Novel structure of a Chinese hamster polyubiquitin gene

Characterization of the nucleotide sequence of a polyubiquitin gene (PUBC1) from Arabian camel, Camelus dromedarius

Molecular amplification and sequencing of genomic DNA that encodes camel polyubiquitin (PUBC1) was performed by a polymerase chain reaction (PCR) using various sets of primers. The amplification generated a number of DNA fragments, which were sequenced and compared with the polyubiquitin coding sequences of various species. One DNA fragment that conformed to 325 bp was found to be 95 and 88% homologous to the sequences of human polyubiquitin B and C, respectively. The DNA translated into 108 amino acids that corresponded to two fused units of ubiquitin with no intervening sequence, which indicates that it is a polyubiquitin and contains at least two units of ubiquitin. Although, variations were found in the nucleotide sequence when compared to those of other species, the amino acid sequence was 100% homologous to the polyubiquitin sequences of humans, mice, and rats. This is the first report of the polyubiquitin DNA coding sequence and its corresponding amino acid sequence from camels, amplified using direct genomic DNA preparations.

Characterization of the ubiquitin-specific protease activity of the mouse/human Unp/Unph oncoprotein

The ubiquitin-specific proteases (Ubps) are a family of largely dissimilar enzymes with two major conserved sequence regions, containing either a conserved cysteine residue or two conserved histidine residues, respectively. The murine Unp oncoprotein and its human homologue, Unph, both contain regions similar to the conserved Cys and His boxes common to all the Ubps. In this study we show that Unp and Unph are active deubiquitinating enzymes, being able to cleave ubiquitin from both natural and engineered linear ubiquitin-protein fusions, including the polyubiquitin precursor. Mutation of the conserved Unp Cys and His residues abolishes this activity, and identifies the likely His residue in the catalytic triad. Unp is tumorigenic when overexpressed in mice, leading to the suggestion that Unp may play a role in the regulation of ubiquitin-dependent protein degradation. We have demonstrated here that the high-level expression of Unp in yeast does not disrupt the degradation of the N-end rule substrate Tyr-beta-galactosidase (betagal), the non-N-end rule substrate ubiquitin-Pro-betagal, or the degradation of abnormal, canavanine-containing proteins. These data suggest that Unp is not a general modulator of ubiquitin-dependent proteolysis. However, Unp may have a role in the regulation of the degradation of a specific, as yet undescribed, substrate(s).

Purifying selection and birth-and-death evolution in the ubiquitin gene family

Ubiquitin is a highly conserved protein that is encoded by a multigene family. It is generally believed that this gene family is subject to concerted evolution, which homogenizes the member genes of the family. However, protein homogeneity can be attained also by strong purifying selection. We therefore studied the proportion (p(S)) of synonymous nucleotide differences between members of the ubiquitin gene family from 28 species of fungi, plants, and animals. The results have shown that p(S) is generally very high and is often close to the saturation level, although the protein sequence is virtually identical for all ubiquitins from fungi, plants, and animals. A small proportion of species showed a low level of p(S) values, but these values appeared to be caused by recent gene duplication. It was also found that the number of repeat copies of the gene family varies considerably with species, and some species harbor pseudogenes. These observations suggest that the members of this gene family evolve almost independently by silent nucleotide substitution and are subjected to birth-and-death evolution at the DNA level.

Higher frequency of concerted evolutionary events in rodents than in man at the polyubiquitin gene VNTR locus

The polyubiquitin gene is an evolutionarily conserved eukaryotic gene, encoding tandemly repeated multiple ubiquitins, and is considered to be subject to concerted evolution. Here, we present the nucleotide sequences of new alleles of the polyubiquitin gene UbC in humans and CHUB2 in Chinese hamster, which encode a different number of ubiquitin units from those of previously reported genes. And we analyze the concerted evolution of these genes on the basis of their orthologous relationship. That the mean of the synonymous sequence difference Ks which is defined as the number of synonymous substitution relative to the total number of synonymous sites, within the UbC and CHUB2 genes (0.192 +/- 0.096) is significantly less than Ks between these genes (0.602 +/- 0.057) provides direct evidence for concerted evolution. Moreover, it also appears that concerted evolutionary events have been much more frequent in CHUB2 than in UbC, because Ks within CHUB2 (0.022 +/- 0.018) is much less than that within UbC (0.362 +/- 0.192). By a numerical simulation, postulating that the major mechanism of concerted evolution in polyubiquitin genes is unequal crossing over, we estimated the frequency of concerted evolutionary events of CHUB2 at 3.3 x 10(-5) per year and that of UbC at no more than 5.0 x 10(-7) per year.

An Acanthamoeba polyubiquitin gene and application of its promoter to the establishment of a transient transfection system

We have isolated and sequenced a 2388 bp polyubiquitin encoding genomic DNA from Acanthamoeba encompassing two complete and one incomplete ubiquitin units. Codon usage frequency shows extreme bias. The deduced amino acid sequences of each unit are identical to each other and the same as that deduced from a previously sequenced Acanthamoeba castellanii cDNA. The upstream region of this gene, which contained some putative regulatory modules, was recovered by PCR (polymerase chain reaction) amplification and subcloning. This upstream fragment was ligated to the CAT (chloramphenicol acetyltransferase) gene in a eukaryotic expression plasmid and successfully applied to the establishment of an Acanthamoeba transient transfection system. Transfection was performed by electroporation and the optimal voltage was 4500 volts/cm at capacitance 25 microF. DEAE-dextran (25 microg/ml) added into the electroporation buffer increased the transfection efficiency by about 45%. The CAT activity was proportional to the amount of DNA transfected and reached the peak level 48 h after transfection. CAT assays showed that the polyubiquitin gene upstream fragment contains a functional promoter which is about 2.5 times as strong as a viral RSV-LTR promoter when driving CAT expression in Acanthamoeba.

Stable transfection of Acanthamoeba

The promoter activity of an Acanthamoeba polyubiquitin gene was analyzed in its homologous system. A modified calcium phosphate transfection method using a neomycin marker vector was developed to achieve highly efficient transfection of the Acanthamoeba polyubiquitin gene into Acanthamoeba cells. In this transfection procedure, the calcium phosphate-DNA complex was formed gradually in the medium during incubation with cells and precipitated on the cells. The crucial factors for obtaining efficient transfection were the pH (6.95) of the transfection buffer used for the calcium phosphate precipitation and the amount (25 micrograms/96-well tissue culture plate) and form (circular) of transfecting DNA. Under these conditions, Acanthamoeba isolate 1B6 was transfected at an efficiency of about 40% with the constructed vector pOPSBU, a pOP13CAT-based polyubiquitin gene incorporated neomycin resistance vector. Acanthamoeba polyphaga was transfected at an efficiency of about 10% with this vector. Transfection of both Acanthamoeba strains appeared to result in low copy plasmid integration (about two copies per cell are suggested). The chloramphenicol acetyltransferase (CAT) assays showed that the promoter of the Acanthamoeba polyubiquitin gene in the constructed vector was especially strong in A. polyphaga, thus the pOPSBU-Acanthamoeba system may be useful for the construction of cDNA expression libraries, as well as for the expression of cloned genes.

Comparison of the 5' upstream region of the evolutionarily equivalent polyubiquitin gene of humans and Chinese hamsters

The 5' upstream region of the Chinese hamster polyubiquitin gene CHUB2 was determined, and compared to that of the evolutionarily equivalent polyubiquitin gene UbC of humans. The 5' upstream region of the CHUB2 gene is distinct from that of the UbC gene in containing fewer recognition sequences for binding of transcription factors, which are quite sparsely distributed in this region. It seemed probable that the absence of AP-1 sites in the promoter of the CHUB2 gene was likely to be responsible for the very dissimilar regulation of the two genes by UV light and TPA, despite the fact that these genes are evolutionarily equivalent.

Heterogeneous structure of the polyubiquitin gene UbC of HeLa S3 cells

The nucleotide sequence of the polyubiquitin gene UbC of HeLa S3 cells and its upstream region was determined and characterized. Recognition sequences for the transcription factors HSF, NF kappa B, AP-1(c-jun), NF-IL6 and Sp1 were found in the upstream control region, a result consistent with the observation of a distinct regulatory response for the UbC gene compared with that of another polyubiquitin gene UbB. Employing a PCR procedure to amplify the entire coding region from genomic DNA, we found a heterogeneity in the repeat number (eight and nine repeats) of the ubiquitin coding units, which resulted from an apparent deletion of either the seventh or the eighth unit in the predominant nine-ubiquitin-unit coding gene. In addition, by comparison with the nucleotide sequence of the UbC gene of human leukocytes previously determined, we found a significant number of nucleotide discrepancies. However, these discrepancies could be substantially reduced by realigning the units so that the first and second ubiquitin units of the sequence determined here are translocated to the boundary between the eighth and the ninth units.

Analysis of early initiating event(s) in radiation-induced thymic lymphomagenesis

Since the T cell receptor rearrangement is a sequential process and unique to the progeny of each clone, we investigated the early initiating events in radiation-induced thymic lymphomagenesis by comparing the oncogenic alterations with the pattern of gamma T cell receptor (TCR) rearrangements. We reported previously that after leukemogenic irradiation, preneoplastic cells developed, albeit infrequently, from thymic leukemia antigen-2+ (TL-2+) thymocytes. Limited numbers of TL-2+ cells from individual irradiated B10.Thy 1.1 mice were injected into B10.Thy 1.2 mice intrathymically, and the common genetic changes among the donor-type T cell lymphomas were investigated with regard to p53 gene and chromosome aberrations. The results indicated that some mutations in the p53 gene had taken place in these lymphomas, but there was no common mutation among the donor-type lymphomas from individual irradiated mice, suggesting that these mutations were late-occurring events in the process of oncogenesis. On the other hand, there were common chromosome aberrations or translocations such as trisomy 15, t(7F;10C), t(1A;13D) or t(6A;XB) among the donor-type lymphomas derived from half of the individual irradiated mice. This indicated that the aberrations/translocations, which occurred in single progenitor cells at the early T cell differentiation either just before or after gamma T cell receptor rearrangements, might be important candidates for initiating events. In the donor-type lymphomas from the other half of the individual irradiated mice, microgenetic changes were suggested to be initial events and also might take place in single progenitor cells just before or right after gamma TCR rearrangements.