Faculty Bibliography

The c-abl proto-oncogene encodes a cytoplasmic tyrosine kinase which is homologous to the src gene product in its kinase domain and in the upstream kinase regulatory domains SH2 (src homology region 2) and SH3 (src homology region 3). The murine v-abl oncogene product has lost the SH3 domain as a consequence of N-terminal fusion of gag sequences. Deletion of the SH3 domain is sufficient to render the murine c-abl proto-oncogene product transforming when myristylated N-terminal membrane localization sequences are also present. In contrast, the human BCR/ABL oncogene of the Philadelphia chromosome translocation has an intact SH3 domain and its product is not myristylated at the N terminus. To analyze the contribution of BCR-encoded sequences to BCR/ABL-mediated transformation, the effects of a series of deletions and substitutions were assessed in fibroblast and hematopoietic-cell transformation assays. BCR first-exon sequences specifically potentiate transformation and tyrosine kinase activation when they are fused to the second exon of otherwise intact c-ABL. This suggests that BCR-encoded sequences specifically interfere with negative regulation of the ABL-encoded tyrosine kinase, which would represent a novel mechanism for the activation of nonreceptor tyrosine kinase-encoding proto-oncogenes

Several epidemiologic and clinical studies suggest that patients coinfected with human immunodeficiency virus (HIV), the primary etiologic agent in AIDS, and other viruses, such as cytomegalovirus or human T-cell leukemia virus (HTLV), have a more severe clinical course than those infected with HIV alone. Cells infected with two viruses can, in some cases, give rise to phenotypically mixed virions with altered or broadened cell tropism and could therefore account for some of these findings. Such pseudotypes could alter the course of disease by infecting more tissues than are normally infected by HIV. We show here that HIV type 1 (HIV-1) efficiently incorporates the HTLV type I (HTLV-I) envelope glycoprotein and that both HIV-1 and HTLV-II accept other widely divergent envelope glycoproteins to form infectious pseudotype viruses whose cellular tropisms and relative abilities to be transmitted by cell-free virions or by cell contact are determined by the heterologous envelope. We also show that the mechanism by which virions incorporate heterologous envelope glycoproteins is independent of the presence of the homologous glycoprotein or heterologous gag proteins. These results may have important implications for the mechanism of HIV pathogenesis

We constructed a recombinant human immunodeficiency virus (HIV) vector to facilitate studies of virus infectivity. A drug resistance gene was inserted into a gp160- HIV proviral genome such that it could be packaged into HIV virions. The HIV genome was rendered replication defective by deletion of sequences encoding gp160 and insertion of a gpt gene with a simian virus 40 promoter at the deletion site. Cotransfection of the envelope-deficient genome with a gp160 expression vector resulted in packaging of the defective HIV-gpt genome into infectious virions. The drug resistance gene was transmitted and expressed upon infection of susceptible cells, enabling their selection in mycophenolic acid. This system provides a quantitative measure of HIV infection, since each successful infection event leads to the growth of a drug-resistant colony. The HIV-gpt virus produced was tropic for CD4+ human cells and was blocked by soluble CD4. In the absence of gp160, noninfectious HIV particles were efficiently produced by cells transfected with the HIV-gpt genome. These particles packaged HIV genomic RNA and migrated to the same density as gp160-containing virions in a sucrose gradient. This demonstrates that HIV virion formation is not dependent on the presence of a viral envelope glycoprotein. Expression of a murine leukemia virus amphotropic envelope gene in cells transfected with HIV-gpt resulted in the production of virus capable of infecting both human and murine cells. These results indicate that HIV can incorporate envelope glycoproteins other than gp160 onto particles and that this can lead to altered host range. Like HIV type 1 and vesicular stomatitis virus(HIV) pseudotypes, gp-160+ HIV-gpt did not infect murine NIH 3T3 cells that bear human CD4, confirming that these cells are blocked at an early stage of HIV infection

CD4, a cell-surface glycoprotein expressed on a subset of T-cells and macrophages, serves as the receptor for the human immunodeficiency virus (HIV) (reviewed in ref. 1), binding to the HIV envelope glycoprotein, gp120 with high affinity. Attempts to block infection in vivo by raising antibodies against gp120 have failed, probably because these antibodies have insufficient neutralizing activity. In addition, because of the extensive polymorphism of gp120 in different isolates of HIV, antibodies raised against one HIV isolate are only weakly effective against others. Because interaction with CD4 is essential for infectivity by all isolates of HIV, an agent that could mimic CD4 in its ability to bind to gp120, such as a peptide or monoclonal antibody, might block infection by a wide spectrum of isolates. To aid the identification of such a ligand we have defined regions of CD4 that are required for binding to gp120. Although human CD4 is similar to mouse CD4 in amino-acid sequence (55% identity, ref. 6) and structure, we have found that the murine protein fails to bind detectably to gp120 and have exploited this finding to study binding of gp120 to mouse-human chimaeric CD4 molecules. These studies show that amino-acid residues within the amino-terminal immunoglobulin-like domain of human CD4 are involved in binding to gp120 as well as to many anti-CD4 monoclonal antibodies

The 2',3'-dideoxynucleosides (ddNs) are currently undergoing clinical evaluation as antiretroviral agents in HIV-infected individuals. When phosphorylated, the ddNs (ddNTPs) function as chain-terminating substrate analogues with reverse transcriptase, thereby inhibiting HIV replication. These nucleoside analogues can also inhibit, by chain-terminating additions, the primitive lymphoid DNA polymerase, terminal deoxynucleotidyl transferase (TdT). To determine the effect of possible intracellular chain-terminating additions of ddNMPs by TdT, we exposed a series of TdT-positive and TdT-negative cell lines to 2',3'-dideoxyadenosine (ddA), a representative ddN. At ddA concentrations 25-fold higher than required for inhibition of HIV replication, progressive dose-related cytotoxicity was observed in the TdT-positive cell lines. This was accentuated by the adenosine deaminase inhibitor Coformycin (CF), presumably by enhancing the intracellular generation of ddATP from ddA. A central role of TdT in mediating the ddA/CF cytotoxicity was suggested by studies in a pre-B-cell line rendered TdT positive by infection with a TdT cDNA-containing retroviral vector. After a 48-hour continuous exposure period to 250 mumol/L ddA and 30 mumol/L CF, 30% cell death was observed in the TdT-negative parental line, whereas 90% cell death was observed in the TdT-positive daughter line. Exposure of fresh TdT-positive leukemic cells to ddA/CF for 72 hours ex vivo resulted in cytotoxicity (six cases of acute lymphocytic leukemia [ALL]) while not affecting TdT-negative acute leukemic cells (six cases). We conclude that ddA/CF selectively damages TdT-positive cells, presumably by chain-terminating additions of ddAMP, and that this may have therapeutic relevance in TdT-positive malignant disease

The role of terminal deoxynucleotidyl transferase (TdT) in the insertion of N regions into the junctional sites of immunoglobulin genes was investigated. Pre-B-cell lines capable of continuous rearrangement of immunoglobulin light-chain genes and differing only in the presence or apparent absence of TdT were derived by infecting cells with a TdT retroviral expression vector or a control vector. The cell lines were then superinfected with a retrovirus-based artificial immunoglobulin gene rearrangement substrate. The substrate was allowed to rearrange in the cell lines and the rearranged proviruses were rescued from the cell lines. Nucleotide sequence analysis of the V-J junctions of the proviral rearranged genes showed a fivefold greater frequency of N-region insertion in proviruses rescued from the TdT+ cell lines than in those rescued from the TdT- cell lines, so that at least 50% of the rearrangements that occurred in the presence of TdT had N regions. It is thus evident that TdT can stimulate N-region insertion, and the enzyme is presumably directly responsible for adding nucleotides at V-J and other immunoglobulin and T-cell receptor gene junctions

A 1750 base pair cDNA to human terminal deoxynucleotidyl transferase (TdT) has been cloned. This cDNA detects a dominant 2200 base pair messenger RNA species in normal and leukemic cells synthesizing the enzyme. A quantitative dot blot assay was utilized to survey a number of clinical samples from patients with TdT positive and negative leukemias as well as cells from normal volunteers. A linear relationship was detected between the amount of TdT mRNA and the amount of enzyme activity in bone marrow cells. The assay is sensitive enough to detect normal TdT levels in bone marrow, and distinguish these levels from the lack of such mRNA in peripheral blood and bone marrow of patients with myeloid leukemia. Elevated levels of mRNA were found in two cases of patients in clinical remission. The prognostic significance of these observations must await further study

Terminal deoxynucleotidyltransferase (TdT) is a DNA polymerase expressed in immature lymphocytes of the thymus and bone marrow, as well as certain leukemic cells. Chromosomal assignment of the gene coding for human TdT was accomplished by in situ hybridization of a 3H-labeled cDNA probe to human chromosome preparations and by Southern blot analysis of somatic cell hybrid DNAs. The human TdT gene was mapped to the region q23----q24 of chromosome 10. Breaks at this site have been reported in different translocations in human leukemias. The mouse TdT gene was assigned to chromosome 19 by Southern blot analysis of mouse X Chinese hamster somatic cell hybrids. This result adds a fourth locus to the conserved syntenic group on mouse chromosome 19 and human chromosome 10

A cDNA library was prepared from a terminal deoxynucleotidyltransferase-containing thymoma in the lambda phage vector lambda gt11. By screening plaques with anti-terminal transferase antibody, positive clones were identified of which some had beta-galactosidase-cDNA fusion proteins identifiable after electrophoretic fractionation by immunoblotting with anti-terminal transferase antibody. The predominant class of cross-hybridizing clones was determined to represent cDNA for terminal transferase by showing that one representative clone hybridized to a 2200-nucleotide mRNA in close-matched enzyme-positive but not to enzyme-negative cells and that the cDNA selected a mRNA that translated to give a protein of the size and antigenic characteristics of terminal transferase. Only a small amount of genomic DNA hybridized to the longest available clone, indicating that the sequence is virtually unique in the mouse genome