CD4 molecules on human cells function as a major receptor for human immunodeficiency virus (HIV); however, certain CD4-negative cell types may also be susceptible to infection. Therefore, we attempted to quantitate the relationship between HIV infection and CD4 expression on human cell lines before and after introduction of the CD4 gene by using a retrovirus vector. Prior to introduction of the CD4 expression vector, low levels of HIV infection were detected by a sensitive focal immunoassay on all three cell types studied. With several HIV strains in clones of human cervical carcinoma (HeLa) cells expressing different levels of CD4, HIV titer increased with increasing CD4 expression. In contrast, in squamous cell carcinoma cells (SCL1) and astroglial cells (U87MG), even high levels of CD4 expression failed to augment HIV infection. The CD4 protein expressed in these two cell lines had the expected molecular weight and was capable of binding HIV virions. However, in contrast to CD4-positive HeLa cells, CD4-positive U87MG and SCL1 cells were unable to form syncytia when cultured with cells expressing HIV envelope protein. Thus, the inability of HIV to infect these cells appeared to be due to lack of fusion between HIV virion envelope proteins and CD4-positive cell membranes. This block is infectivity was overcome when cells were infected with HIV which was pseudotyped with the envelope protein of amphotropic murine leukemia virus. Thus, in addition to CD4, other cell surface molecules appear to be required for successful HIV entry into and infection of these two human cell lines.
Previous studies have indicated that scrapie infection results in the accumulation of a proteinase K-resistant form of an endogenous brain protein generally referred to as prion protein (PrP). The molecular nature of the scrapie-associated modification of PrP accounting for proteinase K resistance is not known. As an approach to understanding the cellular events associated with the PrP modification in brain tissue, we sought to identify proteinase K-resistant PrP (PrP-res) in scrapie-infected neuroblastoma cells in vitro and to compare properties of PrP-res with those of its normal proteinase K-sensitive homolog, PrP-sen. PrP-res was detected by immunoblot in scrapie-infected but not uninfected neuroblastoma clones. Densitometry of immunoblots indicated that there was two-to threefold more PrP-res than PrP-sen in one infected clone. Metabolic labeling and membrane immunofluorescence experiments indicated that PrP-sen was located on the cell surface and could be removed from intact cells by phosphatidylinositol-specific phospholipase C and proteases. In contrast, PrP-res was not removed after reaction with these enzymes. Thus, either the scrapie-associated PrP-res was not on the cell surface or it was there in a form that is resistant to these hydrolytic enzymes. Attempts to detect intracellular PrP-res by immunofluorescent staining of fixed and permeabilized cells revealed that PrP was present in discrete perinuclear Golgi-like structures. However, the staining pattern was similar in both scrapie-infected and uninfected clones, and thus the intracellular staining may have represented only PrP-sen. Analysis of scrapie infectivity in cells treated with extracellular phospholipase, proteinase K, and trypsin indicated that, like PrP-res, the scrapie agent was not removed from the infected cells by any of these enzymes.
An immunotoxin has been made by coupling anti-human immunodeficiency virus (HIV) envelope antibody 907 to ricin A chain (907-RAC). 907 recognizes an epitope within the immunodominant PB-1 loop of gp120. Variant cells were selected by cloning persistently infected H9/human T lymphocyte virus IIIB cells in the presence of the immunotoxin. Clones resistant to 907-RAC arose at a frequency of 0.1-1.0%. Seven clones were selected for intensive analysis. When studied, these clones fell into two distinct groups, members of which appeared to be identical, suggesting that the variation arose before the selection process. In contrast to the parent cells, none of the cloned variants produced infectious HIV. The first set of clones, designated the "E" variants, expressed decreased levels of the HIV envelope on the cell surface. However, levels of intracellular HIV antigens and reverse transcriptase were equal to or greater than that of the parental cell line. Radioimmunoprecipitation demonstrated that the gp160 was truncated to 145 kD (gp120 was normal length), capable of binding to CD4, and, unlike normal gp160, was released in its unprocessed form into the cellular supernatant. Sequence analysis demonstrated that a deletion at codon 687 of the envelope gene resulted in the production of this truncated protein. Ultrastructural analysis of E variants demonstrated some budding forms of virus, but also large numbers of HIV within intracellular vesicles. The second set of variants, the "F" series, produced no HIV antigens, reverse transcriptase, nor was there ultrastructural evidence of virus. However, proviral DNA was present. Virus could not be induced with agents known to activate latent HIV. These cells also lacked cell surface CD4 and could not be infected with HIV. These studies demonstrate that variation in HIV can affect the phenotype of the cells carrying the altered virus, allowing for escape from immunologic destruction. The E variants may serve as prototypes for attenuated HIV, which could be used as a vaccine. We have reconstructed the mutation found in the E variants within the infectious HIV clone HXB-2 and demonstrated that the resulting virus retains its noninfectious phenotype.
The Rmcf locus restricts the in vitro replication of mink cell focus-forming (MCF) viruses in cell cultures derived from mice carrying the resistance allele. Previously we reported that in cell cultures from first backcross progeny, this Rmcf-linked restriction segregates with the expression of an endogenous retroviral gp70 serologically related to that of MCF viruses. The current report details the results of genetic studies designed to examine the possible association of this endogenous gp70 with resistance of mice to Friend murine leukemia virus (F-MuLV)-induced erythroleukemia. This env gene segregates as a single dominant trait in (DBA/2 X IRW) X IRW progeny, in which the expression of the gene can be detected by serological techniques. Results indicated that the gp70- progeny developed leukemia at the same rate as the susceptible IRW parent, whereas the tempo of disease among the gp70+ progeny was significantly slower. However, the resistance mediated by this gene was only partial, since most of the gp70+ offspring eventually developed erythroleukemia when followed for 6 mo. This endogenous gp70 also segregated with a restriction to the expression of recombinant MCF viruses after infection with F-MuLV. Since in this study all unlinked genes segregated independently, this is direct evidence that MCF viruses participate in the induction of erythroleukemia.
Multiple copies of retroviral sequences are stably integrated in the genomes of many higher organisms, and are thus transmitted vertically to offspring via the germline (1). Most of these heritable viral genes are not expressed, and expression, when observed, is commonly limited to envelope (env) genes as demonstrated by the presence of cell surface and serum envelope glycoprotein (gp70) in mice. Studies of the mouse have shown that certain tissues such as the reproductive tract and lymphoid organs are common sites for the expression of endogenous env genes, suggesting that the transcription of at least some endogenous sequences is tissue specific. The transcription of endogenous viral genes is regulated by both cis and trans mechanisms (2-5) and their expression can be temporally linked to differentiation and development (6-8). The consequences to the host of endogenous retroviral genes are varied. At one extreme, expression of endogenous virus can result in the development of leukemia and death. Another potentially detrimental effect is that of insertional mutagenesis, seen when the integration of retroviral sequences interrupts the functioning of a cellular gene (9, 10). However, it is now clear that expression of endogenous retroviral genes may also have a beneficial effect for the host: namely, mediating resistance to retroviral leukemias as has been demonstrated for the Fv-4 gene in mice (11) and some ea loci in chickens (12). This form of resistance is due to the blockage of cellular viral receptors by the expression of envelope glycoprotein on the cell surface. The Rmcf locus of the mouse is another resistance gene that may exert its effect by the expression of an endogenous env gene. A summary of our current state of knowledge concerning the Rmcf gene is shown in Table I. The Rmcf gene was originally described when it was observed that fibroblast cell cultures derived from certain strains of mice restricted the replication of recombinant mink cell focus-forming(MCF)1 viruses (13). As detailed in Table I, DBA/2 mice are the prototypic strain exhibiting the Rmcf resistance (Rmcf(r)) phenotype. Cell cultures from other strains, such as C57BL/6 and IRW, are permissive for MCF viral replication and are termed Rmcf sensitive (Rmcf(s)). Previously, we described two allelic forms of an endogenous env gene, whose expression is linked to the Rmcf gene (14). Cell cultures from Rmcf(r) mice express gp70 related to that of MCF viruses, whereas cultures derived from Rmcf(s) mice either express no gp70 (IRW) or express an endogenous xenotropic gp70 (C57BL/6). These two gp70 alleles are detectable by type-specific mAbs.
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