Carol Stocking

Identification of genes involved in growth autonomy of hematopoietic cells by analysis of factor-independent mutants

The factor-dependent myeloid precursor cell line D35 mutates spontaneously at a frequency greater than 2.4 x 10(-7) to growth factor autonomy. This frequency could be increased at least 20-fold by retrovirus insertional mutagenesis. The isolation and characterization of factor-independent mutants allowed the identification of genes involved in growth autonomy. Mutants could be subdivided into two sets: those that secreted a stimulating factor (10/11) and those that did not (1/11). In one case, the factor released was distinct from previously characterized growth factors. In most mutants (6/9), the activation of a growth factor gene was associated with rearrangement that could be attributed to the insertion of a transposable-like element either 5 or 3 of the factor coding region in all cases examined, excluding oncogene involvement. All factor-independent mutants were tumorigenic, consistent with the hypothesis that growth-factor independence initiated by aberrant growth factor gene activation is an important and early step in tumorigenesis.

EXPRESSION OF THE GM-CSF GENE AFTER RETROVIRAL TRANSFER IN HEMATOPOIETIC STEM CELL LINES INDUCES SYNCHRONOUS GRANULOCYTE-MACROPHAGE DIFFERENTIATION

Multipotent murine stem cell lines (FDC-Pmix) depend on IL-3 for self-renewal and proliferation and can be induced to differentiate into multiple hematopoietic lineages. Single FDC-Pmix cells infected with retroviral vectors expressing GM-CSF are induced to differentiate into granulocytes and macrophages. This results in a complete loss of clonogenic cells if IL-3 is not exogenously supplied; however, multipotent variants can be selected that do not terminally differentiate if cells are kept in the presence of IL-3. Unidirectional and synchronous granulocyte and macrophage differentiation accompanied with loss of self-renewal capacity is induced when IL-3 is removed. Our data indicate that activation of the GM-CSF receptor induces differentiation of stem cells by an instructive mechanism that can be blocked by the activated IL-3 receptor. A model of how receptors can induce proliferation and cell-specific differentiation by two separate pathways is discussed.

Cloning of genes involved in chromosomal translocations by high-resolution single nucleotide polymorphism genomic microarray

High-resolution single nucleotide polymorphism genomic microarray (SNP-chip) is a useful tool to define gene dosage levels over the whole genome, allowing precise detection of deletions and duplications/amplifications of chromosomes in cancer cells. We found that this new technology can also identify breakpoints of chromosomes involved in unbalanced translocations, leading to identification of fusion genes. Using this technique, we found that the PAX5 gene was rearranged to a variety of partner genes including ETV6, FOXP1, AUTS2, and C20orf112 in pediatric acute lymphoblastic leukemia (ALL). The 3′ end of the PAX5 gene was replaced by the partner gene. The PAX5 fusion products bound to PAX5 recognition sequences as strongly as wild-type PAX5 and suppressed its transcriptional activity in a dominant-negative fashion. In human B cell leukemia cells, binding of wild-type PAX5 to a regulatory region of BLK, one of the direct downstream target genes of PAX5, was diminished by expression of the PAX5-fusion protein, leading to repression of BLK. Expression of PAX5-fusion genes in murine bone marrow cells blocked development of mature B cells. PAX5-fusion proteins may contribute to leukemogenesis by blocking differentiation of hematopoietic cells into mature B cells. SNP-chip is a powerful tool to identify fusion genes in human cancers.

Transforming genes and target cells of murine spleen focus-forming viruses.

Publisher Summary This chapter outlines the factors that determine leukemogenesis induced by acutely transforming retroviruses by the interaction with either myeloid stem or progenitor cells of the mammalian system. The acutely transforming retroviruses described will be limited to the spleen focus-forming viruses, defined as those retroviruses that induce a proliferative hematopoietic disease upon the intravenous injection of adult animals. The chapter discusses the molecular features of the three known groups of acutely transforming murine viruses: (1) viruses with recombinant env genes, (2) viruses with the mos oncogene, and (3) viruses with the ras oncogene. Data pertaining to the relevant proto-oncogenes and their products are also presented. It outlines the critical factors of the viral genome or transforming gene, based on structure-function analysis, which determine the oncogenicity of the retroviruses and its target cell specificity. It also discusses retrovirus-target cell interaction and outlines the experiments that are still necessary to fully understand the oncogenesis induced by spleen focus-forming viruses in the myeloid system.

Sodium-Dependent myo-Inositol Transporter 1 Is a Cellular Receptor for Mus cervicolor M813 Murine Leukemia Virus

ABSTRACT Retrovirus infection is initiated by binding of the surface (SU) portion of the viral envelope glycoprotein (Env) to specific receptors on cells. This binding triggers conformational changes in the transmembrane portion of Env, leading to membrane fusion and cell entry, and is thus a major determinant of retrovirus tissue and species tropism. The M813 murine leukemia virus (MuLV) is a highly fusogenic gammaretrovirus, isolated from Mus cervicolor, whose host range is limited to mouse cells. To delineate the molecular mechanisms of its restricted host range and its high fusogenic potential, we initiated studies to characterize the cell surface protein that mediates M813 infection. Screening of the T31 mouse-hamster radiation hybrid panel for M813 infectivity localized the receptor gene to the distal end of mouse chromosome 16. Expression of one of the likely candidate genes (slc5a3) within this region in human cells conferred susceptibility to both M813 infection and M813-induced fusogenicity. slc5a3 encodes sodium myo-inositol transporter 1 (SMIT1), thus adding another sodium-dependent transporter to the growing list of proteins used by MuLVs for cell entry. Characterization of SMIT1 orthologues in different species identified several amino acid variations within two extracellular loops that may restrict susceptibility to M813 infection.

Sequential mutations in the interleukin-3 (IL3)/granulocyte-macrophage colony-stimulating factor/IL5 receptor beta-subunit genes are necessary for the complete conversion to growth autonomy mediated by a truncated beta C subunit.

An amino-terminally truncated beta C receptor (beta C-R) subunit of the interleukin-3 (IL3)/granulocyte-macrophage colony-stimulating factor/IL5 receptor complex mediates factor-independent and tumorigenic growth in two spontaneous mutants of a promyelocytic cell line. The constitutive activation of the JAK2 protein kinase in these mutants confirms that signaling occurs through the truncated receptor protein. Noteworthily, in addition to a 10-kb deletion in the beta C-R subunit gene encoding the truncated receptor, several secondary and independent mutations that result in the deletion or functional inactivation of the allelic beta C-R subunit and the closely related beta IL3-R subunit genes were observed in both mutants, suggesting that such mutations are necessary for the full oncogenic penetrance of the truncated beta C-R subunit. Reversion of these mutations by the expression of the wild-type beta C-R in the two mutants resulted in a fivefold decrease in cloning efficiency of the mutants in the absence of IL3, confirming a functional interaction between the wild-type and truncated proteins. Furthermore, expression of the truncated beta C-R subunit in factor-dependent myeloid cells did not immediately render the cells autonomous but increased the spontaneous frequency to factor-independent growth by 4 orders of magnitude. Implications for both leukemogenic progression and receptor-subunit interaction and signaling are discussed.

Identification of the Myelin Protein Plasmolipin as the Cell Entry Receptor for Mus caroli Endogenous Retrovirus

ABSTRACT The Asian wild mouse species Mus caroli harbors an endogenous retrovirus (McERV) that is closely related to but distinct from the endogenous retrovirus family defined by the Mus dunni endogenous virus and the Mus musculus endogenous retrovirus. McERV could infect some cell types from humans, dogs, and rats, but not all, and did not infect any mouse cell line tested. Because of its interesting host range and proposed ancestral relationship to primate retroviruses and because none of the entry receptors for this family of retroviruses had been identified, we began a search for the McERV receptor. We determined the chromosomal location of the receptor gene in the human genome by phenotypic screening of the G3 human-hamster radiation hybrid cell line panel and confirmed the localization by assaying for receptor activity conferred by bacterial artificial chromosome (BAC) clones spanning the region. We next localized the gene more precisely in one positive BAC by assaying for receptor activity following BAC digestion with several restriction enzymes that cleaved different sets of genes, and we confirmed that the final candidate gene, plasmolipin (PLLP; TM4SF11), is the novel receptor by showing that the expression of the human PLLP cDNA renders hamster and mouse cells susceptible to McERV infection. PLLP functions as a voltage-dependent potassium ion channel and is expressed primarily in kidney and brain, helping to explain the limited range of cell types that McERV can infect. Interestingly, mouse PLLP also functioned well as a receptor for McERV but was simply not expressed in the mouse cell types that we originally tested.

Viral transfer, transcription, and rescue of a selectable myeloproliferative sarcoma virus in embryonal cell lines: expression of the mos oncogene.

A derivative of the myeloproliferative sarcoma virus (Neor-MPSV) carrying the mos oncogene and dominant selection marker for neomycin resistance (Neor) was introduced into embryonal carcinoma and embryo-derived cell lines by transfection and infection using pseudotypes with Friend helper virus (Friend murine leukemia virus [F-MuLV]). Cells resistant to G418 (a neomycin analog) were cloned and expanded. Transductants retained an undifferentiated phenotype as judged by morphology, tumorigenicity, and cell-surface antigen analyses. Nucleic acid analysis of infectants revealed both Neor-MPSV and F-MuLV proviruses, although no virus was released. G418-resistant transductants remained nonpermissive for the expression of other proviruses and for subsequent superinfection. Northern analysis showed expression of full-length Neor-MPSV, as well as mos-specific subgenomic RNA. mos sequences were deleted from Neor-MPSV (Neor mos-1), and pseudotypes were used to infect embryonal carcinoma cells. No morphological differences were observed in either mos+ or mos- transductants as compared with parental cell lines. However, mos+ transductants showed an enhanced anchorage-independent growth compared with that of mos- transductants in agar cloning. PCC4 transductants were induced to differentiate with retinoic acid and superinfected with F-MuLV. Infection with viral supernatant in fibroblasts and in mice confirmed the rescue of biologically active Neor-MPSV.

Investigation of C/EBPα function in human (versus murine) myelopoiesis provides novel insight into the impact of CEBPA mutations in acute myelogenous leukemia (AML)

Investigation of C/EBPα function in human (versus murine) myelopoiesis provides novel insight into the impact of CEBPA mutations in acute myelogenous leukemia (AML)

Point mutations in the U3 region of the long terminal repeat of moloney murine leukemia virus determine disease specificity of the myeloproliferative sarcoma virus

The myeloproliferative sarcoma virus (MPSV) is made up entirely of sequences derived from the Moloney murine leukemia virus (Mo-MuLV) and the cellular mos oncogene. As other members of the Moloney murine sarcoma virus (Mo-MuSV) family, MPSV transforms fibroblasts in vitro and causes sarcomas in vivo. In addition, however, MPSV also causes an acute myeloproliferative disease in adult mice. The mos oncogene is essential for its transforming capacity, but sequences specific to the long terminal repeat (LTR) U3 region of MPSV account for its expanded target specificity as compared to Mo-MuSV (C. Stocking, R. Kollek, U. Bergholz, and W. Ostertag, Proc. Natl. Acad. Sci. USA 82, 5746-5750 (1985)). The U3 region of the LTR of MPSV is, however, closely related to that of the Mo-MuLV, and it appeared likely that the difference between MPSV and Mo-MuSV was caused by a divergent evolution of Mo-MuSV LTRs. In this paper, we show that this is not the case. The few nucleotide differences in the LTR between Mo-MuLV and MPSV are crucial for the expanded host range of MPSV. Moreover, Mo-MuLV-related gag sequences retained in MPSV are not essential for the distinctive biological properties of MPSV.