Transduction of host cellular sequences by a retroviral shuttle vector

R-Ras C-terminal sequences are sufficient to confer R-Ras specificity to H-Ras

Activated versions of the similar GTPases, H-Ras and R-Ras, have differing effects on biological phenotypes: Activated H-Ras strongly transforms many fibroblast cell lines causing dramatic changes in cell shape and cytoskeletal organization. In contrast, R-Ras transforms fewer cell lines and the transformed cells display only some of the morphological changes associated with H-Ras transformation. H-Ras cells can survive in the absence of serum whereas R-Ras cells seem to die by an apoptotic-like mechanism in response to removal of serum. H-Ras can suppress integrin activation and R-Ras specifically antagonizes this effect. To map sequences responsible for these differences we have generated and investigated a panel of H-Ras and R-Ras chimeras. We found that the C-terminal 53 amino acids of R-Ras were necessary and sufficient to specify the contrasting biological properties of R-Ras with respect to focus morphology, reactive oxygen species (ROS) production and reversal of H-Ras-induced integrin suppression. Surprisingly, we found chimeras in which the focus formation and integrin-mediated phenotypes were separated, suggesting that different effectors could be involved in mediating these responses. An integrin profile of H-Ras and R-Ras cell pools showed no significant differences; both activated H-Ras and R-Ras expressing cells were found to have reduced beta(1) activity, suggesting that the activity state of the beta(1) subunit is not sufficient to direct an H-Ras transformed cell morphology.

The role of the Src homology domains in morphological transformation by v-src

The Src homology (SH2 and SH3) domains of v-Src are required for transformation of Rat-2 cells and for wild-type (morphr) transformation of chicken embryo fibroblasts (CEFs). We report herein that the N-terminal domains of v-Src, when expressed in trans, cannot complement the transformation defect of a deletion mutant lacking the "unique," SH3, and SH2 regions. However, the same regions of Src can promote transformation when translocated to the C terminus of v-Src, although the transformation of CEFs is somewhat slower. We conclude that the SH3 and SH2 domains must be present in cis to the catalytic domain to promote transformation but that transformation is not dependent on the precise intramolecular location of these domains. In CEFSs and in Rat-2 cells, the expression of wild-type v-Src results in tyrosine phosphorylation of proteins that bind to the v-Src SH3 and SH2 domains in vitro; mutations in the SH2 or SH3 and SH2 domains prevent the phosphorylation of these proteins. These findings are most consistent with models in which the SH3 and SH2 domains of v-Src directly or indirectly target the catalytic domain to substrates involved in transformation. However, the N-terminal domains of v-Src can promote tyrosine phosphorylation of certain proteins, in particular p130Cas, even when expressed in the absence of the catalytic domain, indicating that the N-terminal domains of v-Src have effects that are independent of the catalytic domain.

Neurofibromin can inhibit Ras-dependent growth by a mechanism independent of its GTPase-accelerating function

The NF1 gene, which is altered in patients with type 1 neurofibromatosis, has been postulated to function as a tumor suppressor gene. The NF1 protein product neurofibromin stimulates the intrinsic GTPase activity of active GTP-bound Ras, thereby inactivating it. Consistent with a tumor suppressor function, we have found that the introduction of NF1 in melanoma cell lines that are deficient in neurofibromin inhibited their growth and induced their differentiation. In addition, overexpression of neurofibromin in NIH 3T3 cells was growth inhibitory but did not alter the level of GTP.Ras in the cells. Transformation by v-ras, whose protein product is resistant to GTPase stimulation by neurofibromin, was inhibited in a cell line overexpressing neurofibromin, while transformation by v-raf was not altered. The results demonstrate that NF1 is a tumor suppressor gene that can inhibit Ras-dependent growth by a regulatory mechanism that is independent of neurofibromin's ability to stimulate Ras GTPase.

Neurofibromin can inhibit Ras-dependent growth by a mechanism independent of its GTPase-accelerating function

The NF1 gene, which is altered in patients with type 1 neurofibromatosis, has been postulated to function as a tumor suppressor gene. The NF1 protein product neurofibromin stimulates the intrinsic GTPase activity of active GTP-bound Ras, thereby inactivating it. Consistent with a tumor suppressor function, we have found that the introduction of NF1 in melanoma cell lines that are deficient in neurofibromin inhibited their growth and induced their differentiation. In addition, overexpression of neurofibromin in NIH 3T3 cells was growth inhibitory but did not alter the level of GTP.Ras in the cells. Transformation by v-ras, whose protein product is resistant to GTPase stimulation by neurofibromin, was inhibited in a cell line overexpressing neurofibromin, while transformation by v-raf was not altered. The results demonstrate that NF1 is a tumor suppressor gene that can inhibit Ras-dependent growth by a regulatory mechanism that is independent of neurofibromin's ability to stimulate Ras GTPase.

A phenotypic host range alteration determines RD114 virus restriction in feline embryonic cells

We have characterized the restriction mechanism for RD114 virus replication in embryonic feline cells (FeF). By comparing growth properties of the virus in FeF cells with its behavior in a fetal feline glial cell line (G355) permissive for RD114, we showed that both cell lines were readily infectible by virus grown in permissive cells and that no significant differences in viral integration or viral RNA expression could be detected. However, analysis of viral protein expression revealed differences in viral env gene processing in the two cell types. Envelope precursor pR85 was produced, but the expected processed gp70 product was detectable only in permissive (G355) cells. An envelope product of 85 kDa was packaged into virions produced by FeF cells, while virions produced by G355 cells contained the expected RD114 gp70. While the gp85 env-containing virions were infectious for permissive G355 cells, they were unable to infect FeF cells. The block to infection by the gp85-containing particles in FeF cells could be abrogated by treatment with the glycosylation inhibitor tunicamycin. Our results indicate that restriction of RD114 virus involves a novel mechanism dependent on two factors: altered glycosylation of the envelope to a gp85 form and an altered RD114 receptor in FeF cells.

C-ets-1 protooncogene expression alters the growth properties of immortalized rat fibroblasts

Ets family genes have been cloned and characterized from a variety of species ranging from human to Drosophila. The ets proteins encode transcription factors that activate transcription via specific binding to GGAA core sequence present in various promoter/enhancers. To investigate the role of ets protooncogene expression on the growth properties of rat embryo fibroblasts (REF), we constructed and introduced ets expression vectors into primary, as well as immortalized REF cells. The transfected cells contained multiple copies of the vector DNA, and the Northern blot analysis demonstrated overexpression of the c-ets-1-specific mRNA. Although the expression of the ets genes was unable to immortalize primary rat embryo fibroblasts, the expression of ets-1 in REF-1 cells enabled their growth in serum-free medium and effected tumorigenic activity in nude mice.

Host range mutants of v-src: alterations in kinase activity and substrate interactions

Host range mutants of Schmidt-Ruppin v-src that transform chicken embryo fibroblasts (CEF) but not Rat-2 cells were generated previously by linker insertion-deletion mutagenesis (J. E. DeClue and G. S. Martin, J. Virol. 63:542-554, 1989). One of these mutants, SRX5, in which Tyr-416 is substituted by the sequence Ser Arg Asp, retained high levels of kinase activity in vitro and in vivo, both in CEF and in Rat-2 cells. Phosphorylation of p36 (the calpactin I heavy chain) was drastically reduced in cells expressing SRX5 src, suggesting that the phenotype of SRX5 results from an alteration in substrate recognition by the src kinase. Three mutants, SPX1, SHX13, and XD6, containing linker insertions or small deletions within the src homology 2 (SH2) region, induced reduced levels of kinase activity in both CEF and Rat-2 cells. However, the residual levels of kinase activity in Rat-2 cells were above the threshold at which wild-type pp60v-src transforms Rat-2 cells, indicating that the reduction in kinase activity was not sufficient to account for the failure to transform. Cells infected by these mutants exhibited reduced levels of phosphorylation of 120- and 62-kDa proteins. We have reported elsewhere (M. F. Moran, C. A. Koch, D. Anderson, C. Ellis, L. England, G. S. Martin, and T. Pawson, Proc. Natl. Acad. Sci. USA 87:8622-8626, 1990) that ras GTPase-activating protein GAP and associated protein p62 are not tyrosine phosphorylated in Rat-2 cells expressing SHX13 or XD6. The transformation defect in Rat-2 cells may result from the failure to phosphorylate those proteins. The fifth mutant, XD4, contains a deletion which removes all of the src homology 3 (SH3) and most of the SH2 sequences of src. The protein encoded by XD4 is active as a kinase when expressed in CEF, indicating that in CEF the SH2 and SH3 regions of v-src are not necessary for kinase activity and transformation. The XD4 src product is not tyrosine phosphorylated and is inactive as a kinase when expressed in Rat-2 cells. Thus, host cell factors can affect the tyrosine phosphorylation and activity of the v-src kinase in the absence of the SH2 and SH3 regions. These results indicate that the host-dependent transformation phenotype results from alterations in src kinase activity and substrate specificity.

Genetic definition of ras effector elements

The products of ras genes may function as GTP-binding signal transducers, but the nature of their targets is largely unknown. To define genetically the cellular effector(s) of ras in rat fibroblast transformation, somatic variants that suppress the nontransforming phenotype of v-H-ras effector domain mutations were sought. Variant cell lines perturbed in the ras effector pathway were recovered, and the properties of one suggest that the primary target of ras action may be altered. In this cell variant, no single residue in the ras protein effector domain must be wild type to bring about transformation. In parental rat cells, conservative substitutions are tolerated in six of nine residues. Functional interaction with the target may not require a high degree of structural specificity in the ras protein effector domain.

Genetic definition of ras effector elements

The products of ras genes may function as GTP-binding signal transducers, but the nature of their targets is largely unknown. To define genetically the cellular effector(s) of ras in rat fibroblast transformation, somatic variants that suppress the nontransforming phenotype of v-H-ras effector domain mutations were sought. Variant cell lines perturbed in the ras effector pathway were recovered, and the properties of one suggest that the primary target of ras action may be altered. In this cell variant, no single residue in the ras protein effector domain must be wild type to bring about transformation. In parental rat cells, conservative substitutions are tolerated in six of nine residues. Functional interaction with the target may not require a high degree of structural specificity in the ras protein effector domain.

A ras effector domain mutant which is temperature sensitive for cellular transformation: interactions with GTPase-activating protein and NF-1

A series of v-rasH effector domain mutants were analyzed for their ability to transform rat 2 cells at either low or high temperatures. Three mutants were found to be significantly temperature sensitive: Ile-36 changed to Leu, Ser-39 changed to Cys (S39C), and Arg-41 changed to Leu. Of these, the codon 39 mutant (S39C) showed the greatest degree of temperature sensitivity. When the same mutation was analyzed in the proto-oncogene form of ras(c-rasH), this gene was also found to be temperature sensitive for transformation. Biochemical analysis of the proteins encoded by v-rasH(S39C) and c-rasH(S39C) demonstrated that the encoded p21ras proteins were stable and bound guanine nucleotides in vivo at permissive and nonpermissive temperatures. On the basis of these findings, it is likely that the temperature-sensitive phenotype results from an inability of the mutant (S39C) p21ras to interact properly with the ras target effector molecule(s) at the nonpermissive temperature. We therefore analyzed the interaction between the c-rasH(S39C) protein and the potential target molecules GTPase-activating protein (GAP) and the GAP-related domain of NF-1, on the basis of stimulation of the mutant p21ras GTPase activity by these molecules in vitro. Assays conducted across a range of temperatures revealed no temperature sensitivity for stimulation of the mutant protein, compared with that of authentic c-rasH protein. We conclude that for this mutant, there is a dissociation between the stimulation of p21ras GTPase activity by GAP and the GAP-related domain NF-1 and their potential target function. Our results are also consistent with the existence of a distinct, as-yet-unidentified effector for mammalian ras proteins.

A ras effector domain mutant which is temperature sensitive for cellular transformation: interactions with GTPase-activating protein and NF-1

A series of v-rasH effector domain mutants were analyzed for their ability to transform rat 2 cells at either low or high temperatures. Three mutants were found to be significantly temperature sensitive: Ile-36 changed to Leu, Ser-39 changed to Cys (S39C), and Arg-41 changed to Leu. Of these, the codon 39 mutant (S39C) showed the greatest degree of temperature sensitivity. When the same mutation was analyzed in the proto-oncogene form of ras(c-rasH), this gene was also found to be temperature sensitive for transformation. Biochemical analysis of the proteins encoded by v-rasH(S39C) and c-rasH(S39C) demonstrated that the encoded p21ras proteins were stable and bound guanine nucleotides in vivo at permissive and nonpermissive temperatures. On the basis of these findings, it is likely that the temperature-sensitive phenotype results from an inability of the mutant (S39C) p21ras to interact properly with the ras target effector molecule(s) at the nonpermissive temperature. We therefore analyzed the interaction between the c-rasH(S39C) protein and the potential target molecules GTPase-activating protein (GAP) and the GAP-related domain of NF-1, on the basis of stimulation of the mutant p21ras GTPase activity by these molecules in vitro. Assays conducted across a range of temperatures revealed no temperature sensitivity for stimulation of the mutant protein, compared with that of authentic c-rasH protein. We conclude that for this mutant, there is a dissociation between the stimulation of p21ras GTPase activity by GAP and the GAP-related domain NF-1 and their potential target function. Our results are also consistent with the existence of a distinct, as-yet-unidentified effector for mammalian ras proteins.

Inhibition of v-src-induced transformation by a GTPase-activating protein

Previous work has shown that microinjection into cells of antibodies against p21ras blocks transformation by src, suggesting that oncogenic transformation by pp60v-src is dependent on p21ras. The activity of p21ras itself is regulated by its cyclic association with GDP-GTP, where p21ras-GTP is the active form and p21ras-GDP is the inactive form. A GTPase-activating protein (GAP) mediates the inactivation of p21ras by facilitating the conversion of the active p21ras-GTP to the inactive p21ras-GDP. This predicts that overexpression of GAP would inactivate p21ras and block transformation of cells by src. In this paper, we confirm this prediction. We report that overexpression of GAP in NIH 3T3 cells blocks transformation by pp60v-src but not by v-ras. Susceptibility to transformation by v-src is restored when GAP expression is lowered to levels comparable to that in control cells. These results support the suggestion that p21ras plays a central role in the signalling pathway used by pp60v-src.

Inhibition of v-src-induced transformation by a GTPase-activating protein

Previous work has shown that microinjection into cells of antibodies against p21ras blocks transformation by src, suggesting that oncogenic transformation by pp60v-src is dependent on p21ras. The activity of p21ras itself is regulated by its cyclic association with GDP-GTP, where p21ras-GTP is the active form and p21ras-GDP is the inactive form. A GTPase-activating protein (GAP) mediates the inactivation of p21ras by facilitating the conversion of the active p21ras-GTP to the inactive p21ras-GDP. This predicts that overexpression of GAP would inactivate p21ras and block transformation of cells by src. In this paper, we confirm this prediction. We report that overexpression of GAP in NIH 3T3 cells blocks transformation by pp60v-src but not by v-ras. Susceptibility to transformation by v-src is restored when GAP expression is lowered to levels comparable to that in control cells. These results support the suggestion that p21ras plays a central role in the signalling pathway used by pp60v-src.

Suppression of c-ras transformation by GTPase-activating protein

The ras genes are required for normal cell growth and mediate transformation by oncogenes encoding protein tyrosine kinases. Normal ras can transform cells in vitro and in vivo, but mutationally activated ras does so much more efficiently, and highly transforming mutant versions of ras have been isolated from a variety of human and animal tumours. The ras genes encode membrane-associated, guanine nucleotide-binding proteins that are active when GTP is bound and inactive when GDP is bound. The slow intrinsic GTPase activity of normal mammalian Ras proteins can be greatly accelerated by the GTPase-activating protein (GAP), which is predominantly cytoplasmic. This activity of GAP, which can increase with cell density in contact-inhibited cells, suggests that it functions as a negative, upstream regulator of ras. Other studies, however, show that GAP interacts with a region of ras-encoded protein implicated in ras effector function, which raises the possibility that GAP might also be a downstream target of ras. Mutationally activated ras-encoded proteins also interact with GAP, although they are resistant to its catalytic activity. In an attempt to define the role of GAP in ras-mediated transformation, we examined the effects on transformation of normal or mutant ras when cells overexpress GAP. We found that GAP suppresses transformation of NIH 3T3 cells by normal Ha-ras (c-ras) but does not inhibit transformation by activated Ha-ras (v-ras). These results support the hypothesis that GAP functions as a negative regulator of normal ras and make it unlikely that GAP alone is the ras target.

Functional heterogeneity of proto-oncogene tyrosine kinases: the C terminus of the human epidermal growth factor receptor facilitates cell proliferation

Previous reports have indicated that the C termini of the membrane-associated tyrosine kinases encoded by c-src and c-fms proto-oncogenes have a negative effect on their biological activity and that this effect is mediated by their C-terminal tyrosine residue. To determine whether this was true for the human epidermal growth factor (EGF) receptor, which is also a membrane-associated tyrosine kinase proto-oncogene, we have constructed two premature termination mutants, dc19 and dc63, that delete the C-terminal 19 and 63 amino acids, respectively, from the human full-length receptor (hEGFR). The smaller deletion removes the C-terminal tyrosine residue, while the larger deletion removes the two most C-terminal tyrosines; similar deletions are found in v-erbB. As previously shown for the gene encoding the full-length EGF receptor, the two C-terminal mutants induced EGF-dependent focal transformation and anchorage-independent growth of NIH 3T3 cells. However, both dc19 and dc63 were quantitatively less efficient than the gene encoding the full-length receptor, with dc63 being less active than dc19. Although the C-terminal mutants displayed lower biological activity than the gene encoding the full-length receptor, the mutant receptors were found to be similar in several respects to the full-length receptor. These parameters included receptor localization, stability in the absence of EGF, receptor half-life in the presence of EGF, EGF binding, extent of EGF-dependent autophosphorylation in vitro, and EGF-dependent phosphorylation of an exogenous substrate in vitro. Therefore, the C-terminal 63 amino acids of the human receptor have no detectable influence on EGF-dependent early events. We conclude that in contrast

Functional heterogeneity of proto-oncogene tyrosine kinases: the C terminus of the human epidermal growth factor receptor facilitates cell proliferation

Previous reports have indicated that the C termini of the membrane-associated tyrosine kinases encoded by c-src and c-fms proto-oncogenes have a negative effect on their biological activity and that this effect is mediated by their C-terminal tyrosine residue. To determine whether this was true for the human epidermal growth factor (EGF) receptor, which is also a membrane-associated tyrosine kinase proto-oncogene, we have constructed two premature termination mutants, dc19 and dc63, that delete the C-terminal 19 and 63 amino acids, respectively, from the human full-length receptor (hEGFR). The smaller deletion removes the C-terminal tyrosine residue, while the larger deletion removes the two most C-terminal tyrosines; similar deletions are found in v-erbB. As previously shown for the gene encoding the full-length EGF receptor, the two C-terminal mutants induced EGF-dependent focal transformation and anchorage-independent growth of NIH 3T3 cells. However, both dc19 and dc63 were quantitatively less efficient than the gene encoding the full-length receptor, with dc63 being less active than dc19. Although the C-terminal mutants displayed lower biological activity than the gene encoding the full-length receptor, the mutant receptors were found to be similar in several respects to the full-length receptor. These parameters included receptor localization, stability in the absence of EGF, receptor half-life in the presence of EGF, EGF binding, extent of EGF-dependent autophosphorylation in vitro, and EGF-dependent phosphorylation of an exogenous substrate in vitro. Therefore, the C-terminal 63 amino acids of the human receptor have no detectable influence on EGF-dependent early events. We conclude that in contrast

Identification of bovine papillomavirus E1 mutants with increased transforming and transcriptional activity

The E1 open reading frame of bovine papillomavirus type 1 (BPV) has been shown previously to encode trans-acting functions, M and R, that are involved in extrachromosomal replication of the viral genome. We have determined that several E1 mutants mapping in both the M and R regions and a single mutant of the upstream regulatory region have a higher transforming activity on mouse C127 cells than the wild-type genome does. A representative mutant in M, a mutant in R, and the upstream regulatory region mutant were complemented in trans by the wild-type genome, but the two E1 mutants did not complement each other, suggesting that they affect the same inhibitory function. A long terminal repeat-activated clone constructed to express the intact E1 open reading frame reversed the high-transformation phenotype of the mutants. In contrast to the high-copy-number autonomous replication of the wild-type genome, the genomes of the E1 mutants were, as previously described for other E1 mutants, integrated at lower copy numbers in the transformed cells. Relative to the viral genome copy number, both the E1 M and R mutant transformed cells contained an average of 10-fold more BPV-specific transcripts than did the wild-type transformed cells. Cycloheximide treatment of the cells transformed by the E1 mutants did not lead to the rapid 10-fold increase in the accumulation of viral transcripts observed with the wild-type genome. These results suggest either that integration of the BPV genome makes it unresponsive to a labile repressor or that an E1 gene product, containing both M and R sequences, is a repressor of BPV transcription.

p21-ras effector domain mutants constructed by "cassette" mutagenesis

A series of mutations encoding single-amino-acid substitutions within the v-rasH effector domain were constructed, and the ability of the mutants to induce focal transformation of NIH 3T3 cells was studied. The mutations, which spanned codons 32 to 40, were made by a "cassette" mutagenesis technique that involved replacing this portion of the v-rasH effector domain with a linker carrying two BspMI sites in opposite orientations. Since BspMI cleaves outside its recognition sequence, BspMI digestion of the plasmid completely removed the linker, creating a double-stranded gap whose missing ras sequences were reconstructed as an oligonucleotide cassette. Based upon the ability of the mutants to induce focal transformation of NIH 3T3 cells, a range of phenotypes from virtually full activity to none (null mutants) was seen. Three classes of codons were present in this segment: one which could not be altered, even conservatively, without a loss of function (codons 32 and 35); one which retained detectable biologic activity with conservative changes but which lost function with more drastic substitutions (codons 36 and 40); and one which retained function even with a nonconservative substitution (codon 39).

Retroviruses expressing different levels of the normal epidermal growth factor receptor: biological properties and new bioassay

Two retroviral DNAs that encode the normal human epidermal growth factor (EGF) receptor hEGFR have been generated by inserting a hEGFR cDNA into two different retroviral vectors. One DNA (pCO11-EGFR-neo) also contained a linked selectable marker gene (neoR). The other (pCO12-EGFR) only expresses hEGFR. When introduced into NIH3T3 cells, the two DNAs and the viruses derived from them induced a fully transformed phenotype, including focal transformation and growth in agar or low serum, but transformation depended entirely upon EGF being present in the growth medium. Compared with pCO11-EGFR-neo, pCO12-EGFR induced EGF-dependent transformation 2-5 times more efficiently and expressed higher numbers of receptors (4 x 10(5) vs. 1 x 10(5) EGF receptors per cell). The results indicate that transforming potential is directly related to the number of EGF receptors. In defined, serum-free medium that contained only very low concentrations of insulin (0.6 microgram/ml) and transferrin (0.6 micrograms/ml), hEGFR-virus infected cells were able to grow with EGF as the only growth factor. Moreover, daily incubation of the cells with EGF for only 30 min was sufficient to induce growth. NR6 cells, which lack endogenous EGF receptors, were transformed as efficiently as NIH3T3 cells by the hEGFR virus. The dose-dependent growth response to EGF of infected NR6 cells grown in serum-free medium can be used as a highly sensitive bioassay for the quantitative assessment of EGF and transforming growth factor type alpha (TGF alpha). This bioassay is at least as sensitive as previously reported radioimmunoassays and can measure a much wider concentration range (10 pg-100 ng/ml). Uninfected NR6 cells or NR6 cells infected by helper virus alone can be used as controls for the EGF specificity of growth stimulation.

p21-ras effector domain mutants constructed by "cassette" mutagenesis

A series of mutations encoding single-amino-acid substitutions within the v-rasH effector domain were constructed, and the ability of the mutants to induce focal transformation of NIH 3T3 cells was studied. The mutations, which spanned codons 32 to 40, were made by a "cassette" mutagenesis technique that involved replacing this portion of the v-rasH effector domain with a linker carrying two BspMI sites in opposite orientations. Since BspMI cleaves outside its recognition sequence, BspMI digestion of the plasmid completely removed the linker, creating a double-stranded gap whose missing ras sequences were reconstructed as an oligonucleotide cassette. Based upon the ability of the mutants to induce focal transformation of NIH 3T3 cells, a range of phenotypes from virtually full activity to none (null mutants) was seen. Three classes of codons were present in this segment: one which could not be altered, even conservatively, without a loss of function (codons 32 and 35); one which retained detectable biologic activity with conservative changes but which lost function with more drastic substitutions (codons 36 and 40); and one which retained function even with a nonconservative substitution (codon 39).

A quantitative bioassay for HIV-1 based on trans-activation

A bioassay that is based on trans-activation has been developed for the detection and quantitation of the human immunodeficiency virus type 1 (HIV-1). Indicator cell lines were constructed that contain the HIV-1 long terminal repeat ligated to the chloramphenicol acetyltransferase (CAT) gene. Infection of these cells by HIV activates the expression of CAT protein. Isolates of HIV-1 with divergent nucleotide sequences activated the indicator cell lines to a similar extent, approximately 500- to 1000-fold. Human T cell lymphotropic viruses types 1 and 2, equine infectious anemia virus, and herpes simplex virus 1 did not activate the indicator cell lines. Isolates of simian immunodeficiency virus and human T cell lymphotropic virus type 4 activated these cells to a much lesser extent, which suggests that these viruses contain similar, but distinct, trans-activators. This assay can be used for the detection, quantitation, and typing of HIV and for studying the effect of drugs on the replication of HIV in different cellular backgrounds.