United States Patent:  6,117,653

Assignee:  Medeva Holdings B.V. (Amsterdam, NL)

Filed:  June 7, 1995

HBV surface antigen particles, prepared by recombinant DNA technology are described, said particles being composed of epitopes from the group of surface peptides and/or core peptide of non-A, non-B hepatitis virus, hepatitis virus A and/or hepatitis virus B. Respective particles are especially characterized by a composition of different epitopes selected from pre-S and S peptides. There are also described DNA-sequences, plasmids and cell lines coding for respective HBV surface antigen particles as well as a new vaccine containing the same.

SUMMARY OF THE INVENTION

The term "HBV S peptide" as used herein refers to the peptide encoded by the entire S region of the HBV genome. The term "HVB pre-S₂ peptide" as used herein refers to the peptide encoded by the entire pre-S₂ and S regions of the HBV genome. The term "HBV pre-S₁ peptide" as used herein refers to the polypeptide encoded by the entire pre-S₁, pre-S₂ and S regions of the HBV genome. The term "epitope" as used herein refers to a sequence of at least six consecutive amino acids encoded by the designated genome region (e.g., a "HBV pre-S₂ epitope" refers to a sequence of at least six amino acids encoded by the pre-S₂ region of the HBV genome). As used herein "antigenicity" means the ability to provoke an immune response (e.g., acting as a vaccine or an antigen), the ability to cause the production of antibodies (e.g. acting as an antigen) and/or the ability to interact with a cell surface receptor so as to enhance an immune response or production of antibodies (e.g., reacting with a T-cell surface receptor to enhance immune response).

The term "HBV" means any subtype of the virus, particularly adw, ayw, adr and ayr, described in the literature (P. Valenzuela, Nature Vol. 280, p. 815 (1979), Gerlich, EP-A-85 111 361, Neurath, EP-A-85 102 250). 

In accordance with the present invention, recombinant DNA molecules are disclosed which comprise a first DNA sequence and a second DNA sequence. The first DNA sequence encodes for expression of an amino acid sequence a portion of which displays the antigenicity of an epitope selected from the group consisting of an HBV pre-S₁ epitope and an HBV pre-S₂ epitope. The second DNA sequence encodes for expression of a peptide which upon secretion will form particles which are at least 10 nm in diameter. These particles are believed to be the smallest particles which will effectively form a good vaccine. Preferably the peptide which upon secretion will form particles which are at least 10 nm in diameter is either HBV S peptide, HBV core antigen, polio surface antigen, Hepatitis A surface antigen, Hepatitis A core antigen, HIV surface antigen and HIV core antigen. A substantial portion or all of the HBV S peptide is especially preferred as the peptide encoded by the second DNA sequence. In the recombinant DNA molecules encoding for the first and second DNA sequences must be (1) in the same reading frame, (2) encode for respective discrete regions of a single peptide, and (3) be operatively linked to an expression control sequence. Finally, these recombinant DNA molecules are free of DNA sequences encoding for the expression of the entire HBV pre-S₁ peptide or HBV pre-S₂ peptide.

Specific recombinant DNA molecules of the present invention are also disclosed wherein the first DNA sequence comprises a nucleotide sequence corresponding to the nucleotide sequence of (1) the HBV pre-S₁ and pre-S₂ regions from which the pre-S₂ start codon ATG has been deleted, (2) the HBV pre-S₁ and pre-S₂ regions and wherein the sequences flanking the pre-S₁ ATG have been changed from the natural sequence, (3) the HBV pre-S₁ and pre-S₂ regions and wherein the sequences flanking the pre-S₂ ATG have been changed from the natural sequence, (4) the HBV pre-S₁ and pre-S₂ regions and wherein the 5' terminus of the pre-S₁ region has been deleted, (5) the HBV pre-S₁ and pre-S₂ regions and wherein the 5' terminus of the pre-S₂ region has been deleted, (6) the HBV pre-S₁ region and wherein the 3' terminus of the pre-S₁ region has been deleted, (7) the HBV pre-S₂ region has been deleted, (8) the HBV pre-S₁ and pre-S₂ regions from which the pre-S₂ ATG has been deleted and the second DNA sequence comprises a sequence corresponding to the nucleotide sequence of the HBV S region from which the S ATG has been deleted, and/or (a) an oligonucleotide.

Host cells transfected with the recombinant DNA molecules of the present invention are also disclosed. As used herein, "transfected" or "transfection" refer to the addition of exogenous DNA to a host cell whether by transfection, transformation or other means. Host cells include any unicellular organism capable of transcribing and translating recombinant DNA molecules including without limitation mammalian cells, bacteria and yeast. Host cells of the present invention may also be cotransfected with a second recombinant DNA molecule comprising a DNA sequence encoding for expression of an amino acid sequence corresponding to a substantial portion or all of the amino acid sequence of the HBV S peptide.

Peptides are also disclosed comprising a first discrete region and a second discrete region. The first region displays the antigenicity of an epitope of an HBV pre-S₁ epitope or an HBV pre-S₂ epitope. The second region correspond to a substantial portion of a peptide which upon secretion will form particles which are at least 10 nm in diameter. Preferably the peptide which upon secretion will form particles which are at least 10 nm in diameter is either HBV S peptide, HBV core antigen, polio surface antigen, Hepatitis A surface antigen, Hepatitis A core antigen, HIV surface antigen and HIV core antigen. A substantial portion or all of the HBV S peptide is especially preferred. Preferably, the first region is located closer to the N-terminus of the peptide than the second region.

Immunogenic particles are also disclosed which comprise a plurality of first peptide monomers. Each of said first peptide monomers comprises a first discrete region and a second discrete region which can be the same as the first and second discrete regions of the peptides described above. Immunogenic particles are also disclosed which further comprise a plurality of second peptide monomers and wherein the first and second peptide monomers are bound together by interactive forces between the monomers. Each of said second peptide monomers comprising an amino acid sequence corresponding to a substantial portion of or all of the amino acid sequence of the HBV S peptide.

Immunogenic particles are also disclosed which contain substantially more than one percent, preferably more than five percent, of the pre-S₁ epitope. As used herein, a particle "contains one percent" of a designated epitope if peptide monomers having the designated epitope constitute one percent of all protein in the particle. Immunogenic particles which contain substantially more than ten percent, preferably more than fifteen percent, of the pre-S₂ epitope are also disclosed.

Pharmaceutical preparations and preparations useful for production of antibodies comprising the above-described immunogenic particles in sufficient concentration to elicit an immune response upon administration of said preparation and a suitable carrier are also disclosed. Suitable carriers are known to those skilled in the art and may include simple buffer solutions.

Other preparations useful for production of antibodies are disclosed comprising the above-described immunogenic particles in sufficient concentration to elicit an immune response upon administration of said preparation and a suitable carrier. Suitable carriers are known to those skilled in the art and may include simple buffer solutions.

A process for producing a transfected host cell is disclosed which comprises providing host cells which have been made competent for uptake of DNA, exposing the host cells to a first preparation of DNA comprising one of the above-described recombinant DNA molecules, allowing under suitable conditions the host cells to take up DNA from the first preparation of DNA, and selecting for host cells which have taken up exogenous DNA. The process may further comprise exposing the host cells to a second preparation of DNA comprising a DNA molecule encoding for a peptide including the amino acid sequence of the HBV S peptide and allowing under suitable conditions the host cells to take up DNA from the second preparation of DNA. The exposure and uptake of the second preparation of DNA can be done before or after exposure to and uptake of the first DNA preparation. Alternatively, the first DNA preparation can also include a DNA molecule encoding for a peptide including the amino acid sequence of the HBV S peptide.

A method for producing a peptide is also disclosed which comprises preparing an above-described recombinant DNA molecule, transfecting a host cell with the recombinant DNA molecule, culturing the host cell under conditions allowing expression and secretion of protein by the host cell, and collecting the peptide produced as a result of expression of DNA sequences within the recombinant DNA molecule. The peptide produced by such method can contain less than the entire amino acid encoded by the coding region of the recombinant DNA molecule. This may result from transcription and/or translation of only a portion of the coding region of the recombinant molecule or by deletions made in the peptide after translation.

A method of producing immunogenic particles is disclosed comprising preparing an above-described recombinant DNA molecule, transfecting a host cell with the recombinant DNA molecule, culturing the host cell under conditions allowing expression and secretion of protein by the host cell, and allowing under suitable conditions the aggregation of peptide monomers produced as a result of expression of exogenous DNA sequence within the host cell. A method of producing immunogenic particles is also disclosed which further comprises transfecting (cotransfection) the host cell with a DNA molecule encoding for a peptide including the amino acid sequence of the HBV S peptide. The cotransfection can occur before, after or simultaneous with the transfection of the above-described recombinant DNA molecule. Presence of peptides encoded by the cotransfected DNA molecule are necessary to obtain more than trace amounts of particles secreted from the host cell.

Methods of manufacturing a pharmaceutical preparation and a preparation useful for production of antibodies are disclosed comprising preparing an above-described recombinant DNA molecule, transfecting a host cell with the recombinant DNA molecule, culturing the host cell under conditions allowing expression and secretion of protein by the host cell, allowing under suitable conditions the aggregation of peptides produced as a result of expression of DNA sequences within the host cell to form immunogenic particles, and combining the immunogenic particles with a suitable carrier such that the immunogenic particles are present in sufficient concentration to cause production of antibodies upon administration of a preparation to an individual. Host cells used in these methods can also be cotransfected as previously described.

Claim 1 of 15 Claims

1. A vaccine comprising a particle comprising a polypeptide, wherein the polypeptide is prepared by recombinant DNA processes from gene constructs in cultured host cells, and wherein the polypeptide comprises:

a first amino acid sequence, wherein the first amino acid sequence comprises all or a portion of the sequence of amino acids 1 to 47 of an HBV pre-S1 peptide and exhibits the antigencity of an HBV pre-S1 epitope; and

a second amino acid sequence, wherein the second amino acid sequence comprises all or a portion of an HBV surface antigen peptide having the capacity to be assembled into particles; and

wherein the polypeptide:

does not comprise the entire sequence of amino acids of an HBV pre-S1 peptide;

exhibits antigenicity of the HBV pre-S1 epitope; and

when produced from the gene constructs in the cultured host cells, retains the capacity of the second amino acid sequence to be assembled into particles.

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