Haematopoietic repopulating activity in human cord blood CD133+ quiescent cells.

We have demonstrated previously that cord blood CD133(+) cells isolated in the G(0) phase of the cell cycle are highly enriched for haematopoietic stem cell (HSC) activity, in contrast to CD133(+)G(1) cells. Here, we have analysed the phenotype and functional properties of this population in more detail. Our data demonstrate that a large proportion of the CD133(+)G(0) cells are CD38 negative (60.4%) and have high aldehyde dehydrogenase activity (75.1%) when compared with their CD133(+)G(1) counterparts (13.5 and 4.1%, respectively). This suggests that stem cell activity resides in the CD133(+)G(0) population. In long-term BM cultures, the CD133(+)G(0) cells generate significantly more progenitors than the CD34(+)G(0) population (P<0.001) throughout the culture period. Furthermore, a comparison of CD133(+)G(0) versus CD133(+)G(1) cells revealed that multilineage reconstitution was obtained only in non-obese diabetic/SCID animals receiving G(0) cells. We conclude that CD133(+) cells in the quiescent phase of the cell cycle have a phenotype consistent with HSCs and are highly enriched for repopulating activity when compared with their G(1) counterparts. This cell population should prove useful for selection and manipulation in ex vivo expansion protocols.

Marker gene transfer into human haemopoietic cells using a herpesvirus saimiri-based vector.

Herpesvirus-based gene therapy vectors offer an attractive alternative to retroviral vectors because of their episomal nature and ability to accommodate large transgenes. Saimiriine herpesvirus 2 (HVS) is a prototypical gamma-2 herpesvirus that can latently infect numerous different cell types. A cosmid-generated HVS vector in which transforming genes have been deleted and the marker gene encoding enhanced green fluorescent protein (HVS-GFP) has been incorporated was evaluated for its potential to transduce CD34+ haemopoietic progenitors selected from cord blood. Expression of GFP could subsequently be readily detected in cells of the erythroid lineage in both CFU-GEMM assays and liquid differentiation cultures. These results confirm the potential of HVS as a candidate vector for gene therapy applications using primitive haemopoietic cells and suggest that it may be applicable to disorders affecting cells of the erythroid lineage.

BCL10 in malignant lymphomas--an evaluation using fluorescence in situ hybridization.

BCL10 is a tumour suppressor gene originally cloned from a t(1;14)(p22;q32) breakpoint in a case of mucosa-associated lymphoid tissue (MALT) lymphoma. Translocations involving this gene, though uncommon, are sometimes encountered in MALT lymphomas. This gene is thought to play an important role in the development of malignant lymphomas. Fluorescence in situ hybridization (FISH) was therefore undertaken on 22 cases of malignant lymphoma of varying histology to establish the incidence of rearrangements involving the BCL10 gene. Initially, one case with a novel t(1;2)(p22;p12) translocation involving the BCL10 gene was identified, in a marginal zone lymphoma of the MALT type, and was reported elsewhere. Seven other cases were subsequently identified with abnormalities in the 1p region, including a translocation with a breakpoint in the 1p22 region in a case of lymphoblastic lymphoma. However, none of these involved the BCL10 gene. Mutation analysis of BCL10 was then performed on 57 cases of malignant lymphoma, including 17 MALT lymphomas, by single-strand conformational polymorphism (SSCP) analysis of tumour DNA. Tissue was obtained for mutation analysis for 12 of the 22 cases analysed by FISH. Selected cases with SSCP band shifts were further studied by direct sequencing. Polymorphisms were identified in eight cases, but no mutations of pathogenic significance were identified. Further RT-PCR and mutation analysis was performed on cDNAs from 12 cases (four MALT, seven diffuse large B-cell lymphoma, one Hodgkin's disease) in which DNA analysis had already been completed. This included the MALT lymphoma with the t(1;2)(p22;p12) rearrangement. Again, no mutations were identified in the coding sequence. This study confirms that rearrangements of the BCL10 gene are uncommon in lymphoma (1/22) and may be limited tothe MALT subtype of non-Hodgkin's lymphomas. It was also found that breakpoints or rearrangements in the 1p22 region do not necessarily involve the BCL10 gene. Moreover, the absence of mutations at both the DNA (0/60) and the mRNA (0/12) level indicates that this gene is not frequently inactivated by mutation, in those tumours in which it is not involved in translocations. Our findings suggest that the BCL10 gene is unlikely to have a frequent or key role in general lymphomagenesis.

Genetic events during the transformation of a tamoxifen-sensitive human breast cancer cell line into a drug-resistant clone.

Tamoxifen resistance is a serious clinical problem commonly encountered in the management of patients with breast cancer. The mechanisms leading to its development are unclear. Tamoxifen acts via multiple pathways and has diverse effects. Hence transformation from a tamoxifen-sensitive to a resistant phenotype could involve multiple genetic events. Knowledge of the genetic pathways leading to resistance may facilitate the development of novel therapeutic strategies. In this study, a variation of conventional comparative genomic hybridization (CGH) has been employed to detect genetic alterations associated with tamoxifen resistance. MCF-7, a tamoxifen-sensitive human breast cancer cells line, and its tamoxifen-resistant clone, CL-9 were used. Both cell lines showed extensive areas of concordance but consistent differences were seen with the acquisition of tamoxifen resistance. These differences included the amplification of 2p16.3 approximately p23.2, 2q21 approximately q34, 3p12.3 approximately p14.1, 3p22 approximately p26, 3q, 12q13.2 approximately q22, 13q12 approximately q14, 17q21.3 approximately q23, 20q11.2 approximately q13.1 and 21q11.2 approximately q21 as well as the deletion of 6p21.1, 6p23 approximately p25, 7q11.1 approximately q31, 7q35 approximately q36, 11p15, 11q24, 13q33, 17p, 18q12 approximately q21.1, 19p, 19q13.3, 22q13.1 approximately q13.2. These findings were supported by conventional cytogenetics and chromosome painting. The regions identified by CGH potentially harbor genes that could be important in the development of tamoxifen resistance.

Characterisation of the human and mouse orthologues of the Drosophila ariadne gene.

The specificity of the ubiquitin degradation system is regulated through interaction between individual ubiquitin-conjugating enzymes (E2s) and multiple ubiquitin-protein ligases (E3s). Here we describe the characterisation of a novel gene (ARIH1) that encodes the human homologue of Drosophila ariadne which interacts with the E2s, UbcH7 and UbcH8 and represents a component of an E3 complex. Three PACs (189N19, 142P17 and 179H7) were isolated that contain this gene. Using these PACs as probes, we mapped ARIH1 to human chromosome 15q24 by fluorescence in situ hybridisation (FISH). Sequencing of the ARIH1 PACs showed that the gene has 13 introns. In addition, we isolated two PACs (345D8 and 571P19) containing the mouse orthologue (Arih1) of ARIH1. The intron-exon structure of Arih1 was identical to ARIH1 and the proteins demonstrated a 98% identity at the amino acid level. Furthermore, comparison of Drosophila ariadne with ARIH1 indicates an identity at the amino acid level of 70% and introns at 3/7 identical sites. The high degree of homology demonstrated by the mouse and human orthologues of Drosophila ariadne indicates an important, conserved biological function, consistent with a putative role in ubiquitylation.

Novel translocation of the BCL10 gene in a case of mucosa associated lymphoid tissue lymphoma.

Interest has focused on a recently identified gene, BCL10, thought to play an important role in the genesis of extranodal, marginal zone (MALT) lymphomas. This gene belongs to a family containing caspase recruitment domains (CARD), that are involved in the apoptotic pathway. Translocations of the BCL10 gene to the immunoglobulin heavy chain locus at 14q32 have been described. We report herein a case of MALT lymphoma showing t(1; 2)(p22; p12). The translocation was shown to involve the BCL10 gene and the immunoglobulin kappa light chain locus by fluorescence in situ hybridization.

Genomic organization of the human ubiquitin-conjugating enzyme gene, UBE2L6 on chromosome 11q12.

The human UBE2L6 gene encodes UbcH8(Kumar), a ubiquitin-conjugating enzyme (E2) highly simliar in primary structure to UbcH7 which is encoded by UBE2L3. Like UBC4 and UBC5 in yeast, these proteins demonstrate functional redundancy. Herein we report the intron/exon structure of UBE2L6. Comparison of the genomic organization of UBE2L6 with UBE2L3 demonstrates that these genes remain highly conserved at the genomic as well as at the protein level. We also describe the chromosomal localization of UBE2L6, which maps to chromosome 11q12.

Identification of a novel microsatellite marker tightly linked to the KAI-1 gene for predicting prostate cancer progression.

BACKGROUND: We have mapped the human prostate-specific membrane antigen (PSM) gene to the chromosome 11p11.2 region at 62.5 cM, a region which also contains the prostatic cancer metastasis suppressor gene KAI-1. The genetic marker D11S1344 has been utilised for loss of heterozygosity (LOH) studies on the KAI-1 gene in a large series of prostate cancer specimens. The results were negative and it was concluded that deletions of the KAI-1 gene were not involved in the development of the metastatic phenotype in these tumours. One possible explanation for this result could be that D11S1344 is not sufficiently tightly linked to the KAI-1 gene to detect small deletions. OBJECTIVE: To attempt to identify a genetic marker more tightly linked to the KAI-1 gene than D11S1344. METHODS: Yeast artificial chromosome (YAC) clones containing the KAI-1 gene and the neighbouring marker D11S1344 were analysed by the fluorescent in situ hybridisation technique. The human genomic inserts in these novel clones were sized by pulsed field gel electrophoresis. For more accurate mapping of the KAI-1 gene, YACs containing it were screened for polymorphic markers (including D11S1344) from the 11p11.2 region. RESULTS: The novel YAC clones localised exclusively to the 11p11.2 region, with single hybridisation signals compared to the dual signals consistently obtained with nearby PSM-containing YACs. All the KAI-1 clones found had small inserts (<300 kb). The only known microsatellite which gave amplification products with these YACs was D11S986 which has been mapped at 61.3 cM on human chromosome 11. CONCLUSIONS: We have precisely localised KAI-1 at 61.3 cM on human chromosome 11. This is some 1.2 cM away from the previously utilised LOH microsatellite marker, D11S1344. We suggest that the very tightly linked microsatellite D11S986 may be a more accurate marker to assess LOH of the KAI-1 gene and thus predict progression of prostate cancer. The region of genetic duplication around the PSM gene does not extend as far distally on 11p as KAI-1.

A locus for isolated cleft palate, located on human chromosome 2q32.

We present evidence for the existence of a novel chromosome 2q32 locus involved in the pathogenesis of isolated cleft palate. We have studied two unrelated patients with strikingly similar clinical features, in whom there are apparently balanced, de novo cytogenetic rearrangements involving the same region of chromosome 2q. Both children have cleft palate, facial dysmorphism, and mild learning disability. Their karyotypes were originally reported as 46, XX, t(2;7)(q33;p21) and 46, XX, t(2;11)(q33;p14). However, our molecular cytogenetic analyses localize both translocation breakpoints to a small region between markers D2S311 and D2S116. This suggests that the true location of these breakpoints is 2q32 rather than 2q33. To obtain independent support for the existence of a cleft-palate locus in 2q32, we performed a detailed statistical analysis for all cases in the human cytogenetics database of nonmosaic, single, contiguous autosomal deletions associated with orofacial clefting. This revealed 2q32 to be one of only three chromosomal regions in which haploinsufficiency is significantly associated with isolated cleft palate. In combination, our data provide strong evidence for the location at 2q32 of a gene that is critical to the development of the secondary palate. The close proximity of these two translocation breakpoints should also allow rapid progress toward the positional cloning of this cleft-palate gene.

Detailed genetic mapping around a putative prostate-specific membrane antigen locus on human chromosome 11p11.2.

Physical mapping of the human prostate-specific membrane antigen gene (FOLH) has not been straightforward. Previously, localisations of this gene to either 11p11.2 or 11q14 have been described. This raised the possibility of the presence of more than one related FOLH gene in man. We now present detailed characterisation of the region around a FOLH gene in a 500-kb non-chimaeric YAC clone, putatively assigned to 11p11.2. This clone contains two known microsatellites, D11S1326 and D11S1357 which have been previously mapped unequivocally to the 11p11.2 region at 62.5 cM. This data strongly supports the original 11p11.2 localisation of FOLH. The YAC clone also has a putative EST at each of its ends and these have thus been physically positioned on this chromosome. However, the two regions previously highlighted at 11p11.2 and 11q14 are apparently extensively duplicated, as evidenced by the appearance of dual FISH signals with a number of different genomic probes selected across this 500-kb 11p11.2 region.

Organization of the human glucokinase regulator gene GCKR.

Glucokinase plays an important role in regulating insulin secretion in response to changes in blood glucose levels. As a result, one form of maturity onset diabetes of the young (MODY) results from haploinsufficiency of glucokinase. In both liver and pancreatic islet, glucokinase is allosterically regulated by an inhibitory protein (glucokinase regulatory protein, GCKR). GCKR has therefore become an important gene for functional analysis in type 2 diabetes. To allow genetic assessment of any such role, we have determined the structure of the human GCKR gene. Characterization of P1 and YAC clones containing GCKR shows it to consist of 19 exons spanning 27 kb. RT-PCR, RACE, and RNase protection experiments defined a transcriptional start site for GCKR 66 bp upstream of the initiation codon, but provided no evidence for islet cell specific alternative splicing in the rat. By SSCP screening, a common polymorphic sequence variant has been defined within exon 15 of human GCKR, at nt 1400 of the cDNA. This alters amino acid residue 446 from proline, conserved in rat and Xenopus, to leucine.

Characterization of human SHC p66 cDNA and its processed pseudogene mapping to Xq12-q13.1.

SHC is an adapter protein in the Ras-MAPkinase pathway that is involved in the regulation of cell growth and differentiation. The p46 and p52 isoforms are thought to be produced by the use of two alternative translation initiation sites in a 3.4-kb transcript from the SHCA gene, which maps to chromosome 1q21. The p66 isoform could be encoded by a different 3.8- or 2.8-kb transcript of the same gene or alternatively by a SHC-related gene. To characterize other putative genes coding for SHC-like proteins, primers from the 3' UTR of the SHCA gene were used to screen a yeast artificial chromosome (YAC) library by polymerase chain reaction (PCR). Two YAC clones, 20D11B and 36D1D, were isolated and used as probes for fluorescence in situ hybridization analysis. Both these probes hybridized to chromosome Xq12-q13.1. This novel SHC-related sequence was characterized by direct sequencing of vectorette library PCR products produced from clone 20D11B. A transcript of 3.2 kb that was 85% identical to the mouse Shc cDNA encoding the p66 isoform was identified. Sequence analysis demonstrated the presence of multiple stop codons identifying this isoform of SHC as a processed pseudogene. Using primers designed on the basis of the nucleotide sequence of the pseudogene, we have now amplified and sequenced a human cDNA that encodes the SHC p66 protein. Thus, we have characterized the human SHC p66 isoform cDNA and identified a processed SHC pseudogene that maps to chromosome Xq12-q13.1.