Assignment of genes encoding metallothioneins I and II to Chinese hamster chromosome 3: evidence for the role of chromosome rearrangement in gene amplification

Characterization of metallothioneins (MT-I and MT-II) in the yak

The cDNA-encoding sequences for yak metallothionein isoforms I (MT-I) and II (MT-II) were amplified and cloned by reverse-transcription PCR to characterize the nucleotide sequence and protein structure of metallothionein in the yak. The cDNA sequences of MT-I and MT-II were subjected to BLAST searching at the National Center for Biotechnology Information, and the results indicated that the nucleotide sequences of yak MT-I and MT-II, when compared among different species of mammals, are highly conserved. The yak open reading frames have a length of 183 nucleotides, which encode for yak MT-I and MT-II proteins of 61 AA, respectively. Analysis of hydrophobicity, trans-membrane region, and signal peptides suggested that metallothioneins of the yak are nonsecretory proteins. There were several conserved tripeptide sequences, such as C-X-C, C-C-X-C-C, and C-X-X-C (X designates AA excluding cysteine in MT-I and MT-II), and they are highly conserved in their evolution. By homologous comparative modeling, we predicted the molecular spatial structures of yak MT-I and MT-II, which are composed of alpha- and beta-domains that are linked by the conserved tripeptide Lys(30)-Lys(31)-Ser(32) (KKS).

The sequence and analysis of duplication-rich human chromosome 16

Human chromosome 16 features one of the highest levels of segmentally duplicated sequence among the human autosomes. We report here the 78,884,754 base pairs of finished chromosome 16 sequence, representing over 99.9% of its euchromatin. Manual annotation revealed 880 protein-coding genes confirmed by 1,670 aligned transcripts, 19 transfer RNA genes, 341 pseudogenes and three RNA pseudogenes. These genes include metallothionein, cadherin and iroquois gene families, as well as the disease genes for polycystic kidney disease and acute myelomonocytic leukaemia. Several large-scale structural polymorphisms spanning hundreds of kilobase pairs were identified and result in gene content differences among humans. Whereas the segmental duplications of chromosome 16 are enriched in the relatively gene-poor pericentromere of the p arm, some are involved in recent gene duplication and conversion events that are likely to have had an impact on the evolution of primates and human disease susceptibility.

Cytogenetic analysis of amplification and deamplification of UMP synthase genes in Chinese hamster cells

Chinese hamster lung cells selected for resistance to pyrazofurin and 6-azauridine contain amplified UMP synthase genes. With selection in 5-fluorouracil, cells that have lost the amplified gene copies can be isolated. Reselection of deamplified cells in pyrazofurin and 6-azauridine results in reamplification of the UMP synthase genes. We have used chromosomal banding and in situ hybridization techniques to characterize this cyclic process of amplification and deamplification. Homogeneously staining regions (HSRs) were observed in cells containing amplified copies of the UMP synthase gene but not in cells in which the amplified UMP synthase genes had been lost. After reselection in pyrazofurin and 6-azauridine, abnormally banded regions (ABRs) were observed. Both HSRs and ABRs were located at a single site on the distal regions of a small acrocentric autosome, and both were shown to contain the amplified genes. The majority of 5-fluorouracil-selected cells showed residual marker acrocentric chromosomes of various sizes, suggesting excision of portions of the HSR or ABR as the mechanism of deamplification. The acrocentrics carrying the amplified genes resulted from rearrangements involving chromosome 4, site of the endogenous gene. This reversible selection system provides a unique model for investigating gene amplification and deamplification in association with chromosomal rearrangements and the relationship of G-banding to underlying DNA structure.

Molecular and cellular mechanisms of cadmium resistance in cultured cells

Heavy metal induction of the synthesis of metallothioneins (MTs) provides an ideal model system for basic mechanistic studies of gene expression. Cell lines varying in their resistance to heavy metals have been isolated through a regime of exposure to serially increasing levels of Cd followed by clonal isolation. These cell lines have been used to examine the role of methylation and amplification in the Cd-resistant (Cdr) phenotype. It is suggested that regulation of expression of the MT genes in Cdr Chinese hamster cells is modulated at both the transcriptional and translational levels. An analysis of the MT2 gene sequence has uncovered a potential alternative splice site in the first intron. Usage of this site would insert 3 or 12 additional amino acids between amino acids 9 and 10. Analysis of the splicing pattern of the MT2 gene transcript in cultured cells has indicated that the second intron is preferentially removed prior to first intron excision.

5-Azacytidine-induced conversion to cadmium resistance correlates with early S phase replication of inactive metallothionein genes in synchronized CHO cells

Previous studies have shown both hypermethylation and late replication of DNA sequences to be associated with gene inactivity. To determine whether there is a causal relationship between patterns of DNA methylation and replication timing during S phase, we have examined the timing of replication of the inactive, hypermethylated metallothionein (MT) I and II genes in synchronized, cadmium-sensitive (Cds) CHO cells. The time of S-phase replication of the MT genes was ascertained by determining the period of S phase wherein cadmium-resistant (Cdr) cells could be induced with highest frequency by pulse treatment of synchronized Cds cells with the hypomethylating drug 5-azacytidine (5-aza-CR), and by analyzing Southern blots of density fractionated DNAs isolated from synchronized cells pulse-labeled with BrdU during different intervals after release from hydroxyurea blockade. Southern filter hybridization analyses demonstrated replication of both MTI and II gene sequences within the first half of S phase. Consistent with this result, phenotypic conversion of Cds to Cdr was maximal immediately after hydroxyurea release and decreased abruptly within three hours. The replication of inactive hypermethylated MT genes in early S phase argues that transcriptional inactivity and gene-specific hypermethylation are not sufficient conditions for late DNA replication.