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ABSTRACT: Chromosomal rearrangements involving the immunoglobulin heavy chain gene (IGH) at 14q32 are observed in approximately 50% of patients with B-cell non-Hodgkin's lymphoma (NHL). The 5' end of the IGH gene is located within 8 kb of the telomeric repeats of 14q. Translocations involving the IGH locus and the telomeric band of a partner chromosome are difficult to identify, because most terminal bands of human chromosomes appear pale by conventional G-banding techniques. To determine whether there are cryptic translocations involving the IGH locus, we used dual-color fluorescence in situ hybridization (FISH) of 5' and 3' IGH genomic clones containing the variable sequences, or the J(H) and the 5' constant regions, respectively. We examined cells from 51 patients with B-cell NHL who had a normal karyotype (3 patients), clonal abnormalities not involving 14q32 (35 patients), or alterations of 14q32 other than recurring translocations, i.e., add(14)(q32) (13 patients). FISH detected 17 IGH translocations in 16 of 51 (31%) cases. Of the 13 cases with add(14)(q32), FISH identified the partner chromosome in 9 cases (69%; 3q27, 6 cases; 2p13, 19p13.3, and 18q21.3, 1 case each). Six of thirty-eight (16%) patients without visible alterations of 14q32 and 2 of 13 (15%) patients with an abnormality of one chromosome 14 had masked (5 patients) or cryptic IGH translocations (3 patients), involving 3q27 (3 patients), 5p15.3 (2 patients), 19p13.3 (3 patients), or 14q32 (1 patient; 1 patient had two rearrangements). We identified two novel, recurring, cryptic translocations: t(5;14)(p15.3;q32) (2 patients) and t(14;19)(q32;p13.3) (3 patients). In summary, FISH permitted the detection of cryptic or masked IGH rearrangements in approximately 20% of lymphoma cases without visible rearrangements of 14q32 analyzed retrospectively.
Cancer Research 11/2002; 62(19):5523-7. · 7.86 Impact Factor
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ABSTRACT: The FRA3B, at 3p14.2, lies within the fragile histidine triad (FHIT) gene and is the most highly expressed of the common fragile sites observed when DNA replication is perturbed by aphidicolin. Common fragile sites are highly unstable regions of the genome. Large intragenic deletions within FHIT, localized within the FRA3B sequences, have been identified in a variety of tumor cells. To characterize the FRA3B deletions in tumor cells and identify FRA3B sequences that are required for fragile site induction, we used microcell-mediated chromosome transfer to isolate hybrid cell clones that retain chromosome 3 homologues with various deletions within FRA3B. Detailed molecular mapping of the FHIT/FRA3B locus in the resultant hybrid cells revealed a complex pattern of instability within FRA3B. Each tumor cell line contained multiple chromosome 3 homologues with variable deletion patterns, often with discontinuous deletions, suggesting that the process of breakage and repair within FRA3B is an ongoing one. By comparing the approximate location of the breakpoints in the hybrid clones, we identified 11 recurring breakpoint/repair regions within the FRA3B. A comparison of the frequency of breaks/gaps within FRA3B in the hybrid clones with various deletions of FRA3B sequences revealed that the loss of FRA3B sequences does not reduce the overall rate of breakage and instability within the remaining FRA3B sequences. The majority of breaks occurred in the proximal portion of the FRA3B, in a 300-kb interval between exon 4 and the proximal 50 kb of intron 5. Our observations suggest that there is no single sequence within the FRA3B that influences breakage or recombination within this region; however, we cannot rule out the presence of multiple "hot spots" within the FHIT/FRA3B locus. Together, the results suggest that factors other than the DNA sequence per se are responsible for the formation of DNA breaks/gaps.
Cancer Research 07/2002; 62(12):3477-84. · 7.86 Impact Factor
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ABSTRACT: The ERKs are a subfamily of the MAPKs that have been implicated in cell growth and differentiation. By using the rat ERK7 cDNA to screen a human multiple tissue cDNA library, we identified a new member of the ERK family, ERK8, that shares 69% amino acid sequence identity with ERK7. Northern analysis demonstrates that ERK8 is present in a number of tissues with maximal expression in the lung and kidney. Fluorescence in situ hybridization localized the ERK8 gene to chromosome 8, band q24.3. Expression of ERK8 in COS cells and bacteria indicates that, in contrast to constitutively active ERK7, ERK8 has minimal basal kinase activity and a unique substrate profile. ERK8, which contains two SH3-binding motifs in its C-terminal region, associates with the c-Src SH3 domain in vitro and co-immunoprecipitates with c-Src in vivo. Co-transfection with either v-Src or a constitutively active c-Src increases ERK8 activation indicating that ERK8 can be activated downstream of c-Src. ERK8 is also activated following serum stimulation, and the extent of this activation is reduced by pretreatment with the specific Src family inhibitor PP2. The ERK8 activation by serum or Src was not affected by the MEK inhibitor U0126 indicating that activation of ERK8 does not require MEK1, MEK2, or MEK5. Although most closely related to ERK7, the relatively low sequence identity, minimal basal activity, and different substrate profile identify ERK8 as a distinct member of the MAPK family that is activated by an Src-dependent signaling pathway.
Journal of Biological Chemistry 06/2002; 277(19):16733-43. · 4.77 Impact Factor
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Genes Chromosomes and Cancer 05/2002; 33(4):346-61. · 3.31 Impact Factor
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ABSTRACT: The efforts to localize genes to human chromosomes date back to the early 1970s. Although few techniques were available to
map genes, many scientists recognized that the ability to determine the location of genes and DNA sequences on human chromosomes
would not only facilitate the identification of disease-related genes, but might also provide important knowledge on the organization
of chromosomes and the mechanisms of gene expression. With the introduction of somatic cell genetics and the development of
hybrid cell panels in the mid-1970s, investigators were now capable of mapping sequences to whole chromosomes and, in some
cases, to specific chromosome regions or bands. Nonetheless, the major breakthrough in mapping efforts was provided by the
development of in situ hybridization of isotopically labeled probes; this technique provided the first method by which scientists could actually
visualize the hybridization of a DNA probe to chromosomes (1,2). Using this technique, genes could be mapped to a few chromosome bands and often to a single band. The disadvantages of
this method were the relatively poor spatial resolution owing to scatter of the radioactive emissions, the length of time
for the procedure (long autoradiographic exposure times were typically required), and the poor stability of the probes. The
introduction of techniques to detect hybridized probes using fluorochromes in the late 1970s circumvented many of these problems
(3,4); however, it was not until the end of the next decade that fluorescence in situ hybridization (FISH) techniques became widely applicable (5,6).
12/1999: pages 991-1010;
