Sequence elements in cis influence heterochromatic silencing in trans

The brown(Dominant) (bw(D)) allele contains a large insertion of heterochromatin, which causes the locus to aberrantly associate with heterochromatin in interphase nuclei and silences the wild-type allele in heterozygotes. Transgenes placed near the bw(+) locus, in trans to bw(D), can also be silenced. The strength of silencing (called trans inactivation) varies with the regulatory sequences of the transgene and its distance away from the bw(D) insertion site in trans. In this study, we examine endogenous sequences in cis that influence susceptibility of a reporter gene to trans inactivation. Flanking deletions were induced in two parental lines containing P-element transgenes showing trans inactivation of the mini-white reporter. These new lines, which have mini-white under the influence of different endogenous sequence elements, now show varied ability to be silenced by bw(D). Determination of the deleted regions and the levels of mini-white expression and trans inactivation has allowed us to explore the correlation between cis sequence elements and susceptibility to trans inactivation and to identify a 301-bp sequence that acts as an enhancer of trans inactivation. Intriguingly, this region encompasses the upstream regions of two divergently transcribed genes and contains a sequence motif that may bind BEAF, a protein involved in delimiting chromatin boundaries.     

Nonprolyl cis peptide bonds in unfolded proteins cause complex folding kinetics

Folding of tendamistat, an inhibitor of alpha-amylase, is a fast two-state process accompanied by two minor slow reactions, which were assigned to prolyl isomerization. In a proline-free variant, 5% of the molecules still fold slowly with a rate constant of 2.5 s(-1). This reaction is caused by a slow equilibrium between two populations of unfolded molecules. The time constant for this equilibration process, its sensitivity to LiCl and its temperature dependence identify it as a cis-trans isomerization of nonprolyl peptide bonds. Although nonprolyl peptide bonds have the cis conformation populating only approximately 0.15% in unfolded proteins, their large number generates a significant fraction of slow-folding molecules. This emphasizes that heterogeneous populations in an unfolded protein can induce complex folding kinetics on various time scales.     

Sequence polymorphisms of mitochondrial D-loop and hepatocellular carcinoma outcome

Accumulation of mutations and single nucleotide polymorphisms (SNPs) in the displacement loop (D-loop) of mitochondrial DNA (mtDNA) might be associated with cancer risk and disease outcome. We investigated the prediction power of D-loop SNPs in hepatocellular carcinoma (HCC) patients. No mutation in these HCC patients has prediction power for post-operational survival, whereas two SNP sites (nucleotides 146 T/C and 150 C/T) were identified by the log-rank test for statistically significant prediction of HCC survival. In an overall multivariate analysis, allele 146 was identified as an independent predictor of HCC outcome. The length of survival of patients with allele 146C was significantly shorter than that of patients with allele 146T (relative risk, 2.781; 95% CI, 1.127–6.859; p = 0.026). The analysis of genetic polymorphisms in the mitochondrial D-loop can help identify patient subgroups at high risk of a poor disease outcome.     

Wolbachia bacteria, the cause for false vesicular staining pattern in Drosophila melanogaster

Majority of fly laboratory strains is infected with Wolbachia, intracellular rickettsial-type symbiotic bacteria widespread in various organisms including insects and nematodes. To make the matter worse, I found that certain antisera used for fly immunocytochemistry can recognize Wolbachia bacteria in addition to their own antigens, due to impurity in the antisera generated against the recombinant fusion proteins frequently used as antigens. Thus, combinatorial use of contaminated antisera and Wolbachia-infected flies can result in serious misinterpretations, which can be avoided by curing laboratory strains of Wolbachia.     

Treponema denticola infection is not a cause of false positive Treponema pallidum serology

It has long been assumed that parodontal disease can be a cause of false positive results in syphilis serology, but so far there are no definitive data supporting this hypothesis. In this study we tested 250 serum samples obtained from blood donors. All of them were negative when routinely screened for antibodies against Treponema pallidum. Then, all these samples were tested by immunoenzymatic (ELISA) and Western Blot (WB) assays to investigate reactivities against T. denticola. Thirteen samples showed a strong positivity when tested by both methods. When tested by WB against T. pallidum no sample met the positivity criteria. Nevertheless, bands with molecolar weights of about 30-35 KDa (endoflagellar core antigens) were recognized. All the 13 subjects serologically T. denticola positive underwent oral clinical and radiological observation: all showed a very poor parodontal status (CPSS > 103). Eleven crevicular fluid samples out of the total of 13 patients were T. denticola positive by Real Time PCR carried out using a LightCycler system. In this study we demonstrated that the presence of T. denticola in the crevicular fluid samples obtained from patients with a severe periodontal status and/or a positive serology against T. denticola is not a cause of false positive results in syphilis serology.     

Sequence variation in G-protein-coupled receptors: analysis of single nucleotide polymorphisms

We assessed the disease-causing potential of single nucleotide polymorphisms (SNPs) based on a simple set of sequence-based features. We focused on SNPs from the dbSNP database in G-protein-coupled receptors (GPCRs), a large class of important transmembrane (TM) proteins. Apart from the location of the SNP in the protein, we evaluated the predictive power of three major classes of features to differentiate between disease-causing mutations and neutral changes: (i) properties derived from amino-acid scales, such as volume and hydrophobicity; (ii) position-specific phylogenetic features reflecting evolutionary conservation, such as normalized site entropy, residue frequency and SIFT score; and (iii) substitution-matrix scores, such as those derived from the BLOSUM62, GRANTHAM and PHAT matrices. We validated our approach using a control dataset consisting of known disease-causing mutations and neutral variations. Logistic regression analyses indicated that position-specific phylogenetic features that describe the conservation of an amino acid at a specific site are the best discriminators of disease mutations versus neutral variations, and integration of all our features improves discrimination power. Overall, we identify 115 SNPs in GPCRs from dbSNP that are likely to be associated with disease and thus are good candidates for genotyping in association studies.     

Assembly errors cause false tandem duplicate regions in the chicken (Gallus gallus) genome sequence

The complexity of eukaryote genomes makes assembly errors inevitable in the process of constructing reference genomes. Next-generation sequencing (NGS) could provide an efficient way to validate previously assembled genomes. Here, we exploited NGS data to interrogate the chicken reference genome and identified 35 pairs of nearly identical regions with >99.5 % sequence similarity and a median size of 109 kb. Several lines of evidence, including read depth, the composition of junction sequences, and sequence similarity, suggest that these regions present genome assembly errors and should be excluded from forthcoming genomic studies.     

Sequence polymorphisms within the pMGA genes and pMGA antigenic variants in Mycoplasma gallisepticum

Antigenic variants of Mycoplasma gallisepticum major surface lipoprotein, pMGA, are encoded by a large gene family. In this study sequence analyses of the PCR-amplified pMGA genes showed two types of sequences similar to the pMGA1.2 gene in M. gallisepticum strains. They differed in the sequence encoding a proline-rich region (PRR) at the N-terminus of the pMGA protein. The type A genes had sequences similar to the published pMGA1.2 gene sequence of strain S6, whereas the type B genes lacked the second repetitive segment encoding PTPN sequence within PRR and were similar to the published sequence of PG31 strain. Low in vitro passages of M. gallisepticum strains isolated recently in Slovenia from four avian species showed very different expression patterns of pMGA1.2 and pMGA1.9 genes. Among isogenic populations of S6(B) and IHB1 strains a high frequency of pMGA antigenic variants lacking an epitope for monoclonal antibody (mAb) 71 was found. Strain IHB1 clones, which synthesized pMGA recognized by mAb 71, transcribed pMGA genes whose partial sequence encoded the amino acid sequence (262)TNGDEPRSVS of the mAb 71 epitope. Other IHB1 clones synthesized pMGA variants with different isoelectric points, lacking the epitope for mAb 71, but expressing downstream epitopes for other mAbs. Our study suggests that a molecular basis for pMGA antigenic variation lies in the corresponding changes at the DNA level.     

Sequence polymorphisms in porcine homologs of murine coat colour‐related genes

Herein, we report the variability among 57 porcine homologs of murine coat colour‐related genes. We identified single nucleotide polymorphisms (SNPs) and insertions/deletions (InDels) within 44 expressed gene sequences by aligning eight pig complementary DNA (cDNA) samples. The sequence alignment revealed a total of 485 SNPs and 15 InDels. The polymorphisms were then validated by performing matrix‐assisted laser desorption/ionization time‐of‐flight mass spectrometry (MALDI‐TOF MS) with reference DNA samples obtained from 384 porcine individuals. Of the 384 individuals, three parents of the experimental F₂ family were included to detect polymorphisms between them for linkage mapping. We also genotyped previously reported polymorphisms of 12 genes, and one SNP each in three genes that were detected by performing a BLAST search of the Trace database. A total of 211 SNPs and three InDels were successfully genotyped from our porcine DNA panel. We detected SNPs in 33 of the 44 genes among the parents of an experimental F₂ family and then constructed a linkage map of the 33 genes for this family. The linkage assignment of each gene to the porcine chromosomes was consistent with the location of the BAC clone in the porcine genome and the corresponding gene sequence. We confirmed complete substitutions of EDNRB and MLPH in the Jinhua and Clawn miniature breeds, respectively. Furthermore, we identified polymorphic alleles exclusive to each pig group: 13 for Jinhua, two for Duroc, three for Meishan, four for the Japanese wild boar, one for the Clawn miniature pig and four for the Potbelly pig.     

Sequence context analysis in the mouse genome: single nucleotide polymorphisms and CpG island sequences

A genome-wide view of sequence mutability in mice is still limited, although biologists usually assume the same scenario for mice as for humans. In this study, we examined the sequence context in the local environment of 482,528 mouse single nucleotide polymorphisms (SNPs). We found that CpG-containing short sequences, in general, had more representation in the local sequences of SNPs compared to the genome sequences. The extent of this overrepresentation was stronger in mice than in humans, which is inconsistent with previous observations of the weaker neighboring-nucleotide biases on mouse SNPs. To exclude the CpG effect, we compared the distribution patterns of short sequences among the six categories of SNPs. The results revealed an even stronger pattern in the CpG-containing group for C/G substitution compared to for A/G or C/T substitutions. We next performed the first genome-wide sequence context analysis of SNPs in the mouse CpG islands. SNPs occurring at CpG sites were 3.14-fold less prevalent than expected, suggesting the suppression of methylation-dependent deamination in the CpG islands. The extent of this suppression was less in mice than in humans. Finally, compared with humans, the observations of a greater deficit of CpG dinucleotides, a stronger overrepresentation of CpG-containing n-mers surrounding the polymorphic sites, and a higher SNP/genome ratio of CpG dinucleotides in the mouse genome support the "loss of CpG islands" model in the mouse lineage.     

安徽汉族群体mtDNA高变区I序列多态性分析

以Anderson标准序列作为对照,用GeneDOC软件确定42个安徽汉族无关个体的mtDNA高变区I序列在线粒体基因组中的位置,通过序列比对软件clustalX分析安徽汉族群体mt DNA高变区I序列多态性,共检测到38种单倍型和57个变异位点.在mtDNA高变区I序列中14个bp的高变结构域中,安徽汉人16183位点变异率高达38%,在16187位点的变异率为4.8%.同时发现,安徽汉人与成都汉人在mtDNA高变区I 16183和16189位点的变异率接近,明显高于广东汉人.