ITSN1 regulates SAM68 solubility through SH3 domain interactions with SAM68 proline-rich motifs.

SAM68 is an mRNA-binding protein involved in mRNA processing in the nucleus that forms membraneless compartments called SAM68 Nuclear Bodies (SNBs). We found that intersectin 1 (ITSN1), a multidomain scaffold protein harboring five soluble SH3 domains, interacts with SAM68 proline-rich motifs (PRMs) surrounded by self-adhesive low complexity domains. While SAM68 is poorly soluble in vitro, the interaction of ITSN1 SH3 domains and mRNA with SAM68 enhances its solubility. In HeLa cells, the interaction between the first ITSN1 SH3 domain (SH3A) and P0, the N-terminal PRM of SAM68, induces the dissociation of SNBs. In addition, we reveal the ability of another SH3 domain (SH3D) of ITSN1 to bind to mRNAs. ITSN1 and mRNA may thus act in concert to promote SAM68 solubilization, consistent with the absence of mRNA in SNBs in cells. Together, these results support the notion of a specific chaperoning of PRM-rich SAM68 within nuclear ribonucleoprotein complexes by ITSN1 that may regulate the processing of a fraction of nuclear mRNAs, notably SAM68-controlled splicing events related to higher neuronal functions or cancer progression. This observation may also serve as a putative model of the interaction between other PRM-rich RBPs and signaling proteins harboring SH3 domains.

Methylation pattern of the putative tumor-suppressor gene LRRC3B promoter in clear cell renal cell carcinomas.

The leucine rich repeat containing 3B (LRRC3B) gene is a putative tumor suppressor located on human chromosome 3 in the 3p24 region. LRRC3B is frequently altered in colon and gastric cancers and also in leukaemias. In this study we investigated the promoter region methylation as a possible mechanism of LRRC3B gene inactivation in clear cell renal cell carcinomas. We found that the LRRC3B gene promoter was methylated in 43% of clear cell renal carcinoma samples. However, no correlation between DNA methylation and LRRC3B expression was found.

Genetic and epigenetic changes of NKIRAS1 gene in human renal cell carcinomas.

UNLABELLED: Renal cell carcinoma (RCC) is the most common malignant tumor of kidney associated with the worst clinical outcome. No molecular markers for RCC diagnostics and prognosis that could be applied in clinics were described yet. Large-scale screening of 3p human chromosome genes/loci in RCC and histologically normal tissues surrounding the tumors using NotI-microarray approach demonstrated that NKIRAS1 gene contained the largest percent of genetic/epigenetic changes in RCC tumor cells. AIM: To validate the results of NotI microarray analysis and study genetic, epigenetic changes, and the expression level of NKIRAS1 gene in human RCC samples. METHODS: DNA and RNA were isolated from freshly-frozen renal tumors' samples (n = 12) and from normal tissues surrounding the tumors. Epigenetic changes (methylation status) of NKIRAS1 were detected by bisulfite sequencing. Genetic changes and expression level were analyzed by Quantitative real-time PCR (qPCR) with SYBR Green. For relative quantification 2-(DeltaDeltaCP) method was used. Nonparametric tests (Wilcoxon, Kruskal - Wallis and Mann - Whitney) were applied for statistical data analysis using the BioStat software. RESULTS: NKIRAS1 expression was downregulated in 75% of RCC samples (9 of 12) compared with surrounding normal tissue. High grade tumors (3 and 4) showed lower expression of NKIRAS1 at the mRNA level than tumors of low grade (1 and 2). No significant association was found between gene expression level and gender or age. Analysis of NKIRAS1 gene copy number was performed in 19 tumor samples. Changes in the copy number of NKIRAS1 gene were observed in 64% (9 of 14) of cRCC samples. 9 samples displayed ratio (< 0.85 and >or= 0.35), thus were considered as hemizygous deletions. 3 samples showed ratio (> 0.85) and were considered as normal copy number. Changes in NKIRAS1 gene copy number were detected in all 3 benign oncocytomas, 1 papillary cancer and 1 sarcoma, where hemizygous deletion was observed. No changes in methylation status of NKIRAS1 were found in RCC. CONCLUSIONS: We have validated the results of NotI microarray analysis of NKIRAS1 gene in RCC. It was shown the decreased expression level of NKIRAS1 in this type of tumor.

Screening of epigenetic and genetic disturbances of human chromosome 3 genes in colorectal cancer.

DNA microarray technology comprising NotI-linking clones was used in a large-scale study of genetic and epigenetic changes in colorectal cancer. Analysis of samples from 24 patients revealed methylation, deletions, and amplifications in 137 of 181 NotI clones. For 27 genes/loci, these changes occurred in more than 30% of the tumor samples, suggesting that these genes are involved in the development of colorectal cancer. An analysis of the methylation status of CpG island of the ITGA9 gene/loci by bisulfite sequencing confirmed the NotI microarray data on the gene/loci methylation in colorectal cancer. Aberrations in 19 genes/loci were unknown previously. Their characterization may help ascertain the mechanisms responsible for colorectal cancer development and identify novel diagnostic and prognostic markers.

Complete nucleotide sequences of ALV-related endogenous retroviruses available from the draft chicken genome sequence.

Complete nucleotide sequences of chicken endogenous retroviruses belonging to E33/E51 and EAV-0 groups have been analysed on the basis of the recently available draft genome sequence of red jungle fowl (Gallus gallus), the progenitor of domestic chicken (G.g. domesticus). It was shown that all these proviruses have deletions in the SU-coding domain of the env gene, involved in receptor recognition, whereas gag and pol genes appear to be intact. Phylogenetic analysis demonstrated that E33/E51 and EAV-0 groups are related to the ALV genus. An analysis of expression using chicken EST databases showed that these proviruses are transcriptionally active.

Distribution of HIV-1 in the genomes of AIDS patients.

The localization of HIV-1 proviruses in compositional DNA fractions from 27 AIDS patients during the chronic phase of the disease with depletion of CD4+ and different levels of viremia showed the following. (1) At low viremia, proviruses are predominantly localized in the GC-richest isochores, which are characterized by an open chromatin structure; this result mimics findings on HIV-1 integration in early infected cells in culture. (2) At higher viremia, an increased distribution of proviruses in GC-poor isochores (which match the GC poorness of HIV-1) was found; this suggests a selection of cells in which the 'isopycnic' localization leads to a higher expression of proviruses and, in turn, to higher viremia. (3) At the highest viremia, integrations in GC-rich isochores are often predominant again, but generally not at the same level as in (1); this may be the consequence of new integrations from the extremely abundant RNA copies.

Initial isolation and analysis of the human Kv1.7 (KCNA7) gene, a member of the voltage-gated potassium channel gene family.

A novel human potassium channel gene was identified and isolated. The maximal open reading frame encodes a protein of 456 amino acids. The predicted product exhibits 91% amino acid identity to the murine voltage-gated potassium channel protein Kv1.7 (Kcna7), which plays an important role in the repolarization of cell membranes. Based on the high similarity, the human gene has been classified as the ortholog of the mouse Kcna7 and given the name Kv1.7 (KCNA7). A structural prediction identified a pore region characteristic of potassium channels and six membrane-spanning domains. Northern expression analysis revealed the gene is expressed preferentially in skeletal muscle, heart and kidney. However, it is expressed at lower level in other tissues, including liver. A single mRNA isoform was observed, with a size of approximately 4.5 kb. Using fluorescence in situ hybridization, the gene was mapped to chromosomal band 19q13.4 (269.13 cR(3000)). A genomic sequence was identified in the database from this region, and the KCNA7 gene structure determined. Computational analysis of the genomic sequence reveals the location of a putative promoter and a likely muscle-specific regulatory region. Initial comparison to the published murine Kcna7 cDNA suggested a different N-terminal sequence for the human protein, however, further analysis suggests that the original mouse sequence contained an error or an unusual polymorphism.

Criteria for gene identification and features of genome organization: analysis of 6.5 Mb of DNA sequence from human chromosome 21.

To establish criteria for and the limitations of novel gene identification, to identify novel genes of potential relevance to Down Syndrome and to investigate features of genome organization, 6. 550kb. In total, 41 novel gene models were predicted, and for a subset of these, RT-PCR experiments helped to verify and refine the models, and were used to assess expression in early development and in adult brain regions of potential relevance to Down syndrome. Results suggest generally low and/or restricted patterns of expression, and also reveal examples of complex alternative processing, especially in brain, that may have important implications for regulation of protein function. Analysis of complete gene structures of the known genes identified a number of very large introns, a number of very short intergenic distances, and at least one potentially bi-directional promoter. At least 3/4 of known genes and 1/2 of predicted genes are associated with CpG islands. For novel genes, three cases of overlapping genes are predicted. Results of these analyses illustrate some of the complexities inherent in mammalian genome organization and some of the limitations of current sequence analysis technologies. They also doubled the number of potential genes within the region.

Localization of HTLV-1 and HIV-1 proviral sequences in chromosomes of persistently infected cells.

Integration sites for HTLV-1 and HIV-1proviruses were detected by FISH on the chromosomes of HTHIV27 cells persistently infected by HIV-1 (strain IIIB). HTLV-1 signals were found on 9 loci of chromosomes 4, 6, 9, 15 and 16. Integration sites of GC-rich HTLV-1 provirus are located in GC-rich isochores, confirming an 'isopycnic' integration, namely an integration in which the GC level of the host sequences around the integration site match the GC level of the provirus. This conclusion is not only derived from the compositional map of human chromosomes, but also from HTLV-1 hybridization on compositional fractions of human DNA. Integration of GC-poor HIV-1 provirus was found on 4 loci of chromosomes 2, 7, 17 and 19. One copy of a complete HIV-1 provirus, which is active, was integrated in H1 isochores, whereas other defective copies were located in GC-poor L isochores. These results are discussed in terms of regional integration of retroviral sequences.

The regional integration of retroviral sequences into the mosaic genomes of mammals.

We have reviewed here three sets of data concerning the integration of retroviral sequences in the mammalian genome: (i) our experimental localization of a number of proviruses integrated in isochores characterized by different GC levels; (ii) results from other laboratories on the localization of retroviral sequences in open chromatin regions and/or next to CpG islands; and (iii) our compositional analysis of genes located in the neighborhood of integrated retroviral sequences. The three sets of data have provided a very consistent picture in that a compartmentalized, isopycnic integration of expressed proviruses appears to be the rule ('isopycnic' refers to the compositional match between viral and host sequences around the integration site). The results reviewed here suggest that: (i) integration of proviral sequences is targeted initially towards 'open chromatin regions'; while these exist in both GC-rich and GC-poor isochores, the 'open chromatin regions' of GC-rich isochores are the main targets for integration of retroviral sequences because of their much greater abundance; (ii) isopycnicity is associated with stability of integration; indeed, even non-expressed integrated retroviral sequences tend to show an isopycnic localization in the genome; (iii) transcription of integrated viral sequences (like transcription of host genes) appears to be associated, as a rule, with an isopycnic localization, as indicated by transcribed sequences that show an isopycnic integration and act in trans; (iv) selection plays a role in the choice of specific sites within an isopycnic region; in exceptional cases [such as mouse mammary tumor virus (MMTV) activating GC-rich oncogenes], selection may override isopycnicity.

Activation of a novel gene in 3q21 and identification of intergenic fusion transcripts with ecotropic viral insertion site I in leukemia.

We have identified a novel gene, GR6, located within the leukemia breakpoint region of 3q21, that is normally expressed in early fetal development but not in adult peripheral blood. GR6 is activated in the UCSD-AML1 cell line and in a leukemic sample, both of which carry a t(3;3)(q21;q26). In UCSD-AML1, we have also identified fusion transcripts between the ecotropic viral insertion site I (EVI1) gene in 3q26 and GR6 and between EVI1 and Ribophorin I that maps 30 kb telomeric to GR6 in 3q21. All fusions splice the 5' ends of the 3q21 genes into exon 2 of the EVI1 gene, an event that is similar to the normal intergenic splicing of MDS1-EVI1 and to those previously documented in leukemias with t(3;21) and t(3;12), in which acute myelogenous leukemia 1-EVI1 fusions and ETV6-EVI1 fusions, respectively, occur. The Ribophorin I-EVI1 fusion in particular may be a common occurrence in t(3;3).

Leukemia breakpoint region in 3q21 is gene rich.

Rearrangements of the long arm of human chromosome 3, including reciprocal translocations, inversions and deletion/duplication of bands 3q21-3q26, as well as deletions of 3q21 and reciprocal translocations between 3q21 and other chromosomes, are well documented in leukemia. Previous studies showed that the breakpoints within 3q21 cluster within a 10-40 kb region but no candidate genes were described. In this work, we have identified partial cDNAs corresponding to five to nine new transcripts from an 80 kb P1 clone that spans ten breakpoints. These transcripts, with one exception, appear to be expressed only at low levels in the set of cancer cell lines examined. Four transcripts are located between the previously mapped Ribophorin I gene and the most centromeric breakpoint; three map directly within the 20 kb spanning nine independent breakpoints. These data (i) show that among characterized leukemia breakpoint regions 3q21 is unusually gene rich, (ii) provide new candidates for relevance to leukemia in 3q21, and (iii) suggest possibilities for chromatin configuration effects.

Cloning of breakpoints in 3q21 associated with hematologic malignancy.

Rearrangements of band 3q21 have been well documented in leukemia. To analyze the region involved, we have isolated a normal genomic P1 clone that spans the 3q21 breakpoints derived from two leukemia patients carrying t(3;3)(q21;q26). Both breakpoints are contained within a 50-kb NotI restriction fragment, but are not identical. They are separated by 9-11 kb and may disrupt genes associated with either the proximal or distal NotI sites. We further show that one patient carried a small insertion of material from chromosome 2 in the 3q- derivative. The P1 clone will allow isolation of candidate genes for these breakpoints and investigations into the clustering of other 3q21 leukemia breakpoints.

Origin and evolution of the c-src-transducing avian sarcoma virus PR2257.

Avian sarcoma virus PR2257 transduced de novo the c-src gene and about 900 bp of 3' non-coding sequences belonging to the src locus. This virus contains only one mutation in the c-src coding sequence causing a reading frame shift after Pro-525. The molecular clone studied was derived from a cell line of transformed quail fibroblasts, C7. It contains endogenous virus (ev) derived sequences in the U5 and 3' non-coding regions, indicating that multiple recombination occurred with endogenous virus. Here we investigated the possible evolution of PR2257 when the original tumour was repeatedly passaged in vivo. After 16 passages a new virus, designated PR2257/16, appeared with a tenfold higher titre. The sequence of PR2257/16 was determined and showed that PR2257/16 resulted from recombination of PR2257 with the env gene of the helper virus (td daPR-C). This recombination expanded the env gene content in PR2257/16 and, in addition, five point mutations occurred in its genome. Because we thought that an endogenous virus might be involved in the mechanism of c-src transduction, we also reinvestigated the presence of ev sequences in PR2257 proviruses from several early passages of the original tumour. We found that in contrast with the first isolate from the C7 cell line, the provirus in these tumours did not contain such sequences. These results do not support the hypothesis that endogenous sequences were involved in the transduction process.

The 3' region of c-src gene mRNA is entirely included in exon 12 and does not encode another protein.

We previously reported the isolation of PR2257, a novel replication defective avian sarcoma virus which transduced the entire c-src coding region together with about 900 bp of c-src 3' non coding sequences. This virus originated from a chicken sarcoma induced by inoculation of a transformation-defective Rous sarcoma virus carrying only replicative genes. The 5' end of PR2257 was formed by a splice junction between viral leader sequences and the first exon of c-src. To understand the mechanism of 3' recombination between viral and cellular sequences, we analyzed the genomic organization of the 3' region in chicken and quail src DNA. We report that this sequence is colinear with that of a chicken src cDNA. Therefore, exon 12, which encodes the last 68 amino acids of c-src, also contains all 3' non coding sequences present in c-src mRNA and consequently, appears to be the last and largest (about 2 kbp) exon of c-src. We also show that the 3' regions of chicken and quail c-src genes does not contain the additional open reading frame (orf) which was previously reported (Dorai et al. (1991) Mol. Cell. Biol. 11, 4165-4176), and that no other significant conserved open reading frames could be found in this region for both species. Therefore, this region of src does not code for another protein. Taken together, our results suggest that PR2257 was generated by recombination at the RNA level. However, because of the absence of introns in this region of c-src, we cannot formally rule out the possibility that this recombination took place at the DNA level.

Regional specificity of HTLV-I proviral integration in the human genome.

The location of HTLV-I (human T-cell leukemia virus type 1) proviral sequences in the genome of infected human cells was explored by hybridization of a viral probe with compositional fractions of host-cell DNAs. In the twelve cases examined, HTLV-I sequences were absent from the GC-poorest 40% of the host genome (namely, from isochores that are below 39% GC). Transcriptionally inactive proviral sequences were localized in GC-poor isochores (comprised between 39% and 42-44% GC) of the human genome, which are characterized by a constant and low gene concentration. In contrast, transcriptionally active proviral sequences were found in the GC-rich and very GC-rich isochores, which are gene rich, transcriptionally and recombinationally active, and endowed with an open chromatin structure. Since GC-rich isochores are present in R'-bands and very GC-rich isochores form T-bands, these results also provide information on the location of HTLV-I proviral sequences in human chromosomes. The results obtained with HTLV-I are in agreement with the non-random, compartmentalized integration of animal retroviral sequences that had been previously observed in other viral-host systems. They provide, however, much more detailed information on the regional location of proviral sequences in the host genome and on the correlation between their transcription and their location.

New case of c-src gene transduction: the generation of virus PR2257.

PR2257 is a new replication-defective avian sarcoma virus which harbours in addition to the spliced version of the c-src gene also about 950 bp of no-coding cellular sequences located downstream from the c-src stop codon (Geryk et al., 1989). Comparison of the 950 bp region transduced by PR2257 with the chicken c-src cDNA (Dorai et al., 1991) and genomic sequences of the c-src 3' non-coding region from chicken and quail has shown that there are no additional introns. The c-src 3' non-coding region represents the largest c-src exon (No. 12) comprising about 2 kb. Absence of conserved open reading frames within this region in chicken and quail genomic DNAs excludes the possibility for coding a protein by these sequences. Also, the possibility was excluded that numerous endogenous virus-derived sequences identified in molecularly cloned PR2257 provirus played a role in the c-src transduction. After serial passaging of PR2257 virus in vivo a variant PR2257/16 was isolated. In PR2257/16, the size of the env gene was increased due to homologous recombination with a helper virus. In addition to mutations in the viral leader and the v-src coding region, a large deletion in transduced c-src 3' non-coding sequences was found in the PR2257/16 genome. The significance of genome modifications for selective advantage of this viral variant in vivo is discussed.

Role of replaced v-src and env genes in the duck-adapted variant of Rous sarcoma virus.

The env and v-src genes of a duck-adapted variant of Rous sarcoma virus were replaced for corresponding genes from parental chick-derived virus. The generation of viral constructs with replaced genes is described. DNAs of viruses with replaced genes were assayed on chick and duck embryo fibroblasts by transfection assays. Transformation efficiency was measured by the focus assay and multiplication of virus by the reverse transcriptase assay. Duck-adapted virus with replaced env gene lost the higher transformation efficiency for duck cells, whereas replacement of the v-src gene had no effect on its host-specific transformation activity.

Compositional bimodality and evolution of retroviral genomes.

The compositional distributions of genomes, genes (and their third codon positions) and long terminal repeats from retroviruses of warm-blooded vertebrates are characterized by a striking bimodality which is accompanied by a remarkable compositional homogeneity within each retroviral genome. A first, major class of retroviral genomes is GC-rich, whereas a second, minor class is GC-poor. Representative expressed viral genomes from the two classes integrate in GC-rich and GC-poor isochores, respectively, of host genomes. The first class comprises all oncoviruses (except B-types and some D-types), the second, lentiviruses, spumaviruses, as well as B-type and some D-type oncoviruses (e.g., mouse mammary tumor virus and simian retroviruses type D, respectively). The compositional bimodal distribution of retroviral genomes and the accompanying compositional homogeneity within each retroviral genome appear to be the result of the compositional evolution of retroviral genomes in their integrated form.

Biology of Rous sarcoma virus adapted for replication and transformation of duck cells.

A duck-adapted variant of the Prague strain of Rous sarcoma virus and its molecularly cloned derivatives were characterized biologically. The virus replicated and transformed with the same efficiency both duck and chicken embryo fibroblasts. The daPR-RSV-C was also used for induction of tumours in newborn hamsters. The virus from virogenic hamster tumours could be rescued using the duck cells as indicator cells. The virus rescue was influenced by restricted replication of the virus in the indicator cells.