Mark A. Pershouse

Identification of a candidate tumour suppressor gene, MMAC1, at chromosome 10q23.3 that is mutated in multiple advanced cancers

Deletions involving regions of chromosome 10 occur in the vast majority (>90%) of human glioblastoma multiformes. A region at chromosome 10q23–24 was implicated to contain a tumour suppressor gene and the identification of homozygous deletions in four glioma cell lines further refined the location. We have identified a gene, designated MMAC1, that spans these deletions and encodes a widely expressed 5.5-kb mRNA. The predicted MMAC1 protein contains sequence motifs with significant homology to the catalytic domain of protein phosphatases and to the cytoskeletal proteins, tensin and auxilin. MMAC1 coding-region mutations were observed in a number of glioma, prostate, kidney and breast carcinoma cell lines or tumour specimens. Our results identify a strong candidate tumour suppressor gene at chromosome 10q23.3, whose loss of function appears to be associated with the oncogenesis of multiple human cancers.

Deletion mapping of chromosome 4 in head and neck squamous cell carcinoma

Genomic deletions involving chromosome 4 have recently been implicated in several human cancers. To identify and characterize genetic events associated with the development of head and neck squamous cell carinoma (HNSCC), a fine mapping of allelic losses associated with chromosome 4 was performed on DNA isolated from 27 matched primary tumor specimens and normal tissues. Loss of heterozygosity (LOH) of at least one chromosome 4 polymorphic allele was seen in the majority of tumors (92%). Allelic deletions were confined to short arm loci in four tumors and to the long arm loci in 12 tumors, suggesting the presence of two regions of common deletion. One region of frequent deletion was centered at D4S405 on 4p and included the loci D4S1546 to D4S428 in ∼41% of the tumors. The common region of deletion on 4q was more complex and extended from D4S1571 to D4S1573. Frequent genetic alterations were observed within this region (4q25) and one marker, D4S407, exhibited a high frequency of LOH (>75%). These results indicate that alterations of chromosome 4 regions are associated with HNSCC tumorigenesis and further localizes the regions that may harbor tumor suppressor genes.

Cytoplasmic immunoglobulin content in multiple myeloma.

Bone marrow cells of 82 patients with multiple myeloma were subjected to flow cytometric analysis of DNA and cytoplasmic immunoglobulin (CIg) content using propidium iodide and direct immunofluorescence assays. Except for two patients with nonsecretory myeloma, there was conformity in the immunoglobulin type derived from immunoelectrophoresis and plasma cell CIg staining. One patient with nonsecretory myeloma exhibited monotypic CIg staining, while the second showed no reaction. In eight patients with IgG lambda myeloma, the same tumor cells contained both lambda and kappa light chains, suggesting the productive rearrangement of both light chain genes. 14 patients with previously unrecognized plasma cells of low RNA content, all of whom were resistant to chemotherapy, were identified by CIg staining. By revealing previously unrecognized plasma cells with low RNA content, CIg analysis identified more patients with treatment-refractory myeloma.

Functional and molecular analyses of 10q deletions in human gliomas.

Extensive genomic deletions involving chromosome 10 are the most common genetic alteration in glioblastoma multiforme (GBM). To localize and examine the potential roles of two chromosome arm 10q tumor suppressor regions, we used two independent strategies: mapping of allelic deletions, and functional analysis of phenotypic suppression after transfer of chromosome 10 fragments. By allelic deletion analysis, the region of 10q surrounding the MMAC/PTEN locus was shown to be frequently lost in GBMs but maintained in most low‐grade astrocytic tumors. An additional region at 10q25 containing the DMBT1 locus was lost in all grades of gliomas examined. The potential biological significance of these two regions was further assessed by examining microcell hybrids that contained various fragments of 10q. Somatic cell hybrid clones that retained the MMAC/PTEN locus have a less transformed phenotype with clones exhibiting an inability to grow in soft agarose. However, presence or absence of DMBT1 did not correlate with any in vitro phenotype assessed in our model system. These results support a model of molecular progression in gliomas in which the frequent deletion of 10q25–26 is an early event and is followed by the deletion of the MMAC/PTEN during the progression to high‐grade GBMs. Genes Chromosomes Cancer 24:135–143, 1999.

Silica, Apoptosis, and Autoimmunity

Abstract Relatively little is known regarding mechanisms of environmental exposures in the development of autoimmune disease. However, several environmental agents are implicated in triggering or accelerating systemic autoimmune disease, including mercury, iodine, vinyl chloride, certain pharmaceuticals, and crystalline silica. There is increasing epidemiological evidence supporting the hypothesis that occupational silica exposure is associated with a variety of systemic autoimmune diseases, including scleroderma (SSc), rheumatoid arthritis (RA), systemic lupus erythematosus (SLE), glomerulonephritis (GN) and small vessel vasculitis (SVV). However, there have been few mechanistic studies examining silica exposure and autoimmune disease initiation and progression. This review summarizes human epidemiology data linking silica exposure with systemic autoimmune disease, but focuses on possible mechanisms by which silica can lead to the development and progression of autoimmunity.

Pharmacogenetics in American Indian populations: analysis of CYP2D6, CYP3A4, CYP3A5, and CYP2C9 in the Confederated Salish and Kootenai Tribes.

Objectives Cytochrome P450 enzymes play a dominant role in drug elimination and variation in these genes is a major source of interindividual differences in drug response. Little is known, however, about pharmacogenetic variation in American Indian and Alaska Native (AI/AN) populations. We have developed a partnership with the Confederated Salish and Kootenai Tribes (CSKT) in northwestern Montana to address this knowledge gap. Methods We resequenced CYP2D6 in 187 CSKT individuals and CYP3A4, CYP3A5, and CYP2C9 in 94 CSKT individuals. Results We identified 67 variants in CYP2D6, 15 in CYP3A4, 10 in CYP3A5, and 41 in CYP2C9. The most common CYP2D6 alleles were CYP2D6*4 and *41 (20.86 and 11.23%, respectively). CYP2D6*3, *5, *6, *9, *10, *17, *28, *33, *35, *49, *1xN, *2xN, and *4xN frequencies were less than 2%. CYP3A5*3, CYP3A4*1G, and *1B were detected with frequencies of 92.47, 26.81, and 2.20%, respectively. Allelic variation in CYP2C9 was low: CYP2C9*2 (5.17%) and *3 (2.69%). In general, allele frequencies in CYP2D6, CYP2C9, and CYP3A5 were similar to those observed in European Americans. There was, however, a marked divergence in CYP3A4 for the CYP3A4*1G allele. We also observed low levels of linkage between CYP3A4*1G and CYP3A5*1 in the CSKT. The combination of nonfunctional CYP3A5*3 and putative reduced function CYP3A4*1G alleles may predict diminished clearance of CYP3A substrates. Conclusion These results highlight the importance of carrying out pharmacogenomic research in AI/AN populations and show that extrapolation from other populations is not appropriate. This information could help optimize drug therapy for the CSKT population.

Direct formation of microcells from mitotic cells for use in chromosome transfer

Microcells, cytoplasmic fragments that contain micronuclei composed of one or a few chromosomes, can be generated directly from mitotic cells. Cytochalasin B, which causes nuclear extrusion in interphase cells, has a similar effect on the chromosomes of colcemid-blocked mitotic cells. The forces generated during centrifugation in a Percoll gradient are sufficient to separate the extruded microcells from the parent cell. The chromosomes contained in an extruded microcell form micronuclei during the process, and in all respects are comparable to microcells generated from micronucleated cells except that they are uniformly in the G1 phase of the cell replication cycle. The procedure is probably applicable to all mammalian cells that grow in culture and can be employed to make microcells for the transfer of both intact and fragmented chromosomes.

The Role of SV40 in Malignant Mesothelioma and Other Human Malignancies

SV40 is a DNA tumor virus thrust upon human populations primarily as a contaminant in various vaccine preparations. Some estimates suggest that millions of people are currently infected with the virus. The virus causes primary brain tumors, bone tumors, lymphomas, and mesotheliomas when injected into some rodent models. It has also been detected in a similar spectrum of human tumors. However, epidemiological studies have failed to conclusively demonstrate a higher incidence of disease in affected populations. To date, over 60 reports from 49 different laboratories have shown SV40 sequences in tissues from human cancer patients. Six studies, however, have failed to detect evidence of virus in similar tissues. Some have suggested that SV40 may act as a cocarcinogen with asbestos to cause mesothelioma formation, or that it may be responsible for the 10–20% of mesotheliomas with no reported history of asbestos exposure. This report briefly covers the historical evidence for SV40 carcinogenesis and then covers experiments now underway to better understand the role of SV40 in human mesotheliomas.

Gene expression changes after exposure to six-mix in a mouse model.

The exposure of Libby MT residents to amphibole-contaminated vermiculite is well known. To explore the gene-environment interactions in the development of asbestos-related diseases (ARD), a mouse model of asbestos exposure using Six-mix (a combination of amphibole fibers gathered from six sites at the Libby vermiculite mine), crocidolite asbestos, or saline as a negative control was used to determine both gene expression responses by using mouse 10,000 oligonucleotide array and to visualize these changes histologically. Mice were sacrificed and whole lungs harvested for histology and microarray analysis six months following exposure via intratracheal instillation. Using an arbitrary cutoff of 1.25-fold change, genes whose RNA expression levels were specifically altered in response to the different amphibole exposures were grouped into categories by a gene ontology analysis program, GoMiner. Our hypothesis was that assessment of asbestos-responsive genes would provide a better understanding of response mechanisms. These experiments have provided new candidates for genes involved in the asbestos response pathways.

Identification of a novel gene product, RIG, that is down-regulated in human glioblastoma.

Genetic deletions to chromosome 10 have been extensively documented for human glioblastomas (GBMs). To identify gene products that may be involved in malignant progression, a subtractive hybridization was performed between GBM cells and hybrid cells suppressed for tumorigenicity following microcell transfer of chromosome 10. One novel cDNA isolated from this subtraction showed consistent upregulation (∼4 to 10-fold) that correlated with the nontumorigenic phenotype of the hybrid cells. Subsequent analysis resulted in the identification of a full length cDNA (2,569 bp) termed RIG (regulated in glioma). RIG expression was either not detected or detected only at low levels in cultured glioma cells and primary glioblastoma specimens compared to normal brain cells. The 2.6 kb RIG mRNA was expressed predominantly in normal brain with lower levels in heart and lung. Sequence analysis showed no significant homology to known gene products. Genomic alterations of RIG were present in ∼25% of glioma cell lines examined. Also, RIG mapped to chromosome 11p15.1, a region that is known to be altered in malignant astrocytomas. The differential expression pattern, tissue distribution and chromosomal location of RIG suggests it serves as a molecular marker for or may play a role in the malignant progression of GBMs.