation of highly stable structure that characterizes the post-fusion conformation of the fusion protein.


The class II fusion proteins are elongated finger-like molecules with three globular domains composed almost entirely of ß-sheets. Domain I is a ß-barrel that contains the N-terminus and two long insertions that connect adjacent ß-strands and together form the elongated domain II. The first of these insertions contains the highly conserved fusion peptide loop at its tip, connecting the c and d ß-strands of domain II (termed the cd loop) and containing 4 conserved disulfide bonds including several that are located at the base of the fusion loop. The second insertion contains the ij loop at its tip, adjacent to the fusion loop, and one conserved disulfide bond at its base. A hinge region is located between domains I and II. A short linker region connects domain Ito domain III, a ß-barrel with an immunoglobulin-like fold stabilized by three conserved disulfide bonds. In the full-length molecule, domain III is followed by a stem region that connects the protein to the virus TM anchor. Fitting of the structure of alphavirus E1 to cryo-electron microscopy reconstructions of the virus particle reveals that E1 is located almost parallel to the virus membrane, and that E1-E1 interactions form the an icosahedral lattice.


Immunosuppressive Properties of Enveloped Viruses with Type I Fusion Proteins

Fusion proteins of a subset of enveloped Type I [1] viruses (retrovirus, lentivirus and filoviruses) have previously been shown to feature an immune suppressive activity. Inactivated retroviruses are able to inhibit proliferation of immune cells upon stimulation [2-4]. Expression of these proteins is enough to enable allogenic cells to grow to a tumor in immune competent mice. In one study, introduction of ENV expressing construct into MCA205 murine tumor cells, which do not proliferate upon s.c. injection into an allogeneic host, or into CL8.1 murine tumor cells (which overexpress class I antigens and are rejected in a syngeneic host) resulted in tumor growth in both cases [5]. Such immunosuppressive domains have been found in a variety of different viruses with type 1 fusion mechanism such as gamma-retroviruses like Mason pfeizer monkey virus (MPMV) and murine leukemia virus (MLV), lentiviruses such as HIV and in filoviruses such as Ebola and Marburg viruses [6-9].


This immune suppressive activity was in all cases located to a very well-defined structure within the class I fusion proteins, more precisely at the bend in the heptad repeat just N-terminale of the transmembrane structure in the fusion protein. The immunosuppressive effects range from significant inhibition of lymphocyte proliferation [7,8], cytokine skewing (up regulating IL-10; down regulating TNF-α, IL-12, IFN-γ) [10] and inhibition of monocytic burst [11] to cytotoxic T cell killing [12]. Importantly, peptides spanning ISD in these assays must either be linked as dimers or coupled to a carrier (i.e. >monomeric) to be active. Such peptides derived from immune-suppressive domains are able to reduce or abolish immune responses such as cytokine secretion or proliferation of T-cells upon stimulation. The protection mediated by the immunosuppressive properties of the fusion protein from the immune system of the host is not limited to the fusion protein but covers all the viral envelope proteins displayed at viral or cellular membranes in particular also the protein mediating attachment of the virus to the cell.


Co-Location of the Immunosuppression Domain and the Fusion Domain

The immunosuppressive domain of retro-, lenti- and filoviruses overlap a structurally important part of the fusion subunits of the envelope proteins. Although the primary structure (sequence) of this part of the fusion proteins can vary greatly from virus to virus, the secondary structure, which is very well preserved among different virus families, is that of an alpha helix that bends in different ways during the fusion process This structure plays a crucial role during events that result in fusion of viral and cellular membranes. It is evident that the immunosuppressive domains of these (retroviral, lentiviral and filoviral) class I fusion proteins overlap with a very important protein structure needed for the fusion proteins mechanistic function.


The energy needed for mediating the fusion of viral and cellular membranes is stored in the fusion proteins, which are thus found in a meta-stable conformation on the viral surface. Once the energy is released to drive the fusion event, the protein will find its most energetically stable conformation. In this regard fusion proteins can be compared with loaded springs that are ready to be sprung. This high energy conformation makes the viral fusion proteins very susceptible to modifications; Small changes in the primary structure of the protein often result in the protein to be folded in its stable post fusion conformation. The two conformations present very different tertiary structures of the same protein.


It has been shown in the case of simple retroviruses that small structural changes in the envelope protein are sufficient to remove the immune suppressive effect without changing structure and hence the antigenic profile.


The mutated non-immune suppressive envelope proteins are much better antigens for vaccination. The proteins can induce a 30-fold enhancement of anti-env antibody titers when used for vaccination and are much better at launching an effective CTL response [6]. Furthermore, viruses that contain the non-immunosuppressive form of the friend murine leukemia virus envelope protein, although fully infectious in irradiated immunocompromised mice cannot establish an infection in immunocompetent animals. Interestingly in the latter group the non-immunosuppressive viruses induce both a higher cellular and humeral immune response, which fully protect the animals from subsequent challenge by wild type viruses [13].


Immunosuppressive domains in the fusion proteins (viral envelope proteins) from Retroviruses, lentiviruses and Filoviruses have been known since 1985 for retrovirus [7], since 1988 for lentivirus [8] and since 1992 for filoviruses [14]. These viruses, as mentioned above, all belong to enveloped RNA viruses with a type I fusion mechanism. The immunosuppressive domains of lentivirus, retroviruses and filoviruses show large structural similarity. Furthermore the immunosuppressive domain of these viruses are all located at the same position in the structure of the fusion protein, more precisely in the linker between the two heptad repeat structures just N-terminal of the transmembrane domain in the fusion protein. These heptad repeat regions constitute two alpha helices that play a critical role in the active mechanism of membrane fusion by these proteins. The immune suppressive domains can be located in relation to two well conserved cystein residues that are found in these structures. These cystein residues are between 4 and 6 amino acid residues from one another and in many cases are believed to form disulfide bridges that stabilize the fusion proteins. The immune suppressive domains in all three cases include at least some of the first 22 amino acids that are located N-terminal to the first cysteine residue. Recently the immunosuppressive domains in the fusion protein of these viruses have been successfully altered in such a way that the fusogenic properties of the fusion protein have been preserved. Such mutated fusion proteins with decreased immunosuppressive properties have been shown to be superior antigens for vaccination purposes [13].


SUMMARY OF THE INVENTION

The inventors have been able to devise methods for the identification of new immunosuppressive domains or potentially immunosuppressive domains located in proteins displayed at the surface of enveloped RNA viruses. The inventors of the present invention have surprisingly found immunosuppressive domains or potentially immunosuppressive domains in fusion proteins in a large number of other enveloped RNA viruses in addition to lentivirus, retrovirus and filovirus, where such immunosuppressive domains had not been described previously. In addition, the inventors have been able to develop methods for mutating said immunosuppressive domains in order to reduce the immunosuppressive properties of viral surface proteins, which are useful for providing strategies for producing new vaccines with improved properties by making superior antigens, or for generation of neutralizing antibodies. Through such approaches, the inventors have been able to propose vaccination regimes against different types of viruses such as e.g. Hepatitis C, Dengue virus and Influenza where effective vaccination regimes have been in great demand for many years. This may allow the production of vaccines against virus for which no vaccines has been known e.g. hepatitis C and Dengue, as well as improved versions of known vaccines, e.g. for Influenza.


According to an aspect, the inventors propose the use of up to four parameters for the identification of immunosuppressive domain in enveloped RNA viruses with hitherto un-described immunosuppressive properties. Proposed parameters used as part of a strategy for identifying a peptide sequence or a peptide which likely acts as immunosuppressive domains may comprise one or more of the following parameters (preferably all parameters are used):

    • 1): The peptide is preferably located in the fusion protein of enveloped RNA viruses;
    • 2): The peptide is preferably capable of interacting with membranes;
    • 3): Preferably a high degree of homology in the primary structure (sequence) of the peptide of said domain exists either within the Order, Family, Subfamily, Genus, or Species of viruses. This feature is due to the immunosuppressive domain being under a dual selection pressures, one as an immunosuppressive entity ensuring protection of the viral particle from the host immune system, another as a peptide interacting with membranes;
    • 4): The position at the surface of the fusion protein at a given conformation is preferably a feature of immunosuppressive domains. This can be revealed either by position in a 3D structure or by antibody staining of cells expressing the fusion protein or on viral surfaces displaying the fusion protein.


Based upon these parameters the inventors have inter alia identified three new groups of enveloped RNA viruses with immunosuppressive domains in their fusion protein:

    • 1: The inventors have identified immunosuppressive domains among enveloped RNA viruses with type II fusion mechanism. Hitherto, immunosuppressive domains have not been described for any enveloped RNA viruses with a type II fusion mechanism. Immunosuppressive domains have been identified by the inventors at two positions in two different groups of viruses:
      • i. Co-localizing with the fusion peptide exemplified by the identification of an common immunosuppressive domain in the fusion peptide of Flavirius (Dengue virus, west Nile virus etc), and
      • ii. In the hydrophobic alpha helix N-terminal of the transmembrane domain in the fusion protein exemplified by the finding of an immunosuppressive domain in said helixes of all flaviridae e.g. Hepatitis C virus, Dengue, west nile etc.
    • 2: The inventors have identified immunosuppressive domains in the fusion protein among enveloped RNA viruses with type I fusion mechanism (excluding lentivirus, retrovirus and filovirus). This position co-localizes with the fusion peptide of said fusion protein as demonstrated by the identification of a common immunosuppressive domain in the fusion peptide of all Influenza A and B types.
    • 3: The inventors have identified potential immunosuppressive domains located at various positions of type I enveloped RNA viruses (excluding lentivirus, retrovirus and filovirus) as well as in enveloped RNA viruses featuring a fusion protein with neither a type I nor a type II fusion structure.


After identification of the immunosuppressive domains these must be mutated in order to decrease or completely abrogate the immunosuppressive properties of the whole envelope protein (preferably both the attachment and fusion part of the envelope protein if these are separate proteins). Such viral envelope proteins with reduced immunosuppressive properties are ideal candidates for use as antigens in vaccine compositions or for the production of neutralizing antibodies.


According to an aspect, the invention concerns a method for identifying an immunosuppressive domain of an enveloped RNA virus containing a lipid membrane, said method comprising the following steps:

    • a. Identifying the fusion protein of said virus;
    • b. Identifying at least one well conserved domain preferably among the membrane associated domains of said fusion protein (where the immunosuppressive domain is preferably located at the surface of the protein in one or more of the different conformations of the fusion protein undergoing fusion);
    • c. Optionally multimerizing or dimerizing said peptide; and
    • d. Confirming the immunosuppressive activity of at least one optionally multimerized or dimerized peptide by testing said optionally dimerized or multimerized peptide for immunosuppresive activity.


Concerning step a., fusion proteins or putative fusion proteins are usually identified by searching scientific databases, e.g. such as searching NCBI taxonomy database (www.ncbi.nlm.nih.gov/Taxonomy/) and selecting proteins of the Family, Subfamily, Genus or Species to be investigated and subsequently searching these for fusion, or the specific fusion protein, such as the protein listed in Table 1 below.


Concerning step b., vira are divided according to the following classification: Order (-virales), Family (-viridae), Subfamily (-virinae), Genus (-virus), Species (-virus). In order to localize conserved regions in the fusion proteins one or a few candidates from all viruses within an order are aligned first using an alignment tool such as the cobalt alignment tool (www.ncbi.nlm.nih.gov/tools/cobalt/). If stretches of conserved amino acids, such as ranging from 6 to 30 amino acids long, can be identified these are considered as candidates for immunosuppressive regions and are subjected to further investigation. If no candidates are found in an order, the same procedure is applied to the family of viruses. If still no candidates are found by testing different viruses belonging to a family of viruses we move on to the subfamily of viruses. If we cannot localize regions of homology among the subfamily we then test viruses from a genus and if we still cannot localize regions of homology we ultimately align as many possible individual viral sequences from a single species of virus (up to 1400 individual viral sequences). In general regions of homology are identified by having at least 25%, more preferred at least 30%, preferably at least 40%, more preferred at least 50%, more preferred at least 60%, preferably at least 70%, and even more preferably at least 75% homology (i.e. sequence identity) within a given region.


Concerning step c., the dimerized peptide could be synthetic, the multimerized peptide could be displayed as dimerized or trimerized fusion proteins either displayed alone or on membranes such as a viral particle. Alternatively the multimerized peptides can be coupled to a carrier protein.


According to another aspect, the invention concerns a method for decreasing or completely abrogating the immunosuppressive properties of an immunosuppressive domain of a fusion protein of an enveloped RNA virus containing a lipid membrane, said method comprising the steps of:

    • e. Mutating an immunosuppressive domain to produce at least one, preferably a plurality of mutated peptides
    • f. Optionally dimerizing or multimerizing said at least one, preferably plurality of mutated peptides;
    • g. Selecting at least one of said, preferably a plurality of said mutated peptides by testing for reduced immunosuppressive properties, preferably as shown by at least 25% reduction as compared to a wildtype peptide mono-, di- or multimer corresponding to the multimerization status of said mutated peptides;
    • h. Mutating a fusion protein of an enveloped RNA virus containing a lipid membrane to contain said selected mutated peptide having reduced immunosuppressive properties;
    • i. Confirming expression by testing the whole viral envelope protein encompassing said mutated fusion protein for capability of being expressed by at least one of cellular or viral surfaces.


According to an aspect, the invention concerns a method, further comprising the step of:

    • j. Using said viral envelope protein encompassing said mutated fusion protein with reduced immunosuppressive properties as an antigen for generation of an enhanced immune response.


A number of strategies are proposed for knock-out (i.e. decreasing or completely abrogating) of the immunosuppressive domain, these strategies comprise, but are not limited to, mutating or modifying the immunosuppressive domain into having the sequence of a mutant. A knock-out may be achieved e.g. by mutation, deletion or insertion in an immunosuppressive domain. A mutation may be at least one exchange of an amino acid with another amino acid, at least one insertion, at least one deletion, or a combination of one or more of these.


Mutants decreasing or completely abrogating the immunosuppressive properties will be identified by performing a complete or partly scanning of said immunosuppressive peptide with either Isoleucine, Alanine Leucine, Asparagine, Lysine, Aspartic acid, Methionine, Cysteine, Phenylalanine, Glutamic acid, Threonine, Glutamine, Tryptophan, Glycine, Valine, Proline, Serine, Tyrosine, Arginine, Histidine, insertions, deletions or point mutations. Alternatively the literature will be searched for mutations in said regions where said mutation did not eliminate expression of the fusion protein on the surface of the cell or viral envelope. Dimerized versions of said mutants may be tested in a cell proliferation assay. The literature provides further details (as an example see Cross K J, Wharton S A, Skehel J J, Wiley D C, Steinhauer D A. Studies on influenza haemagglutinin fusion peptide mutants generated by reverse genetics. EMBO J. 2001 Aug. 15; 20(16):4432-42).


According to an aspect, the invention concerns a method for identifying an immunosuppressive domain in the fusion protein of an enveloped RNA virus having a lipid membrane, said method comprising:

    • a. Identifying at least one well conserved domain among the group consisting of the membrane associated domains of the fusion protein and the surface associated domains of the fusion protein;
    • b. Providing at least one peptide with the sequence of said identified at least one well conserved domain;
    • c. Optionally dimerizing or multimerizing said at least one peptide; and
    • d. Confirming the immunosuppressive activity of said at least one optionally dimerized or multimerized peptide by testing said at least one optionally dimerized or multimerized peptide for immunosuppressive activity.


According to another aspect, the invention concerns an immunosuppressive domain identified according to the invention.


According to another aspect, the invention concerns an immunosuppressive domain selected among the sequences of Table 1 and Seq. Id. 1-200.


According to an aspect, the invention concerns a method for decreasing or completely abrogating the immunosuppressive properties of an immunosuppressive domain of the fusion protein of an enveloped RNA virus having a lipid membrane, said method comprising the steps of:

    • e. Mutating an immunosuppressive domain to provide at least one mutated peptide;
    • f. Optionally dimerizing or multimerizing said at least one mutated peptide;
    • g. Selecting one of said optionally dimerized or multimerized mutated peptides showing reduced immunosuppressive properties;
    • h. Mutating the fusion protein of the enveloped RNA virus to contain said selected mutated peptide having reduced immunosuppressive properties;
    • i. Confirming expression by testing the viral envelope protein encompassing said mutated fusion protein for capability of being expressed by at least one of cellular or viral surfaces.


According to an aspect, the invention concerns a mutated peptide providing reduced immunosuppressive properties, said mutated peptide having a sequence according to Table 1 or any of Seq. Id. 201-203 or obtainable as said selected mutated peptide of the method according to the invention.


According to an aspect, the invention concerns a method for generating an enhanced immune response further comprising the step of:

    • j. Using said viral envelope protein encompassing said mutated fusion protein with reduced immunosuppressive properties as an antigen for generation of an enhanced immune response.


According to an aspect, the invention concerns a method for making an envelope protein having diminished immunosuppressive activity, comprising: Mutating or modifying an immunosuppressive domain, identifiable according to the invention, of an enveloped RNA virus with a lipid membrane surrounding the core, to include a peptide obtainable according to the invention.


According to an aspect, the invention concerns an envelope protein obtainable according to the invention.


According to an aspect, the invention concerns a mutated envelope protein obtainable according to the invention.


According to an aspect, the invention concerns a viral fusion protein from an enveloped RNA virus with reduced immunosuppressive properties, said fusion protein encompassing a mutated peptide, said mutated peptide displaying reduced immunosuppression, and said mutated peptide replacing an un-mutated wildtype peptide having a sequence of an ISU of Table 1 or is selected among Seq. Id. 1-200.


According to an aspect, the invention concerns an envelope protein comprising a mutated peptide according to the invention, said mutated fusion protein being displayed on the surface of cells wherein said mutated fusion protein is expressed.


According to an aspect, the invention concerns an enveloped RNA virus, different from a viruses selected among the group consisting of Retrovirus, Lentivirus and Filovirus, wherein an immunosuppressive domain has been modified or mutated to decrease or completely abrogate the immunosuppressive properties of an immunosuppressive domain of the fusion protein.


According to an aspect, the invention concerns a virus selected among the vira of Table 1, wherein an immunosuppressive domain has been modified or mutated to decrease or completely abrogate the immunosuppressive properties of an immunosuppressive domain of the fusion protein.


According to an aspect, the invention concerns an antigen obtainable by selecting a part of a mutated envelope protein according to the invention, said part comprising the mutated domain of said envelope protein.


According to an aspect, the invention concerns a nucleic acid sequence, preferably recombinant, encoding a mutated envelope protein, an envelope polypeptide or an antigen according to the invention.


According to an aspect, the invention concerns an isolated eukaryotic expression vector comprising a nucleic acid sequence according to the invention.


According to an aspect, the invention concerns a method for producing an antibody, said method comprising the steps of: Administering an entity selected among a mutated envelope, an envelope polypeptide, an antigen, a nucleic acid sequence or a vector according to the invention to a host, such as an animal; and obtaining the antibody from said host.


According to an aspect, the invention concerns an antibody obtainable according to the invention.


According to an aspect, the invention concerns neutralizing antibodies obtained or identified by the use of at least one envelope protein according to the invention.


According to an aspect, the invention concerns a method for manufacturing neutralizing antibodies comprising the use of at least one protein according to the invention.


According to an aspect, the invention concerns a method for manufacturing humanized neutralizing antibodies, comprising the use of at least one sequence selected among the sequences of Table 1 and sequences 201 to 203.


According to an aspect, the invention concerns a vaccine comprising a virus according to the invention.


According to an aspect, the invention concerns a vaccine composition comprising an envelope protein according to the invention.


According to an aspect, the invention concerns a vaccine composition comprising an entity selected among the group consisting of a mutated envelope protein, an envelope polypeptide, an antigen, a nucleic acid sequence, a vector and an antibody according to the invention, and in addition at least one excipient, carrier or diluent.


According to an aspect, the invention concerns a medical composition comprising antibodies raised using a virus according to the invention.


According to an aspect, the invention concerns a pharmaceutical composition comprising a mutated peptide, an envelope protein, a mutated envelope protein, an antigen, a nucleic acid sequence, a vector, an antibody or a vaccine composition according to the invention, and at least one pharmaceutically acceptable excipient, diluents or carrier.


According to an aspect, the invention concerns a use of a mutated peptide, an envelope protein, a mutated envelope protein, an antigen, a nucleic acid sequence, a vector or an antibody according to the invention, for a medical purpose, such as for the treatment, amelioration or prevention of a clinical condition, and/or such as for the manufacture of a medicament for the treatment, amelioration or prevention of a clinical condition.


According to an aspect, the invention concerns a method of treating or ameliorating the symptoms of an individual, or prophylactic treating an individual, comprising administering an amount of mutated peptide, an envelope protein, a mutated envelope protein, antigen, nucleic acid sequence, vector or vaccine composition according to the invention.





BRIEF DESCRIPTION OF THE DRAWINGS


FIG. 1 shows the result of an experiment using Influenza derived peptides, and the effect of the dimeric pepides on proliferation of CTLL-2 cells. The peptides are coupled through an ss-bond involving the cysteine residues. The wt INF peptide inhibits synthesis of new DNA, whereas the non-IS #1 peptide has a much less and the non-IS #2 peptide no significant effect.











INF wt:



(SEQ ID NO: 214)



GLFGAIAGFIENGWEGCGGEKEKEK







INF non-IS #1:



(SEQ ID NO: 215)



GLFGAAGFIENGWEGCGGEKEKEK







INF non-IS #2:



(SEQ ID NO: 216)



GLFAGFIENGWEGCGGEKEKEK







FIG. 2 shows the result of two independent experiments on Flavi virus derived peptides.


FLV IS/1 and FLV IS/2 are two independent experiments using the dimerized peptide: In both cases, a significant inhibition of proliferation of CTLL-2 cells is evident, while the monomeric peptide has no effect.











FLV IS/1 and FLV IS/2: dimeric 



(SEQ ID NO: 2)



DRGWGNGCGLFGKG







FLV IS mono/1: monomeric 



(SEQ ID NO: 2)



DRGWGNGCGLFGKG






Control peptide: a dimerized non-immune suppressive control peptide.


The concentrations are given in μM.



FIG. 3 shows another experimental result. The dimeric peptide derived from Hepatits C surface protein inhibits proliferation of T-cells in a concentration dependent manner.


Hep C IS peptide has the sequence:











(SEQ ID NO: 217)



PALSTGLIHLHQNIVDVQCGGEKEKEK







FIG. 4 shows yet an experimental result. The effect of the dimeric pepides derived from Flavi viruses on proliferation of CTLL-2 cells. The peptides are coupled through an ss-bond using the cysteine residues. FLV FUS non-IS is representative of a non-immune suppressive mutant.











Den H3:



(SEQ ID NO: 218)



GDTAWDFGSIGGVFTSVGKCGGEKEKEK







FLV FUS non-IS:



(SEQ ID NO: 202)



DRGWGNGCGDFGKG









DETAILED DESCRIPTION OF THE INVENTION

Table 1 provides a list of viruses and their immunosuppressive domain(s). Asterix denotes extremely conserved sequence in the immunosuppressive domain for a given class, group, family or species of viruses. New immunosuppressive domains identified and tested in CTLL-2 assay for a given class, group, family or species of viruses are listed. Both the columns with “Putative ISU as described in this application for identification of immunosuppressive domains” and “Peptides from domains from fusion proteins exhibiting immunosuppressive activity (ISU)” are candidates for domains which are immunosuppressive. Note that all of the entries of the latter column, were originally identified by the inventors as a member of the former column. Due to the redundancy, the entries of the latter column were not included in the former column.


1: The inventors have identified immunosuppressive domains in the fusion proteins among enveloped RNA viruses with a type II fusion mechanism. Insofar immunosuppressive domains have not been previously described for type II enveloped RNA viruses. The immunosuppressive domain has been identified at two positions in the fusion protein in two different groups of viruses A: Co-localizing with the fusion peptide exemplified by the identification of an common immunosuppressive domain in the fusion peptide of Flavirus (Dengue virus, westNile virus etc.) and B: in the hydrophobic alpha helix N-terminal of the transmembrane domain in the fusion protein exemplified by the finding of an immunosuppressive domain in said helixes of Flaviridae e.g. Hepatitis C virus, Dengue, WestNile virus etc, cf. Table 1.


2: The inventors have identified immunosuppressive domains in the fusion protein among enveloped RNA viruses with type I fusion mechanism (excluding lentivirus, retrovirus and filovirus). This new position co-localizes with the fusion peptide of said fusion protein as demonstrated by the identification of a common immunosuppressive domain in the fusion peptide of all Influenza A and B types, cf. Table 1.


3: The inventors have identified potential immunosuppressive domains located at various positions of type I enveloped RNA viruses (excluding lentivirus, retrovirus and filovirus) and enveloped RNA viruses with neither Type I nor type II fusion mechanism, cf. Table 1.













TABLE 1











Putative ISU as






identified using






the criteria 






described in this 






application for






identification of




Species
Species
immunosuppressive 


Family
Genus
(group)
(Strain)
domains





Flavi-
Flavi-virus
Aroa virus
Bussuquara virus
SEQ ID NO: 85


viridae


guape virus
NRGWNNGCGLFGKG





Naranjal virus
**************






SEQ ID NO: 7






GDAAWDFGSVGGVFNSLGK






**o****o*****oo*o**




Dengue virus
Dengue 1
SEQ ID NO: 8






GGTAWDFGSIGGVFTSVGK






*o*****************





Dengue 2
SEQ ID NO: 9






GDTAWDFGSLGGVFTSVGK






****************o**






SEQ ID NO: 173






KGSSIGKMFEATARGARRMAILG





Dengue 3
SEQ ID NO: 174






KGSSIGQMFETTMRGAKRMAILG





Dengue 4
SEQ ID NO: 10






GETAWDFGSVGGLLTSLGK






************oo*****






SEQ ID NO: 173






KGSSIGKMFEATARGARRMAILG




Japanese
Japanese encephalitis virus
SEQ ID NO: 11




encephalitis

LGDTAWDFGSIGGVFNSIG




virus group

***o***************





Koutango virus
SEQ ID NO: 12






LGDTAWDFGSVGGIFTSLG





Murray Valley encephalitis Virus
SEQ ID NO: 13






LGDTAWDFGSVGGVFNSIG





St. Louis encephalitis virus
SEQ ID NO: 11






LGDTAWDFGSIGGVFNSIG






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





Usutu virus
SEQ ID NO: 14






LGDTAWDFGSVGGIFNSVG






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





West Nile virus
SEQ ID NO: 15






LGDTAWDFGSVGGVFTSVG






**********o********




Kokobera virus
Kokobera virus unclassified Kokobera
SEQ ID NO: 16




group
virus group
IGDDAWDFGSVGGILNSVG




Modoc Virus group
Modoc Virus
SEQ ID NO: 17






VGSAFWNSDQRFSAINLMD






SEQ ID NO: 18






DRGWGNGCALFGKG





Cowbone Ridge virus






Jutiapa virus






Sal Vieja virus






San Perlita virus





mosquito-borne
Ilheus virus
SEQ ID NO: 84




viruses

LGDTAWDFGSVGGIFNSIG





Sepik virus
SEQ ID NO: 19






TGEHSWDFGSTGGFFASVG




Ntaya virus group
Bagaza virus
SEQ ID NO: 20






LGDTAWDFGSVGGFFTSLG





Tembusu virus
SEQ ID NO: 83






LGDTAWDFGSVGGVLTSIG





Yokose virus
SEQ ID NO: 21






IGDDAWDFGSTGGIFNTIG




Rio Bravo virus
Apoi virus
SEQ ID NO: 22




group

SSAFWNSDEPFHFSNLISII





Entebbe bat virus
SEQ ID NO: 23






GDDAWDFGSTGGIFNTIGKA





Rio Bravo virus
SEQ ID NO: 24






SSAYWSSSEPFTSAGIMRIL





Saboya virus
SEQ ID NO: 18






DRGWGNGCALFGKG






SEQ ID NO: 25






GSSSWDFSSAGGFFGSIGKA




Seaborne tick-
Meaban virus
SEQ ID NO: 26




borne virus group

GDAAWDFGSVGGFMTSIGRA






SEQ ID NO: 27






DRGWGNHCGLFGKG





Saumarez Reef virus
SEQ ID NO: 28






GETAWDFGSAGGFFTSVGRG






SEQ ID NO: 27






DRGWGNHCGLFGKG





Tyuleniy virus
SEQ ID NO: 29






GEAAWDFGSAGGFFQSVGRG






SEQ ID NO: 27






DRGWGNHCGLFGKG




Spondweni virus
Zika virus
SEQ ID NO: 30




group

LGDTAWDFGSVGGVFNSLGK






*************oo**o**





Kyasanur forest disease virus
SEQ ID NO: 31






VGEHAWDFGSVGGMLSSVG






*************o*****






SEQ ID NO: 27






DRGWGNHCGLFGKG





Langat virus
SEQ ID NO: 32






VLGEHAWDFGSVGGVMTSIG






SEQ ID NO: 27






DRGWGNHCGLFGKG





Louping ill virus
SEQ ID NO: 33






IGEHAWDFGSAGGFFSSIG






**********o***oo*o*






SEQ ID NO: 27






DRGWGNHCGLFGKG





Omsk hemorrhagic fever virus
SEQ ID NO: 34






LGEHAWDFGSTGGFLSSIG






SEQ ID NO: 27






DRGWGNHCGLFGKG





Powassan virus
SEQ ID NO: 35






VGEHAWDFGSVGGILSSVG






*************o*****






SEQ ID NO: 36






DRGWGNHCGFFGKG






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





Royal Farm virus
SEQ ID NO: 27






DRGWGNHCGLFGKG





Tick-borne encephalitis virus
SEQ ID NO: 37






IGEHAWDFGSAGGFLSSIG






SEQ ID NO: 38






IGEHAWDFGSTGGFLTSVG






SEQ ID NO: 39






IGEHAWDFGSTGGFLASVG






SEQ ID NO: 27






DRGWGNHCGLFGKG




Yaounde virus

SEQ ID NO: 40






LGDTAWDFGSIGGVFTSLG




Yellow fever
Banzi virus
SEQ ID NO: 41




virus group

VGSSSWDFSSTSGFFSSVG





Bouboui virus
SEQ ID NO: 42






VGRSSWDFSSAGGFFSSVG





Edge Hill virus






Uganda S virus






Wesselsbron virus






Yellow fever virus
SEQ ID NO: 43






MGDTAWDFSSAGGFFTSVG






***o***************




unclassified Flavivirus
Batu Cave virus
SEQ ID NO: 44





Cacipacore virus
NRGWGTGCFKWGIG





Calbertado virus
SEQ ID NO: 45





Cell fusing agent virus
NRGWGTGCFEWGLG





Chaoyang virus






Chimeric Tick-borne encephalitis






virus/Dengue virus 4






Culex theileri flavivirus






Donggang virus






Duck hemorrhagic ovaritis virus






Flavivirus Aedes/MO-Ac/ITA/2009






Flavivirus Anopheles/PV-Am/ITA/2009






Flavivirus CbaAr4001






Flavivirus FSME






Flavivirus Phlebotomine/76/Arrabida/2007






Gadgets Gully virus






Greek goat encephalitis virus






Jugra virus






Kadam virus






Kamiti River virus






Kedougou virus






Montana myotis leukoencephalitis virus






Mosquito flavivirus






Ngoye virus






Nounane virus






Phlebotomus flavivirus Alg_F19






Phlebotomus flavivirus Alg_F8






Quang Binh virus






Russian Spring-Summer encephalitis virus






Sokoluk virus






Spanish sheep encephalitis virus






T′Ho virus






Tai forest virus B31






Tamana bat virus






Tick-borne flavivirus






Wang Thong virus






Flavivirus sp.






Aedes flavivirus
SEQ ID NO: 45






NRGWGTGCFEWGLG






SEQ ID NO: 46






HVAGRYSKHGMAGIGSV






WEDLVR





Culex flavivirus
SEQ ID NO: 44






NRGWGTGCFKWGIG






SEQ ID NO: 47






VDKYRRFGTAGVGG



Hepacivirus
Hepatitis C virus
Hepatitis C virus genotype 1 a






Hepatitis C virus genotype 1b
SEQ ID NO: 48






GLIHLHRNIVDVQYLYG






SEQ ID NO: 176






PALSTGLIHLHRNIVDVQ





Hepatitis C virus genotype 2
SEQ ID NO: 49






GLIHLHQNIVDVQYMYG






SEQ ID NO: 175






PALSTGLIHLHQNIVDVQ





Hepatitis C virus genotype 3
SEQ ID NO: 175






PALSTGLIHLHQNIVDVQ





Hepatitis C virus genotype 4
SEQ ID NO: 175






PALSTGLIHLHQNIVDVQ





Hepatitis C virus genotype 5
SEQ ID NO: 50






GLIHLHQNIVDTQYLYG






SEQ ID NO: 177






PALSTGLIHLHQNIVDTQ





Hepatitis C virus genotype 6
SEQ ID NO: 175






PALSTGLIHLHQNIVDVQ





All Hepatitis C virus




Pesti virus
Border disease
Border disease virus -
SEQ ID NO: 51




virus
Border disease virus - X818
NTTLLNGSAFQLICPYGWVGRVEC





Border disease virus 1
SEQ ID NO: 52





Border disease virus 2
SYFQQYMLKGQYQYWFDLE





Border disease virus 3






Border disease virus isolates





Bovine viral
Bovine viral diarrhea virus 1-CP7
SEQ ID NO: 53




diarrhea virus 1
Bovine viral diarrhea virus 1-NADL
NTTLLNGPAFQMVCPLGWTGTVSC





Bovine viral diarrhea virus 1-Osloss
SEQ ID NO: 54





Bovine viral diarrhea virus 1-SD1
SYFQQYMLKGEYQYWFDLE





Bovine viral diarrhea virus isolates 






and strains






Bovine viral diarrhea virus type 1a






Bovine viral diarrhea virus type 1b






Pestivirus isolate 97-360






Pestivirus isolate Hay 87/2210






Pestivirus strain mousedeer






Pestivirus type 1 isolates





Bovine viral
Bovine viral diarrhea virus 2
SEQ ID NO: 55




diarrhea virus 2
Pestivirus sp. strain 178003
SLLNGPAFQMVCPQGWTGTIEC




(BVDV-2)
Pestivirus sp. strain 5250Giessen-3
SEQ ID NO: 56





Bovine viral diarrhea virus-2 
DRYFQQYMLKGKWQYWFDLD





isolate






SCP





Classical swine
Classical swine fever virus
SEQ ID NO: 57




fever virus
Hog cholera virus strain Zoelen
TLLNGSAFYLVCPIGWTGVIEC






SEQ ID NO: 58






SYFQQYMLKGEYQYWFDLD




unclassified
Bovine viral diarrhea virus 3
SEQ ID NO: 59




Pestivirus

SEQ ID NO: 82






TLLNGPAFQLVCPYGWTGTIEC






SEQ ID NO: 60






DNYFQQYMLKGKYQYWFDLEATD





Chamois pestivirus 1
SEQ ID NO: 61






TLLNGSAFQMVCPFGWTGQVEC






SEQ ID NO: 62






DSYFQQYMLKGEYQYWFDLDAKD





Porcine pestivirus isolate 
SEQ ID NO: 205





Bungowannah
TLLNGPAFQLVCPYGWTGTI






ECDSYYQ






SEQ ID NO: 206






QYIIKSGYQYWFDLTAKD



Unnclassified

Barkedji virus




Flaviviridae

Canine hepacivirus AAK-2011






GB virus A






Douroucouli hepatitis GB virus A






GBV-A-like agents






GB virus D






GBV-C/HGV group






GB virus C






Hepatitis GB virus C-like virus






Hepatitis GB virus B






Lammi virus






Marmoset hepatitis GB virus A






Nakiwogo virus






Turkey meningoencephalitis virus






Toga-
Alpha-virus
Aura virus

SEQ ID NO: 63


viridae

Barmah Forest

GVYPFMWGGAYCFCDTENTQVS




virus

**********o****o**o*o*




Middelburg virus

SEQ ID NO: 64




Ndumu virus

APFGCEIYTNPIRAENCAVGSIP




Salmon pancreas

*****o*ooo*o**oo*oo*oo*




disease virus

SEQ ID NO: 65




Getah virus

SDFGGIATVKYSASKSGKCAVH




Mayaro virus

o***oooooo*ooooo*o*oo*




Trocara virus

SEQ ID NO: 66




EEEV complex

FSTANIHPEFRLQICTSY






VTCKGDCHPP




WEEV complex
Fort Morgan virus
*oooooooo*oooo





Highlands J virus
*ooooo*ooo*o**





Sindbis virus






Western equine encephalomyelitis 






virus






Whataroa virus






Cabassou virus





VEEV complex
Mucambo virus






Pixuna virus






Venezuelan equine encephalitis 






virus
SEQ ID NO: 67






GVYPFMWGGAYCFCD






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






SEQ ID NO: 68






GDCHPPKDHIVTHPQYHAQ






************o**o*o*






SEQ ID NO: 69






AVSKTAWTWLTS






*********oo*




SFV complex
Bebaru virus
SEQ ID NO: 63





O'nyong-nyong virus
GVYPFMWGGAYCFCDTENTQVS





Ross River virus
**********o****o**o*o*





Semliki forest virus
SEQ ID NO: 64





Una virus
APFGCEIYTNPIRAENCAVGSIP






*****o*ooo*o**oo*oo*oo*






SEQ ID NO: 65






SDFGGIATVKYSASKSGKCAVH






o***oooooo*ooooo*o*oo*






SEQ ID NO: 66






FSTANIHPEFRLQICTSYV






TCKGDCHPP






*oooooooo*oooo*oooo






o*ooo*o**





Chikungunya virus
SEQ ID NO: 67






GVYPFMWGGAYCFCD






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






SEQ ID NO: 70






VHCAAECHPPKDHIVNY






oo*o*o**o********






SEQ ID NO: 71






PASHTTLGVQDISATAMSWV






o****oo******o******



Rubivirus
Rubella virus
Rubella virus (strain BRD1)
SEQ ID NO: 72





Rubella virus (strain BRDII)
ACTFWAVNAYSSGGYAQLA





Rubella virus (strain Cendehill)
SYFNPGGSYYK





Rubella virus (strain M33)
***o*o****o**oo****





Rubella virus (strain RN-UK86)
o**o******o





Rubella virus (strain THERIEN)
SEQ ID NO: 73





Rubella virus (strain TO-336 vaccine)
QYHPTACEVEPAFGHSDAACWGFPTDT





Rubella virus (strain TO-336)
***o*o*o*o****o********o***





Rubella virus (vaccine strain RA27/3)
SEQ ID NO: 74






MSVFALASYVQHPHKTVRVKFHT






***oo*****o**o**o******






SEQ ID NO: 159






ETRTVWQLSVAGVSC






o*o*********oo*






SEQ ID NO: 76






NVTTEHPFCNMPHGQLEVQVPP






o*o*o**oo*o*o****o*oo*






SEQ ID NO: 77






DPGDLVEYIMNYTGNQQSRW






****o******o*o******






SEQ ID NO: 78






GSPNCHGPDWASPVCQRHSPDCS






****o***o**************






SEQ ID NO: 79






RLVGATPERPRLRLV






o***o**o**o****






SEQ ID NO: 80






DADDPLLRTAPGP






*oo**********






SEQ ID NO: 81






GEVWVTPVIGSQARKCGL






oo*o**o**o*****o**






SEQ ID NO: 86






HIRAGPYGHATVEM






oo***********o






SEQ ID NO: 87






PEWIHAHTTSDPWHP






o**oooo*o***o*o






SEQ ID NO: 88






PGPLGLKFKTVRPVALPR






****o***o**o*oo***






SEQ ID NO: 89






ALAPPRNVRVTGCYQCGTPAL






oooo**o*o*o**o*******






SEQ ID NO: 90 and 






SEQ ID NO: 91






EGLAPGGGNCHLTVNGEDVG






***o*****o**oo*o*oo*






SEQ ID NO: 207






LLNTPPPYQVSCGG






******o*o*o***






SEQ ID NO: 92






RASARVIDPAAQSFTGVVYGTHT






**o***oo*o*************






SEQ ID NO: 93






TAVSETRQTWAEWAAAHWWQLTLG






o*******ooo*****o*******





Bunya-
Hanta-virus 
Amur virus

SEQ ID NO: 94


viridae
(continued
Bayou virus

NPPDCPGVGTGCTACGVYLD



on next page) 
Black Creek Canal

**o****o********o***




virus

SEQ ID NO: 95




Cano Delgadito

RKVCIQLGTEQTCKTIDSNDC




virus

*oo*o*o*o*oo**oo*v***




Calabazo virus

SEQ ID NO: 96




Catacamas virus

DTLLFLGPLEEGGMIFKQWC






TTTCQFGDPGDIM




Choclo virus

SEQ ID NO: 97




Dobrava-Belgrade

GSFRKKCSFATLPSCQYDGNTVSG




virus

*o***o*o***o*o*ooo**oo**




El Moro Canyon

SEQ ID NO: 98




virus

ATKDSFQSFNITEPH




Hantaan virus

**o****o**oooo*




Isla Vista virus

SEQ ID NO: 99




Khabarovsk virus

GSGVGFNLVCSVSLTEC




Laguna Negra

******o*o*ooo****




virus

SEQ ID NO: 100




Limestone Canyon

KACDSAMCYGSSTANLVRGQNT




virus

****o*o***ooooo*o**o**




Monongahela virus

SEQ ID NO: 101




Muleshoe virus

GKGGHSGSKFMCCHDKKC






SATGLVAAAPHL




Muju virus

********o*o***ooo*






ooo**o*oo***




New York virus

SEQ ID NO: 102




Oran virus

DDGAPQCGVHCWFKKSGEW




Playa de Oro

***o*o*ooo***oo****




virus






Prospect Hill






virus






Puumala virus






Rio Mamore virus






Rio Segundo virus






Saaremaa virus






Seoul virus






Sin Nombre virus






Soochong virus






Thailand virus






Thottapalayam






virus






Topografov virus






Tula virus





Ortho-bunya-virus
Anopheles A virus

SEQ ID NO: 103




Anopheles B virus

KHDELCTGPCPVNINHQTGWLT




Bakau virus

*o*o***o**oooooooo*o*o




Batama virus

SEQ ID NO: 104




Bwamba virus

WGCEEFGCLAVSDGCVFGSCQD




Caraparu virus

**o*oo**o*ooo**oo*****




Kaeng Khoi virus

SEQ ID NO: 105




Kairi virus

GNGVPRFDYLCHLASRKEVIVRKC




Madrid virus

*o*ooo*ooo*oooo*ooooo*o*




Main Drain virus

SEQ ID NO: 106




Marituba virus

SCAGCINCFQNIHC




Nyando virus

*o**ooooooooo*




Oriboca virus






Oropouche virus






Sathuperi virus






Shamonda virus






Shuni virus






Simbu virus






Tacaiuma virus






Tete virus






Turlock virus






unclassified






Orthobunyavirus






Akabane virus
Sabo virus






Tinaroo virus






Yaba-7 virus





Bunyamwera virus
Batai virus






Birao virus






Bozo virus






Cache Valley virus






Fort Sherman virus






Germiston virus






Guaroa virus






Iaco virus






Ilesha virus






Lokern virus






Maguari virus






Mboke virus






Ngari virus






Northway virus






Playas virus






Potosi virus






Shokwe virus






Tensaw virus






Tlacotalpan virus






Xingu virus





California
California encephalitis serogroup virus





Encephalitis
LEIV





virus
California encephalitis virus - BFS-283






Chatanga virus






Inkoo virus






Jamestown Canyon virus






Jamestown Canyon-like virus






Jerry Slough virus






Keystone virus






La Crosse virus






Lumbo virus






Melao virus






Morro Bay virus






San Angelo virus






Serra do Navio virus






Snowshoe hare virus






South River virus






Tahyna virus






Trivittatus virus





Caraparu virus
Apeu virus






Bruconha virus






Ossa virus






Vinces virus





Manzanilla virus
Buttonwillow virus






Ingwavuma virus






Mermet virus





Marituba virus
Gumbo Limbo virus






Murutucu virus






Nepuyo virus






Restan virus





Wyeomyia virus
Anhembi virus






BeAr328208 virus






Macaua virus






Sororoca virus






Taiassui virus




Phlebovirus
Bujaru virus






Candiruvirus






Chilibre virus






Frijoles virus






Punta






Tor_|Salehabad






virus






Sandflyfever






Naples virus






Uukuniemi viruso






virus






Rift Valley

SEQ ID NO: 107




fever virus

KTVSSELSCREGQSYWT






**oo**oo*o**o*o**






SEQ ID NO: 108






GSFSPKCLSSRRC






*******oooooo






SEQ ID NO: 109






ENKCFEQCGGWGCGCFN






VNPSCLFVHT






**o*o**o*oo*oo***






ooo***o**o






SEQ ID NO: 110






WGSVSLSLDAEGISGSNSFSF






**ooo*o**o*o*o*o*oo**






SEQ ID NO: 111






RQGFLGEIRCNSE






*o*****o**oo*






SEQ ID NO: 112






AHESCLRAPNLVSYKPMIDQLEC






*oo**oo**oooo*o*oo*ooo*






SEQ ID NO: 113






DPFVVFERGSLPQTR






**ooo*oo*o***o*






SEQ ID NO: 114






QAFSKGSVQADLTLMFD






**ooo*ooo*oooooo*






SEQ ID NO: 115






CDAAFLNLTGCYSCNAG






*o*o*o*oo*****oo*






SEQ ID NO: 116






CQILHFTVPEVEEEFMYSC






*ooo*ooo*ooooooo*o*






SEQ ID NO: 117






STVVNPKSGSWN






*o*o**oooooo






SEQ ID NO: 118






FFDWFSGLMSWFGGPLK






*o***oo*o**oooooo




unclassified
Anhanga virus





Phlebovirus (continued 
Arumowot virus





on next page)
Chagres virus






Corfou virus






Gabek Forest virus






Itaporanga virus






Phlebovirus Adria/ALB1/2005






Phlebovirus Adria/ALB5/2005






Phlebovirus AH12






Phlebovirus AH12/China/2010






Phlebovirus AH15/China/2010






Phlebovirus B105-05






Phlebovirus B151-04






Phlebovirus B43-02






Phlebovirus B68-03






Phlebovirus B79-02






Phlebovirus Chios-A






Phlebovirus Cyprus






Phlebovirus HB29/China/2010






Phlebovirus HN13/China/2010






Phlebovirus HN6/China/2010






Phlebovirus Hu/Xinyang1/China/2010






Phlebovirus Hu/Xinyang2/China/2010






Phlebovirus IB13-04






Phlebovirus JS2007-01






Phlebovirus JS24






Phlebovirus JS26






Phlebovirus JS3/China/2010






Phlebovirus JS4/China/2010






Phlebovirus JS6






Phlebovirus JSD1






Phlebovirus LN2/China/2010






Phlebovirus LN3/China/2010






Phlebovirus sandflies/Gr29/Spain/2004






Phlebovirus sandflies/Gr36/Spain/2004






Phlebovirus sandflies/Gr44/Spain/2004






Phlebovirus sandflies/Gr49/Spain/2004






Phlebovirus sandflies/Gr52/Spain/2004






Phlebovirus sandflies/Gr65/Spain/2004






Phlebovirus sandflies/Gr98/Spain/2004






Phlebovirus SD24/China/2010






Phlebovirus SD4/China/2010






Phlebovirus tick/XCQ-2011






Phlebovirus XLL/China/2009






Rio Grande virus






Salobo virus






Sandfly fever sicilian virus






Sandfly Sicilian Turkey virus






Utique virus






Phlebovirus sp.






Phlebovirus sp. Be An 24262






Phlebovirus sp. Be An 356637






Phlebovirus sp. Be An 416992






Phlebovirus sp. Be An 578142






Phlebovirus sp. Be Ar 371637






Phlebovirus sp. Co Ar 170255






Phlebovirus sp. Co Ar 171616






Phlebovirus sp. GML 902878






Phlebovirus sp. Pa Ar 2381






Phlebovirus sp. PAN 479603






Phlebovirus sp. PAN 483391






Phlebovirus sp. VP-161A






Phlebovirus sp. VP-334K






Phlebovirus sp. VP-366G






Ortho-
Influenzavirus A
Influenza A virus
INFA H1
SEQ ID NO: 119


myxo-



GLFGAIAGFIEGGWTG


viridae



SEQ ID NO: 178






WTYNAELLVLLENERTLD






SEQ ID NO: 179






NAELLVLLENERTLDYHD





INFA H2
SEQ ID NO: 120






GLFGAIAGFIEGGWQG






SEQ ID NO: 180






WTYNAELLVLMENERTLD






SEQ ID NO: 181






NAELLVLMENERTLDYHD





INFA H3
SEQ ID NO: 121






GIFGAIAGFIENGWEG






SEQ ID NO: 182






WSYNAELLVALENQHTID






SEQ ID NO: 183






NAELLVALENQHTIDLTD





INFA H4
SEQ ID NO: 122






GLFGAIAGFIENGWQG






SEQ ID NO: 182






WSYNAELLVALENQHTID






SEQ ID NO: 184






NAELLVALENQHTIDVTD





INFA H5
SEQ ID NO: 120






GLFGAIAGFIEGGWQG






SEQ ID NO: 180






WTYNAELLVLMENERTLD






SEQ ID NO: 185






NAELLVLMENERTLDFHD





INFA H6
SEQ ID NO: 123






GIFGAIAGFIEGGWTG






SEQ ID NO: 119






GLFGAIAGFIEGGWTG






SEQ ID NO: 178






WTYNAELLVLLENERTLD






SEQ ID NO: 186






NAELLVLLENERTLDMHD





INFA H7
SEQ ID NO: 187






WSYNAELLVAMENQHTID






SEQ ID NO: 208






WSYNAELLVAMENQHLAD





INFA H8
SEQ ID NO: 124






GLFGAIAGFIEGGWSG






SEQ ID NO: 189






WAYNAELLVLLENQKTLD






SEQ ID NO: 190






NAELLVLLENQKTLDEHD





INFA H9
SEQ ID NO: 125






GLFGAIAGFIEGGWPG






SEQ ID NO: 124






GLFGAIAGFIEGGWSG






SEQ ID NO: 189






WAYNAELLVLLENQKTLD






SEQ ID NO: 190






NAELLVLLENQKTLDEHD





INFA H10
SEQ ID NO: 191






WTYQAELLVAMENQHTID






SEQ ID NO: 192






QAELLVAMENQHTIDMAD





INFA H11
SEQ ID NO: 125






GLFGAIAGFIEGGWPG






SEQ ID NO: 193






WSYNAQLLVLLENEKTLD






SEQ ID NO: 194






NAQLLVLLENEKTLDLHD





INFA H12
SEQ ID NO: 125






GLFGAIAGFIEGGWPG






SEQ ID NO: 189






WAYNAELLVLLENQKTLD






SEQ ID NO: 190






NAELLVLLENQKTLDEHD





INFA H13
SEQ ID NO: 125






GLFGAIAGFIEGGWPG






SEQ ID NO: 195






WSYNAKLLVLLENDKTLD






SEQ ID NO: 196






NAKLLVLLENDKTLDMHD





INFA H14
SEQ ID NO: 122






GLFGAIAGFIENGWQG






SEQ ID NO: 182






WSYNAELLVALENQHTID






SEQ ID NO: 184






NAELLVALENQHTIDVTD





INFA H15
SEQ ID NO: 187






WSYNAELLVAMENQHTID






SEQ ID NO: 188






NAELLVAMENQHTIDLAD





INFA H16
SEQ ID NO: 125






GLFGAIAGFIEGGWPG






SEQ ID NO: 197






WSYNAKLLVLIENDRTLD






SEQ ID NO: 198






NAKLLVLIENDRTLDLHD



Influenzavirus B
Influenza B virus
All strains
SEQ ID NO: 126






GFFGAIAGFLEGGWEG






SEQ ID NO: 199






ISSQIELAVLLSNEGIIN






SEQ ID NO: 200






QIELAVLLSNEGIINSED



Influenzavirus C
Influenza C virus







Paramyxo-
Paramyxovirinae
Avulavirus
Avian paramyxovirus 2 Yucaipa virus
SEQ ID NO: 127


viridae


Avian paramyxovirus 3
GAIALGVATAAAVTAG





Avian paramyxovirus 3b
oooo*o*oo*o*oo**





Avian paramyxovirus 4






Avian paramyxovirus 5






Avian paramyxovirus 6






Avian paramyxovirus 7






Avian paramyxovirus 8






Avian paramyxovirus 9






Newcastle disease virus






Pigeon paramyxovirus 1






unclassified Avulavirus






Avian paramyxovirus 10_Avian






paramyxovirus duck/Miyagi/885/05






Avian paramyxovirus penguin/Falkland






Islands/324/2007






Goosramyxovirus HZ






Goose paramyxovirus JS/1/97/Go






Goose paramyxovirus SF02





Henipavirus
Hendra virus Hendra virus






horse/Australia/Hendra/1994






Nipah virus






unclassified Henipavirus






Bat paramyxovirus






Eid.hel/GH45/2008





Morbillivirus
Canine distemper virus






Cetacean morbillivirus_Dolphin






morbillivirus_Pilot whale morbillivirus






Porpoise morbillivirus






Measles virus






Peste-des-petits-ruminants virus






Phocine distemper virus






Phocine distemper virus 1






Phocine distemper virus-2






Rinderpest virus





Respirovirus
Bovine parainfluenza virus 3






Porcine paramyxovirus strain Frost






Porcine paramyxovirus strain Texas






Human parainfluenza virus 1






Human parainfluenza virus 3






Simian Agent 10






Sendai virus






unclassified Respirovirus






Atlantic salmon respirovirus






Guinea pig parainfluenza virus TS-9






Pacific salmon paramyxovirus






Trask River 1983 Swine parainfluenza






virus 3






Tursiops truncatus parainfluenza virus 






1





Rubulavirus
Human parainfluenza virus 2






Human parainfluenza virus 2 (strain






Greer)






Human parainfluenza virus 2 (strain






Toshiba)






Human parainfluenza virus 4






Human parainfluenza virus 4a






Human parainfluenza virus 4b






Mapuera virus






Mumps virus






Parainfluenza virus 5






Porcine rubulavirus






Simian virus 41






unclassified Rubulavirus






Porcine parainfluenza virus






Tuhoko virus 1






Tuhoko virus 2






Tuhoko virus 3





unclassified
Atlantic salmon paramyxovirus





Paramyxovirinae
Beilong virus






Canine parainfluenza virus






Chimeric human parainfluenza virus






rPIV3-2






Fer-de-lance virus






J-virus






Menangle virus






Mossman virus






Murayama virus






Ovine parainfluenza virus 3






Pacific salmon paramyxovirus






Paramyxovirus GonoGER85






Recombinant PIV3/PIV1 virus






Reptilian paramyxovirus






Salem virus






Salmo salar paramyxovirus






Snake ATCC-VR-1408 paramyxovirus






Snake ATCC-VR-1409 paramyxovirus






Tioman virus






Tupaia paramyxovirus




Pneumovirus
Human respiratory
Human respiratory syncytial virus A
SEQ ID NO: 128




syncytial virus
Human respiratory syncytial virus
FLGLILGLGAAVTAGVA





(strain RSB1734)
***oo**o*o*ooo*o*





Human respiratory syncytial virus
SEQ ID NO: 129





(strain RSB5857)
TNEAVVSLTNGMSVL





Human respiratory syncytial virus
**o*****o**o***





(strain RSB6190)
SEQ ID NO: 130





Human respiratory syncytial virus
VIRFQQLNKRLLE





(strain RSB6256)
**o***o*o****





Human respiratory syncytial virus
SEQ ID NO: 131





(strain RSB642)
REFSSNAGLT





Human respiratory syncytial virus
****o***o*





(strain RSB6614)
SEQ ID NO: 132





Human respiratory syncytial virus A
MLTDRELTSIVGGM





strain Long LinkOut
***oo**o*oooo*





Human respiratory syncytial virus A2
SEQ ID NO: 133





Human respiratory syncytial virus B
YVIQLPLFGVMDTDCW





Human respiratory syncytial
*oo***oo**o**o**





virus (subgroup B/strain 18537)
SEQ ID NO: 134





Human respiratory syncytial virus
CLARADNGWYCHNAGSLSYFP





(subgroup B strain 8/60)
**ooo*o**o*o****o*o**





Human Respiratory syncytial virus 9320
SEQ ID NO: 135





Human respiratory syncytial virus B1
DTLKSLTVPVTSRECN





Human respiratory syncytial virus S2
**oo***o*ooooo**





Human respiratory syncytial virus 
SEQ ID NO: 136





strain RSS-2
YDCKISTSKTYVSTAVLTTMG





unclassified Human respiratory 
*o*o*o***ooo*oo*o*oo*





syncytial virus
SEQ ID NO: 137






VSCYGHNSCTVIN






*****ooo**oo*






SEQ ID NO: 209






GIIRTLPDGCHYISNKGVDR






VQVGNTVYYLSKEVGK






***o*ooo**o*o**o*






o*o*o****o**oo*oo**






SEQ ID NO: 139






PLSFPDDKFDVAIRDVEHSIN






QTRTFLKASDQLL






**o**o*o*ooo*oo*oo






o***ooo*ooo**o**






SEQ ID NO: 140






KIMTSKTDISSSVITSIGAIVSCYG






o*o***ooo*oo*o*oo*oo*****




Bovine
All strains
SEQ ID NO: 128




respiratory

FLGLILGLGAAVTAGVA




syncytial virus

***oo**o*o*ooo*o*



Metapneumovirus
Avian metapneumo-
All strains
SEQ ID NO: 134




virus

CLARADNGWYCHNAGSLSYFP






**ooo*o**o*o****o*o**




Human metapneumo-
All strains
SEQ ID NO: 133




virus

YVIQLPLFGVMDTDCW






*oo***oo**o**o**





Corona-
Coronavirinae
Alphacorona-virus
Alphacoronavirus 1
SEQ ID NO: 141


viridae


Coronavirus group 1b
RSAIEDLLFDKVKLSDVG





Human coronavirus 229E
**oo****oo**ooo*o*





Human coronavirus NL63
SEQ ID NO: 142





Miniopterus bat coronavirus 1
VPFYLNVQYRINGLGVT





Miniopterus bat coronavirus HKU8
o**ooooo**o**o***





Porcine epidemic diarrhea virus
SEQ ID NO: 143





Rhinolophus bat coronavirus HKU2
VLSQNQKLIANAFNNALHAIQ





Scotophilus bat coronavirus 512
**oo***o*ooo*oo*ooo**





unclassified Alphacoronavirus
SEQ ID NO: 144




Betacorona-
Betacoronavirus 1
TNSALVKIQAVVNANA




virus
Coronavirus group 2b
*oo**o*o*o***oo*





Coronavirus group 2c
SEQ ID NO: 145





Human coronavirus HKU1
AEAQIDRLINGRLTALNAYVSQQL





Murine coronavirus
*oo******o***oo*oo*oo***





Pipistrellus bat coronavirus HKU5
SEQ ID NO: 146





Rousettus bat coronavirus HKU9
SAAQAMEKVNECVKSQSSR





Severe acute respiratory syndrome-
INFCGNGNHIIS





related coronavirus recombinant SARSr-
o*oo*oo*oo***oo*oo*





CoV
oo***o*o*oo*





SARS coronavirus
SEQ ID NO: 147





Tylonycteris bat coronavirus HKU4
APYGLYFIHFNYVP





unclassified Betacoronavirus
**o*oo*o*oo*o*






SEQ ID NO: 148






LQEAIKVLNHSYINLKDI






GTYEYYVKWPWYVW






oo*oo*o**o*ooo*ooo*oo*






o*o*****o*




Gammacorona-virus
Avian coronavirus






Beluga Whale coronavirus SW1





unclassified
Alpaca coronavirus CA08-1/2008





coronaviruses
Bat coronavirus






Bird droppings coronavirus






Bovine respiratory coronavirus






Chicken enteric coronavirus






Coronavirus Anas






Coronavirus oystercatcher/p17/2006/GBR






Coronavirus red knot/p60/2006/GBR






Ferret enteric coronavirus 1202






Ferret systemic coronavirus MSU-S






Ferret systemic coronavirus WADL






Guangxi coronaviridae






Human coronavirus NO






Human enteric coronavirus strain 4408






Kenya bat coronavirus






Mink coronavirus strain WD1133






Parrot coronavirus AV71/99






Quail coronavirus Italy/Elvia/2005






Tai Forest coronavirus






unidentified coronavirus






unidentified human coronavirus






Arena-
Arena-virus
LCMV-Lassa virus
Ippy virus
SEQ ID NO: 149


viridae

(Old World)
Lassa virus
NALINDQLIMKNHLRDIMGIPYC




complex
Lujo virus
*o**o***o*o***o*o**o***





Lymphocytic choriomeningitis virus
SEQ ID NO: 150





Mobala virus
FTWTLSDSEGKDTPGGYCLT





Mopeia virus
oo*ooo*oo*ooo***o**o






SEQ ID NO: 151






KCFGNTAIAKCNQKHDEEF






CDMLRLFDFN






***o*ooo****oo*






oo****ooo*ooo*






SEQ ID NO: 152






MLQKEYMERQGKTPLGLVDLFVFS






*ooo*oo**oo**oo*o*oooo*o




Tacaribe virus
Amapari virus
SEQ ID NO: 150




(New World)
Chapare virus
FTWTLSDSEGKDTPGGYCLT




complex
Flexal virus
oo*ooo*oo*ooo***o**o





Guanarito virus
SEQ ID NO: 151





Junin virus
KCFGNTAIAKCNQKHD





Latino virus
EEFCDMLRLFDFN





Machupo virus
***o*ooo****oo*





Oliveros virus
oo****ooo*ooo*





Parana virus
SEQ ID NO: 152





Pichinde virus
MLQKEYMERQGKTPLGLVDLFVFS





Pirital virus
*ooo*oo**oo**oo*o*oooo*o





Sabia virus






Tacaribe virus






Tamiami virus






Whitewater Arroyo virus






Hepadna-
Genus 
Hepatitis B virus
HBV genotype A
SEQ ID NO: 153


viridae
Orthohepadnavirus

HBV genotype B
FNPLGFFPSHQLDPLF





HBV genotype C
o***o*o*o*o*o*o*





HBV genotype D
SEQ ID NO: 154





HBV genotype E
ADWDKNPNKDPWP





HBV genotype F
o*o*o*oo*oooo





HBV genotype G
SEQ ID NO: 155





HBV genotype H
MESITSGFLGPLLVLQAVFF





Hepatitis B virus alpha1
oooooooo*ooooo**oooo





Hepatitis B virus LSH/chimpanzee
SEQ ID NO: 156





Hepatitis B virus strain cpz
LLTRILTIPQSLDSWWTSLNFLGGA





Hepatitis B virus subtype adr
oooooo*oooo*oooo***o*o*oo





Hepatitis B virus subtype adw
SEQ ID NO: 157





Hepatitis B virus subtype adyw
CPPTCPGYRWMC





Hepatitis B virus subtype ayw
oo*o*****o*o






SEQ ID NO: 158






LFILLLCLIFLLVLLDYQ






*oo*ooo*oo*oo*oooo





Rhabdo-
Dimarhabdovirus
Ephemerovirus
Bovine ephemeral fever virus
SEQ ID NO: 160


viridae



LDGYLCRKQKWEVTCTETWYFVTD






*o*oo****o*ooo*o*****o*o






SEQ ID NO: 161






KYQIIEVIPTENEC






o***o**o*oooo*






SEQ ID NO: 162






LKGEYIPPYYPPTNCVWNAIDTQE






oo*oo*******oo*o**oooo**






SEQ ID NO: 163






IEDPVTMTLMDSKFTKPC






ooo*oooooo**o*oo**






SEQ ID NO: 164






LHCQIKSWECIPV






o**oo*o****o*






SEQ ID NO: 165






SHRNMMEALYLESPD






*oo*oo*o*oo*o**






SEQ ID NO: 166






LTFCGYNGILLDNGEWWSIY






o****oo**oooo******






SEQ ID NO: 167






ELEHEKCLGTLEKLQNGE






*****o**o*oo*oo*o*






SEQ ID NO: 168






LDLSYLSPSNPGKHYAY






**o***o*oo**oo***






SEQ ID NO: 169






IRAVCYYHTFSMNLD






o**o*o*oo*oooo*




Vesiculovirus
Carajas virus
SEQ ID NO: 170





Chandipura virus
EWKTTCDYRWYGPQYITHSI





Cocal virus
o*o****o*****o*o*o*





Isfahan virus
SEQ ID NO: 171





Maraba virus
LGFPPQSCGWASVTT





Piry virus
o****oo**oooooo





recombinant Vesiculovirus
SEQ ID NO: 1





Spring viraemia of carp virus
VQVTPHHVLVDEYTGEW





Vesicular stomatitis Alagoas virus
VDSQFINGKC





Vesicular stomatitis Indiana virus
ooooo*o*oooo*o*o*





Vesicular stomatitis New Jersey virus
o*oooooooo



Lyssavirus
Aravan virus






Australian bat






lyssavirus






Duvenhage virus






European bat






lyssavirus 1






European bat






lyssavirus 2






Irkut virus






Khujand virus






Lagos bat virus






Mokola virus






West Caucasian






bat virus






Rabies virus
Rabies virus AB21
SEQ ID NO: 5





Rabies virus AB22
GFTCTGVVTEAETYTNFVGYVT





Rabies virus AVO1
*o****o**o*oo*oooo***





Rabies virus BNG4
SEQ ID NO: 6





Rabies virus BNG5
SLHNPYPDYRWLRTVKTT





Rabies virus China/DRV
*ooooooooooo***o*





Rabies virus China/MRV
SEQ ID NO: 210





Rabies virus CVS-11
ESLVIISPSVADLDPYDRSLHS





Rabies virus ERA
*ooo***oooo*o**ooo





Rabies virus Eth2003
SEQ ID NO: 211





Rabies virus HEP-FLURY
CKLKLCGVLGLRLMDGT





Rabies virus India
*ooo****oooo*ooo*





Rabies virus Nishigahara RCEH
SEQ ID NO: 212





Rabies virus Ontario fox
ILGPDGNVLIPEMQSS





Rabies virus Ontario skunk
o**o*ooo*******o





Rabies virus PM
SEQ ID NO: 213





Rabies virus red fox/08RS-
QHMELLESSVIPLVHPL





1981/Udine/2008
*ooo**o*ooo**oo**





Rabies virus SAD B19






Rabies virus silver-haired bat-






associated SHBRV






Rabies virus strain Pasteur vaccin






Rabies virus strain Street






Rabies virus vnukovo-32






Thailand genotype 1 dog lyssavirus





unclassified
Bokeloh bat lyssavirus





Lyssavirus
European bat lyssavirus






Lyssavirus Ozernoe






Shimoni bat virus




Novirhabdovirus
Hirame






rhabdovirus






Infectious






hematopoietic






necrosis virus






Snakehead






rhabdovirus






Viral hemorrhagic






septicemia virus





unassigned Rhabdoviridae
Bangoran virus






Bimbo virus






Bivens Arm virus






Flanders virus






Garba virus






Klamath virus






Malpais Spring






virus






Nasoule virus






Ngaingan virus






Ouango virus






Sigma virus






Tupaia virus






Wongabel virus



















Peptides from domains from
knock-out (K.O.)






fusion proteins exhibiting
mutants of the




Species
Species
immunosuppressive activity
immunosuppressive


Family
Genus
(group)
(Strain)
(ISU)
domain (ISU)





Flavi-
Flavi-virus
Aroa virus
Bussuquara virus

SEQ ID NO: 202


viridae


guape virus

DRGWGNGCGDFGKG





Naranjal virus






Dengue virus
Dengue 1
SEQ ID NO: 2







DRGWGNGCGLFGKG







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







SEQ ID NO: 172







KGSSIGKMFESTYRGAKRMAILG






Dengue 2
SEQ ID NO: 2







DRGWGNGCGLFGKG







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






Dengue 3
SEQ ID NO: 2







DRGWGNGCGLFGKG







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







SEQ ID NO: 204







GDTAWDFGSVGGVLNSLGK







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






Dengue 4
SEQ ID NO: 2







DRGWGNGCGLFGKG







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





Japanese
Japanese encephalitis virus
SEQ ID NO: 2





encephalitis

DRGWGNGCGLFGKG





virus group

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






Koutango virus
SEQ ID NO: 2







DRGWGNGCGLFGKG







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






Murray Valley encephalitis Virus
SEQ ID NO: 2







DRGWGNGCGLFGKG







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






St. Louis encephalitis virus
SEQ ID NO: 2







DRGWGNGCGLFGKG







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






Usutu virus
SEQ ID NO: 2







DRGWGNGCGLFGKG







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






West Nile virus
SEQ ID NO: 2







DRGWGNGCGLFGKG







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





Kokobera virus
Kokobera Virus 
SEQ ID NO: 2





group
unclassified Kokobera
DRGWGNGCGLFGKG






virus group






Modoc Virus group
Modoc Virus







Cowbone Ridge virus







Jutiapa virus







Sal Vieja virus







San Perlita virus






mosquito-borne
Ilheus virus
SEQ ID NO: 2





viruses

DRGWGNGCGLFGKG






Sepik virus
SEQ ID NO: 2







DRGWGNGCGLFGKG





Ntaya virus group
Bagaza virus
SEQ ID NO: 2







DRGWGNGCGLFGKG






Tembusu virus
SEQ ID NO: 2







DRGWGNGCGLFGKG






Yokose virus
SEQ ID NO: 2







DRGWGNGCGLFGKG





Rio Bravo virus
Apoi virus
SEQ ID NO: 2





group

DRGWGNGCGLFGKG






Entebbe bat virus
SEQ ID NO: 2







DRGWGNGCGLFGKG






Rio Bravo virus
SEQ ID NO: 2







DRGWGNGCGLFGKG






Saboya virus






Seaborne tick-
Meaban virus






borne virus group








Saumarez Reef virus







Tyuleniy virus






Spondweni virus
Zika virus
SEQ ID NO: 2





group

DRGWGNGCGLFGKG






Kyasanur forest disease virus







Langat virus







Louping ill virus







Omsk hemorrhagic fever virus







Powassan virus







Royal Farm virus







Tick-borne encephalitis virus






Yaounde virus

SEQ ID NO: 2







DRGWGNGCGLFGKG





Yellow fever
Banzi virus
SEQ ID NO: 2





virus group

DRGWGNGCGLFGKG






Bouboui virus
SEQ ID NO: 2







DRGWGNGCGLFGKG






Edge Hill virus







Uganda S virus







Wesselsbron virus







Yellow fever virus
SEQ ID NO: 2







DRGWGNGCGLFGKG





unclassified
Batu Cave virus
SEQ ID NO: 2





Flavivirus
Cacipacore virus
DRGWGNGCGLFGKG






Calbertado virus







Cell fusing agent virus







Chaoyang virus







Chimeric Tick-borne encephalitis







virus/Dengue virus 4







Culex theileri flavivirus







Donggang virus







Duck hemorrhagic ovaritis virus







Flavivirus Aedes/MO-Ac/ITA/2009







Flavivirus Anopheles/







PV-Am/ITA/2009







Flavivirus CbaAr4001







Flavivirus FSME







Flavivirus Phlebotomine/76/







Arrabida/2007







Gadgets Gully virus







Greek goat encephalitis virus







Jugra virus







Kadam virus







Kamiti River virus







Kedougou virus







Montana myotis 







leukoencephalitis virus







Mosquito flavivirus







Ngoye virus







Nounane virus







Phlebotomus flavivirus Alg_F19







Phlebotomus flavivirus Alg_F8







Quang Binh virus







Russian Spring-Summer 







encephalitis virus







Sokoluk virus







Spanish sheep encephalitis virus







T′Ho virus







Tai forest virus B31







Tamana bat virus







Tick-borne flavivirus







Wang Thong virus







Flavivirus sp.







Aedes flavivirus







Culex flavivirus





Hepacivirus
Hepatitis C 
Hepatitis C virus genotype 1 a
SEQ ID NO: 3





virus

GLIHLHQNIVDVQYLYG







SEQ ID NO: 175







PALSTGLIHLHQNIVDVQ






Hepatitis C virus genotype 1b







Hepatitis C virus genotype 2







Hepatitis C virus genotype 3
SEQ ID NO: 3







GLIHLHQNIVDVQYLYG






Hepatitis C virus genotype 4
SEQ ID NO: 3







GLIHLHQNIVDVQYLYG






Hepatitis C virus genotype 5







Hepatitis C virus genotype 6
SEQ ID NO: 3







GLIHLHQNIVDVQYLYG






All Hepatitis C virus
SEQ ID NO: 3







GLIHLHQNIVDVQYLYG




Pesti virus
Border disease
Border disease virus -






virus
Border disease virus - X818







Border disease virus 1







Border disease virus 2







Border disease virus 3







Border disease virus isolates






Bovine viral
Bovine viral diarrhea virus 1-CP7






diarrhea 
Bovine viral diarrhea virus 1-NADL






virus 1
Bovine viral diarrhea 







virus 1-Osloss







Bovine viral diarrhea virus 1-SD1







Bovine viral diarrhea virus 







isolates  and strains







Bovine viral diarrhea virus type 1a







Bovine viral diarrhea virus type 1b







Pestivirus isolate 97-360







Pestivirus isolate Hay 87/2210







Pestivirus strain mousedeer







Pestivirus type 1 isolates






Bovine viral
Bovine viral diarrhea virus 2






diarrhea virus 2
Pestivirus sp. strain 178003






(BVDV-2)
Pestivirus sp. strain 5250Giessen-3







Bovine viral diarrhea virus-2 isolate







SCP






Classical swine
Classical swine fever virus






fever virus
Hog cholera virus strain Zoelen






unclassified
Bovine viral diarrhea virus 3






Pestivirus








Chamois pestivirus 1







Porcine pestivirus isolate Bungowannah





Unnclassified

Barkedji virus





Flaviviridae

Canine hepacivirus AAK-2011







GB virus A







Douroucouli hepatitis GB virus A







GBV-A-like agents







GB virus D







GBV-C/HGV group







GB virus C







Hepatitis GB virus C-like virus







Hepatitis GB virus B







Lammi virus







Marmoset hepatitis GB virus A







Nakiwogo virus







Turkey meningoencephalitis virus







Toga-
Alpha-virus
Aura virus





viridae

Barmah Forest







virus







Middelburg virus







Ndumu virus







Salmon pancreas







disease virus







Getah virus







Mayaro virus







Trocara virus







EEEV complex







WEEV complex
Fort Morgan virus







Highlands J virus







Sindbis virus







Western equine encephalomyelitis virus







Whataroa virus






VEEV complex
Cabassou virus







Mucambo virus







Pixuna virus







Venezuelan equine encephalitis virus






SFV complex
Bebaru virus







O'nyong-nyong virus







Ross River virus







Semliki forest virus







Una virus







Chikungunya virus





Rubivirus
Rubella virus
Rubella virus (strain BRD1)







Rubella virus (strain BRDII)







Rubella virus (strain Cendehill)







Rubella virus (strain M33)







Rubella virus (strain RN-UK86)







Rubella virus (strain THERIEN)







Rubella virus (strain TO-336 vaccine)







Rubella virus (strain TO-336)







Rubella virus (vaccine strain RA27/3)







Bunya-
Hanta-virus
Amur virus





viridae
(continued on
Bayou virus






next page)
Black Creek Canal







virus







Cano Delgadito







virus







Calabazo virus







Catacamas virus







Choclo virus







Dobrava-Belgrade







virus







El Moro Canyon







virus







Hantaan virus







Isla Vista virus







Khabarovsk virus







Laguna Negra







virus







Limestone Canyon







virus







Monongahela virus







Muleshoe virus







Muju virus







New York virus







Oran virus







Playa de Oro







virus







Prospect Hill







virus







Puumala virus







Rio Mamore virus







Rio Segundo virus







Saaremaa virus







Seoul virus







Sin Nombre virus







Soochong virus







Thailand virus







Thottapalayam







virus







Topografov virus







Tula virus






Ortho-bunya-virus
Anopheles A virus







Anopheles B virus







Bakau virus







Batama virus







Bwamba virus







Caraparu virus







Kaeng Khoi virus







Kairi virus







Madrid virus







Main Drain virus







Marituba virus







Nyando virus







Oriboca virus







Oropouche virus







Sathuperi virus







Shamonda virus







Shuni virus







Simbu virus







Tacaiuma virus







Tete virus







Turlock virus







unclassified







Orthobunyavirus







Akabane virus
Sabo virus







Tinaroo virus







Yaba-7 virus






Bunyamwera virus
Batai virus







Birao virus







Bozo virus







Cache Valley virus







Fort Sherman virus







Germiston virus







Guaroa virus







Iaco virus







Ilesha virus







Lokern virus







Maguari virus







Mboke virus







Ngari virus







Northway virus







Playas virus







Potosi virus







Shokwe virus







Tensaw virus







Tlacotalpan virus







Xingu virus






California
California encephalitis 






Encephalitis
serogroup virus






virus
LEIV







California encephalitis virus-







BFS-283







Chatanga virus







Inkoo virus







Jamestown Canyon virus







Jamestown Canyon-like virus







Jerry Slough virus







Keystone virus







La Crosse virus







Lumbo virus







Melao virus







Morro Bay virus







San Angelo virus







Serra do Navio virus







Snowshoe hare virus







South River virus







Tahyna virus







Trivittatus virus






Caraparu virus
Apeu virus







Bruconha virus







Ossa virus







Vinces virus






Manzanilla virus
Buttonwillow virus







Ingwavuma virus







Mermet virus






Marituba virus
Gumbo Limbo virus







Murutucu virus







Nepuyo virus







Restan virus






Wyeomyia virus
Anhembi virus







BeAr328208 virus







Macaua virus







Sororoca virus







Taiassui virus





Phlebovirus
Bujaru virus







Candiruvirus







Chilibre virus







Frijoles virus







Punta







Tor_|Salehabad







virus







Sandflyfever







Naples virus







Uukuniemi viruso







virus







Rift Valley







fever virus







unclassified
Anhanga virus






Phlebovirus
Arumowot virus






(continued on
Chagres virus






next page)
Corfou virus







Gabek Forest virus







Itaporanga virus







Phlebovirus Adria/ALB1/2005







Phlebovirus Adria/ALB5/2005







Phlebovirus AH12







Phlebovirus AH12/China/2010







Phlebovirus AH15/China/2010







Phlebovirus B105-05







Phlebovirus B151-04







Phlebovirus B43-02







Phlebovirus B68-03







Phlebovirus B79-02







Phlebovirus Chios-A







Phlebovirus Cyprus







Phlebovirus HB29/China/2010







Phlebovirus HN13/China/2010







Phlebovirus HN6/China/2010







Phlebovirus Hu/Xinyang1/China/2010







Phlebovirus Hu/Xinyang2/China/2010







Phlebovirus IB13-04







Phlebovirus JS2007-01







Phlebovirus JS24







Phlebovirus JS26







Phlebovirus JS3/China/2010







Phlebovirus JS4/China/2010







Phlebovirus JS6







Phlebovirus JSD1







Phlebovirus LN2/China/2010







Phlebovirus LN3/China/2010







Phlebovirus sandflies/Gr29/Spain/2004







Phlebovirus sandflies/Gr36/Spain/2004







Phlebovirus sandflies/Gr44/Spain/2004







Phlebovirus sandflies/Gr49/Spain/2004







Phlebovirus sandflies/Gr52/Spain/2004







Phlebovirus sandflies/Gr65/Spain/2004







Phlebovirus sandflies/Gr98/Spain/2004







Phlebovirus SD24/China/2010







Phlebovirus SD4/China/2010







Phlebovirus tick/XCQ-2011







Phlebovirus XLL/China/2009







Rio Grande virus







Salobo virus







Sandfly fever sicilian virus







Sandfly Sicilian Turkey virus







Utique virus







Phlebovirus sp.







Phlebovirus sp. Be An 24262







Phlebovirus sp. Be An 356637







Phlebovirus sp. Be An 416992







Phlebovirus sp. Be An 578142







Phlebovirus sp. Be Ar 371637







Phlebovirus sp. Co Ar 170255







Phlebovirus sp. Co Ar 171616







Phlebovirus sp. GML 902878







Phlebovirus sp. Pa Ar 2381







Phlebovirus sp. PAN 479603







Phlebovirus sp. PAN 483391







Phlebovirus sp. VP-161A







Phlebovirus sp. VP-334K







Phlebovirus sp. VP-366G







Ortho-
Influenzavirus A
Influenza A 
INFA H1

INF F#2 DELTA6:


myxo-

virus


SEQ ID NO: 201


viridae




GLFGAAGFIENGWEG







InFAH1-3: SEQ ID NO: 203





INFA H2







INFA H3
SEQ ID NO: 4







GLFGAIAGFIENGWEG






INFA H4







INFA H5







INFA H6







INFA H7
SEQ ID NO: 4







GLFGAIAGFIENGWEG






INFA H8







INFA H9







INFA H10
SEQ ID NO: 4







GLFGAIAGFIENGWEG






INFA H11







INFA H12







INFA H13







INFA H14







INFA H15
SEQ ID NO: 4







GLFGAIAGFIENGWEG






INFA H16





Influenzavirus B
Influenza B virus
All strains





Influenzavirus C
Influenza C virus








Paramyxo-
Paramyxovirinae
Avulavirus
Avian paramyxovirus 2 Yucaipa virus




viridae


Avian paramyxovirus 3







Avian paramyxovirus 3b







Avian paramyxovirus 4







Avian paramyxovirus 5







Avian paramyxovirus 6







Avian paramyxovirus 7







Avian paramyxovirus 8







Avian paramyxovirus 9







Newcastle disease virus







Pigeon paramyxovirus 1







unclassified Avulavirus







Avian paramyxovirus 10_Avian







paramyxovirus duck/Miyagi/885/05







Avian paramyxovirus penguin/Falkland







Islands/324/2007







Goosramyxovirus HZ







Goose paramyxovirus JS/1/97/Go







Goose paramyxovirus SF02






Henipavirus
Hendra virus Hendra virus







horse/Australia/Hendra/1994







Nipah virus







unclassified Henipavirus







Bat paramyxovirus







Eid.hel/GH45/2008






Morbillivirus
Canine distemper virus







Cetacean morbillivirus_Dolphin







morbillivirus_Pilot whale morbillivirus







Porpoise morbillivirus







Measles virus







Peste-des-petits-ruminants virus







Phocine distemper virus







Phocine distemper virus 1







Phocine distemper virus-2







Rinderpest virus






Respirovirus
Bovine parainfluenza virus 3







Porcine paramyxovirus strain Frost







Porcine paramyxovirus strain Texas







Human parainfluenza virus 1







Human parainfluenza virus 3







Simian Agent 10







Sendai virus







unclassified Respirovirus







Atlantic salmon respirovirus







Guinea pig parainfluenza virus TS-9







Pacific salmon paramyxovirus







Trask River 1983 Swine parainfluenza







virus 3







Tursiops truncatus parainfluenza virus 1






Rubulavirus
Human parainfluenza virus 2







Human parainfluenza virus 2 (strain







Greer)







Human parainfluenza virus 2 (strain







Toshiba)







Human parainfluenza virus 4







Human parainfluenza virus 4a







Human parainfluenza virus 4b







Mapuera virus







Mumps virus







Parainfluenza virus 5







Porcine rubulavirus







Simian virus 41







unclassified Rubulavirus







Porcine parainfluenza virus







Tuhoko virus 1







Tuhoko virus 2







Tuhoko virus 3






unclassified
Atlantic salmon paramyxovirus






Paramyxovirinae
Beilong virus







Canine parainfluenza virus







Chimeric human parainfluenza virus







rPIV3-2







Fer-de-lance virus







J-virus







Menangle virus







Mossman virus







Murayama virus







Ovine parainfluenza virus 3







Pacific salmon paramyxovirus







Paramyxovirus GonoGER85







Recombinant PIV3/PIV1 virus







Reptilian paramyxovirus







Salem virus







Salmo salar paramyxovirus







Snake ATCC-VR-1408 paramyxovirus







Snake ATCC-VR-1409 paramyxovirus







Tioman virus







Tupaia paramyxovirus





Pneumovirus
Human respiratory
Human respiratory syncytial virus A






syncytial virus
Human respiratory syncytial virus







(strain RSB1734)







Human respiratory syncytial virus







(strain RSB5857)







Human respiratory syncytial virus







(strain RSB6190)







Human respiratory syncytial virus







(strain RSB6256)







Human respiratory syncytial virus







(strain RSB642)







Human respiratory syncytial virus







(strain RSB6614)







Human respiratory syncytial virus A







strain Long LinkOut







Human respiratory syncytial virus A2







Human respiratory syncytial virus B







Human respiratory syncytial







virus (subgroup B/strain 18537)







Human respiratory syncytial virus







(subgroup B strain 8/60)







Human Respiratory syncytial virus 9320







Human respiratory syncytial virus B1







Human respiratory syncytial virus S2







Human respiratory syncytial virus strain







RSS-2







unclassified Human respiratory syncytial







virus






Bovine
All strains






respiratory







syncytial virus






Metapneum
Avian metapneumo-
All strains






virus







Human metapneumo-
All strains






virus








Corona-
Coronavirinae
Alphacorona-virus
Alphacoronavirus 1




viridae


Coronavirus group 1b







Human coronavirus 229E







Human coronavirus NL63







Miniopterus bat coronavirus 1







Miniopterus bat coronavirus HKU8







Porcine epidemic diarrhea virus







Rhinolophus bat coronavirus HKU2







Scotophilus bat coronavirus 512







unclassified Alphacoronavirus






Betacorona-
Betacoronavirus 1






virus
Coronavirus group 2b







Coronavirus group 2c







Human coronavirus HKU1







Murine coronavirus







Pipistrellus bat coronavirus HKU5







Rousettus bat coronavirus HKU9







Severe acute respiratory syndrome-







related coronavirus recombinant SARSr-







CoV







SARS coronavirus







Tylonycteris bat coronavirus HKU4







unclassified Betacoronavirus






Gammacorona-
Avian coronavirus






virus
Beluga Whale coronavirus SW1






unclassified
Alpaca coronavirus CA08-1/2008






coronaviruses
Bat coronavirus







Bird droppings coronavirus







Bovine respiratory coronavirus







Chicken enteric coronavirus







Coronavirus Anas







Coronavirus oystercatcher/p17/2006/GBR







Coronavirus red knot/p60/2006/GBR







Ferret enteric coronavirus 1202







Ferret systemic coronavirus MSU-S







Ferret systemic coronavirus WADL







Guangxi coronaviridae







Human coronavirus NO







Human enteric coronavirus strain 4408







Kenya bat coronavirus







Mink coronavirus strain WD1133







Parrot coronavirus AV71/99







Quail coronavirus Italy/Elvia/2005







Tai Forest coronavirus







unidentified coronavirus







unidentified human coronavirus







Arena-
Arena-virus
LCMV-Lassa virus
Ippy virus




viridae

(Old World)
Lassa virus






complex
Lujo virus







Lymphocytic choriomeningitis virus







Mobala virus







Mopeia virus






Tacaribe virus
Amapari virus






(New World)
Chapare virus






complex
Flexal virus







Guanarito virus







Junin virus







Latino virus







Machupo virus







Oliveros virus







Parana virus







Pichinde virus







Pirital virus







Sabia virus







Tacaribe virus







Tamiami virus







Whitewater Arroyo virus







Hepadna-
Genus
Hepatitis B virus
HBV genotype A




viridae

Orthohepadnavirus
HBV genotype B







HBV genotype C







HBV genotype D







HBV genotype E







HBV genotype F







HBV genotype G







HBV genotype H







Hepatitis B virus alpha1







Hepatitis B virus LSH/chimpanzee







Hepatitis B virus strain cpz







Hepatitis B virus subtype adr







Hepatitis B virus subtype adw







Hepatitis B virus subtype adyw







Hepatitis B virus subtype ayw







Rhabdo-
Dimarhabdovirus
Ephemerovirus
Bovine ephemeral fever virus




viridae

Vesiculovirus
Carajas virus







Chandipura virus







Cocal virus







Isfahan virus







Maraba virus







Piry virus







recombinant Vesiculovirus







Spring viraemia of carp virus







Vesicular stomatitis Alagoas virus







Vesicular stomatitis Indiana virus







Vesicular stomatitis New Jersey virus





Lyssavirus
Aravan virus







Australian bat







lyssavirus







Duvenhage virus







European bat







lyssavirus 1







European bat







lyssavirus 2







Irkut virus







Khujand virus







Lagos bat virus







Mokola virus







West Caucasian







bat virus







Rabies virus
Rabies virus AB21







Rabies virus AB22







Rabies virus AVO1







Rabies virus BNG4







Rabies virus BNG5







Rabies virus China/DRV







Rabies virus China/MRV







Rabies virus CVS-11







Rabies virus ERA







Rabies virus Eth2003







Rabies virus HEP-FLURY







Rabies virus India







Rabies virus Nishigahara RCEH







Rabies virus Ontario fox







Rabies virus Ontario skunk







Rabies virus PM







Rabies virus red fox/08RS-







1981/Udine/2008







Rabies virus SAD B19







Rabies virus silver-haired bat-







associated SHBRV







Rabies virus strain Pasteur vaccin







Rabies virus strain Street







Rabies virus vnukovo-32







Thailand genotype 1 dog lyssavirus






unclassified
Bokeloh bat lyssavirus






Lyssavirus
European bat lyssavirus







Lyssavirus Ozernoe







Shimoni bat virus





Novirhabdo-
Hirame






virus
rhabdovirus







Infectious







hematopoietic







necrosis virus







Snakehead







rhabdovirus







Viral hemorrhagic







septicemia virus






unassigned
Bangoran virus






Rhabdoviridae
Bimbo virus







Bivens Arm virus







Flanders virus







Garba virus







Klamath virus







Malpais Spring







virus







Nasoule virus







Ngaingan virus







Ouango virus







Sigma virus







Tupaia virus







Wongabel virus









Name of





Species
Species
envelope attachment/
IU group and


Family
Genus
(group)
(Strain)
fusion protein
fusion type





Flavi-
Flavi-virus
Aroa virus
Bussuquara virus
Envelope protein prME
Group 1 Type II


viridae


guape virus
Fusion protein E
Fusion mechanism





Naranjal virus






Dengue virus
Dengue 1







Dengue 2







Dengue 3







Dengue 4






Japanese
Japanese encephalitis virus






encephalitis







virus group








Koutango virus







Murray Valley encephalitis Virus







St. Louis encephalitis virus







Usutu virus







West Nile virus






Kokobera virus
Kokobera Virus unclassified Kokobera






group
virus group






Modoc Virus group
Modoc Virus







Cowbone Ridge virus







Jutiapa virus







Sal Vieja virus







San Perlita virus






mosquito-borne
Ilheus virus






viruses








Sepik virus






Ntaya virus group
Bagaza virus







Tembusu virus







Yokose virus






Rio Bravo virus
Apoi virus






group








Entebbe bat virus







Rio Bravo virus







Saboya virus






Seaborne tick-
Meaban virus






borne virus group








Saumarez Reef virus







Tyuleniy virus






Spondweni virus
Zika virus






group








Kyasanur forest disease virus







Langat virus







Louping ill virus







Omsk hemorrhagic fever virus







Powassan virus







Royal Farm virus







Tick-borne encephalitis virus






Yaounde virus







Yellow fever
Banzi virus






virus group








Bouboui virus







Edge Hill virus







Uganda S virus







Wesselsbron virus







Yellow fever virus






unclassified
Batu Cave virus






Flavivirus
Cacipacore virus







Calbertado virus







Cell fusing agent virus







Chaoyang virus







Chimeric Tick-borne encephalitis







virus/Dengue virus 4







Culex theileri flavivirus







Donggang virus







Duck hemorrhagic ovaritis virus







Flavivirus Aedes/MO-Ac/ITA/2009







Flavivirus Anopheles/PV-Am/ITA/2009







Flavivirus CbaAr4001







Flavivirus FSME







Flavivirus Phlebotomine/76/Arrabida/2007







Gadgets Gully virus







Greek goat encephalitis virus







Jugra virus







Kadam virus







Kamiti River virus







Kedougou virus







Montana myotis leukoencephalitis virus







Mosquito flavivirus







Ngoye virus







Nounane virus







Phlebotomus flavivirus Alg_F19







Phlebotomus flavivirus Alg_F8







Quang Binh virus







Russian Spring-Summer encephalitis virus







Sokoluk virus







Spanish sheep encephalitis virus







T′Ho virus







Tai forest virus B31







Tamana bat virus







Tick-borne flavivirus







Wang Thong virus







Flavivirus sp.







Aedes flavivirus







Culex flavivirus





Hepacivirus
Hepatitis C virus
Hepatitis C virus genotype 1 a
E1/E2






Hepatitis C virus genotype 1b







Hepatitis C virus genotype 2







Hepatitis C virus genotype 3







Hepatitis C virus genotype 4







Hepatitis C virus genotype 5







Hepatitis C virus genotype 6







All Hepatitis C virus





Pesti virus
Border disease
Border disease virus -
E1/E2





virus
Border disease virus - X818







Border disease virus 1







Border disease virus 2







Border disease virus 3







Border disease virus isolates






Bovine viral
Bovine viral diarrhea virus 1-CP7






diarrhea virus 1
Bovine viral diarrhea virus 1-NADL







Bovine viral diarrhea virus 1-Osloss







Bovine viral diarrhea virus 1-SD1







Bovine viral diarrhea virus isolates and







strains







Bovine viral diarrhea virus type 1a







Bovine viral diarrhea virus type 1b







Pestivirus isolate 97-360







Pestivirus isolate Hay 87/2210







Pestivirus strain mousedeer







Pestivirus type 1 isolates






Bovine viral
Bovine viral diarrhea virus 2






diarrhea virus 2
Pestivirus sp. strain 178003






(BVDV-2)
Pestivirus sp. strain 5250Giessen-3







Bovine viral diarrhea virus-2 isolate







SCP






Classical swine
Classical swine fever virus






fever virus
Hog cholera virus strain Zoelen






unclassified
Bovine viral diarrhea virus 3






Pestivirus








Chamois pestivirus 1







Porcine pestivirus isolate Bungowannah





Unnclassified

Barkedji virus





Flaviviridae

Canine hepacivirus AAK-2011







GB virus A







Douroucouli hepatitis GB virus A







GBV-A-like agents







GB virus D







GBV-C/HGV group







GB virus C







Hepatitis GB virus C-like virus







Hepatitis GB virus B







Lammi virus







Marmoset hepatitis GB virus A







Nakiwogo virus







Turkey meningoencephalitis virus







Toga-
Alpha-virus
Aura virus

E2/E1



viridae

Barmah Forest







virus







Middelburg virus







Ndumu virus







Salmon pancreas







disease virus







Getah virus







Mayaro virus







Trocara virus







EEEV complex







WEEV complex
Fort Morgan virus







Highlands J virus







Sindbis virus







Western equine encephalomyelitis virus







Whataroa virus






VEEV complex
Cabassou virus







Mucambo virus







Pixuna virus







Venezuelan equine encephalitis virus






SFV complex
Bebaru virus







O'nyong-nyong virus







Ross River virus







Semliki forest virus







Una virus







Chikungunya virus





Rubivirus
Rubella virus
Rubella virus (strain BRD1)







Rubella virus (strain BRDII)







Rubella virus (strain Cendehill)







Rubella virus (strain M33)







Rubella virus (strain RN-UK86)







Rubella virus (strain THERIEN)







Rubella virus (strain TO-336 vaccine)







Rubella virus (strain TO-336)







Rubella virus (vaccine strain RA27/3)







Bunya-
Hanta-virus
Amur virus

Gn(G2)/Gc(G1)



viridae
(continued on
Bayou virus






next page)
Black Creek Canal







virus







Cano Delgadito







virus







Calabazo virus







Catacamas virus







Choclo virus







Dobrava-Belgrade







virus







El Moro Canyon







virus







Hantaan virus







Isla Vista virus







Khabarovsk virus







Laguna Negra







virus







Limestone Canyon







virus







Monongahela virus







Muleshoe virus







Muju virus







New York virus







Oran virus







Playa de Oro







virus







Prospect Hill







virus







Puumala virus







Rio Mamore virus







Rio Segundo virus







Saaremaa virus







Seoul virus







Sin Nombre virus







Soochong virus







Thailand virus







Thottapalayam







virus







Topografov virus







Tula virus






Ortho-bunya-
Anopheles A virus






virus
Anopheles B virus







Bakau virus







Batama virus







Bwamba virus







Caraparu virus







Kaeng Khoi virus







Kairi virus







Madrid virus







Main Drain virus







Marituba virus







Nyando virus







Oriboca virus







Oropouche virus







Sathuperi virus







Shamonda virus







Shuni virus







Simbu virus







Tacaiuma virus







Tete virus







Turlock virus







unclassified







Orthobunyavirus







Akabane virus
Sabo virus







Tinaroo virus







Yaba-7 virus






Bunyamwera virus
Batai virus







Birao virus







Bozo virus







Cache Valley virus







Fort Sherman virus







Germiston virus







Guaroa virus







Iaco virus







Ilesha virus







Lokern virus







Maguari virus







Mboke virus







Ngari virus







Northway virus







Playas virus







Potosi virus







Shokwe virus







Tensaw virus







Tlacotalpan virus







Xingu virus






California
California encephalitis serogroup virus






Encephalitis
LEIV






virus
California encephalitis virus - BFS-283







Chatanga virus







Inkoo virus







Jamestown Canyon virus







Jamestown Canyon-like virus







Jerry Slough virus







Keystone virus







La Crosse virus







Lumbo virus







Melao virus







Morro Bay virus







San Angelo virus







Serra do Navio virus







Snowshoe hare virus







South River virus







Tahyna virus







Trivittatus virus






Caraparu virus
Apeu virus







Bruconha virus







Ossa virus







Vinces virus






Manzanilla virus
Buttonwillow virus







Ingwavuma virus







Mermet virus






Marituba virus
Gumbo Limbo virus







Murutucu virus







Nepuyo virus







Restan virus






Wyeomyia virus
Anhembi virus







BeAr328208 virus







Macaua virus







Sororoca virus







Taiassui virus





Phlebovirus
Bujaru virus







Candiruvirus







Chilibre virus







Frijoles virus







Punta







Tor_|Salehabad







virus







Sandflyfever







Naples virus







Uukuniemi viruso







virus







Rift Valley







fever virus







unclassified
Anhanga virus






Phlebovirus
Arumowot virus






(continued on
Chagres virus






next page)
Corfou virus







Gabek Forest virus







Itaporanga virus







Phlebovirus Adria/ALB1/2005







Phlebovirus Adria/ALB5/2005







Phlebovirus AH12







Phlebovirus AH12/China/2010







Phlebovirus AH15/China/2010







Phlebovirus B105-05







Phlebovirus B151-04







Phlebovirus B43-02







Phlebovirus B68-03







Phlebovirus B79-02







Phlebovirus Chios-A







Phlebovirus Cyprus







Phlebovirus HB29/China/2010







Phlebovirus HN13/China/2010







Phlebovirus HN6/China/2010







Phlebovirus Hu/Xinyang1/China/2010







Phlebovirus Hu/Xinyang2/China/2010







Phlebovirus IB13-04







Phlebovirus JS2007-01







Phlebovirus JS24







Phlebovirus JS26







Phlebovirus JS3/China/2010







Phlebovirus JS4/China/2010







Phlebovirus JS6







Phlebovirus JSD1







Phlebovirus LN2/China/2010







Phlebovirus LN3/China/2010







Phlebovirus sandflies/Gr29/Spain/2004







Phlebovirus sandflies/Gr36/Spain/2004







Phlebovirus sandflies/Gr44/Spain/2004







Phlebovirus sandflies/Gr49/Spain/2004







Phlebovirus sandflies/Gr52/Spain/2004







Phlebovirus sandflies/Gr65/Spain/2004







Phlebovirus sandflies/Gr98/Spain/2004







Phlebovirus SD24/China/2010







Phlebovirus SD4/China/2010







Phlebovirus tick/XCQ-2011







Phlebovirus XLL/China/2009







Rio Grande virus







Salobo virus







Sandfly fever sicilian virus







Sandfly Sicilian Turkey virus







Utique virus







Phlebovirus sp.







Phlebovirus sp. Be An 24262







Phlebovirus sp. Be An 356637







Phlebovirus sp. Be An 416992







Phlebovirus sp. Be An 578142







Phlebovirus sp. Be Ar 371637







Phlebovirus sp. Co Ar 170255







Phlebovirus sp. Co Ar 171616







Phlebovirus sp. GML 902878







Phlebovirus sp. Pa Ar 2381







Phlebovirus sp. PAN 479603







Phlebovirus sp. PAN 483391







Phlebovirus sp. VP-161A







Phlebovirus sp. VP-334K







Phlebovirus sp. VP-366G







Orthomyxo-
Influenzavirus A 
Influenza 
INFA H1
HA
Group 2 Type I


viridae

A virus

(HA1/HA2)
fusion mechanism





INFA H2







INFA H3







INFA H4







INFA H5







INFA H6







INFA H7







INFA H8







INFA H9







INFA H10







INFA H11







INFA H12







INFA H13







INFA H14







INFA H15







INFA H16





Influenzavirus B
Influenza B virus
All strains





Influenzavirus C
Influenza C virus








Paramyxo-
Paramyxovirinae
Avulavirus
Avian paramyxovirus 2 Yucaipa virus
F0



viridae


Avian paramyxovirus 3
(F2/F1)






Avian paramyxovirus 3b







Avian paramyxovirus 4







Avian paramyxovirus 5







Avian paramyxovirus 6







Avian paramyxovirus 7







Avian paramyxovirus 8







Avian paramyxovirus 9







Newcastle disease virus







Pigeon paramyxovirus 1







unclassified Avulavirus







Avian paramyxovirus 10_Avian







paramyxovirus duck/Miyagi/885/05







Avian paramyxovirus penguin/Falkland







Islands/324/2007







Goosramyxovirus HZ







Goose paramyxovirus JS/1/97/Go







Goose paramyxovirus SF02






Henipavirus
Hendra virus Hendra virus







horse/Australia/Hendra/1994







Nipah virus







unclassified Henipavirus







Bat paramyxovirus







Eid.hel/GH45/2008






Morbillivirus
Canine distemper virus







Cetacean morbillivirus_Dolphin







morbillivirus_Pilot whale morbillivirus







Porpoise morbillivirus







Measles virus







Peste-des-petits-ruminants virus







Phocine distemper virus







Phocine distemper virus 1







Phocine distemper virus-2







Rinderpest virus






Respirovirus
Bovine parainfluenza virus 3







Porcine paramyxovirus strain Frost







Porcine paramyxovirus strain Texas







Human parainfluenza virus 1







Human parainfluenza virus 3







Simian Agent 10







Sendai virus







unclassified Respirovirus







Atlantic salmon respirovirus







Guinea pig parainfluenza virus TS-9







Pacific salmon paramyxovirus







Trask River 1983 Swine parainfluenza







virus 3







Tursiops truncatus parainfluenza virus 1






Rubulavirus
Human parainfluenza virus 2







Human parainfluenza virus 2 (strain







Greer)







Human parainfluenza virus 2 (strain







Toshiba)







Human parainfluenza virus 4







Human parainfluenza virus 4a







Human parainfluenza virus 4b







Mapuera virus







Mumps virus







Parainfluenza virus 5







Porcine rubulavirus







Simian virus 41







unclassified Rubulavirus







Porcine parainfluenza virus







Tuhoko virus 1







Tuhoko virus 2







Tuhoko virus 3






unclassified
Atlantic salmon paramyxovirus






Paramyxovirinae
Beilong virus







Canine parainfluenza virus







Chimeric human parainfluenza virus







rPIV3-2







Fer-de-lance virus







J-virus







Menangle virus







Mossman virus







Murayama virus







Ovine parainfluenza virus 3







Pacific salmon paramyxovirus







Paramyxovirus GonoGER85







Recombinant PIV3/PIV1 virus







Reptilian paramyxovirus







Salem virus







Salmo salar paramyxovirus







Snake ATCC-VR-1408 paramyxovirus







Snake ATCC-VR-1409 paramyxovirus







Tioman virus







Tupaia paramyxovirus





Pneumovirus
Human respiratory
Human respiratory syncytial virus A

Group 3




syncytial virus
Human respiratory syncytial virus

Type I fusion mechanism





(strain RSB1734)







Human respiratory syncytial virus







(strain RSB5857)







Human respiratory syncytial virus







(strain RSB6190)







Human respiratory syncytial virus







(strain RSB6256)







Human respiratory syncytial virus







(strain RSB642)







Human respiratory syncytial virus







(strain RSB6614)







Human respiratory syncytial virus A







strain Long LinkOut







Human respiratory syncytial virus A2







Human respiratory syncytial virus B







Human respiratory syncytial







virus (subgroup B/strain 18537)







Human respiratory syncytial virus







(subgroup B strain 8/60)







Human Respiratory syncytial virus 9320







Human respiratory syncytial virus B1







Human respiratory syncytial virus S2







Human respiratory syncytial virus strain







RSS-2







unclassified Human respiratory syncytial







virus






Bovine
All strains

Group 3




respiratory


Type I




syncytial virus


fusion



Metapneum
Avian metapneumo-
All strains






virus







Human metapneumo-
All strains






virus








Corona-
Coronavirinae
Alphacorona-
Alphacoronavirus 1
S
Group 3 Type I


viridae

virus
Coronavirus group 1b
(S1/S2)
fusion mechanism





Human coronavirus 229E







Human coronavirus NL63







Miniopterus bat coronavirus 1







Miniopterus bat coronavirus HKU8







Porcine epidemic diarrhea virus







Rhinolophus bat coronavirus HKU2







Scotophilus bat coronavirus 512







unclassified Alphacoronavirus






Betacorona-
Betacoronavirus 1






virus
Coronavirus group 2b







Coronavirus group 2c







Human coronavirus HKU1







Murine coronavirus







Pipistrellus bat coronavirus HKU5







Rousettus bat coronavirus HKU9







Severe acute respiratory syndrome-







related coronavirus recombinant SARSr-







CoV







SARS coronavirus







Tylonycteris bat coronavirus HKU4







unclassified Betacoronavirus






Gammacorona-
Avian coronavirus






virus
Beluga Whale coronavirus SW1






unclassified
Alpaca coronavirus CA08-1/2008






coronaviruses
Bat coronavirus







Bird droppings coronavirus







Bovine respiratory coronavirus







Chicken enteric coronavirus







Coronavirus Anas







Coronavirus oystercatcher/p17/2006/GBR







Coronavirus red knot/p60/2006/GBR







Ferret enteric coronavirus 1202







Ferret systemic coronavirus MSU-S







Ferret systemic coronavirus WADL







Guangxi coronaviridae







Human coronavirus NO







Human enteric coronavirus strain 4408







Kenya bat coronavirus







Mink coronavirus strain WD1133







Parrot coronavirus AV71/99







Quail coronavirus Italy/Elvia/2005







Tai Forest coronavirus







unidentified coronavirus







unidentified human coronavirus







Arena-
Arena-virus
LCMV-Lassa virus
Ippy virus
GpC
Group 3 Type I


viridae

(Old World)
Lassa virus
(Gp1/Gp2)
fusion mechanism




complex
Lujo virus







Lymphocytic choriomeningitis virus







Mobala virus







Mopeia virus






Tacaribe virus
Amapari virus






(New World)
Chapare virus






complex
Flexal virus







Guanarito virus







Junin virus







Latino virus







Machupo virus







Oliveros virus







Parana virus







Pichinde virus







Pirital virus







Sabia virus







Tacaribe virus







Tamiami virus







Whitewater Arroyo virus







Hepadna-
Genus
Hepatitis B virus
HBV genotype A
L and M and S
Group 3 Fusion


viridae

Orthohepadnavirus
HBV genotype B
Where S mediates fusion
mechanism - Neither





HBV genotype C

type I nor type II





HBV genotype D







HBV genotype E







HBV genotype F







HBV genotype G







HBV genotype H







Hepatitis B virus alpha1







Hepatitis B virus LSH/chimpanzee







Hepatitis B virus strain cpz







Hepatitis B virus subtype adr







Hepatitis B virus subtype adw







Hepatitis B virus subtype adyw







Hepatitis B virus subtype ayw







Rhabdo-
Dimarhabdovirus
Ephemerovirus
Bovine ephemeral fever virus
Glycoprotein G
Group 3


viridae




Neither type I nor







Type II fusion







mechanism




Vesiculovirus
Carajas virus







Chandipura virus







Cocal virus







Isfahan virus







Maraba virus







Piry virus







recombinant Vesiculovirus







Spring viraemia of carp virus







Vesicular stomatitis Alagoas virus







Vesicular stomatitis Indiana virus







Vesicular stomatitis New Jersey virus





Lyssavirus
Aravan virus







Australian bat







lyssavirus







Duvenhage virus







European bat







lyssavirus 1







European bat







lyssavirus 2







Irkut virus







Khujand virus







Lagos bat virus







Mokola virus







West Caucasian







bat virus







Rabies virus
Rabies virus AB21







Rabies virus AB22







Rabies virus AVO1







Rabies virus BNG4







Rabies virus BNG5







Rabies virus China/DRV







Rabies virus China/MRV







Rabies virus CVS-11







Rabies virus ERA







Rabies virus Eth2003







Rabies virus HEP-FLURY







Rabies virus India







Rabies virus Nishigahara RCEH







Rabies virus Ontario fox







Rabies virus Ontario skunk







Rabies virus PM







Rabies virus red fox/08RS-







1981/Udine/2008







Rabies virus SAD B19







Rabies virus silver-haired bat-







associated SHBRV







Rabies virus strain Pasteur vaccin







Rabies virus strain Street







Rabies virus vnukovo-32







Thailand genotype 1 dog lyssavirus






unclassified
Bokeloh bat lyssavirus






Lyssavirus
European bat lyssavirus







Lyssavirus Ozernoe







Shimoni bat virus





Novirhabdovirus
Hirame







rhabdovirus







Infectious







hematopoietic







necrosis virus







Snakehead







rhabdovirus







Viral hemorrhagic







septicemia virus






unassigned
Bangoran virus






Rhabdoviridae
Bimbo virus







Bivens Arm virus







Flanders virus







Garba virus







Klamath virus







Malpais Spring







virus







Nasoule virus







Ngaingan virus







Ouango virus







Sigma virus







Tupaia virus







Wongabel virus









According to an embodiment, the invention concerns a method for identifying an immunosuppressive domain in the fusion protein of an enveloped RNA virus having a lipid membrane, said method comprising:

    • a. Identifying at least one well conserved domain among the group consisting of the membrane associated domains of the fusion protein and the surface associated domains of the fusion protein;
    • b. Providing at least one peptide with the sequence of said identified at least one well conserved domain;
    • c. Optionally dimerizing or multimerizing said at least one peptide; and
    • d. Confirming the immunosuppressive activity of said at least one optionally dimerized or multimerized peptide by testing said at least one optionally dimerized or multimerized peptide for immunosuppressive activity.


The at least one well conserved domain may be identified among domains, which are membrane associated and domains, which are surface associated. Naturally, a domain which is both membrane and surface associated may be a well conserved domain.


The fusion protein may be identified by searching NCBI taxonomy (www.ncbi.nlm.nih.gov/Taxonomy/), and selecting proteins of the Family, Subfamily, Genus or Species to be investigated, and subsequently search these for fusion or the specific name of the fusion protein, e.g. as listed in Table 1.


The dimerized peptide could be synthetic, the multimerized peptide could be displayed as dimerized or trimerized fusion proteins either displayed alone or on membranes such as a viral particle.


One way of testing the immunosuppressive activity of the at least one dimerized or multimerized peptide is to test the immunosuppressive activity of the fusion protein in the absence and presence of the at least one dimerized or multimerized peptide, and comparing the results.


According to other embodiments, the invention concerns the method, wherein the identification of said at least one well conserved domain is done among the group consisting of the surface associated domains of the fusion protein in one or more of the different conformations of the fusion protein undergoing fusion.


According to an embodiment, the invention concerns a method, wherein the enveloped RNA virus is not selected among Retroviruses, Lentiviruses or Filoviruses. In particular, according to an embodiment, the invention concerns a method, wherein said at least one well conserved immunosuppressive domain is not located in the linker between the two heptad repeat structures just N-terminal of the transmembrane domain in the fusion protein of either Retrovirus, Lentivirus or Filovirus. More particularly, according to an embodiment, the invention concerns a method, wherein said at least one well conserved domain does not include some of the 22 amino acids located N-terminal to the first of two well conserved cysteine residues that are found in these structures in the fusion protein of either Retrovirus, Lentivirus or Filovirus. These cysteine residues are between 4 and 6 amino acid residues from one another and in many cases are believed to form disulfide bridges that stabilize the fusion proteins.


According to other embodiments, the invention concerns the method, wherein said at least one well conserved domain is selected among the group consisting of Putative ISUs and Identified ISUs of Table 1 and Seq. Id. 1-200.


According to an embodiment, the invention concerns an immunosuppressive domain identified according to the invention.


According to an embodiment, the invention concerns an immunosuppressive domain selected among the sequences of Table 1 and Seq. Id. 1-200.


According to an embodiment, the invention concerns a method for decreasing or completely abrogating the immunosuppressive properties of an immunosuppressive domain of the fusion protein of an enveloped RNA virus having a lipid membrane, said method comprising the steps of:

    • e. Mutating an immunosuppressive domain to provide at least one mutated peptide;
    • f. Optionally dimerizing or multimerizing said at least one mutated peptide;
    • g. Selecting one of said optionally dimerized or multimerized mutated peptides showing reduced immunosuppressive properties;
    • h. Mutating the fusion protein of the enveloped RNA virus to contain said selected mutated peptide having reduced immunosuppressive properties;
    • i. Confirming expression by testing the viral envelope protein encompassing said mutated fusion protein for capability of being expressed by at least one of cellular or viral surfaces.


The envelope protein may be identified by searching NCBI taxonomy (www.ncbi.nlm.nih.gov/Taxonomy/) and selecting proteins of the Family, Subfamily, Genus or Species to be investigated and subsequently searching these for envelope or the specific name for the envelope protein or the attachment and fusion protein, e.g. as listed in Table 1.


According to other embodiments, the invention concerns the method, wherein:

    • e. Said immunosuppressive domain is mutated to provide a plurality of mutated peptides;
    • f. Said plurality of mutated peptides are optionally dimerized or multimerized;
    • g. One of said optionally dimerized or multimerized mutated peptides showing reduced immunosuppressive properties is selected;
    • h. The fusion protein of the enveloped RNA virus is mutated to contain said selected optionally dimerized or multimerized peptide having reduced immunosuppressive properties;
    • i. Expression is confirmed by testing the viral envelope protein encompassing said mutated fusion protein for capability of being expressed by at least one of cellular or viral surfaces.


According to other embodiments, the invention concerns the method, wherein:

    • g. One of said optionally dimerized or multimerized mutated peptide(s) is selected, which has reduced immunosuppressive properties as shown by at least 25% reduction as compared to a dimerized Wildtype peptide.


According to other embodiments, the invention concerns the method, wherein:

    • e. Said mutated immunosuppressive domain is mutated to provide a knock-out mutant of Table 1 or selected among the sequences of Seq. Id. 201-203.


According to an embodiment, a proven knock-out (i.e. a mutation of the immunosuppressive domain abrogating the immunosuppressive properties of the peptide) from one family, genus, group and/or strain, may be used for another family, genus, group and/or strain.


According to an embodiment, the invention concerns a mutated peptide providing reduced immunosuppressive properties, said mutated peptide having a sequence according to Table 1 or any of Seq. Id.—202 to 203 or obtainable as said selected mutated peptide of a method according to the invention.


Preliminary experiments indicate the immunosuppressive domains may have a size of 4-30 amino acids.


According to an embodiment, the invention concerns a method for generating an enhanced immune response, comprising a method according to the invention, and further comprising the step of:

    • j. Using said viral envelope protein encompassing said mutated fusion protein with reduced immunosuppressive properties as an antigen for generation of an enhanced immune response.


According to an embodiment, the invention concerns a method for making an envelope protein having diminished immunosuppressive activity, comprising:

    • Mutating or modifying an immunosuppressive domain, identifiable according to the invention, of an enveloped RNA virus with a lipid membrane surrounding the core, to include a peptide obtainable according to the invention.


The diminished immunosuppressive activity is suitably measured by comparing to the immunosuppressive activity from an envelope of a wildtype peptide. It is preferably demonstrated by an increased proliferation of at least 25% in a cell proliferation assay of homodimers of said mutated peptide as compared to the homodimers of said non-mutated wildtype peptide at the same concentration. More preferably the cell assay is either the CTLL-2 or the PBMC assay.


According to an embodiment, the invention concerns the method, for making a envelope protein encompassing a mutated fusion protein from a enveloped RNA virus for medical use, such as therapeutic or prophylactic purpose, preferably for use as a vaccine.


According to an embodiment, the invention concerns the method, for making an enveloped protein encompassing a mutated fusion protein from an envelope RNA virus for vaccination purposes or for the generation of neutralizing antibodies.


According to an embodiment, the invention concerns the method, wherein the enveloped RNA virus has a fusion protein with a type II fusion mechanism.


According to an embodiment, the invention concerns the method, wherein the enveloped RNA virus, preferably excluding lentivius, retrovirus and filovirus, has a fusion protein with a type I fusion mechanism and where the immunosuppressive domains co-localizes with the fusion peptide in the fusion protein, preferably as demonstrated by the identification of a common immunosuppressive domain in the fusion peptide of all H1 to H16 of Influenza A and influenza B.


According to an embodiment, the invention concerns the method, wherein the enveloped RNA virus, preferably excluding lentivius, retrovirus and filovirus, has a fusion protein with a type I fusion mechanism excluding viruses with a type I fusion mechanism where the ISU co-localizes with the fusion peptide or the fusion protein has a structure that is neither a type I nor a type II fusion structure.


According to an embodiment, the invention concerns an envelope protein obtainable according to the invention.


The immunosuppressive domain has so far been identified by the inventors at two positions in two different groups of viruses A: Co-localizing with the fusion peptide exemplified by the identification of an common immunosuppressive domain in the fusion peptide of all Flavirus (Dengue virus, west Nile virus etc) and Influenza A and B viruses and B: in the hydrophobic alpha helix N-terminal of the transmembrane domain in the fusion protein exemplified by the finding of an immunosuppressive domain in said helixes of Flaviridae like e.g. Hepatitis C virus, Dengue, WestNile, Yellow fever.


The inventors have realized that the potential immunosuppressive domains are located at various positions in the fusion protein identifiable by

    • 1): The peptide is preferably located in the fusion protein of enveloped RNA viruses;
    • 2): The peptide is preferably capable of interacting with membranes;
    • 3): Preferably a high degree of homology in the primary structure (sequence) of the peptide of said domain exists either within the viral species itself, in the family of viruses or in a group of viruses. This requirement is due to the immunosuppressive domain being under a dual selection pressures, one as an immunosuppressive entity ensuring protection of the viral particle from the host immune system, another as a peptide interacting with membranes; and/or
    • 4): The position at the surface of the fusion protein at a given conformation is preferably a feature of immunosuppressive domains. This can be revealed either by position in a 3D structure or by antibody staining of cells expressing the fusion protein or on viral surfaces displaying the fusion protein.


According to an embodiment, the invention concerns a mutated envelope protein according to the invention.


According to an embodiment, the invention concerns a viral fusion protein from an enveloped RNA virus with reduced immunosuppressive properties, said fusion protein encompassing a mutated peptide, said mutated peptide displaying reduced immunosuppression, and said mutated peptide replacing an un-mutated wildtype peptide having a sequence of an ISU of Table 1 or is selected among Seq. Id. 1-200.


According to an embodiment, the invention concerns the fusion protein, where the reduced immunosuppression is identified by comparing to the un-mutated wildtype peptide when said peptide is dimerized.


According to an embodiment, the invention concerns the fusion protein, wherein said immunosuppressive activity being determined by at least 25% reduction, more preferred at least 40% reduction, in proliferation rate in a cell proliferation assay using a homodimer of said un-mutated peptide compared to the monomeric version of said peptide at the same concentration.


According to an embodiment, the invention concerns the fusion protein, wherein said cell proliferation assay is selected among the group consisting of the CTLL-2 and the PBMC assay.


According to an embodiment, the invention concerns the fusion protein, wherein said fusion protein has a type I or type II fusion mechanism.


According to an embodiment, the invention concerns the fusion protein, wherein said fusion protein has neither a type I nor type II fusion mechanism.


According to an embodiment, the invention concerns the fusion protein, wherein said mutated peptide is located either in the fusion peptide or in a, preferably amphipatic, helix upstream of the C-terminal transmembrane domain of said fusion protein.


The fusion peptide is a small membrane penetrating peptide located in the fusion protein of enveloped viruses.


According to another embodiment, the invention concerns the viral fusion protein, wherein said mutated peptide is derived from the fusion peptide from a flavivirus or Influenzavirus or from the amphipatic helix of the Flaviridae, such as the group consisting of Hepatitis C virus fusion protein, Dengue virus fusion protein, and WestNile virus fusion protein.


According to an embodiment, the invention concerns an envelope protein, said mutated fusion protein being displayed on the surface of cells wherein said mutated fusion protein is expressed.


According to an embodiment, the invention concerns the envelope protein, said mutated fusion protein being displayed on the surface of viral or viral like particles.


According to an embodiment, the invention concerns the envelope protein, having retained some fusiogenic activity.


According to an embodiment, the invention concerns the envelope protein, wherein the fusiogenic activity is measured by a technique for measuring cell-cell fusion, preferably selected among the group consisting of counting syncytia by light microscopy, resonance energy transfer based assays, and indirect reporter gene using techniques or by measuring infectious titers; alternatively, or in addition, the presence of fusiogenic activity may be indicated by the presence of at least one cell expressing the modified envelope and one cell expressing the receptor and/or coreceptors being fused together.


According to an embodiment, the invention concerns an enveloped RNA virus, different from a virus selected among the group consisting of Retrovirus, Lentivirus and Filovirus, wherein an immunosuppressive domain has been modified or mutated to decrease or completely abrogate the immunosuppressive properties of an immunosuppressive domain of the fusion protein.


According to an embodiment, the invention concerns a virus selected among the vira of Table 1, wherein an immunosuppressive domain has been modified or mutated to decrease or completely abrogate the immunosuppressive properties of an immunosuppressive domain of the fusion protein.


According to an embodiment, the invention concerns an antigen obtainable by selecting a part of a mutated envelope protein according to any of the preceding claims, said part comprising the mutated domain of said envelope protein.


According to an embodiment, the invention concerns an antigen comprising an mutated immunosuppressive domain selected among the sequences of Table 1 and Seq. Id. 201 to 202.


According to an embodiment, the invention concerns an antigen of the invention furthermore harboring 1 or 2 or 3 or 4 or 5 or 6 or 7 or 8 or 9 or 10 or 11 point mutation(s) in any of the sequences of Table 1 or of Seq. Id. 1-200.


According to an embodiment, the invention concerns an antigen, which mediates fusion of virus to host cells.


According to an embodiment, the invention concerns an antigen, which is recombinant or obtained by recombinant technology.


According to an embodiment, the invention concerns a nucleic acid sequence, preferably recombinant, encoding a mutated envelope protein, an envelope polypeptide or an antigen according to any of the preceding claims.


According to an embodiment, the invention concerns an isolated eukaryotic expression vector comprising a nucleic acid sequence according to the invention.


According to another embodiment, the invention concerns the vector, which is a virus vector, preferably a virus selected among the group consisting of vaccinia virus, measles virus, retroviridae, lentivirus, baculovirus and adeno virus.


According to an embodiment, the invention concerns a method for producing an antibody, said method comprising the steps of:

    • Administering an entity selected among a mutated envelope, an envelope polypeptide, an antigen, a nucleic acid sequence or a vector according to any of the preceding claims to a host, such as an animal; and
    • Obtaining the antibody from said host.


According to an embodiment, the invention concerns an antibody obtainable according to a method of the invention.


According to another embodiment, the invention concerns an antibody, which is specific for an entity selected among a mutated peptide, an envelope protein, a mutated envelope protein, an antigen, a nucleic acid sequence or a vector according to any of the preceding claims.


According to an embodiment, the invention concerns neutralizing antibodies obtained or identified by the use of at least one envelope protein according to any of the preceding claims.


According to an embodiment, the invention concerns a method for manufacturing neutralizing antibodies comprising the use of at least one protein according to any of the preceding claims.


According to an embodiment, the invention concerns a method for manufacturing humanized neutralizing antibodies, comprising the use of at least one sequence selected among the sequences of Table 1 and sequences 201 to 203


According to an embodiment, the invention concerns a vaccine comprising a virus according to the invention.


According to an embodiment, the invention concerns a vaccine comprising an envelope protein from a virus according to the invention.


According to an embodiment, the invention concerns a vaccine composition comprising an envelope protein according to any of the preceding claims.


According to an embodiment, the invention concerns a vaccine composition comprising a virus like particle (VLP).


According to an embodiment, the invention concerns the vaccine composition, wherein the virus like particle is produced ex vivo in a cell culture.


According to an embodiment, the invention concerns the vaccine composition, wherein the virus like particle is partly or completely assembled ex vivo.


According to an embodiment, the invention concerns the vaccine composition, wherein the virus like particle is generated in vivo in the patient by infection, transfection and/or electroporation by expression vectors.


According to an embodiment, the invention concerns the vaccine composition, comprising a vector derived from a measles or vaccinia virus.


According to an embodiment, the invention concerns the vaccine composition, comprising an expression vector for DNA vaccination.


According to an embodiment, the invention concerns the vaccine composition, comprising a purified envelope protein.


According to an embodiment, the invention concerns the vaccine composition, comprising a multimerized purified envelope protein.


According to an embodiment, the invention concerns the vaccine composition, comprising a dimerized purified envelope protein.


According to an embodiment, the invention concerns the vaccine composition, comprising a trimerized purified envelope protein.


According to an embodiment, the invention concerns a vaccine composition comprising an entity selected among the group consisting of a mutated envelope protein, an envelope polypeptide, an antigen, a nucleic acid sequence, a vector and an antibody according to any of the preceding claims, and in addition at least one excipient, carrier or diluent.


According to an embodiment, the invention concerns the vaccine composition, further comprising at least one adjuvant.


According to an embodiment, the invention concerns a medical composition comprising antibodies raised using a virus according to the invention.


According to an embodiment, the invention concerns a pharmaceutical composition comprising a mutated peptide, an envelope protein, a mutated envelope protein, an antigen, a nucleic acid sequence, a vector, an antibody or a vaccine composition according to any of the preceding claims, and at least one pharmaceutically acceptable excipient, diluents or carrier.


According to an embodiment, the invention concerns a use of a mutated peptide, an envelope protein, a mutated envelope protein, an antigen, a nucleic acid sequence, a vector or an antibody according to any of the preceding claims, for a medical purpose, such as for the treatment, amelioration or prevention of a clinical condition, such as for the manufacture of a medicament for the treatment, amelioration or prevention of a clinical condition.


According to an embodiment, the invention concerns a method of treating or ameliorating the symptoms of an individual, or prophylactic treating an individual, comprising administering an amount of mutated peptide, an envelope protein, a mutated envelope protein, antigen, nucleic acid sequence, vector or vaccine composition according to any of the preceding claims.


According to an embodiment, the invention may be used with human and/or animal vira.


Table 2 below, provides the location of a number of identified immunosuppressive domains.









TABLE 2







Localization of identified immunosuppressive domains









Family (-viridae),




Subfamily (-virinae),




Genus (-virus) or




Species (-virus) of
Localization of prototype



viruses
immunosuppressive domain
Reference





All Flavirus
Protein E
Seligman S J. Constancy and



98-DRGWGNXCGXFGKGXX-113
diversity in the flavivirus




fusion peptide. Virol J. 2008




Feb 14; 5:27.





All Flavirus
Protein E
FIG. 1


(e.g. Dengue 3)
416-GDTAWDFGSVGGVLNSLGK-434
Schmidt A G, Yang P L, Harrison S C.




Peptide inhibitors of




dengue-virus entry target a




late-stage fusion




intermediate. PLoS Pathog.




2010 Apr 8; 6(4): e1000851.





Hepatitis C
E2 (SEQ ID NO: 3)
Albecka A, Montserret R, Krey T,



71-GLIHLHQNIVDVQYLYG-87
Tarr A W, Diesis E, Ball J K,




Descamps V,




Duverlie G, Rey F, Penin F,




Dubuisson J. Identification of




new functional regions in




hepatitis C virus envelope




glycoprotein E2. J Virol. 2011




Feb; 85(4): 1777-92.




Epub 2010 Dec 8.





Influenza A1-16
HA2 (SEQ ID NO: 4)
Cross K J, Wharton S A, Skehel J J,


Influenza B
1-GLFGAIAGFIENGWEG-16
Wiley D C, Steinhauer D A.




Studies on influenza




haemagglutinin fusion peptide




mutants generated by reverse




genetics. EMBO J. 2001




Aug 15; 20(16): 4432-42.









According to an embodiment, an immunosuppressive domain may be identified by its position, e.g. as indicated in Table 2.


According to an embodiment, the invention concerns an immunosuppressive domain identified by its position.


According to an embodiment, the invention concerns an immunosuppressive domain identified by its secondary, tertiary or quaternary structure in the folded fusion protein.


According to an embodiment, the invention concerns an entity selected among the group consisting of a mutated peptide, an envelope protein, a mutated envelope protein, an antigen, a nucleic acid sequence and a vector, wherein an immunosuppressive domain identified by its position, has been modified or mutated in order to suppress its immunosuppressive properties.


All cited references are incorporated by reference.


The accompanying Figures and Examples are provided to explain rather than limit the present invention. It will be clear to the person skilled in the art that aspects, embodiments and claims of the present invention may be combined.


EXAMPLES
Peptide Solutions

The peptides were either dissolved in water or in cases of low water solubility, 5% DMSO solutions were used to dissolve the peptides.


Assay to Measure the Immunosuppressive Activity of Peptides Derived From Viral Surface Proteins or Their Mutants

The peptides can be prepared by different means including, but not limited to, solid phase synthesis commonly used for such purposes. The peptides can be dimerized using a cysteine residue either at the N- or C-terminal or in the middle of the peptide or by using any other molecule or atom that is covalently bound to peptide molecules.


The peptides can be coupled to a carrier protein such as BSA by covalent bounds including, but not limited to, disulfide bridges between the peptide cysteine residues and the carrier protein or through amino groups including those in the side chain or Lysine residues.


The peptides can have non-viral derived amino acids added to their C-terminal for increasing their water solubility.


Assay to Test the Immunosuppressive Activity of Peptides
Experiment Design

Human Peripheral Blood Mononuclear Cells (PBMC) are prepared freshly from healthy donors. These are stimulated by Con A (5 ug/mL) concomitant to peptide addition at different concentrations (i.e. 25 uM, 50 uM and 100 uM). Cultures are maintained and lymphocyte proliferation is measured 72 hrs later by EdU incorporation and Click-iT labelling with Oregon Green (Invitrogen, Denmark) as recommended by the manufacturer. The degree of activated lymphocytes is proportional to the fluorescence detection.


CTLL-2 Assay

100.000 CTLL-2 cells are seeded pr. well in a 48 well-plate (Nunc) in 200 uL of medium (RPMI+2 mM L-glutamine+1 mM Na-pyruvat+10% FCS+0.5 ng/mL IL-2) 2 hours later the peptides are added to the wells. 24 h later the cells are labeled using the Click-it reaction kit (Invitrogen cat. #C35002). The fluorescence of the cells is measured on a flow cytometer. The degree of proliferation in each sample is proportional to the detected fluorescence.


Test of Immunosuppression From Monomer and Dimeric Peptides

100.000 CTLL-2 cells were seeded pr. well in a 48 well-plate (Nunc) in 200 uL of medium (RPMI+2 mM L-glutamine+1 mM Na-pyruvat+10% FCS+0.5 ng/mL IL-2) 2 hours later the peptides were added to the wells. 24 h later the cells were labeled using the Click-it reaction kit (Invitrogen cat. #C35002). The fluorescence of the cells was measured on a flow cytometer. The degree of proliferation in each sample is proportional to the detected fluorescence.


Quantification of Proliferation Inhibition

The degree of inhibition of proliferation of CTLL-2 cells is visualized in the diagrams in the figures. The ratios are calculated by dividing the number of labeled cells (growing cells) in cultures in presence of peptide with cultures in absence of peptides, but added the same volume of the solute that was used to dissolve the peptides. That is in cases where the peptides were dissolved in 5% DMSO, the same volume of 5% DMSO was added to the control cells.


Appendix
Classes of Enveloped RNA Viruses That Contain Human Pathogens
Flaviridae (Type II Fusion)

Flaviviridae have monopartite, linear, single-stranded RNA genomes of positive polarity, 9.6- to 12.3-kilobase in length. Virus particles are enveloped and spherical, about 40-60 nm in diameter.


Major diseases caused by the Flaviviridae family include:

    • Dengue fever
    • Japanese encephalitis
    • Kyasanur Forest disease
    • Murray Valley encephalitis
    • St. Louis encephalitis
    • Tick-borne encephalitis
    • West Nile encephalitis
    • Yellow fever
    • Hepatitis C Virus Infection


Existing Vaccines for Flaviridae

The successful yellow fever 17D vaccine, introduced in 1937, produced dramatic reductions in epidemic activity. Effective killed Japanese encephalitis and Tick-borne encephalitis vaccines were introduced in the middle of the 20th century. Unacceptable adverse events have prompted change from a mouse-brain killed Japanese encephalitis vaccine to safer and more effective second generation Japanese encephalitis vaccines. These may come into wide use to effectively prevent this severe disease in the huge populations of Asia—North, South and Southeast. The dengue viruses produce many millions of infections annually due to transmission by a successful global mosquito vector. As mosquito control has failed, several dengue vaccines are in varying stages of development. A tetravalent chimeric vaccine that splices structural genes of the four dengue viruses onto a 17D yellow fever backbone is in Phase III clinical testing.


Genus Flavivirus

Flaviviruses share a common size (40-65 nm), symmetry (enveloped, icosahedral nucleocapsid), nucleic acid (positive-sense, single stranded RNA approximately 10,000-11,000 bases), and appearance in the electron microscope.


These viruses are transmitted by the bite from an infected arthropod (mosquito or tick). Human infections with these viruses are typically incidental, as humans are unable to replicate the virus to high enough titres to reinfect arthropods and thus continue the virus life cycle. The exceptions to this are yellow fever and dengue viruses, which still require mosquito vectors, but are well-enough adapted to humans as to not necessarily depend upon animal hosts (although both continue have important animal transmission routes as well).


Genus Hepacivirus (type species Hepatitis C virus, the single member)


Hepatitis C is an infectious disease affecting the liver, caused by the hepatitis C virus (HCV). The infection is often asymptomatic, but once established, chronic infection can progress to scarring of the liver (fibrosis), and advanced scarring (cirrhosis), which is generally apparent after many years. In some cases, those with cirrhosis will go on to develop liver failure or other complications of cirrhosis, including liver cancer or life threatening esophageal varices and gastric varices. The hepatitis C virus is spread by blood-to-blood contact. Most people have few, if any symptoms after the initial infection, yet the virus persists in the liver in about 85% of those infected. Persistent infection can be treated with medication, peg-interferon and ribavirin being the standard-of-care therapy. Overall, 51% are cured. Those who develop cirrhosis or liver cancer may require a liver transplant, and the virus universally recurs after the transplant takes place. An estimated 180 million people worldwide are infected with hepatitis C. Hepatitis C is not known to cause disease in other animals. No vaccine against hepatitis C is currently available. The existence of hepatitis C (originally “non-A non-B hepatitis”) was postulated in the 1970s and proven in 1989. It is one of five known hepatitis viruses: A, B, C, D, and E.


The hepatitis C virus is a small (50 nm in size), enveloped, single-stranded, positive sense RNA virus. There are six major genotypes of the hepatitis C virus, which are indicated numerically (e.g., genotype 1, genotype 2, etc.). Based on the NS5 gene there are three major and eleven minor genotypes. The major genotypes diverged about 300-400 years ago from the ancestor virus. The minor genotypes diverged about 200 years ago from their major genotypes. All of the extant genotypes appear to have evolved from genotype 1 subtype 1b.


The hepatitis C virus is transmitted by blood-to-blood contact. In developed countries, it is estimated that 90% of persons with chronic HCV infection were infected through transfusion of unscreened blood or blood products or via injecting drug use or sexual exposure. In developing countries, the primary sources of HCV infection are unsterilized injection equipment and infusion of inadequately screened blood and blood products.


Genus Pestivirus
TogaviridaeType II Fusion

The Togaviridae are a family of viruses, including the following genera:


Genus Alphavirus

Alphaviruses have a positive sense single stranded RNA genome. There are 27 alphaviruses, able to infect various vertebrates such as humans, rodents, fish, birds, and larger mammals such as horses as well as invertebrates. Transmission between species and individuals occurs mainly via mosquitoes making the alphaviruses a contributor to the collection of Arboviruses- or Arthropod Borne Viruses. Alphaviruses particles are enveloped, have a 70 nm diameter, tend to be spherical and have a 40 nm isometric nucleocapsid.


There are two open reading frames (ORF's) in the genome, non-structural and structural. The first is non structural and encodes proteins for transcription and replication of viral RNA, and the second encodes three structural proteins: the core nucleocapsid protein C, and the envelope proteins P62 and E1 that associate as a heterodimer. The viral membrane-anchored surface glycoproteins are responsible for receptor recognition and entry into target cells through membrane fusion. The proteolytic maturation of P62 into E2 and E3 causes a change in the viral surface. Together the E1, E2, and sometimes E3, glycoprotein “spikes” form an E1/E2 dimer or an E1/E2/E3 trimer, where E2 extends from the centre to the vertices, E1 fills the space between the vertices, and E3, if present, is at the distal end of the spike. Upon exposure of the virus to the acidity of the endosome, E1 dissociates from E2 to form an E1 homotrimer, which is necessary for the fusion step to drive the cellular and viral membranes together. The alphaviral glycoprotein E1 is a class II viral fusion protein. The structure of the Semliki Forest virus revealed a structure that is similar to that of flaviviral glycoprotein E, with three structural domains in the same primary sequence arrangement. The E2 glycoprotein functions to interact with the nucleocapsid through its cytoplasmic domain, while its ectodomain is responsible for binding a cellular receptor. Most alphaviruses lose the peripheral protein E3, but in Semliki viruses it remains associated with the viral surface.


Genus Rubivirus
Genus Rubivirus
Bunyaviridae Type II Fusion Mechanism

Bunyaviridae is a family of negative-stranded RNA viruses. Though generally found in arthropods or rodents, certain viruses in this family occasionally infect humans. Some of them also infect plants.


Bunyaviridae are vector-borne viruses. With the exception of Hantaviruses, transmission occurs via an arthropod vector (mosquitos, tick, or sandfly). Hantaviruses are transmitted through contact with deer mice feces. Incidence of infection is closely linked to vector activity, for example, mosquito-borne viruses are more common in the summer.


Human infections with certain Bunyaviridae, such as Crimean-Congo hemorrhagic fever virus, are associated with high levels of morbidity and mortality, consequently handling of these viruses must occur with a Biosafety level 4 laboratory. They are also the cause of severe fever with thrombocytopenia syndrome.


Hanta virus or Hantavirus Hemorrhagic fever, common in Korea, Scandinavia, Russia, and the American southwest, is associated with high fever, lung edema and pulmonary failure. Mortality is around 55%.


The antibody reaction plays an important role in decreasing levels of viremia.


Genus Hantavirus; type species: Hantaan virus


Hantaviruses are negative sense RNA viruses in the Bunyaviridae family. Humans may be infected with hantaviruses through rodent bites, urine, saliva or contact with rodent waste products. Some hantaviruses cause potentially fatal diseases in humans, hemorrhagic fever with renal syndrome (HFRS) and hantavirus pulmonary syndrome (HPS), but others have not been associated with human disease. HPS cannot be transmitted person-to-person. The name hantavirus is derived from the Hantan River area in South Korea, which provided the founding member of the group: Hantaan virus (HTNV), isolated in the late 1970s by Ho-Wang Lee and colleagues. HTNV is one of several hantaviruses that cause HFRS, formerly known as Korean hemorrhagic fever.


Genus Ortho-Bunya-Virus

The orthobunyaviruses are maintained in nature by sylvatic transmission cycles between hematophagous mosquitoes and susceptible mammalian hosts, principally rodents and other small mammals. Several members of the California serogroup of orthobunyaviruses, including La Crosse (LAC) and Tahyna (TAH) viruses, are significant human pathogens. LAC virus is an important cause of pediatric encephalitis and aseptic meningitis in the Midwestern United States where approximately 100 cases are reported annually; TAH virus, indigenous to central Europe, is associated with influenzalike febrile illnesses. La Crosse virus is a NIAID Category B priority pathogen.


The orthobunyaviruses are enveloped, negative-stranded RNA viruses with a tripartite genome comprised of large (L), medium (M), and small (S) segments The M segment encodes three proteins in a single open reading frame (ORF): two surface transmembrane glycoproteins, herein referred to as Gn (G2) and Gc (G1), respectively, to delineate their order in the precursor polyprotein, and NSm, a protein of unknown function. Gn and Gc are thought to associate as a heteromultimer after cleavage of the polyprotein.


Genus Phlebovirus; type species: Rift Valley fever virus


Phlebovirus is one of five genera of the family Bunyaviridae. The Phlebovirus genus currently comprises over 70 antigenically distinct serotypes, only a few of which have been studied. The 68 known serotypes are divided into two groups: the Phlebotomus fever viruses (the sandfly group, transmitted by Phlebotominae sandflies) comprises 55 members and the Uukuniemi group (transmitted by ticks) comprises the remaining 13 members.


Of these 68 serotypes, eight of them have been linked to disease in humans. They are: Alenquer virus, Candiru virus, Chagres virus, Naples virus, Punta Toro virus, Rift Valley fever, Sicilian virus, and Toscana virus. Recently identified is another human pathogenic serotype, the SFTS virus.


Rift Valley Fever (RVF) is a viral zoonosis (affects primarily domestic livestock, but can be passed to humans) causing fever. It is spread by the bite of infected mosquitoes, typically the Aedes or Culex genera. The disease is caused by the RVF virus, a member of the genus Phlebovirus (family Bunyaviridae). The disease was first reported among livestock in Kenya around 1915, but the virus was not isolated until 1931. RVF outbreaks occur across sub-Saharan Africa, with outbreaks occurring elsewhere infrequently (but sometimes severely—in Egypt in 1977-78, several million people were infected and thousands died during a violent epidemic. In Kenya in 1998, the virus claimed the lives of over 400 Kenyans. In September 2000 an outbreak was confirmed in Saudi Arabia and Yemen).


In humans the virus can cause several different syndromes. Usually sufferers have either no symptoms or only a mild illness with fever, headache, myalgia and liver abnormalities. In a small percentage of cases (<2%) the illness can progress to hemorrhagic fever syndrome, meningoencephalitis (inflammation of the brain), or affecting the eye. Patients who become ill usually experience fever, generalized weakness, back pain, dizziness, and weight loss at the onset of the illness. Typically, patients recover within 2-7 days after onset.


Approximately 1% of human sufferers die of the disease. Amongst livestock the fatality level is significantly higher. In pregnant livestock infected with RVF there is the abortion of virtually 100% of fetuses. An epizootic (animal disease epidemic) of RVF is usually first indicated by a wave of unexplained abortions.


Orthomyxoviridae Type I Fusion

The Orthomyxoviridae (orthos, Greek for “straight”; myxa, Greek for “mucus”)] are a family of RNA viruses that includes five genera: Influenzavirus A, Influenzavirus B, Influenzavirus C, Isavirus and Thogotovirus. A sixth has recently been described. The first three genera contain viruses that cause influenza in vertebrates, including birds (see also avian influenza), humans, and other mammals. Isaviruses infect salmon; thogotoviruses infect vertebrates and invertebrates, such as mosquitoes and sea lice.


The three genera of Influenzavirus, which are identified by antigenic differences in their nucleoprotein and matrix protein infect vertebrates as follows:

    • Influenzavirus A infects humans, other mammals, and birds, and causes all flu pandemics
    • Influenzavirus B infects humans and seals
    • Influenzavirus C infects humans and pigs


Paramyxoviridae Type I Fusion Mechanism

The fusion protein F projects from the envelope surface as a trimer, and mediates cell entry by inducing fusion between the viral envelope and the cell membrane by class I fusion. One of the defining characteristics of members of the paramyxoviridae family is the requirement for a neutral pH for fusogenic activity. A number of important human diseases are caused by paramyxoviruses. These include mumps, measles, which caused 745,000 deaths in 2001 and respiratory syncytial virus (RSV) which is the major cause of bronchiolitis and pneumonia in infants and children. The parainfluenza viruses are the second most common causes of respiratory tract disease in infants and children. They can cause pneumonia, bronchitis and croup in children and the elderly.


Human metapneumovirus, initially described in about 2001, is also implicated in bronchitis, especially in children.


genus Paramyxoviruses are also responsible for a range of diseases in other animal species, for example canine distemper virus (dogs), phocine distemper virus (seals), cetacean morbillivirus (dolphins and porpoises) Newcastle disease virus (birds), and rinderpest virus (cattle). Some paramyxoviruses such as the henipaviruses are zoonotic pathogens, occurring naturally in an animal host, but also able to infect humans.


Hendra virus (HeV) and Nipah virus (NiV) in the genus Henipavirus have emerged in humans and livestock in Australia and Southeast Asia. Both viruses are contagious, highly virulent, and capable of infecting a number of mammalian species and causing potentially fatal disease. Due to the lack of a licensed vaccine or antiviral therapies, HeV and NiV are designated as biosafety level (BSL) 4 agents. The genomic structure of both viruses is that of a typical paramyxovirus.


Genus Pneumovirinae





    • Genus Pneumovirus (type species Human respiratory syncytial virus, others include Bovine respiratory syncytial virus)

    • Human respiratory syncytial virus (RSV) is a virus that causes respiratory tract infections. It is the major cause of lower respiratory tract infections and hospital visits during infancy and childhood. A prophylactic medication (not a vaccine) exists for preterm birth (under 35 weeks gestation) infants and infants with a congenital heart defect (CHD) or bronchopulmonary dysplasia (BPD). Treatment is limited to supportive care, including oxygen therapy.

    • In temperate climates there is an annual epidemic during the winter months. In tropical climates, infection is most common during the rainy season.

    • In the United States, 60% of infants are infected during their first RSV season and nearly all children will have been infected with the virus by 2-3 years of age. en.wikipedia.org/wiki/Respiratory_syncytial_virus—cite_note-Glezen86-0 Of those infected with RSV, 2-3% will develop bronchiolitis, necessitating hospitalization Natural infection with RSV induces protective immunity which wanes over time—possibly more so than other respiratory viral infections—and thus people can be infected multiple times. Sometimes an infant can become symptomatically infected more than once, even within a single RSV season. Severe RSV infections have increasingly been found among elderly patients.

    • RSV is a negative-sense, single-stranded RNA virus of the family Paramyxoviridae, which includes common respiratory viruses such as those causing measles and mumps. RSV is a member of the paramyxovirus subfamily Pneumovirinae. Its name comes from the fact that F proteins on the surface of the virus cause the cell membranes on nearby cells to merge, forming syncytia.





Coronaviriridae Type I Fusion

Coronaviruses primarily infect the upper respiratory and gastrointestinal tract of mammals and birds. Four to five different currently known strains of coronaviruses infect humans. The most publicized human coronavirus, SARS-CoV which causes SARS, has a unique pathogenesis because it causes both upper and lower respiratory tract infections and can also cause gastroenteritis. Coronaviruses are believed to cause a significant percentage of all common colds in human adults. Coronaviruses cause colds in humans primarily in the winter and early spring seasons. The significance and economic impact of coronaviruses as causative agents of the common cold are hard to assess because, unlike rhinoviruses (another common cold virus), human coronaviruses are difficult to grow in the laboratory.


Coronaviruses also cause a range of diseases in farm animals and domesticated pets, some of which can be serious and are a threat to the farming industry. Economically significant coronaviruses of farm animals include porcine coronavirus (transmissible gastroenteritis coronavirus, TGE) and bovine coronavirus, which both result in diarrhea in young animals. Feline Coronavirus: 2 forms, Feline enteric coronavirus is a pathogen of minor clinical significance, but spontaneous mutation of this virus can result in feline infectious peritonitis (FIP), a disease associated with high mortality. There are two types of canine coronavirus (CCoV), one that causes mild gastrointestinal disease and one that has been found to cause respiratory disease. Mouse hepatitis virus (MHV) is a coronavirus that causes an epidemic murine illness with high mortality, especially among colonies of laboratory mice. Prior to the discovery of SARS-CoV, MHV had been the best-studied coronavirus both in vivo and in vitro as well as at the molecular level. Some strains of MHV cause a progressive demyelinating encephalitis in mice which has been used as a murine model for multiple sclerosis. Significant research efforts have been focused on elucidating the viral pathogenesis of these animal coronaviruses, especially by virologists interested in veterinary and zoonotic diseases.


SARS-Coronavirus

SARS is most closely related to group 2 coronaviruses, but it does not segregate into any of the other three groups of coronaviruses. SARS was determined to be an early split off from the group 2 coronaviruses based on a set of conserved domains that it shares with group 2. A main difference between group 2 coronovirus and SARS is the nsp3 replicase subunit encoded by ORF1a. SARS does not have a papain-like proteinase 1.


Arenaviridae: Glycoprotein G2 is a Type I Fusion

Arenavirus is a genus of virus that infects rodents and occasionally humans. At least eight Arenaviruses are known to cause human disease. The diseases derived from Arenaviruses range in severity. Aseptic meningitis, a severe human disease that causes inflammation covering the brain and spinal cord, can arise from the Lymphocytic choriomeningitis virus (LCMV) infection. Hemorrhagic fever syndromes are derived from infections such Guanarito virus (GTOV), Junin virus (JUNV), Lassa virus (LASV) causing Lassa fever, Machupo virus (MACV), Sabia virus (SABV), or Whitewater Arroyo virus (WWAV).[1] Arenaviruses are divided into two groups; the Old World or New World. The differences between these groups are distinguished geographically and genetically. Because of the epidemiological association with rodents, some arenaviruses and bunyaviruses are designated as Roboviruses.

    • LCMV-Lassa virus (Old World) complex:
      • Ippy virus
      • Lassa virus
      • Lujo virus
      • Lymphocytic choriomeningitis virus


LCMV infection manifests itself in a wide range of clinical symptoms, and may even be asymptomatic for immunocompetent individuals. Onset typically occurs between one or two weeks after exposure to the virus and is followed by a biphasic febrile illness. During the initial or prodromal phase, which may last up to a week, common symptoms include fever, lack of appetite, headache, muscle aches, malaise, nausea, and/or vomiting. Less frequent symptoms include a sore throat and cough, as well as joint, chest, and parotid pain. The onset of the second phase occurs several days after recovery, and consists of symptoms of meningitis or encephalitis. Pathological findings during the first stage consist of leukopenia and thrombocytopenia. During the second phase, typical findings include elevated protein levels, increased leukocyte count, or a decrease in glucose levels of the cerebrospinal fluid).


Congenital Infection

Lymphocytic choriomeningitis is a particular concern in obstetrics, as vertical transmission is known to occur. For immunocompetent mothers, there is no significant threat, but the virus has damaging effects upon the fetus. If infection occurs during the first trimester, LCMV results in an increased risk of spontaneous abortion. Later congenital infection may lead to malformations such as chorioretinitis, intracranial calcifications, hydrocephalus, microcephaly or macrocephaly, mental retardation, and seizures. Other findings include chorioretinal scars, optic atrophy, and cataracts. Mortality among infants is approximately 30%. Among the survivors, two thirds have lasting neurologic abnormalities. If a woman has come into contact with a rodent during pregnancy and LCM symptoms are manifested, a blood test is available to determine previous or current infection. A history of infection does not pose a risk for future pregnancies.


Human-to-Human Transmission Through Organ Donation

In May 2005, four solid-organ transplant recipients contracted an illness that was later diagnosed as lymphocytic choriomeningitis. All received organs from a common donor, and within a month of transplantation, three of the four recipients had died as a result of the viral infection. Epidemiologic investigation traced the source to a pet hamster that the organ donor had recently purchased from a Rhode Island pet store. A similar case occurred in Massachusetts in 2008. Currently, there is not a LCMV infection test that is approved by the Food and Drug Administration for organ donor screening. The Morbidity and Mortality Weekly Report advises health-care providers to “consider LCMV infection in patients with aseptic meningitis and encephalitis and in organ transplant recipients with unexplained fever, hepatitis, or multisystem organ failure.”


Hepadnaviridae: Fusion Mechanism Neither Type I nor Type II

Hepadnaviruses are a family of viruses which can cause liver infections in humans and animals. There are two recognized genera


Hepadnaviruses have very small genomes of partially double-stranded, partially single stranded circular DNA. The genome consists of two uneven strands of DNA. One has a negative-sense orientation, and the other, shorter, strand has a positive-sense orientation.


As it is a group 7 virus, replication involves an RNA intermediate. Three main open reading frames are encoded (ORFs) and the virus has four known genes which encode the core protein, the virus polymerase, surface antigens (preS1, preS2, and S) and the X protein. The X protein is thought to be non-structural; however, its function and significance are poorly understood.


Rhabdoviridae Fusion Mechanism Neither Type I nor Type II

Rhabdoviruses carry their genetic material in the form of negative-sense single-stranded RNA. They typically carry genes for five proteins: large protein (L), glycoprotein (G), nucleoprotein (N), phosphoprotein (P), and matrix protein (M). Rhabdoviruses that infect vertebrates are bullet-shaped. The prototypical and best studied rhabdovirus is vesicular stomatitis virus.


Rhabdoviruses are important pathogens of animals and plants. Rhabdoviruses include RaV (Rabies virus), VSV (Vesicular stomatitis virus). Rhabdoviruses are transmitted to hosts by arthropods, such as aphids, planthoppers, leafhoppers, black flies, sandflies, and mosquitoes.


The content of the XML file of the sequence listing named “Sequence-Listing-ST26-12397-0504.xml”, having a size of 355 kb and a creation date of 8 Jan. 2024, and electronically submitted via Patent Center on 8 Jan. 2024, is incorporated herein by reference in its entirety.


ADDITIONAL REFERENCES





    • 1. Sapir, A., et al., Viral and developmental cell fusion mechanisms: conservation and divergence. Dev Cell, 2008. 14(1): p. 11-21.

    • 2. Cianciolo, G.J., et al., Murine malignant cells synthesize a 19,000-dalton protein that is physicochemically and antigenically related to the immunosuppressive retroviral protein, P15E. J Exp Med, 1983. 158(3): p. 885-900.

    • 3. Hebebrand, L.C., et al., Inhibition of human lymphocyte mitogen and antigen response by a 15,000-dalton protein from feline leukemia virus. Cancer Res, 1979. 39(2 Pt 1): p. 443-7.

    • 4. Cianciolo, G.J., et al., Macrophage accumulation in mice is inhibited by low molecular weight products from murine leukemia viruses. J Immunol, 1980. 124(6): p. 2900-5.

    • 5. Mangeney, M. and T. Heidmann, Tumor cells expressing a retroviral envelope escape immune rejection in vivo. Proc Natl Acad Sci USA, 1998. 95(25): p. 14920-5.

    • 6. Mangeney, M., et al., Placental syncytins: Genetic disjunction between the fusogenic and immunosuppressive activity of retroviral envelope proteins. Proc Natl Acad Sci USA, 2007. 104(51): p. 20534-9.

    • 7. Cianciolo, G.J., et al., Inhibition of lymphocyte proliferation by a synthetic peptide homologous to retroviral envelope proteins. Science, 1985. 230(4724): p. 453-5.

    • 8. Cianciolo, G.J., H. Bogerd, and R. Snyderman, Human retrovirus-related synthetic peptides inhibit T lymphocyte proliferation. Immunol Lett, 1988. 19(1): p. 7-13.

    • 9. Yaddanapudi, K., et al., Implication of a retrovirus-like glycoprotein peptide in the immunopathogenesis of Ebola and Marburg viruses. Faseb J, 2006. 20(14): p. 2519-30.

    • 10. Haraguchi, S., et al. Differential modulation of Th1-and Th2-related cytokine mRNA expression by a synthetic peptide homologous to a conserved domain within retroviral envelope protein. Proc Natl Acad Sci USA, 1995. 92, 3611-15.

    • 11. Harrell, R.A., et al Cianciolo. Suppression of the respiratoryburst of human monocytes by a synthetic peptide homologous to envelope proteins of human and animal retroviruses. J Immunol, 1986. 136, 3517-520.

    • 12. Kleinerman, E.S., et al. Lachman. A synthetic peptide homologous to the envelope proteins of retroviruses inhibits monocyte-mediated killing by inactivating interleukin 1. J Immunol, 1987. 139, 2329-337.

    • 13. Schlecht-Louf G,. et al. Retro viral infection in vivo requires an immune escape virulence factor encrypted in the envelope protein of oncoretroviruses. Proc Natl Acad Sci USA. 2010 Feb. 23; 107(8):3782-7.

    • 14. Volchkov VE et al. The envelope glycoprotein of Ebola virus contains an 25 immunosuppressive-like domain similar to oncogenic retroviruses. FEBS Lett. 1992 Jul. 6; 305(3):181-4.

    • 15. Cross KJ, Wharton SA, Skehel JJ, Wiley DC, Steinhauer DA. Studies on influenza haemagglutinin fusion peptide mutants generated by reverse genetics. EMBO J. 2001 Aug. 15; 20(16):4432-42.




Claims
  • 1. (canceled)
  • 2. A synthetic peptide comprising a dimeric form of an amino acid sequence, the amino acid sequence comprising a variant of SEQ ID NO:4, said variant differing from SEQ ID NO:4 at 1 or 2 or 3 point mutation(s), wherein each of said point mutation(s) consists of at least one exchange of an amino acid of SEQ ID NO:4 with another amino acid.
  • 3. The synthetic peptide according to claim 2, comprising a cysteine residue at an N-terminal or C-terminal position of the amino acid sequence or synthetic peptide.
  • 4. The synthetic peptide according to claim 3, wherein said amino acid sequence is dimerized through said N-terminal or C-terminal cysteine residue.
  • 5. A synthetic peptide comprising a dimeric form of an amino acid sequence, the amino acid sequence comprising a variant of SEQ ID NO:214, said variant differing from SEQ ID NO:214 at 1 or 2 or 3 or 4 or 5 or 6 or 7 or 8 or 9 or 10 or 11 point mutation(s).
  • 6. The synthetic peptide according to claim 5, wherein said amino acid sequence comprises 1 or 2 or 3 point mutation(s).
  • 7. The synthetic peptide according to claim 5, comprising a cysteine residue at an N-terminal or C-terminal position of the amino acid sequence or synthetic peptide.
  • 8. The synthetic peptide according to claim 7, wherein said amino acid sequence is dimerized through said N-terminal or C-terminal cysteine residue.
  • 9. The synthetic peptide according to claim 5, wherein said amino acid sequence has at least 75% sequence identity to SEQ ID NO:214.
  • 10. The synthetic peptide according to claim 9, comprising a cysteine residue at an N-terminal or C-terminal position of the amino acid sequence or synthetic peptide
  • 11. The synthetic peptide according to claim 10, wherein said amino acid sequence is dimerized through said N-terminal or C-terminal cysteine residue.
  • 12. A nucleic acid sequence encoding the synthetic peptide according to claim 2.
  • 13. A pharmaceutical composition comprising the synthetic peptide according to claim 2.
  • 14. The pharmaceutical composition according to claim 13, further comprising at least one pharmaceutically acceptable excipient, diluent or carrier.
Priority Claims (1)
Number Date Country Kind
PA 2011 70564 Oct 2011 DK national
CROSS-REFERENCE TO RELATED APPLICATIONS

This application is a continuation of U.S. application Ser. No. 17/078,877 filed 23 Oct. 2020, which is a divisional application of U.S. application Ser. No. 15/179,005 filed 10 Jun. 2016, which is a divisional application of U.S. application Ser. No. 14/350,151 filed 7 Apr. 2014, now abandoned, which is the U.S. national phase of PCT/DK2012/050381 filed 5 Oct. 2012, which claims the benefit of U.S. Provisional Appl. No. 61/544,441 filed 7 Oct. 2011 and Danish Appl. No. PA 2011 70564 filed 7 Oct. 2011. Each of the aforementioned applications is hereby incorporated by reference in its entirety.

Provisional Applications (1)
Number Date Country
61544441 Oct 2011 US
Divisions (2)
Number Date Country
Parent 15179005 Jun 2016 US
Child 17078877 US
Parent 14350151 Apr 2014 US
Child 15179005 US
Continuations (1)
Number Date Country
Parent 17078877 Oct 2020 US
Child 18141055 US