TUSC1, a putative tumor suppressor gene, reduces tumor cell growth in vitro and tumor growth in vivo.

We previously reported the identification of TUSC1 (Tumor Suppressor Candidate 1), as a novel intronless gene isolated from a region of homozygous deletion at D9S126 on chromosome 9p in human lung cancer. In this study, we examine the differential expression of TUSC1 in human lung cancer cell lines by western blot and in a primary human lung cancer tissue microarray by immunohistochemical analysis. We also tested the functional activities and mechanisms of TUSC1 as a tumor suppressor gene through growth suppression in vitro and in vivo. The results showed no expression of TUSC1 in TUSC1 homozygously deleted cells and diminished expression in some tumor cell lines without TUSC1 deletion. Interestingly, the results from a primary human lung cancer tissue microarray suggested that higher expression of TUSC1 was correlated with increased survival times for lung cancer patients. Our data demonstrated that growth curves of tumor cell lines transfected with TUSC1 grew slower in vitro than those transfected with the empty vector. More importantly, xenograph tumors in nude mice grew significantly slower in vivo in cells stably transfected with TUSC1 than those transfected with empty vector. In addition, results from confocal microscopy and immunohistochemical analyses show distribution of TUSC1 in the cytoplasm and nucleus in tumor cell lines and in normal and tumor cells in the lung cancer tissue microarray. Taken together, our results support TUSC1 has tumor suppressor activity as a candidate tumor suppressor gene located on chromosome 9p.

Identifying novel homozygous deletions by microsatellite analysis and characterization of tumor suppressor candidate 1 gene, TUSC1, on chromosome 9p in human lung cancer.

Loss of heterozygosity (LOH) studies indicate that genetic alterations of chromosome 9p occur in numerous tumor types, suggesting the presence of tumor suppressor genes (TSGs) on chromosome 9p critical in carcinogenesis. Our previous LOH analyses in primary lung tumors led us to propose that chromosome 9p harbors other TSGs important in lung tumorigenesis. In this study, 30 non-small-cell lung cancer and 12 small-cell lung cancer cell lines were screened with 55 markers to identify new regions of homozygous deletion (HD) on chromosome 9p. Three novel noncontiguous homozygously deleted regions were detected and ranged in size from 840 kb to 7.4 Mb. One gene identified in the deletion at D9S126, TUSC1 (tumor suppressor candidate 1), is an intronless gene. Multiplex polymerase chain reaction and Southern blot confirmed the HD of TUSC1. Northern blot analysis of TUSC1 demonstrated two transcripts of approximately 2 and 1.5 kb that are likely generated by alternative polyadenylation signals. Both transcripts are expressed in several human tissues and share an open-reading frame encoding a peptide of 209 amino acids. Analysing cell line cDNAs by reverse transcriptase (RT)-PCR demonstrated downregulation of TUSC1 in cell lines with or without HDs, suggesting that TUSC1 may play a role in lung tumorigenesis.

Identification and characterization of a gene encoding a putative mouse Rho GTPase activating protein gene 8, Arhgap8.

Rho GTPase activating proteins promote the intrinsic GTP hydrolysis activity of Rho family proteins. We isolated a putative mouse ortholog of the human Rho GTPase activating protein 8, ARHGAP8. The open reading frame encodes a peptide of 387 amino acids with high homology to human ARHGAP8 in its N-terminal domain. Both radiation hybrid mapping and fluorescent in situ hybridization localized the gene to mouse chromosome 15E. The 23 kb genomic Arhgap8 sequence consists of eight exons and seven introns. Northern blot and RT-PCR analyses showed that a transcript of approximately 1.9 kb is ubiquitously expressed in various adult mouse tissues with particularly strong expression in kidney.

Isolation and characterization of cold-shock domain protein genes, Oryzias latipes Y-box protein 2 (OlaYP2) and Fugu rubripes Y-box protein 1 (FruYP1), in medakafish and pufferfish.

The Y-box protein (YP) family shares a nucleic acid binding domain, called cold-shock domain, that has been evolutionarily highly conserved from bacteria to human. The different YPs identified so far in vertebrates are thought to function as transcriptional activators, transcriptional repressors and/or translational repressors. Medakafish and pufferfish are very suitable vertebrate models for the study of developmental genetics and comparative genomics, respectively. Here we report the isolation of two teleost YP genes, medakafish Oryzias latipes (Ola)YP2 and Fugu rubripes (Fru)YP1, which are expressed in multiple tissues. Phylogenetic analysis demonstrated that OlaYP2 and FruYP1 belong to different subclasses of the cold-shock domain protein genes. Future studies in suitable model systems, like the medaka for developmental biology and Fugu for evolutionary genomics, are expected to contribute to our understanding of YPs.

A duplicated copy of DMRT1 in the sex-determining region of the Y chromosome of the medaka, Oryzias latipes.

The genes that determine the development of the male or female sex are known in Caenorhabditis elegans, Drosophila, and most mammals. In many other organisms the existence of sex-determining factors has been shown by genetic evidence but the genes are unknown. We have found that in the fish medaka the Y chromosome-specific region spans only about 280 kb. It contains a duplicated copy of the autosomal DMRT1 gene, named DMRT1Y. This is the only functional gene in this chromosome segment and maps precisely to the male sex-determining locus. The gene is expressed during male embryonic and larval development and in the Sertoli cells of the adult testes. These features make DMRT1Y a candidate for the medaka male sex-determining gene.

A cascade of complex subtelomeric duplications during the evolution of the hominoid and Old World monkey genomes.

Subtelomeric duplications of an obscure tubulin "genic" segment located near the telomere of human chromosome 4q35 have occurred at different evolutionary time points within the last 25 million years of the catarrhine (i.e., hominoid and Old World monkey) evolution. The analyses of these segments reported here indicate an exceptional level of evolutionary instability. Substantial intra- and interspecific differences in copy number and distribution are observed among cercopithecoid (Old World monkey) and hominoid genomes. Characterization of the hominoid duplicated segments reveals a strong positional bias within pericentromeric and subtelomeric regions of the genome. On the basis of phylogenetic analysis from predicted proteins and comparisons of nucleotide-substitution rates, we present evidence of a conserved b-tubulin gene among the duplications. Remarkably, the evolutionary conservation has occurred in a nonorthologous fashion, such that the functional copy has shifted its positional context between hominoids and cercopithecoids. We propose that, in a chimpanzee-human common ancestor, one of the paralogous copies assumed the original function, whereas the ancestral copy acquired mutations and eventually became silenced. Our analysis emphasizes the dynamic nature of duplication-mediated genome evolution and the delicate balance between gene acquisition and silencing.