John Ghrayeb

Construction and initial characterization of a mouse-human chimeric anti-TNF antibody

Tumor necrosis factor-alpha (TNF) has been implicated in the pathogenesis of a variety of human diseases including septic shock, cachexia, graft-versus-host disease and several autoimmune diseases. Monoclonal antibodies directed against TNF provide an attractive mode of therapeutic intervention in these diseases. We have generated a murine monoclonal antibody (A2) with high affinity and specificity for recombinant and natural human TNF. To increase its therapeutic usefulness, we used genetic engineering techniques to replace the murine constant regions with human counterparts while retaining the murine antigen binding regions. The resulting mouse-human chimeric antibody should have reduced immunogenicity and improved pharmacokinetics in humans. Molecular analysis of light chain genomic clones derived from the murine hybridoma suggests that two different alleles of the same variable region gene have rearranged independently and coexist in the same hybridoma cell. The chimeric A2 antibody (cA2) exhibits better binding and neutralizing characteristics than the murine A2 which was shown to contain a mixture of two kappa light chains. The properties of cA2 suggest that it will have advantages over existing murine anti-TNF antibodies for clinical use.

CD8+ T Cells Mediate Viral Clearance and Disease Pathogenesis during Acute Hepatitis B Virus Infection

ABSTRACT Although the CD4+- and CD8+-T-cell responses to the hepatitis B virus (HBV) are thought to be crucial for the control of HBV infection, the relative contribution of each T-cell subset as an effector of viral clearance is not known. To examine this question, we monitored the course of HBV infection in control, CD4-depleted, and CD8-depleted chimpanzees. Our results demonstrate that CD8+ cells are the main effector cells responsible for viral clearance and disease pathogenesis during acute HBV infection, and they suggest that viral clearance is mediated by both noncytolytic and cytolytic effector functions of the CD8+-T-cell response.

Memory CD8+ T Cells Are Required for Protection from Persistent Hepatitis C Virus Infection

Few hepatitis C virus (HCV) infections resolve spontaneously but those that do appear to afford protective immunity. Second infections are usually shorter in duration and are less likely to persist but mechanisms of virus control in immune individuals have not been identified. In this study we investigated whether memory helper and/or cytotoxic T lymphocytes provide protection in chimpanzees serially reinfected with the virus. Clearance of the first infection took 3–4 mo and coincided with the delayed onset of CD4+ and CD8+ T cell responses. High frequencies of memory T cells targeting multiple HCV proteins were stable over 7 yr of follow-up. Animals were infected for a second time to assess the protective role of memory T cells. In contrast to the prolonged course of the first infection, viremia was terminated within 14 d. Control of this second infection was kinetically linked to rapid acquisition of virus-specific cytolytic activity by liver resident CD8+ T cells and expansion of memory CD4+ and CD8+ T cells in blood. The importance of memory CD8+ T cells in control of HCV infection was confirmed by antibody-mediated depletion of this lymphocyte subset before a third infection. Virus replication was prolonged despite the presence of memory CD4+ T helper cells primed by the two prior infections and was not terminated until HCV-specific CD8+ T cells recovered in the liver. These experiments demonstrate an essential role for memory CD8+ T cells in long-term protection from chronic hepatitis C.

Role of CD8+ Lymphocytes in Control of Simian Immunodeficiency Virus Infection and Resistance to Rechallenge after Transient Early Antiretroviral Treatment

ABSTRACT Transient antiretroviral treatment with tenofovir, (R)-9-(2-phosphonylmethoxypropyl)adenine, begun shortly after inoculation of rhesus macaques with the highly pathogenic simian immunodeficiency virus (SIV) isolate SIVsmE660, facilitated the development of SIV-specific lymphoproliferative responses and sustained effective control of the infection following drug discontinuation. Animals that controlled plasma viremia following transient postinoculation treatment showed substantial resistance to subsequent intravenous rechallenge with homologous (SIVsmE660) and highly heterologous (SIVmac239) SIV isolates, up to more than 1 year later, despite the absence of measurable neutralizing antibody. In some instances, resistance to rechallenge was observed despite the absence of detectable SIV-specific binding antibody and in the face of SIV lymphoproliferative responses that were low or undetectable at the time of challenge. In vivo monoclonal antibody depletion experiments demonstrated a critical role for CD8+ lymphocytes in the control of viral replication; plasma viremia rose by as much as five log units after depletion of CD8+ cells and returned to predepletion levels (as low as <100 copy Eq/ml) as circulating CD8+ cells were restored. The extent of host control of replication of highly pathogenic SIV strains and the level of resistance to heterologous rechallenge achieved following transient postinoculation treatment compared favorably to the results seen after SIVsmE660 and SIVmac239 challenge with many vaccine strategies. This impressive control of viral replication was observed despite comparatively modest measured immune responses, less than those often achieved with vaccination regimens. The results help establish the underlying feasibility of efforts to develop vaccines for the prevention of AIDS, although the exact nature of the protective host responses involved remains to be elucidated.

A nonhuman primate model for the selective elimination of CD8+ lymphocytes using a mouse-human chimeric monoclonal antibody

Nonhuman primates provide valuable animal models for human diseases. However, studies assessing the role of cell-mediated immune responses have been difficult to perform in nonhuman primates. We have shown that CD8+ lymphocyte-mediated immunity in rhesus monkeys can be selectively eliminated using the mouse-human chimeric anti-CD8 monoclonal antibody cM-T807. In vitro, this antibody completely blocked antigen-specific expansion of cytotoxic T cells and decreased major histocompatibility complex class I-restricted, antigen-specific lysis of target cells but did not mediate complement-dependent cell lysis. In vivo administration of cM-T807 in rhesus monkeys resulted in near total depletion of CD8+ T cells from the blood and lymph nodes for up to 6 weeks. This depletion was not solely complement-dependent and persisted longer in adults than in juveniles. Preservation of B cell and CD4+ T cell function in monkeys depleted of CD8+ lymphocytes was demonstrated by their ability to develop humoral immune responses to the administered chimeric monoclonal antibody. Furthermore, during CD8+ lymphocyte depletion, monkeys developed delayed-type hypersensitivity reactions comprised only of CD4+ T cells but not CD8+ T cells. This CD8+ lymphocyte depletion model should prove useful in defining the role of cell-mediated immune responses in controlling infectious diseases in nonhuman primates.

The immunogenicity of the 7E3 murine monoclonal Fab antibody fragment variable region is dramatically reduced in humans by substitution of human for murine constant regions

A murine monoclonal antibody (7E3) directed against the platelet glycoprotein IIb/IIIa was engineered to reduce immunogenicity by substituting human for murine constant regions. The chimeric antibody is functionally identical to the murine antibody in vitro. Results from clinical trials with 7E3 Fab antibody fragments, however, show that the 7E3 variable region, which elicits the vast majority of the immune response to murine 7E3 Fab, is rendered dramatically less immunogenic (incidence reduced from 17% to 1%) when the identical variable region is linked to human rather than murine constant regions. Neither murine nor human constant regions were highly immunogenic themselves. We conclude that the constant regions of the Fab fragments are critical in modulating the immune response elicited by the linked 7E3 variable region. Because naturally occurring anti-human Fab fragment antibodies are prevalent both in the normal human population and in the patient population studied here, murine 7E3 Fab and chimeric 7E3 Fab may be fundamentally different in their interactions with the human immune system. This difference may be related to the dramatic difference in immunogenicity observed between murine 7E3 Fab and chimeric 7E3 Fab.

TNF receptor fusion proteins are effective inhibitors of TNF-mediated cytotoxicity on human KYM-1D4 rhabdomyosarcoma cells.

KYM-1D4 cells are a subline derived from a human rhabdomyosarcoma which are highly sensitive to TNF-mediated cytotoxicity. They were selected for this study because they express human TNF-R and are therefore a more relevant target for comparing the potential therapeutic value of human TNF-inhibitory agents than the usual murine cell lines. Two recombinant soluble TNF-R-IgG fusion proteins, one containing p55 TNR-R, the other containing p75 TNF-R, and a recombinant monomeric soluble p55 TNF-R were all found to block the cytotoxicity generated by human TNF-alpha and LT as well as also murine TNF. The p55 TNF-R-IgG fusion protein (p55-sf2) was the most effective of the antagonists tested, requiring an equimolar, (based on a monomeric configuration of TNF-alpha) or a 3-fold higher (based on a trimeric configuration of TNF-alpha) molar concentration to inhibit the cytotoxicity mediated TNF-alpha by 50%. p55-sf2 was also as effective at inhibiting the cytotoxicity mediated by LT or murine TNF in the KYM-1D4 assay. In contrast, the monomeric soluble p55 TNF-R was the least effective inhibitor, requiring a > 4000-fold higher molar concentration than p55-sf2 to achieve a similar degree of protection. The fusion proteins, particularly p55-sf2, may be useful as human therapeutic agents, as at low concentrations they can prevent both TNF-alpha-mediated and LT-mediated effects on human cells. As TNF-R-IgG fusion proteins also block the action of murine TNF in vitro, they may also be useful in the investigation of murine models of human inflammatory disease.

Neutralization of TNF by the Antibody cA2 Reveals Differential Regulation of Adhesion Molecule Expression on TNF-Activated Endothelial Cells

Upregulation of adhesion proteins plays an important role in mediating inflammation. The induction of adhesive molecules has been well studied, but the reversibility of their expression has not been well characterized. A neutralizing anti-TNF monoclonal antibody (cA2) was used to study the down regulation of TNF-induced E-selectin, vascular cell adhesion molecule-1 (VCAM-1) and intercellular adhesion molecule-1 (ICAM-1) on cultured human umbilical vein endothelial cells (HUVECs). Addition of cA2 following TNF stimulation of HUVECs enhanced the rate of E-selectin and VCAM-1 down-regulation from the cell surface and also reduced steady state E-selectin and VCAM-1 mRNA levels. The cA2-mediated disappearance of E-selectin, but not VCAM-1 protein was microtubule and not microfilament dependent. Neutralization of TNF only slightly reduced ICAM-1 cell surface levels following initial TNF stimulation, suggesting a slower turnover of ICAM-1 compared to E-selectin and VCAM-1. Microtubule inhibition during TNF stimulation partially inhibited E-selectin, VCAM-1 and ICAM-1 mRNA upregulation. VCAM-1 and ICAM-1 cell surface expression were similarly partially inhibited, however, E-selectin levels were unaffected, presumably due to the dual, opposing effect of inhibiting protein expression and inhibiting internalization. Microfilament inhibition during protein induction specifically inhibited the maximal expression of VCAM-1 protein and mRNA, without affecting E-selectin or ICAM-1. These data support the notion that E-selectin, VCAM-1, and ICAM-1 expression are differentially regulated on HUVECs and suggest that TNF neutralizing therapies may be effective because of their ability to reduce the levels of pre-existing adhesion proteins.

Biological characterization of a chimeric mouse-human IgM antibody directed against the 17-1A antigen

SummaryA chimeric antibody was constructed in which the murine H- and L-chain variable regions of mAb 17-1A, raised against human colorectal cancer cells, were joined with the human constant μ and κ regions. Transfection of these constructs into the murine myeloma Sp2/0 resulted in the expression and secretion of a pentameric Ig, designated chimeric 17-1A IgM. The chimeric 17-1A IgM was subsequently compared to a previously described chimeric 17-1A IgG1 for biological activities. Both chimeric mAbs were equally effective (weight basis) in competing against the binding of murine125I-17-1A to cultures of HT-29 colon carcinoma cells. The calculated association constants for the chimeric 17-1A IgM and IgG1 were 1.63 × 108 1/mol and 3.41 × 107 1/mol, respectively. Unlike chimeric 17-1A IgG1, the chimeric 17-1A IgM was able to render colon carcinoma target cells susceptible to lysis by both xenogeneic (rabbit) and human complement. The extent of complement-mediated lysis dependent upon chimeric 17-1A IgM was correlated to 17-1A antigen expression on target cells. HT-29 colon carcinoma cells treated with chimeric 17-1A IgM did not directly result in antibody-dependent cellular cytotoxicity by human peripheral blood monocytes. However, chimeric 17-1A IgM greatly enhanced the deposition of C3 on complementtreated HT-29 cells, and concomitant incubation with monocytes resulted in heightened lysis of the tumor cells. The feasibility of enhancing host defense against gastrointestinal malignancies by the administration of this chimeric 17-1A IgM may have certain clinical advantages.

High-level expression and characterization of a mouse-human chimeric CD4 antibody with therapeutic potential.

The use of murine anti-CD4 monoclonal antibodies (MAbs) has shown considerable promise for the treatment of allograft rejection and rheumatoid arthritis. We have constructed mouse-human anti-CD4 antibodies with the goal of increasing their clinical potential by decreasing immunogenicity and improving effector functions. The chimeric antibodies were constructed by cloning the heavy and light chain variable regions of M-T412, a murine antibody raised against the human CD4 antigen, and joining them to the human G1, G4, or kappa constant regions in mammalian expression vectors. After transfection into mouse myeloma cells, stable cell lines were isolated that secrete up to 140 micrograms/ml chimeric antibody in static culture. The chimeric antibodies were equivalent to the murine antibody in their binding characteristics and relative affinities. However, the chimeric M-T412 MAbs have enhanced activity when compared to the murine G2a MAb in mediating antibody-dependent cell-mediated cytotoxicity using human CD4+ target and effector cells.