DNA rearrangement of a homeobox gene in myeloid leukaemic cells.

A homeobox gene rearrangement has been detected in WEHI-3B mouse myeloid leukaemic cells. The rearranged gene was identified as Hox-2.4 which is a member of the Hox-2 gene cluster on mouse chromosome 11. Both the normal and the rearranged genes were cloned and analysed, and the rearranged genomic Hox-2.4 gene was sequenced. The results indicate that the rearrangement is due to insertion of an intracisternal A particle 5' upstream to Hox-2.4 and that this resulted in constitutive expression of the homeobox gene. It is suggested that constitutive expression of the homeobox gene may interrupt the normal development program in these leukaemic cells.     

Identification of a human gene (HCK) that encodes a protein-tyrosine kinase and is expressed in hemopoietic cells.

We have isolated cDNAs representing a previously unrecognized human gene that apparently encodes a protein-tyrosine kinase. We have designated the gene as HCK (hemopoietic cell kinase) because its expression is prominent in the lymphoid and myeloid lineages of hemopoiesis. Expression in granulocytic and monocytic leukemia cells increases after the cells have been induced to differentiate. The 57-kilodalton protein encoded by HCK resembles the product of the proto-oncogene c-src and is therefore likely to be a peripheral membrane protein. HCK is located on human chromosome 20 at bands q11-12, a region that is affected by interstitial deletions in some acute myeloid leukemias and myeloproliferative disorders. Our findings add to the diversity of protein-tyrosine kinases that may serve specialized functions in hemopoietic cells, and they raise the possibility that damage to HCK may contribute to the pathogenesis of some human leukemias.     

Haploinsufficiency of ALX4 as a potential cause of parietal foramina in the 11p11.2 contiguous gene-deletion syndrome

Heterozygous mutations in MSX2 are responsible for an autosomal dominant form of parietal foramina (PFM). PFM are oval defects of the parietal bones that are also a characteristic feature of a contiguous gene-deletion syndrome caused by a proximal deletion in the short arm of chromosome 11 (Potocki-Shaffer syndrome). We have identified a human bacterial artificial chromosome (BAC) clone mapping to chromosome 11, containing a region homologous to the human homeobox gene MSX2. Further sequence analysis demonstrated that the human orthologue (ALX4) of the mouse Aristaless-like 4 gene (Alx4) is contained within this 11p clone. We used FISH to test for the presence-or for the heterozygous deletion-of this clone in two patients with the 11p11.2-deletion syndrome and showed that this clone is deleted in these patients. ALX4 and Alx4 were shown to be expressed in bone and to be absent from all other tissues tested. The involvement of Alx4 in murine skull development, its bone-specific expression pattern, the fact that Alx4 is a dosage-sensitive gene in mice, and the localization of a human genomic clone containing ALX4 to 11p11.2, with hemizygosity in patients with deletion of 11p11.2 who have biparietal foramina, support the contention that ALX4 is a candidate gene for the PFM in the 11p11.2-deletion syndrome.     

Localization of the human G-CSF gene to the region of a breakpoint in the translocation typical of acute promyelocytic leukemia

Summary The colony-stimulating factors regulate growth, differentiation, and function of blood cells. The effect of granulocyte colony-stimulating factor (G-CSF) on myeloid leukemias is unique among colony-stimulating factors in driving the leukemic cells from a self-renewing malignant state to a mature differentiated phenotype with the concomitant loss of tumorigenicity. This property of G-CSF has led to suggestions that its absence is responsible for lack of differentiation of leukemic cells and that the therapeutic administration of G-CSF could reverse this defect and result in a cure for leukemia. Here we show that the gene coding for human G-CSF is localized to chromosome 17, bands q11.2-21. The translocation of the long arm of chromosome 17 at q12-21 to chromosome 15 is a specific abnormality occurring in a high proportion of, if not all, patients with acute promyelocytic leukemia, a disease characterized by undifferentiated myeloid cells and a dismal prognosis. Abnormalities of the regulation of a specific differentiation factor gene mediated by a specific chromosomal rearrangement may be directly implicated in the pathogenesis of human leukemia.     

Activation of clg, a novel dbl family guanine nucleotide exchange factor gene, by proviral insertion at evi24, a common integration site in B cell and myeloid leukemias

Retroviruses induce leukemia in inbred strains of mice by activating cellular proto-oncogenes and/or inactivating tumor suppressors. The proviral integration sites in these leukemias provide powerful genetic tags for disease gene identification. Here we show that Evi24, a common site of retroviral integration in AKXD B cell and BXH-2 myeloid leukemias, contains a novel Dbl family guanine nucleotide exchange factor gene. We have designated this gene Clg (common-site lymphoma/leukemia guanine nucleotide exchange factor). Proviral integrations on chromosome 7 at Evi24 are located 7.6-10.3 kb upstream of Clg and increased Clg expression 2-5-fold compared with leukemias lacking proviral integrations at Evi24. Clg contains Dbl/pleckstrin homology domains with substantial sequence homology to many Rho family activators, including the transforming Dbl and Dbs/Ost oncogenes. Nucleotide exchange assays indicated that Clg specifically activated nucleotide exchange on Cdc42, but not RhoA or Rac1, in vitro. NIH 3T3 transfection studies showed that overexpression of full-length and carboxyl-terminally truncated forms of Clg morphologically transformed NIH 3T3 cells. This study and studies showing that the human homolog of EVI24 is located in a region of 19q13 frequently amplified in B cell lymphomas and pancreatic and breast cancers implicate Clg and Cdc42 activation in mouse and human cancers.     

Four of the seven zinc fingers of the Evi-1 myeloid-transforming gene are required for sequence-specific binding to GA(C/T)AAGA(T/C)AAGATAA.

Expression of the Evi-1 gene is activated in murine myeloid leukemias by retroviral insertions and in human acute myelogenous leukemia by translocations and inversions involving chromosome band 3q26 where the gene resides. Aberrant expression of the Evi-1 gene has been shown to interfere with myeloid differentiation, which is proposed to be the basis for its role in leukemias. The Evi-1 gene encodes a 145-kDa DNA-binding protein containing two domains of seven and three Cys2-His2 zinc fingers. Previous studies identified a portion of the consensus DNA-binding sequence for the first domain of zinc fingers. The experiments presented here extend these studies and demonstrate that the first domain recognizes a consensus of 15 nucleotides consisting of GA(C/T)AAGA(T/C)AAGATAA. The first three fingers of the first domain do not detectably bind DNA but contribute to the binding by conferring a relative specificity for GACAA verses GATAA in the first position. The first three fingers also contribute to optimal binding of the 15-nucleotide consensus sequence.     

17 long arm isochromosome. A common anomaly in malignat blood disorders.

A cytogenetic anomaly consisting in the replacement of a 17 by its long arm isochromosome was identified as the only alteration in the marrow cells of two patients with acute granulocytic leukemia. In one case, the specific nature of the abnormal chromosome was established by newly available techniques. Since its identification in 1965, this structural anomaly, which implies 17 long arm duplication and short arm deletion, has been observed, as a sole or as an associated finding, in the malignant cells of a spectrum of blood disorders, including acute granulocytic leukemias, the blast crisis of chronic myeloid leukemia and lymphoreticular proliferative disorders. Attention is called to this particular rearrangement for its clinical as well as fundamental implications, as its presence in blood forming cells unfailingly hearalds a fast, fatal course of evolution.     

Immortalization and leukemic transformation of a myelomonocytic precursor by retrovirally transduced HRX-ENL.

A subset of chromosomal translocations in acute leukemias results in the fusion of the trithorax-related protein HRX with a variety of heterologous proteins. In particular, leukemias with the t(11;19)(q23;p13.3) translocation express HRX-ENL fusion proteins and display features which suggest the malignant transformation of myeloid and/or lymphoid progenitor(s). To characterize directly the potential transforming effects of HRX-ENL on primitive hematopoietic precursors, the fusion cDNA was transduced by retroviral gene transfer into cell populations enriched in hematopoietic stem cells. The infected cells had a dramatically enhanced potential to generate myeloid colonies with primitive morphology in vitro. Primary colonies could be replated for at least three generations in vitro and established primitive myelomonocytic cell lines upon transfer into suspension cultures supplemented with interleukin-3 and stem cell factor. Immortalized cells contained structurally intact HRX-ENL proviral DNA and expressed a low-level of HRX-ENL mRNA. In contrast, wild-type ENL or a deletion mutant of HRX-ENL lacking the ENL component did not demonstrate in vitro transforming capabilities. Immortalized cells or enriched primary hematopoietic stem cells transduced with HRX-ENL induced myeloid leukemias in syngeneic and SCID recipients. These studies demonstrate a direct role for HRX-ENL in the immortalization and leukemic transformation of a myeloid progenitor and support a gain-of-function mechanism for HRX-ENL-mediated leukemogenesis.     

The homeobox genes of <Emphasis Type="Italic">Encephalitozoon cuniculi</Emphasis> (Microsporidia) reveal a putative mating-type locus

Homeobox genes have been found in animals, fungi, and plants. Recently, the complete genomic sequence of Encephalitozoon cuniculi has become available and it was shown that this Microsporida species is related to fungi. Given this close relatedness to fungi, I have searched the genome of E. cuniculifor homeobox genes. There are 12 homeobox genes as well as one STE12 orthologue. The large number of homeobox genes when compared to the annotations, which only list one, suggests that possibly other smaller genes may have been overlooked in the published analysis and E. cuniculi may have more than 1,997 genes. Sequence and phylogenetic analyses show that the E. cuniculi homeobox genes also fall into two distinct groups, with two TALE and ten typical homeobox genes being present. Like in the mating-type locus of yeast and other fungi, one TALE and one typical homeobox are found in close proximity of each other on the chromosome, suggesting that Microsporidia also contain a mating-type locus.     

Molecular characterization of KLHL3, a human homologue of the Drosophila kelch gene

The Drosophila kelch protein is a structural component of ring canals and is required for oocyte maturation. Here, we report the cloning and genomic structure of a new human homologue of kelch, KLHL3. At the amino acid level, KLHL3 shares 77% similarity with Drosophila kelch and 89% similarity with Mayven (KLHL2), another human kelch homolog. The approximately 6.5-kb mRNA has a single open reading frame encoding a protein of 587 amino acids with a predicted molecular mass of 650 kDa. Like kelch and KLHL2, the KLHL3 protein contains a poxvirus and zinc finger domain at the N-terminus and six tandem repeats (kelch repeats) at the C-terminus. At least three isoforms, which differ in the length of the N-terminus, are produced and may be the result of alternative promoter usage. We also identified alternative polyadenylation sites and alternative splicing; thus, as many as 12 mRNA variants and six putative protein isoforms could be produced. The KLHL3 gene is mapped to human chromosome 5, band q31, contains 17 exons, and spans approximately 120 kb of genomic DNA. KLHL3 maps within the smallest commonly deleted segment in myeloid leukemias characterized by a deletion of 5q; however, we detected no inactivating mutations of KLHL3 in malignant myeloid disorders with loss of 5q.     

Assignment of the growth hormone gene locus to 19q26-qter in cattle and to 11q25-qter in sheep by in situ hybridization

The growth hormone gene locus (GH) of cattle and sheep was mapped to a chromosomal region in each species by using in situ hybridization. The probe employed was an 830-bp cDNA sequence from the ovine growth hormone gene. Based on QFQ chromosome preparations, our results show that the GH locus is on cattle chromosome 19 in the region of bands q26-qter and in sheep on chromosome region 11q25-qter. The GH assignments together with previous localizations of type I cytokeratin genes (KRTA) and one homeobox (HOX2) gene in cattle and one type I cytokeratin gene (KRTA) in sheep identify a strongly conserved chromosomal segment on human chromosome 17, bovine chromosome 19, and sheep chromosome 11.     

Cell Fate Decisions in Malignant Hematopoiesis: Leukemia Phenotype Is Determined by Distinct Functional Domains of the MN1 Oncogene

Extensive molecular profiling of leukemias and preleukemic diseases has revealed that distinct clinical entities, like acute myeloid (AML) and T-lymphoblastic leukemia (T-ALL), share similar pathogenetic mutations. It is not well understood how the cell of origin, accompanying mutations, extracellular signals or structural differences in a mutated gene determine the phenotypic identity of leukemias. We dissected the functional aspects of different protein regions of the MN1 oncogene and their effect on the leukemic phenotype, building on the ability of MN1 to induce leukemia without accompanying mutations. We found that the most C-terminal region of MN1 was required to block myeloid differentiation at an early stage, and deletion of an extended C-terminal region resulted in loss of myeloid identity and cell differentiation along the T-cell lineage in vivo. Megakaryocytic/erythroid lineage differentiation was blocked by the N-terminal region. In addition, the N-terminus was required for proliferation and leukemogenesis in vitro and in vivo through upregulation of HoxA9, HoxA10 and Meis2. Our results provide evidence that a single oncogene can modulate cellular identity of leukemic cells based on its active gene regions. It is therefore likely that different mutations in the same oncogene may impact cell fate decisions and phenotypic appearance of malignant diseases.     

TTID: A novel gene at 5q31 encoding a protein with titin-like features.

A deletion of the long arm of chromosome 5 is a recurring abnormality in malignant myeloid disorders. In previous studies, we identified an approximately 1-Mb segment in 5q31 that was deleted in all patients examined. As part of a positional cloning project to identify transcribed sequences in this region, we identified and characterized the TTID gene. This gene contains 10 exons that extend over 19 kb. The composite cDNA is approximately 2.3 kb and encodes a protein of 498 amino acids, with a predicted molecular mass of 55 kDa. The C-terminal half of this putative protein contains an internally repeated domain of 43 amino acids, which resembles the N-terminal half of an immunoglobulin domain from the immense skeletal muscle protein titin. The TTID gene is expressed in multiple muscle tissue types as well as in thyroid gland and bone marrow. We evaluated the gene as a candidate tumor suppressor gene by searching for mutations in malignant myeloid disorders with abnormalities of chromosome 5. However, we detected no inactivating mutations. A single nucleotide change (G to A) was identified at nucleotide position 1889 in the untranslated region of the mRNA, which may represent a polymorphism. Therefore, TTID is unlikely to be the candidate tumor suppressor gene involved in malignant myeloid disorders.