Induction of primary antigen-specific immune reponses in SCID-hu-PBL by coupled T-B epitopes.

Adoptive transfer of human lymphoid cells into immunodeficient (SCID) mice lacking the ability to functionally rearrange T- and B-cell receptor genes constitutes a unique model to study and manipulate human immunocytes. We have investigated this model for the purpose of generating an antigen-specific primary humoral immune response. Peripheral blood lymphocytes (PBL) derived from blood donors were used to repopulate SCID mice, which subsequently were immunized with different B-cell epitopes coupled to either tetanus toxoid (TT), or to a promiscuous helper epitope of TT, or by incorporating the antigens into a liposome construct. By recruiting the necessary T-cell help found in the T-cell memory compartment against TT, primary immune responses were obtained against the hapten dinitrophenyl (DNP), the V3 loop peptide derived from glycoprotein (gp120) (HIV-1), the melanoma-associated GD2 ganglioside and ovine submaxillary mucin. The primary immune response against the GD2 ganglioside was induced by incapsulating TT into GD2-containing liposomes. These liposome constructs also allowed us to induce a high human IgG serotitre (3000-4000) against this normally not very immunogenic ganglioside.     

In vitro immunization of naive human B cells yields high affinity immunoglobulin G antibodies as illustrated by phage display.

In vitro antibody responses to a synthetic immunogen, consisting of both a B cell [V3 loop of gp120 from human immunodeficiency virus type 1 (HIV-1)] and a T-helper epitope (15 amino acids of tetanus toxoid) was studied. The in vitro activation was performed by primary and secondary in vitro immunizations, using lymphocytes obtained from uninfected, seronegative donors. Analysis of the in vitro immune response demonstrated an antigen-specific isotype switch, which was dependent on the presence of antigen-specific T-helper cells, CD40 ligation and antigen. Antibody libraries were constructed from cells derived directly from the naive donors, or from primary or secondary in vitro immunized B cells. Five libraries were displayed on filamentous phage and selected for anti-V3-specific Fab fragments, using a selection approach that linked recognition and phage replication. A panel of 19 recombinant antigen-specific Fab. representing different phases of the humoral in vitro immune response were sequenced, expressed and analysed using a biosensor. Recombinant Fab fragments derived from cultures on day 12 exhibited an increase in affinity of close to two orders of magnitude compared to those obtained from cells primary immunized for 7 days. This study provides the first evidence that an antigen-specific in vitro immune response can yield high-affinity immunoglobulinG antibodies.     

Expression of perforin on HIV-1-specific CD8+ lymphocytes after immunization with a gp120-depleted, whole-killed HIV-1 immunogen.

We examined HIV-1 antigen specific intracellular expression of perforin on CD4+ and CD8+ lymphocytes in subjects with chronic HIV-1 infection on antiviral drug therapy after immunization with a gp120-depleted, whole killed HIV-1 immunogen (inactivated, gp120-depleted HIV-1 in IFA, REMUNE). Based upon previous results, we hypothesized that the restoration of adequate T helper immune responses by vaccination against HIV-1 could result in the augmentation of CD8+ lymphocyte immune responses measured as perforin expression. In the current study we observed an increase in the frequency of perforin in CD8+ lymphocytes in HIV infected individuals immunized with a gp120-depleted HIV-1 immunogen while on antiviral drug therapy. Furthermore, the frequency of HIV-specific CD8+ perforin expressing cells correlated with the T helper immune response as measured by the lymphocyte proliferative response (LPR). The induction of such responses with immunization may have direct antiviral consequences and is being studied in ongoing clinical trials.     

Polyepitope protein incorporated the HIV-1 mimotope recognized by monoclonal antibody 2G12

A major goal in HIV-1 vaccine research is to develop an immunogen that can elicit broadly neutralizing antibodies that efficiently neutralize a wide range of the HIV-1 subtypes. Using biopanning procedure we have selected linear peptide VGAFGSFYRLSVLQS mimicking the structure of discontinuous binding sites of broadly neutralizing antibodies 2G12 from phage peptide library. As a protein carrier, we used the earlier designed artificial polyepitope immunogen named TBI (T- and B-cell immunogen), which comprises B-cell and T-helper epitopes from the HIV-1 Env and Gag proteins. On the base of selected peptide mimotope VGAFGSFYRLSVLQS the artificial protein TBI-2g12 was constructed and its immunogenic properties was investigated. It was shown that the TBI-2g12 as well as the original TBI induces antibodies that recognize HIV-1 proteins and TBI protein using ELISA and immunoblotting. However only anti-TBI-2g12 serum recognized the synthetic peptide mimotope VGAFGSFYRLSVLQS, whereas the antibodies against original TBI don't recognize it. The neutralization assay demonstrated that serum antibodies of the mice immunized with TBI-2g12 possess virus neutralizing activity. The addition of selected peptide leads to inhibition neutralizing activity of anti- TBI-2g12 serum. We conclude from these results that immunogen TBI-2g12 containing the selected peptide VGAFGSFYRLSVLQS elicits HIV-1 neutralizing antibodies during immunization. Our data suggest that this immunogen may be useful in designing effective HIV-vaccine candidates.     

Human monoclonal antibodies against a recombinant HIV envelope antigen produced by primary in vitro immunization. Characterization and epitope mapping.

Peripheral blood lymphocytes from healthy, HIV sero-negative blood donors have been in vitro immunized using penv9, a recombinant fragment of the envelope of HIV-1. This primary in vitro immunization followed by Epstein-Barr virus (EBV) transformation and somatic cell fusion subsequently gave rise to several specific anti-penv9 monoclonal antibodies (MO28, MO30 and MO43) of mu isotype. The hybridomas have been kept in culture for over 6 months and the antibody productivity for MO30 was measured to 18 micrograms x (24 hr x 10(6) cells)-1. The fine specificity of the antibodies was mapped by a peptide inhibition enzyme immunoassay, using overlapping synthetic pentadeca peptides covering the whole penv9. These human monoclonal antibodies exhibited a similar epitope specificity directed against a non-sequential determinant, including the amino acids 632-646, 677-681 and 687-691. This specificity is very rarely found in immune sera from seropositive patients and presently not reported in human monoclonal antibodies derived from in vivo immunized individuals, indicating that different antibody specificities can be obtained by the in vitro immunization technology. These human monoclonal antibodies did not neutralize HIV. The results presented here demonstrate the feasability of generating human monoclonal antibodies against HIV by primary in vitro immunizations, thereby avoiding the use of lymphocytes derived from infected patients when human monoclonal antibodies for therapeutic purposes are to be produced.     

人类免疫缺陷病毒-1 gp41免疫原设计、免疫策略及免疫效果的研究进展

人类免疫缺陷病毒(human immunodeficiency virus type,HIV-1)包膜蛋白gp41序列相对保守,其近膜区(MPER)具有一些已知广谱中和抗体(bNAbs)的表位.在HIV疫苗研究中,尽管利用gp41的MPER中和表位进行疫苗设计,但其免疫效果仍不理想.近年发现,一些靶向于gp120和gp41交界面的bNAbs为HIV疫苗的研制提供了新的靶标.如何更好的模拟天然状态的gp41结构以诱导bNAbs的产生仍是学者们的主要研究方向,有大量研究关于靶向于gp41的bNAbs的表位、gp41免疫原的修饰、免疫策略及免疫效果等,因而探讨gp41作为免疫原候选的可行性及提高其免疫效果的方法具有重要意义.     

Induction of antigen-specific isotype switching by in vitro immunization of human naive B lymphocytes

The use of in vitro immunization technology for the generation of human antigen-specific antibodies has essentially resulted in low affinity IgM antibodies, resembling an in vivo primary immune response. We now describe a detailed reproducible protocol for a two-step in vitro immunization, which yields isotype switched, antigen-specific human antibodies. The immunizing antigen was a 30aa synthetic peptide, containing both a B (15aa V3 peptide of the HIV-1) and a T helper cell epitope (15aa peptide from tetanus toxin). The immunization protocol includes: (i) a selection procedure of donors with a memory T cell response against tetatus toxoid; (ii) immunization of mature naive peripheral B lymphocytes in two distinct phases, involving a primary and a secondary step. None of the donors which were examined after primary 7immunization showed at any time an IgG anti-V3 specific antibody response, while all the donors showed an IgM response. After the secondary immunization step, anti-V3 antibodies of both IgM and IgG isotypes were detected. The switch frequency event was high among the tested donors (5/8).     

Antibodies from HIV-positive and AIDS patients bind to an HIV envelope multivalent vaccine

A major problem impeding development of an effective HIV vaccine is the rapid antigenic variability that is characteristic of several envelope glycoprotein epitopes. Frequent mutations alter the composition of the most immunogenic regions of the envelope glycoprotein. We have prepared a synthetic immunogen representing the evolution of the major hypervariable epitopes on the envelope glycoprotein (gp120) of HIV-1. Five synthetic constructs, representing each of the HIV-1 gp120 hypervariable epitopes were tested for recognition by antibodies from patients infected with HIV-1 from different geographic regions worldwide. An HIV-1 human plasma panel provided a representation of the antibodies recognizing subtype-specific epitope sequences prevalent at different parts of the world. The vaccine construct was recognized by antibodies from HIV-1-positive individuals infected with subtypes A, B, C, D, E, and F. Antibodies in pooled HIV-1 patient sera from San Francisco also recognized all five constructs. This complex immunogen was recognized by antibodies in sera from individual HIV-1-positive and AIDS patients from Puerto Rico and Canada, with a strong binding to the complete vaccine and the V3 component. Altogether, our results demonstrate that antibodies from seropositive patients infected with different HIV-1 clades recognize and bind to the HIV hypervariable epitope construct vaccine preparation and its individual components.     

Antigenicity and Predefined Specificities of the Multi-Epitope Vaccine in Candidate Consisting of Neutralizing Epitope and Mutated Epitopes Suggested a New Way against HIV-1 Mutation

A seven-amino acid epitope GPGRAFY located inside the V3 loop on envelope protein gp120 of HIV-1 is the principal neutralizing epitope (PNE), and a subset of anti-V3 antibodies specific for this epitope show a broad range of neutralizing activity. But this epitope undergoes restricted mutation. In this study, three epitope peptides [C-(GPGRAFY)2, C-(GPGQTFY)2 and C-(GPGQAWY)2] that contain neutralizing epitope GPGRAFY and its two mutated epitope GPGQTFY and GPGQAWY, were synthesized and then conjugated to carrier protein KLH (keyhole limpet hemocyanin). the epitope-vaccines C-(GPGRAFY)2-KLH, C-(GPGQTFY)2-KLH and C-(GPGQAWY)2-KLH induced high levels of antibodies to three V3 loop peptides that contain these epitopes respectively, and the antibody response induced by each epitope-vaccine showed predefined epitope-specific. When these three epitope-peptides mixed together and conjugated to carrier protein, or conjugated to carrier protein separately and then mixed together, high levels of epitope-specific antibodies which respectively recognized these epitopes on V3 loop peptide and both mutated peptides all can be induced by both of them. In blotting assay, these epitope-specific antibodies all recognized the neutralizing epitope and mutated epitopes on peptides respectively. In addition, the reactivity of the antibodies with whole gp120 molecule which contained the epitope GPGRAFY was tested. Only the GPGRAFY-epitope-specific antibodies but not the other antibodies recognized the gp120 molecule. These results provide experimental evidence that the candidate multi-epitope-vaccine containing neutralizing epitope and mutated epitopes may bring new hope against viral mutation resulting in HIV-1 immune evasion and may be developed as an effective vaccine with a broad neutralizing activity against HIV-1 infection.     

Mimicking the humoral immune response in vitro results in antigen-specific isotype switching supported by specific autologous T helper cells: generation of human HIV-1-neutralizing IgG monoclonal antibodies from naive donors

Molecular and cellular requirements for antigen-specific isotype switch of human B cells have been investigated by mimicking signaling occurring in germinal centers. Peripheral blood mononuclear cells from healthy seronegative blood donors were first primary immunized in vitro, using a synthetic immunogen containing both a T and B cell epitope, which generated specific IgM-secreting B cells. We used the apex of the V3 loop of gp120 as B cell epitope linked to a promiscuous T helper epitope from tetanus toxin. In parallel, CD4⁺ T helper cell clones specific for the T epitope of the immunogen were established. In a secondary in vitro stimulation period, we co-cultured the antigen-specific T and B cells on CD32-transfected fibroblasts, together with an anti-CD40 monoclonal antibody. This resulted in isotype switching and human antigen-specific, IgG-secreting B cells were detected. This response was strictly dependent upon the presence of autologous T helper cells and the immunogen. Antigen-specific human B cells derived from this primary and secondary in vitro immunization were subsequently subjected to electrofield-induced somatic cell hybridization and hybridomas secreting human anti-V3 IgG monoclonal antibodies were isolated. One human antibody was further characterized and shown to be specific for the immunizing antigen with an affinity constant of 24 nM. This antibody also effectively neutralized different isolates of HIV-1, achieving a 50% neutralization at 0.46 μg/ml.     

Cross-clade neutralizing antibodies against HIV-1 induced in rabbits by focusing the immune response on a neutralizing epitope

Studies were performed to induce cross-clade neutralizing antibodies (Abs) by testing various combinations of prime and boost constructs that focus the immune response on structurally-conserved epitopes in the V3 loop of HIV-1 gp120. Rabbits were immunized with gp120 DNA containing a V3 loop characterized by the GPGR motif at its tip, and/or with gp120 DNA with a V3 loop carrying the GPGQ motif. Priming was followed by boosts with V3-fusion proteins (V3-FPs) carrying the V3 sequence from a subtype B virus (GPGR motif), and/or with V3 sequences from subtypes A and C (GPGQ motif). The broadest and most consistent neutralizing responses were generated when using a clade C gp120 DNA prime and with the V3_B-FP boost. Immune sera displayed neutralizing activity in three assays against pseudoviruses and primary isolates from subtypes A, AG, B, C, and D. Polyclonal Abs in the immune rabbit sera neutralized viruses that were not neutralized by pools of human anti-V3 monoclonal Abs. Greater than 80% of the neutralizing Abs were specific for V3, showing that the immune response could be focused on a neutralizing epitope and that vaccine-induced anti-V3 Abs have cross-clade neutralizing activity.     

Adjuvanticity of stearyl tyrosine on the antibody response to peptide 503-535 from HIV gp160.

In this present report we compare the humoral immune response induced by immunization with an HIV-1 gp160 peptide corresponding to amino acid sequence 503-535 complexed with different adjuvants. Specifically, the antipeptide, anti-HIV-1 gp160 and neutralizing antibody responses were measured in groups of mice and baboons that received peptide 503-535 conjugated to a carrier protein in either saline, alum, or stearyl tyrosine. The highest antibody responses were induced when mice and baboons were immunized with peptide adsorbed on stearyl tyrosine. These data indicate that stearyl tyrosine represents a potent candidate as a nontoxic adjuvant not only for subunit viral vaccines, but also for HIV peptides.     

In vivo induction of cellular and humoral immune responses by hybrid DNA vectors encoding simian/human immunodeficiency virus/hepatitis B surface antigen virus particles in BALB/c and HLA-A2-transgenic mice

To improve the immunogenicity of epitopes derived from Gag proteins of simian immunodeficiency virus (SIV) and from the envelope (Env) protein of human immunodeficiency virus type 1 (HIV-1), we have designed hybrid DNA vaccines by inserting sequences encoding antigenic domains of SIV and HIV-1 into the hepatitis B virus envelope gene. This gene encodes the hepatitis B surface antigen (HBsAg) capable of spontaneous assembly into virus-like particles that were used here as carrier. Injections of hybrid vectors encoding B-cell epitopes from the gp41 and the gp120 envelope proteins of HIV-1 induced specific humoral responses in BALB/c mice. Furthermore, high frequencies of IFN-gamma-secreting CD8+ T cells specific for various antigenic determinants of SIV-Gag were observed after intramuscular injections of hybrid DNA vectors in BALB/c mice. Genetic immunization of HLA-A2.1-transgenic mice with HIV-Env/HBsAg-encoding DNA generated a strong CTL response and IFN-gamma-secreting CD8+ T lymphocytes specific for HIV-1 envelope-derived peptide. H-2d-restricted HBs-specific T-cell responses dominated over SIV-Gag responses in BALB/c mice whereas HLA-A2-restricted HIV-Env response was enhanced after fusion with HBsAg. These data demonstrate that different B and T-cell epitopes of vaccine-relevant viral antigens can be expressed in vivo as fusion proteins with HBsAg but that the optimal immunogenicity may differ strikingly between individual epitopes.     

An optimally constrained V3 peptide is a better immunogen than its linear homolog or HIV-1 gp120

Synthetic peptides offer an attractive option for development of a V3-directed vaccine. However, immunization with flexible linear peptides may result in an immune response to multiple conformations, many of which differ from the native conformation of the corresponding region in the protein. Here we show that optimization of the location of a disulfide bond in peptides constrained to mimic the β-hairpin conformation of the V3, yields an immunogen that elicits a 30-fold stronger HIV-1 neutralizing response in rabbits compared with the homologous linear V3 peptide. The HIV-1 neutralizing response elicited by the optimally constrained peptide is also significantly stronger than that elicited by a gp120 construct in which the V3 is exposed. Neutralization of an HIV-1 strain that shares only 72% identity with the immunizing peptide was demonstrated. The most effective immunogen was also able to neutralize primary isolates that are more resistant to neutralization such as SS1196 and 6535.     

Confronting the hypervariability of an immunodominant epitope eliciting virus neutralizing antibodies from the envelope glycoprotein of the human immunodeficiency virus type 1 (HIV-1).

Antibody mediated and cell mediated immune responses to the envelope glycoproteins gp120 and gp41 of the human immunodeficiency virus (HIV-1) are considered important for protection against infection and for attenuation of disease symptoms after infection. Virus neutralizing antibodies are mostly subtype specific and primarily directed against epitopes on a hypervariable loop from the V3 region of HIV-1 gp120. Such epitopes are recognized by helper and cytotoxic T-cells suggesting that all protective immune responses to HIV-1 are predominantly subtype specific. The extraordinary primary sequence variability of gp120 indicates that a combination of subtype specific components will be required to design a broadly effective protective immunogen against HIV-1. Peptides from hypervariable loops of the V3 region of 21 distinct HIV-1 isolates (clones) were synthesized and used to raise rabbit antisera. The antisera contained high levels of antibodies recognizing the homologous peptides and the parent gp120 sequence. The serological cross-reactivity between the distinct peptides was evaluated and related to amino acid divergence. The corresponding relationship approximated a linear regression with a correlation coefficient r = 0.718. The 21 peptides were combined into a single immunogen which elicited broadly reactive antibodies recognizing all 21 peptides as well as gp120 from the only isolate tested, HIV-1 IIIB. The results suggest the possibility of developing broadly protective HIV-1 immunogens by combining judiciously selected subtype specific peptides derived from envelope glycoproteins of divergent virus isolates.     

Immunization with subunit human immunodeficiency virus vaccine generates stronger T helper cell immunity than natural infection.

Healthy, human immunodeficiency virus seronegative (HIV-) volunteers were multiply immunized with a recombinant gp160 (rgp160) candidate acquired immunodeficiency syndrome (AIDS) vaccine. Peripheral blood lymphocytes from volunteers immunized with 40 micrograms or with 80 micrograms (two volunteers per group) of rgp160, as well as from control donors, were tested for T helper (Th) cell function either prior to immunization, 8 to 12 months after the third immunization, or 2 to 5 months after the fourth immunization. The Th cell functional tests included antigen-induced in vitro interleukin 2 (IL 2) production and proliferation in response to influenza A virus (FLU) and to four synthetic peptides of HIV gp120 and gp160, previously demonstrated to be recognized by T cells from HIV naturally infected patients. Our results demonstrate the following: (a) immunization of HIV- individuals with rgp160 results in IL 2 production and T cell proliferation in response to HIV determinants; (b) boosting with rgp160 enhances Th function; (c) HIV-specific Th function is up to 100-fold greater in the multiply immunized volunteers than that observed in asymptomatic, HIV-infected individuals; and (d) multiple immunization with rgp160 does not impair Th function to a non-HIV antigen such as influenza A virus. These results indicate that immunization of uninfected individuals with an HIV subunit vaccine results in much stronger Th cell immunity than does natural infection and suggests that vaccination against HIV may be possible.     

Fine specificity of the murine antibody response to HIV-1 gp160 determined by synthetic peptides which define selected epitopes.

In this report, we assess the humoral immune response in inbred strains of mice immunized with baculovirus-derived recombinant HIV-1 gp160 (rgp160). Six inbred strains of mice were each immunized with two different concns (5 and 50 micrograms) of rgp160, and the antibody response to rgp160 and synthetic peptides which define distinct gp160 epitopes was examined. Within a given inbred strain of mice, no significant difference in antibody titers to gp160 was observed in those groups receiving either 5 or 50 micrograms of rgp160 per injection. Following three immunizations with rgp160, differences in anti-gp160 titers were observed among the various inbred strains; however, these differences became less apparent after additional injections with rgp160. In addition, each mouse strain exhibited a unique reactivity pattern to seven gp160 epitopes defined by synthetic peptides. Multiple injections with rpg160 were required to induce responses to certain gp160 epitopes. The observed differences in the fine specificity of the humoral immune response to distinct gp160 epitopes among the six inbred strains suggest a genetic basis for regulating the antibody response to these epitopes. This apparent regulation can be overcome by multiple injections with rgp160.     

Sequence similarity between human immunodeficiency virus type 1 envelope protein (gp120) and human proteins: a new hypothesis on protective antibody production

The production of neutralizing antibodies against the central portion of HIV-1 gp120 requires cooperation between T cell and B cell epitopes of this region. We found a motif common to the carboxyterminus of the second conserved region of HIV-1 gp120 and sequences of some human proteins, most of which participate in immune response. The sequence of gp120 of HTLV-IIIB with the highest T-cell reactivity incorporates this motif. It is suggested that the existence of this sequence motif in the central region of the HIV-1 gp120 molecule prevents the production of neutralizing antibodies against the virus in humans.     

Epitopes for broad and potent neutralizing antibody responses during chronic infection with human immunodeficiency virus type 1

Neutralizing antibody (nAb) response is sporadic and has limited potency and breadth during infection with human immunodeficiency virus type 1 (HIV-1). In rare cases, broad and potent nAbs are actually induced in vivo. Identifying specific epitopes targeted by such broad and potent nAb response is valuable in guiding the design of a prophylactic vaccine aimed to induce nAb. In this study, we have defined neutralizing epitope usage in 7 out of 17 subjects with broad and potent nAbs by using targeted mutagenesis in known neutralizing epitopes of HIV-1 glycoproteins and by using in vitro depletion of serum neutralizing activity by various recombinant HIV-1 glycoproteins. Consistent with recent reports, the CD4 binding site (CD4BS) is targeted by nAbs in vivo (4 of the 7 subjects with defined neutralizing epitopes). The new finding from this study is that epitopes in the gp120 outer domain are also targeted by nAbs in vivo (5 of the 7 subjects). The outer domain epitopes include glycan-dependent epitopes (2 subjects), conserved nonlinear epitope in the V3 region (2 subjects), and a CD4BS epitope composed mainly of the elements in the outer domain (1 subject). Importantly, we found indication for epitope poly-specificity, a dual usage of the V3 and CD4BS epitopes, in only one subject. This study provides a more complete profile of epitope usage for broad and potent nAb responses during HIV-1 infection.