Secretion of glycosylation site mutants can be rescued by the signal/pro sequence of tissue plasminogen activator.

Strategies that prevent the attachment of N-linked carbohydrates to nascent glycoproteins often impair intracellular transport and secretion. In the present study, we describe a method to rescue the intracellular transport and secretion of glycoproteins mutagenized to delete N-linked glycosylation sites. Site-directed mutagenesis was used to delete N-linked glycosylation sites from a chimeric protein, TNFR-IgG1. Deletion of any of the three glycosylation sites in the TNFR portion of the molecule, alone or in combination, resulted in a moderate or near total blockade of TNFR-IgG1 intracellular transport and secretion. Pulse chase experiments suggested that the glycosylation site mutants accumulated in the endoplasmic reticulum (ER) and were inefficiently exported to the Golgi apparatus (GA). Replacement of the TNFR signal sequence with the signal/pro sequence of human tissue plasminogen activator (tPA) overcame the blockade to intracellular transport, and restored secretion to levels comparable to those achieved with the fully glycosylated molecule. Ligand binding studies suggested that the secreted glycosylation variants possessed binding characteristics similar to the fully glycosylated protein. This study demonstrates that N-terminal sequences of tPA are unexpectedly efficient in facilitating transport from the ER to the GA and suggests that these sequences contain a previously unrecognized structural element that promotes intracellular transport.

A humanized, bispecific immunoadhesin-antibody that retargets CD3+ effectors to kill HIV-1-infected cells.

We have developed a humanized, bispecific immunoadhesin-antibody (BsIAb) that targets and kills HIV-infected cells. Comprised of CD4-IgG and humanized anti-CD3-IgG, this BsIAb is bifunctional. First, in targeting, it exploits the natural affinity of CD4 for gp120 to target the BsIAb to HIV-infected cells, and second, it recruits and activates, through its anti-CD3 moiety, cytotoxic T lymphocytes (CTL) to lyse target cells in a non-MHC restricted manner. To produce purified BsIAb from supernantants of transfected mammalian cells, we designed a three-step recovery scheme based on the structural elements of this heterotrimeric protein. The ability of purified BsIAb to specifically lyse HIV-infected target cells was demonstrated using CTL from two different sources: whole peripheral blood lymphocyte (PBL) fractions and pure CTL preparations. In contrast, a human anti-gp120 antibody mediated lysis of HIV-infected target cells only with PBL fractions and not with purified CTL. Moreover, lysis observed in the presence of the human anti-gp120 antibody was completely blocked in the presence of human serum (which competes for Fc gamma receptor binding), whereas BsIAb-mediated lysis of target cells was not affected. We measured the monovalent affinities of BsIAb for HIV-gp120 on infected cells and for CD3 epsilon on CTL. Relative to the bivalent parent molecules, CD4/gp120 affinity in the BsIAb is unchanged, whereas anti-CD3/CD3 is substantially decreased. We further demonstrated by fluorescence microscopy that physical association of CD3+ cells with gp120-expressing cells occurs only in the presence of BsIAb. Thus, the cytocidal activity of BsIAb in the presence of serum reflects its unique ability to recruit CTL as effector cells and highlights a potentially important advantage of this type of construct over antibodies for HIV-directed therapy.

A humanized, bispecific immunoadhesin-antibody that retargets CD3+ effectors to kill HIV-1-infected cells.

HIV infection depletes the immune system of the coordinating functions of CD4+ T cells and APCs, whereas the population of CD8+ CTLs remains largely intact: functional but undirected. We have developed a humanized bispecific immunoadhesin-antibody (BIA) that redirects these remaining T cells to kill HIV-infected cells. This BIA expresses effector cell retargeting via a targeting activity that exploits the natural affinity of CD4 for gp120, and a recruiting activity that employs an anti-CD3 moiety to engage CTLs. The resultant molecule is 97% human in origin. In functional tests, this BIA mediated killing of HIV-infected cells using either pure CTL preparations, or whole PBL fractions that additionally include Fc gamma receptor-bearing large granular lymphocyte effectors. In contrast, a human anti-gp120 Ab induced target lysis via Ab-dependent cellular cytotoxicity (ADCC) only with large granular lymphocyte-containing fractions and not with CTLs. ADCC with this Ab was blocked in human serum, whereas BIA-mediated effector cell retargeting lysis of HIV-infected cells by CTLs was preserved. The affinity of the BIA for HIV-gp120 on infected cells and for CD3 epsilon on CTLs was derived in a flow cytometric Scatchard procedure. Relative to the bivalent parent molecules, CD4/gp120 affinity on cells was unchanged in the BIA (Ka 7 x 10(7) M-1), whereas the anti-CD3 affinity was diminished 50-fold (Ka 2 x 10(6) M-1 vs 1 x 10(8) M-1). Physical association of CD3+ effectors and gp120-expressing targets was confirmed by fluorescence microscopy and was dependent upon the presence of BIA and expression of target gp120. The unimpaired cytocidal activity of the BIA in the presence of serum highlights a potentially important advantage of this type of construct over native Abs for HIV-directed therapy.

Modification of CD4 immunoadhesin with monomethoxypoly(ethylene glycol) aldehyde via reductive alkylation.

CD4 immunoadhesin (CD4-IgG) is a chimeric glycoprotein molecule comprised of the gp120-binding portion of human CD4 fused to the hinge and Fc portions of human IgG. As a candidate for human therapeutic use, CD4-IgG represents an important advance over soluble CD4, insofar as the systemic clearance in humans of CD4-IgG is significantly slower. In an effort to prolong its in vivo residence time even further, we have modified CD4-IgG chemically by attaching monomethoxypoly(ethylene glycol) (MePEG) moieties to lysine residues via reductive alkylation. We synthesized MePEG aldehyde and investigated reaction conditions for adding a range of MePEG moieties per protein molecule. At neutral pH in the presence of sodium cyanoborohydride, the reaction was sufficiently slow to allow for significant control over the extent of MePEGylation. Addition of 7.7 or 14.4 MePEG moieties to CD4-IgG resulted in an approximately 4- or 5-fold increase, respectively, in the persistence of the protein in rats, as compared with unmodified CD4-IgG. These results suggest that the therapeutic utility of a human receptor IgG chimera can be improved by MePEGylation technology, provided that the modified immunoadhesin retains its biological activity in vivo. Such modification can lead to a significant additional increase in the in vivo residence time of the protein.

Inhibition of interferon-gamma by an interferon-gamma receptor immunoadhesin.

Interferon-gamma (IFN-gamma) is an important cytokine which regulates inflammatory and immune response mechanisms. IFN-gamma enhances the presentation and recognition of antigens by inducing the expression of major histocompatibility complex (MHC) proteins, by activating effector T cells and mononuclear phagocytes, and by modulating immunoglobulin production and class selection in B cells. Inappropriate production of IFN-gamma has been implicated in the pathogenesis of several autoimmune and inflammatory diseases and in graft rejection. Here, we describe a recombinant inhibitor of IFN-gamma, termed murine IFN-gamma receptor immunoadhesin (mIFN-gamma R-IgG). We constructed this immunoadhesin by linking the extracellular portion of the mouse IFN-gamma R to the hinge and Fc region of an IgG1 heavy chain. Murine IFN-gamma R-IgG is secreted by transfected cells as a disulphide-bonded homodimer which binds IFN-gamma bivalently, with high affinity and in a species-specific manner. In vitro, mIFN-gamma R-IgG can block mIFN-gamma-induced antiviral activity and expression of the class I MHC antigen H-2Kk in cultured cells. In vivo, mIFN-gamma R-IgG can block the function of endogenous mIFN-gamma in mouse models of infection with Listeria monocytogenes and of contact sensitivity. These results show that mIFN-gamma R-IgG is an effective and specific inhibitor of mIFN-gamma both in vitro and in vivo. Thus, in general, IFN-gamma receptor immunoadhesins may be useful for investigating the biological functions of IFN-gamma as well as for preventing deleterious effects of IFN-gamma in human disease.

Conjugation of soluble CD4 without loss of biological activity via a novel carbohydrate-directed cross-linking reagent.

Chemical conjugates of recombinant soluble CD4 (sCD4) with toxins, or with antibodies that activate cytotoxic T cells, can be used to direct selective killing of human immunodeficiency virus (HIV)-infected cells. This approach takes advantage of the ability of sCD4 to bind with high affinity to gp120, the envelope protein of HIV-1, which is expressed on actively infected cells. However, conjugation of sCD4 via reagents that target amino groups may reduce its affinity for gp120, since at least one such group is important for gp120 binding. Here, we describe a novel cross-linking reagent which enables the conjugation of sCD4 via its carbohydrate moieties rather than its free amino groups. This heterobifunctional reagent, 4-(4-N-maleimidophenyl)butyric acid hydrazide (MPBH), combines a nucleophilic hydrazide with an electrophilic maleimide, thereby allowing coupling of carbohydrate-derived aldehydes to free thiols. We describe conditions by which MPBH is coupled selectively to the sialic acid residues of sCD4, and exemplify the use of MPBH by conjugating sCD4 to hemoglobin and to beta-galactosidase. We show that, whereas conjugation of sCD4 via amino groups markedly reduces its gp120 binding affinity, conjugation via the carbohydrate chains using MPBH does not affect binding. Moreover, we demonstrate the ability of a sCD4-MPBH-fluorescein conjugate to label HIV-infected human CEM cells selectively. These results indicate that, by targeting its carbohydrate moieties, sCD4 can be cross-linked to other molecules without compromising its function. The approach described here can be useful for glycoproteins in which amino groups, but not carbohydrates, are important for function. More generally, this approach can be considered for use in cross-linking glycoconjugates to compounds which either contain thiols, or to which thiols can be added.

Enzymatic cleavage of a CD4 immunoadhesin generates crystallizable, biologically active Fd-like fragments.

CD4, the cell-surface receptor for the human immunodeficiency virus (HIV), is a member of the immunoglobulin (Ig) gene superfamily. It contains four extracellular sequences homologous to Ig VL domains. The first of these (V1) is sufficient for binding to HIV; however, the structural basis for this binding has yet to be elucidated. While several models for the structure of Ig-like domains in CD4 have been proposed on the basis of crystal structures of Ig VL domains, direct evidence that CD4 and VL domains fold similarly has not been obtained. To produce individual domains of CD4 for structural studies, we used molecular fusions of such domains with Ig heavy chain (CD4 immunoadhesins), which are very efficiently expressed and secreted in mammalian cells and can be easily isolated in single-step purification with protein A. Since these fusion molecules are antibody-like homodimeric proteins, we investigated the possibility that they might be cleaved enzymatically to produce Fd-like and Fc fragments. We found that cleavage with papain releases an Fd-like fragment containing the V1 and V2 CD4 domains; this fragment fully retains the ability to bind to the HIV-1 envelope glycoprotein gp120 and to block HIV infection in vitro. Moreover, folding of the CD4 domains in the Fd-like fragment and in the parent immunoadhesin is indistinguishable, as indicated by circular dichroism. Spectral analysis of the Fd-like fragment suggests that secondary structure content is identical with that predicted from the known structure of Ig VL domains; this directly supports the hypothesis that the V1 and V2 domains of CD4 fold similarly to Ig VL domains.(ABSTRACT TRUNCATED AT 250 WORDS)