Silk moth chorion pseudogenes: Hallmarks of genomic evolution by sequence duplication and gene conversion

The part of the genetic locus of the domesticated silk moth,Bombyx mori, in which high cysteine (Hc) chorion genes of late developmental specificity reside contains regions encompassing genelike sequences which exhibit properties distinct from those of functional Hc genes. One of these regions has been characterized and shown to contain a chorion pseudogene, ψHcB.15, which shares pronounced similarities with a transcribed chorion pseudogene, ψHcB.12/13, which was characterized previously. Both pseudogenes are homologous to HcB chorion genes but bear multiple single nucleotide substitutions and short segmental mutations (insertions and deletions) which introduce translational frame shifts and termination codons in the coding regions. Structural characteristics unique to the two pseudogenes suggest that ψHcB.15 was generated first from a functional HcB gene and gave rise subsequently to ψHcB 12/13 as a result of a sequence duplication event. The two pseudogenes can be distinguished from each other by the presence of distinct regions of similarity to the consensus sequence of functional HcB genes which appear to have arisen from gene-conversionmediated correctional events. These findings lend support to the hypothesis that chorion pseudogene sequences represent reservoirs of genetic information that participates in the evolution of the chorion locus rather than relics of inactivated genes passively awaiting extinction. Presented at the NATO Advanced Research Workshop onGenome Organization and Evolution, Spetsai, Greece, 16–22 September 1992     

Gene evolution and regulation in the chorion complex of Bombyx mori. Hybridization and sequence analysis of multiple developmentally middle A/B chorion gene pairs

Twenty-two pairs of chorion genes belonging to the A and B multigene families have been characterized and mapped within two segments of a 320 kb (1 kb = 10(3) bases or base-pairs) chromosomal walk in the domesticated silkmoth Bombyx mori. Eighteen of the gene pairs belong to two groups that are typified by the previously characterized A/B.L12 and A/B.L11 chorion gene pairs, and are defined by two respective types of short (approx. 280 base-pairs) bidirectional promoter sequences. In the chromosome, the L12-like and L11-like pairs are interspersed with each other and with the remaining four gene pairs, which have unrelated promoter sequences. We have sequenced the promoter regions and adjacent small exons of all L12-like and L11-like A and B genes in the walk. The L12-like promoters are highly conserved, whereas L11-like promoters are somewhat more variable. Reconsideration of previous data on RNA accumulation and disappearance during choriogenesis, in the light of the sequences, indicates that L12-like genes are developmentally early-middle, while L11-like genes correspond to two developmental subgroups, middle I and middle II. Sequence comparisons of all these promoters, as well as the previously characterized promoters of the developmentally late HcA and HcB genes, identify short elements of possible regulatory significance. The sequences, as well as extensive cross-hybridization analysis with short probes derived from the reference A/B.L12 gene pair, under carefully controlled conditions of stringency, indicate the occurrence of sequence transfers among A or B genes. These sequence transfers, which could result from gene conversions or unequal crossovers, are less abundant than in the HcA and HcB families, but do result in a patchwork of similarities and differences in the A and B genes. The transfers appear to be least frequent between the moderately divergent A genes that belong to different temporal classes, while the L12-like and L11-like B genes appear to be extensively homogenized in sequence.     

The biolistic method as a tool for testing the differential activity of putative silkmoth chorion gene promoters

Bombyx mori unpaired early chorion gene copies 6F6.1,.2 and.3 are exceptions to the typical organization and distribution pattern of known early ErA/ErB, middle A/B and late HcA/HcB divergently transcribed gene pairs. Contrary to such pairs, the boundaries of the 6F6 regulatory sequences are not easily defined; moreover, they share common sequence elements with the regulatory sequences of middle and late genes. In order to perform a functional study of the tissue and temporal specificity of the 6F6 putative promoter region, we decided to apply biolistics. In the present work, use of a region from the 6F6.2 5' untranslated sequence, spanning nucleotides -138 to the cap site, gave an expected expression pattern of a lacZ reporter gene. Temporal specificity was further verified by control experiments using the cloned intergenic sequence of the late gene pair HcA/B.12, which resulted in lacZ expression in late choriogenic follicles. At present, despite the recent successful germinal transgenesis of Bombyx mori, the biolistic transient expression system seems to be the most rapid technique to pursue the functional study of the promoter region of early chorion genes, including the three unconventional early 6F6 genes.     

人U6基因POI Ⅲ启动子表达反义VEGF cDNA抑制SMMC-7721肝癌细胞VEGF表达的观察

 由 RNA聚合酶启动子在细胞内转录高浓度反义 RNA是抑制靶蛋白的一种有效手段 ,有报道 POI 启动子转录小分子 RNA存在效率不高 ,带有较多的非特异性序列等缺点 ,为了克服这些问题 ,表达反义 VEGF RNA的人 U6基因表达盒对人肝癌细胞株 SMMC- 772 1 VEGF表达的抑制作用进行了研究 .首先 PCR扩增 2 0 0 bp VEGF c DNA以正、反向插入人 U6 sn RNA.通过测序证实反向插入的正确性 .采用细胞原位杂交 ,RNA酶保护分析 ,Northern印迹来证实反义 RNA表达的情况 ,利用 RT- PCR方法研究了其对人肝癌细胞株 SMMC- 772 1 VEGF表达的抑制效果 .细胞原位杂交结果显示 U6启动子转录产物主要分布于细胞核内 ,细胞浆内亦有表达 ,RNA酶保护分析显示 U6基因 POI 启动子能高表达所需大小反义 RNA,Northern印迹结果显示脂质体 lipo-fectamine介导含 U6基因 POI 启动子的质粒转染人肝癌细胞株 SMMC- 772 1后 1 2 h即有表达且可持续表达 6 d. RT- PCR证实 U6基因 POI 启动子转录的反义 VEGF RNA能有效抑制SMMC- 772 1细胞 VEGF的 m RNA表达 .已有的研究结果揭示 POI 启动子是反义基因治疗中一种好的选择     

The silkmoth late chorion locus. I. Variation within two paired multigene families

The 140 X 10(3) base late chorion locus of Bombyx mori contains two 15-member multigene families arranged in tightly linked pairs, which are divergently transcribed (the high-cysteine A (HcA) and the high-cysteine B (HcB) families). Previous DNA hybridization experiments have indicated that all members of these gene families contain a complex pattern of shared sequence variation. The sequence analysis in this paper involving all 15 gene pairs allows a comprehensive examination of the nature of this variation. Average sequence homology between gene pairs is: 95% for the protein-encoding regions; 93% for the common 272 base-pair 5' flanking region; 87% for the introns; and 88% for the 3' untranslated regions. Considering the great degree of sequence homology in the coding regions, an unexpectedly high level of variation is found in the deduced protein sequences. Over 50% of the nucleotide substitutions in the protein-encoding regions lead to amino acid replacements, most of which involve a change in charge or effect the secondary structure of the protein. In addition, significant differences in length between the proteins occur in the carboxyl-terminal arm. In both families, the major portion of this arm is composed of Cys-Gly-Gly and Cys-Gly subrepeats forming a (Cys-Gly-Gly)2-(Cys-Gly)2 major repeat. Differences in the number of complete and partial repeats results in deduced protein sequences that contain arms varying from 32 to 54 amino acid residues for members of the HcA family and 14 to 88 residues for the HcB family. The high level of variation in protein composition indicates a lack of strong selective pressure. We suggest the high level of DNA sequence homology maintained by these genes in the coding as well as in the non-coding regions is the result of sequence exchange between family members.     

Loss of phylogenetic information in chorion gene families of Bombyx mori gene conversion

The silkmoth chorion has provided a stimulating model for the study of evolution and developmental regulation of gene families. Previous attempts at inferring relationships among chorion sequences have been based on pairwise comparisons of overall similarity, a potentially problematic approach. To remedy this, we identified the alignable regions of low sequence variability and then analyzed this restricted database by parsimony and neighbor-joining methods. At the deepest level, the chorion sequence tree is split into two branches, called "alpha" and "beta." Within each branch, early- and late-expressing genes each constitute monophyletic groups, while the situation with middle-expressing genes remains uncertain. The HcB gene family appears to be the most basal beta-branch group, but this conclusion is qualified because the effect of gene conversion on branching order is unknown. Previous studies by Eickbush and colleagues have strongly suggested that ErA, HcA, and HcB families undergo gene conversion within a gene family, whereas the ErB family does not. The occurrence of conversion correlates with a particular tree structure; namely, branch lengths are much greater at the base of the family than at higher internodes and terminal branches. These observations raise the possibility that chorion gene families are defined by gene conversion events (reticulate evolution) rather than by descent with modification (synapomorphy).