Gene targeting in normal somatic cells: inactivation of the interferon-gamma receptor in myoblasts.

Gene targeting in somatic cells represents a potentially powerful method for gene therapy, yet with the exception of pluripotent mouse embryonic stem (ES) cells, homologous recombination has not been reported for a well characterized, non-transformed mammalian cell. Applying a highly efficient strategy for targeting an integral membrane protein--the interferon gamma receptor--in ES cells, we have used homologous recombination to target a non-transformed somatic cell, the mouse myoblast, and to compare targeting efficiencies in these two cell types. Gene-targeted myoblasts display the properties of normal cells including normal morphology, ability to differentiate in vitro, stable diploid karyotype, inability to form colonies in soft agar and lack of tumorigenicity in nude mice.

Antigen-specific human monoclonal antibodies from mice engineered with human Ig heavy and light chain YACs.

We describe a strategy for producing human monoclonal antibodies in mice by introducing large segments of the human heavy and kappa light chain loci contained on yeast artificial chromosomes into the mouse germline. Such mice produce a diverse repertoire of human heavy and light chains, and upon immunization with tetanus toxin have been used to derive antigen-specific, fully human monoclonal antibodies. Breeding such animals with mice engineered by gene targeting to be deficient in mouse immunoglobulin (Ig) production has led to a mouse strain in which high levels of antibodies are produced, mostly comprised of both human heavy and light chains. These strains should provide insight into the adoptive human antibody response and permit the development of fully human monoclonal antibodies with therapeutic potential.

An M2 muscarinic receptor subtype coupled to both adenylyl cyclase and phosphoinositide turnover.

To investigate whether a particular receptor subtype can be coupled to multiple effector systems, recombinant M2 muscarinic receptors were expressed in cells lacking endogenous receptor. The muscarinic agonist carbachol both inhibited adenylyl cyclase and stimulated phosphoinositide hydrolysis. The stimulation of phosphoinositide hydrolysis was significantly less efficient and more dependent on receptor levels than the inhibition of adenylyl cyclase. Both responses were mediated by guanine nucleotide binding proteins, as evidenced by their inhibition by pertussis toxin; the more efficiently coupled adenylyl cyclase response was significantly more sensitive. Thus, individual subtypes of a given receptor are capable of regulating multiple effector pathways.

Blocking of HIV-1 infectivity by a soluble, secreted form of the CD4 antigen.

The initial event in the infection of human T lymphocytes, macrophages, and other cells by human immunodeficiency virus (HIV-1) is the attachment of the HIV-1 envelope glycoprotein gp120 to its cellular receptor, CD4. As a step toward designing antagonists of this binding event, soluble, secreted forms of CD4 were produced by transfection of mammalian cells with vectors encoding versions of CD4 lacking its transmembrane and cytoplasmic domains. The soluble CD4 so produced binds gp120 with an affinity and specificity comparable to intact CD4 and is capable of neutralizing the infectivity of HIV-1. These studies reveal that the high-affinity CD4-gp120 interaction does not require other cell or viral components and may establish a novel basis for therapeutic intervention in the acquired immune deficiency syndrome (AIDS).

The MHC-binding and gp120-binding functions of CD4 are separable.

CD4 is a cell surface glycoprotein that is thought to interact with nonpolymorphic determinants of class II major histocompatibility (MHC) molecules. CD4 is also the receptor for the human immunodeficiency virus (HIV), binding with high affinity to the HIV-1 envelope glycoprotein, gp120. Homolog-scanning mutagenesis was used to identify CD4 regions that are important in class II MHC binding and to determine whether the gp120 and class II MHC binding sites of CD4 are related. Class II MHC binding was abolished by mutations in each of the first three immunoglobulin-like domains of CD4. The gp120 binding could be abolished without affecting class II MHC binding and vice versa, although at least one mutation examined reduced both functions significantly. These findings indicate that, while there may be overlap between the gp120 and class II MHC binding sites of CD4, these sites are distinct and can be separated. Thus it should be possible to design CD4 analogs that can block HIV infectivity but intrinsically lack the ability to affect the normal immune response by binding to class II MHC molecules.

Neutralization of the AIDS retrovirus by antibodies to a recombinant envelope glycoprotein.

Mammalian cell lines have been engineered to produce a secreted form of the AIDS retrovirus envelope glycoprotein. The recombinant protein has been isolated from growth-conditioned culture media and used to immunize animals. Antibodies directed against the recombinant molecule were found to react with the envelope glycoprotein produced in virus-infected cells. Furthermore, these antibodies were able to directly inactivate the AIDS retrovirus in a neutralization assay in vitro. The expression system reported here should provide sufficient quantities of the AIDS retrovirus envelope protein for biological and vaccination studies.

HIV-infected cells are killed by rCD4-ricin A chain.

The gp120 envelope glycoprotein of the human immunodeficiency virus (HIV), which is expressed on the surface of many HIV-infected cells, binds to the cell surface molecule CD4. Soluble derivatives of recombinant CD4 (rCD4) that bind gp120 with high affinity are attractive vehicles for targeting a cytotoxic reagent to HIV-infected cells. Soluble rCD4 was conjugated to the active subunit of the toxin ricin. This conjugate killed HIV-infected H9 cells but was 1/1000 as toxic to uninfected H9 cells (which do not express gp120) and was not toxic to Daudi cells (which express major histocompatibility class II antigens, the putative natural ligand for cell surface CD4). Specific killing of infected cells can be blocked by rgp120, rCD4, or a monoclonal antibody to the gp120 binding site on CD4.

Primary structure and biochemical properties of an M2 muscarinic receptor.

A partial amino acid sequence obtained for porcine atrial muscarinic acetylcholine receptor was used to isolate complementary DNA clones containing the complete receptor coding region. The deduced 466-amino acid polypeptide exhibits extensive structural and sequence homology with other receptors coupled to guanine nucleotide binding (G) proteins (for example, the beta-adrenergic receptor and rhodopsins); this similarity predicts a structure of seven membrane-spanning regions distinguished by the disposition of a large cytoplasmic domain. Stable transfection of the Chinese hamster ovary cell line with the atrial receptor complementary DNA leads to the binding of muscarinic antagonists in these cells with affinities characteristic of the M2 receptor subtype. The atrial muscarinic receptor is encoded by a unique gene consisting of a single coding exon and multiple, alternatively spliced 5' noncoding regions. The atrial receptor is distinct from the cerebral muscarinic receptor gene product, sharing only 38% overall amino acid homology and possessing a completely nonhomologous large cytoplasmic domain, suggesting a role for the latter region in differential effector coupling.

Two distinct families of human and bovine interferon-alpha genes are coordinately expressed and encode functional polypeptides.

The classical human interferon-alpha (HuIFN-alpha) gene family is estimated to consist of 15 or more nonallelic members which encode proteins sharing greater than 77% amino acid sequence homology. Low-stringency hybridization with a HuIFN-alpha cDNA probe permitted the isolation of two distinct classes of bovine IFN-alpha genes. The first subfamily (class I) is more closely related to the known HuIFN-alpha genes than to the second subfamily (class II) of bovine IFN-alpha genes. Extensive analysis of the human genome has revealed a HuIFN-alpha gene subfamily corresponding to the class II bovine IFN-alpha genes. The class I human and bovine IFN-alpha genes encode mature IFN polypeptides of 165 to 166 amino acids, whereas the class II IFN-alpha genes encode 172 amino acid proteins. Expression in Escherichia coli of members of both gene subfamilies results in polypeptides having potent antiviral activity. In contrast to previous studies which found no evidence of class II IFN-alpha protein or mRNA expression, we demonstrate that the class I and class II IFN-alpha genes are coordinately induced in response to viral infection.

A discrete element 3' of human immunodeficiency virus 1 (HIV-1) and HIV-2 mRNA initiation sites mediates transcriptional activation by an HIV trans activator.

An important point of regulation in the reproductive growth and latency of the human and simian immunodeficiency viruses (HIV and SIV, respectively) is provided by virally encoded trans-activators (tat), proteins capable of dramatically increasing viral gene expression. The mechanism of this autostimulatory pathway has remained unclear, however, with substantial effects having been reported at the level of either mRNA accumulation, translational efficiency, or both. Our previous findings indicated that trans-activation results primarily from induction of RNA levels but could not distinguish between the roles of transcriptional rate, RNA stabilization, and RNA transport in this event. In addition, the boundaries of tat-responding elements, which would be valuable in elucidating the mode of tat action, are not precisely known. In this study, HIV-1 and HIV-2 long terminal repeat-directed expression was characterized by using an in vitro nuclear transcription assay to clarify this mechanism, and a detailed mutational analysis was undertaken to localize precisely the sequences participating in this process. Two key findings were revealed: an increased transcription rate was the primary event in tat-mediated activation of HIV-1 and HIV-2, and trans-activation was impaired by mutations in two regions, the TATA box and sequences between +19 to +42, a region lacking enhancer activity. These results implicate a discrete 3' regulatory element in the transcriptional activation of the HIVs.

Functional diversity of muscarinic receptor subtypes in cellular signal transduction and growth.

The regulation of cellular signal transduction and growth by four human muscarinic acetylcholine receptor (mAChR) subtypes has been studied comparatively. The four mAChRs fall into two functional sub-groups, based on their primary effects on second messenger formation; two of the receptors strongly inhibit adenylyl cyclase activity, whereas the other two strongly stimulate PI hydrolysis. Studies on mAChR regulation of two cellular events involved in cellular growth regulation, the transcription of proto-oncogene c-fos and DNA synthesis, indicate that these events are efficiently activated by those mAChRs which couple primarily to phospholipase C.

Production of antigen-specific human antibodies from mice engineered with human heavy and light chain YACs.

Our paper describes the introduction of large fragments of both the human heavy and light chain Ig genes into the mouse germline to create a mouse strain capable of producing a broad repertoire of antigen-specific, fully human antibodies. The human immunoglobulin gene sequences were functional in the context of the mouse machinery for antibody recombination and expression, either in the presence or absence of functional endogenous genes. This was demonstrated by their ability to undergo diverse rearrangement, to be expressed at significant levels, and to exclude expression of mouse immunoglobulins irrespective of their copy number or site of integration. The decrease in susceptibility to influence by adjacent genomic sequences may reflect the greater size, variable gene content, or structural integrity of the human Ig YACs and/or the presence of unidentified but important regulatory elements needed for optimal expression of the human immunoglobulin genes and their correct regulation. Our results show that mouse B cells coexpressing human heavy and kappa chains, upon immunization, can produce antigen-specific, fully human antibodies. Furthermore, the human heavy and kappa chain YACs induced differentiation and maturation of the growth-arrested B-cell lineage in mice with inactivated endogenous Ig genes, leading to the production of a diverse repertoire of fully human antibodies at levels approaching those in normal serum. These results suggest the potential value of these mice as a source of fully human antibodies for human therapy. Furthermore, it is expected that such mice would lack immunological tolerance to and thus readily yield antibodies to human proteins, which may constitute an important class of targets for monoclonal antibody therapy. Our findings suggest that the introduction of even larger portions of the human heavy and light chain loci, which should be achievable with the ES cell-yeast spheroplast fusion technology described, will result in strains of mice ultimately capable of recapitulating the full antibody repertoire characteristic of the human humoral response to infection and immunization. The present and future mouse strains may prove to be valuable tools for studying the molecular mechanisms and regulatory sequences influencing the programmed assembly and expression of human antibodies in the normal immune response, as well as the abnormal response characteristic of autoimmune disease and other disorders. The strategy we have described for the introduction of large segments of the human genome into mice in conjunction with the inactivation of the corresponding mouse loci may also have broad applicability to the investigation of other complex or uncharacterized loci.

The CD4-gp120 interaction and AIDS pathogenesis.

Infection by the human immunodeficiency virus (HIV) leads to progressive destruction of the CD4+ subset of T lymphocytes, resulting in immunodeficiency and AIDS. The selectivity of CD4+ cell destruction is due to the specific binding of gp120, the external envelope glycoprotein of HIV, to CD4, initiating viral entry. Binding of gp120 to CD4 on the cell surface may also lead to CD4+ cell depletion by inappropriate immune targeting, and may interfere with CD4+ cell function and ontogeny by disrupting CD4-mediated cell signaling. The CD4-gp120 interaction is thus an obvious target for AIDS therapeutics.

Regulation of mRNA accumulation by a human immunodeficiency virus trans-activator protein.

HIV LTR-directed expression is markedly stimulated in trans by coexpression of a region of the HIV genome encoding a portion of the tat reading frame. Transient expression assay analysis reveals that trans-activation of LTR-directed expression results primarily from an increase in mRNA accumulation. Deletion analysis of the LTR indicates that upstream promoter and enhancer elements are dispensible for trans-activation, while sequences 3' of the RNA start site displaying strict orientation and position dependence are required. These sequences, contained in the 5' leader of all HIV transcripts, form a stable stem-loop structure with twofold symmetry in the cognate mRNA. Analysis of mutations in the trans-acting region demonstrates that the trans-activator is the protein product of the tat gene, identified biochemically in HIV-infected and transfected cells as an Mr 15,000 polypeptide. We discuss possible mechanisms whereby the interaction of p15tat with the dyad element promotes the accumulation of LTR-directed mRNA.

Acetylcholine analogue stimulates DNA synthesis in brain-derived cells via specific muscarinic receptor subtypes.

Little is known about the factors which regulate the growth and development of the mammalian brain. Although proliferation of neuronal cells ceases relatively early in development, certain types of glial cells proliferate and differentiate mainly perinatally. In the perinatal period, the ability of acetylcholine to stimulate phosphoinositide (PI) hydrolysis in brain reaches peak levels, and indeed the stable acetylcholine analogue carbachol can stimulate PI hydrolysis of primary neonatal astroglial cells. As PI hydrolysis is thought to be important in the regulation of cell proliferation, we investigated whether cellular DNA synthesis can be induced by carbachol. Our results show that carbachol stimulates DNA synthesis via muscarinic acetylcholine receptors (mAChRs), in primary astrocytes derived from perinatal rat brain, in an age-dependent fashion. Carbachol is also mitogenic in certain brain-derived astrocytoma and neuroblastoma cell lines, as well as in chinese hamster ovary (CHO) cells expressing recombinant muscarinic receptors. DNA synthesis is strongly activated by carbachol in those brain-derived cell lines and transfected CHO cells that express mAChR subtypes which activate PI hydrolysis efficiently, and poorly activated in cells expressing mAChR subtypes which only weakly activate PI hydrolysis. These results strongly support a role for acetylcholine in regulating astroglial cell growth in the developing brain, and indicate that the specificity of acetylcholine-induced cell proliferation may be determined by the expression of those mAChR subtypes which activate PI hydrolysis.

Trans-activation of HIV-1 LTR-directed gene expression by tat requires protein kinase C.

Human immunodeficiency virus (HIV) spends a significant part of the viral life cycle as a latent provirus integrated into the host genome. Activation of latent HIV-1 requires mitogenic stimulation of the cell, which increases basal viral transcription, and the HIV-1 tat protein. As tat itself dramatically increases HIV-1 gene expression, it too is presumably regulated in the latent state, and may also be activated by mitogenic stimulation. We show here that depletion of protein kinase C (PKC), which is essential to the stimulation of T cells by several mitogens, dramatically reduces HIV-1 transactivation without affecting synthesis of tat protein. Transactivation in PKC-depleted cells can be restored by transfection with a PKC expression vector. The requirement for PKC in trans-activation does not involve the PMA-responsive enhancer elements responsible for the effect of mitogens on basal transcription. Our results indicate that PKC regulates the process of HIV-1 transactivation, suggesting a key role for the mitogenic induction of trans-activation in the transition of HIV from latency to productive growth.

Differential regulation of PI hydrolysis and adenylyl cyclase by muscarinic receptor subtypes.

Muscarinic acetylcholine receptors (mAChRs), like many other neurotransmitter and hormone receptors, transduce agonist signals by activating G proteins to regulate ion channel activity and the generation of second messengers via the phosphoinositide (PI) and adenylyl cyclase systems. Human mAChRs are a family of at least four gene products which have distinct primary structures, ligand-binding properties and patterns of tissue-specific expression. To examine the question of whether functional differences exist between multiple receptor subtypes, we have investigated the ability of each subtype to regulate PI hydrolysis and adenylyl cyclase when expressed individually in a cell lacking endogenous mAChRs. We show that the HM2 and HM3 mAChRs efficiently inhibit adenylyl cyclase activity but poorly activate PI hydrolysis. In contrast, the HM1 and HM4 mAChRs strongly activate PI hydrolysis, but do not inhibit adenylyl cyclase, and in fact can substantially elevate cAMP levels. Interestingly, the subtypes that we find to be functionally similar are also more similar in sequence. Our results indicate that the different receptor subtypes are functionally specialized.