Genome-wide identification and expression profiling of ankyrin-repeat gene family in maize

Members of the ankyrin repeats (ANK) gene family encode ANK domain that are common in diverse organisms and play important roles in cell growth and development, such as cell-cell signal transduction and cell cycle regulation. Recently, genome-wide identification and evolutionary analyses of the ANK gene family have been carried out in Arabidopsis and rice. However, little is known regarding the ANK genes in the entire maize genome. In this study, we described the identification and structural characterization of 71 ANK genes in maize (ZmANK). Then, comprehensive bioinformatics analyses of ZmANK genes family were performed including phylogenetic, domain and motif analysis, chromosomal localization, intron/exon structural patterns, gene duplications and expression profiling. Domain composition analyses showed that ZmANK genes formed ten subfamilies. Five tandem duplications and 14 segmental duplications were identified in ZmANK genes. Furthermore, we took comparative analysis of the total ANK gene family in Arabidopsis, rice and maize, ZmANKs were more closely paired with OsANKs than with AtANKs. At last, expression profile analyses were performed. Forty-one members of ZmANK genes held EST sequences records. Semi-quantitative expression and microarray data analysis of these 41 ZmANK genes demonstrated that ZmANK genes exhibit a various expression pattern, suggesting that functional diversification of ZmANK genes family. The results will present significant insights to explore ANK genes expression and function in future studies in maize.     

Unrecognized fine-scale recombination can mimic the effects of adaptive radiation

Gene sequences can undergo accelerated nucleotide changes and rapid diversification. The rapid sequence changes can then potentially lead to phylogenetic incongruence. Recently, Bodilis et al. (2011) observed artificial phylogenetic incongruence using the Pseudomonas surface protein gene oprF, and hypothesized that it was the result of a long-branch attraction artifact ultimately caused by adaptive radiation. In this study, an alternative hypothesis, namely fine-scale recombination, was tested on the same dataset. The results reveal that regions in oprF are of different evolutionary origins, and the mosaic gene structure resulted in confounding phylogenetic signals. These findings demonstrate that unrecognized fine-scale recombination can confound the phylogenetic interpretation and emphasize the limitation of using whole genes as the unit of phylogenetic analysis.     

A new repetitive sequence uniquely present in the decay-accelerating factor genes

 The decay-accelerating factor (DAF, CD55) protects cells from autologous complement attack on self cell membranes. We have previously reported that the seventh exon encoding the serine/threonine-rich(S/T)-abc region of the guinea pig DAF gene is composed of five homologous repeats of about 51 base pairs, and that differential usage of these repeats produces the various lengths observed in the S/T region of guinea pig DAF. In this study, we found that the seventh intron of the guinea pig DAF gene was wholly composed of 18 tandem repeats homologous to the repeating unit of the S/T-abc exon. This type of repetitive structure, although the number of repeats was variable, was also found in the corresponding exons and introns of all DAF genes of other species so far tested including human and seven other primates and mouse, in which alternative splicing in this region has not been found. This suggested that generation of the repetitive sequences spanning the exon and intron regions had occurred before the diversification of these species. In addition, all the intron sequences of the tested DAF genes had no stop codon when they were presumably translated in the same reading frame as the seventh and eighth exons, except for that of one of two duplicated mouse DAF genes. These findings and significant interspecies identities of the intron sequence suggest that the intron sequence conceivably could be translated in some tissues and/or in some stages of development although to date we have not yet succeeded in detecting mRNA for this region. Received: 7 July 1997 / Revised: 11 August 1997     

Phylogenetic analysis of chloroplast matK gene from Zingiberaceae for plant DNA barcoding

MaturaseK gene (MatK) of chloroplast is highly conserved in plant systematics which is involved in Group II intron splicing. The size of the gene is 1500 bp in length, located with in the intron of trnK. In the present study, matK gene from Zingiberaceae was taken for the analysis of variants, parsimony site, patterns, transition/tranversion rates and phylogeny. The family of Zingiberaceae comprises 47 genera with medicinal values. The matK gene sequence have been obtained from genbank and used for the analysis. The sequence alignments were performed by Clustal X, transition/transversion rates were predicted by MEGA and phylogenetic analyses were carried out by PHYLIP package. The result indicates that the Zingiberaceae genus Afromonum, Alpinia, Globba, Curcuma and Zingiber shows polyphylogeny. The overall variants between the species are 24% and transition/transversion rate is 1.54. Phylogenetic tree was designed to identify the ideal regions that could be used for defining the inter and intera-generic relationships. From this study it could be concluded that the matK gene is a good candidate for DNA barcoding of plant family Zingiberaceae.     

Genome-wide identification and expression analysis of MAPK and MAPKK gene family in Malus domestica

MAPK signal transduction modules play crucial roles in regulating many biological processes in plants, which are composed of three classes of hierarchically organized protein kinases, namely MAPKKKs, MAPKKs, and MAPKs. Although genome-wide analysis of this family has been carried out in some species, little is known about MAPK and MAPKK genes in apple (Malus domestica). In this study, a total of 26 putative apple MAPK genes (MdMPKs) and 9 putative apple MAPKK genes (MdMKKs) have been identified and located within the apple genome. Phylogenetic analysis revealed that MdMAPKs and MdMAPKKs could be divided into 4 subfamilies (groups A, B, C and D), respectively. The predicted MdMAPKs and MdMAPKKs were distributed across 13 out of 17 chromosomes with different densities. In addition, analysis of exon–intron junctions and of intron phase inside the predicted coding region of each candidate gene has revealed high levels of conservation within and between phylogenetic groups. According to the microarray and expressed sequence tag (EST) analysis, the different expression patterns indicate that they may play different roles during fruit development and rootstock–scion interaction process. Moreover, MAPK and MAPKK genes were performed expression profile analyses in different tissues (root, stem, leaf, flower and fruit), and all of the selected genes were expressed in at least one of the tissues tested, indicating that the MAPKs and MAPKKs are involved in various aspects of physiological and developmental processes of apple. To our knowledge, this is the first report of a genome-wide analysis of the apple MAPK and MAPKK gene family. This study provides valuable information for understanding the classification and putative functions of the MAPK signal in apple.     

Examination of the Intron in the meiosis-specific recombination gene REC114 in Saccharomyces

REC114 is one of 10 genes known to be required for the initiation of meiotic recombination in Saccharomyces cerevisiae. It is transcribed only in meiosis, and our previous sequence analysis suggested the presence of an intron in the 3′ end of the gene. Hypotheses in the literature have suggested, because of its unusual location, either that the putative intron in REC114 is likely to be necessary for expression, or that there may actually be no intron present. This work demonstrates that REC114 does have an intron and is one of only three genes in yeast with introns located in the 3′ end. Furthermore, the 3′ splice site utilized in REC114 is a very rare AAG sequence; only three other genes in yeast use this nonconsensus sequence. The splicing of REC114 does not require MER1, a gene known to be involved in meiosis-specific RNA processing. In fact, an intronless copy of REC114 can complement a null rec114 mutation. Thus, it does not appear that the intron is essential for expression of REC114. Although the intron is not absolutely required for meiotic function, it is conserved in evolution; two other species of yeast contain an intron at the same location in their REC114 genes.     

Characterization of a polymorphism in the 3′ part of the chicken vitellogenin gene

Summary An allele giving rise to a polymorphism within the 3 part of the chicken vitellogenin gene was cloned, sequenced, and compared to the previously cloned allele. The polymorphism is formed by a perfect copy of 343 bp from intron 32 in tandem array with a perfect copy of 244 bp from intron 33; this 587-bp element is inserted in a head-to-tail arrangement in intron 33. We propose a mechanism in which an unequal crossing-over resulted in a vitellogenin gene with two exons 33, one of which was subsequently deleted. Thus, intron 33 was enlarged by the tandem repeats without affecting the protein-encoding sequence of the gene. At the boundaries of the repeated elements, two short direct repeats are found that resemble the recombination signals of immunoglobulin genes. They may have had a key role in the formation of the new allele.     

Generation and analysis of novel mutations of the Trithorax-like gene in Drosophila melanogaster

The Trithorax-like (Trl) gene of Drosophila melanogaster encodes the multifunctional GAGA factor. The expression of Trl is known to depend on numerous factors, such as the organ, the tissue, the ontogenetic stage, and the ambient temperature. Apparently, this expression is controlled by a complex system of regulatory elements, which so far has been scarcely studied. Our preliminary results indicate that the second intron of the Trl gene bears functionally significant elements. To test this assumption, we generated 23 novel alleles of the gene via P-induced male recombination and analyzed them cytogenetically. Of these mutations, 13 (recessive lethals) are deletions, disrupting the coding gene region. Ten mutations (seven deletions and three duplications) remove parts of the second Trl intron only. Some of these mutant stocks exhibit lower viability at different temperatures. These results suggest that the second intron region harbors functionally significant elements. The deletion mapping results verified the localization of the Trl gene in the 70F1-2 region.     

Developmental cis-regulatory analysis of the cyclin D gene in the sea urchin Strongylocentrotus purpuratus

Cyclin D genes regulate the cell cycle, growth and differentiation in response to intercellular signaling. While the promoters of vertebrate cyclin D genes have been analyzed, the cis-regulatory sequences across an entire cyclin D locus have not. Doing so would increase understanding of how cyclin D genes respond to the regulatory states established by developmental gene regulatory networks, linking cell cycle and growth control to the ontogenetic program. Therefore, we conducted a cis-regulatory analysis on the cyclin D gene, SpcycD, of the sea urchin, Strongylocentrotus purpuratus, during embryogenesis, identifying upstream and intronic sequences, located within six defined regions bearing one or more cis-regulatory modules each.     

A 5′UTR-Spliced mRNA Isoform Is Specialized for Enhanced HIV-2 gag Translation

Full-length unspliced genomic RNA plays critical roles in HIV replication, serving both as mRNA for the synthesis of the key viral polyproteins Gag and Gag-Pol and as genomic RNA for encapsidation into assembling viral particles. We show that a second gag mRNA species that differs from the genomic RNA molecule by the absence of an intron in the 5′ untranslated region (5′UTR) is produced during HIV-2 replication in cell culture and in infected patients. We developed a cotransfection system in which epitopically tagged Gag proteins can be traced back to their mRNA origins in the translation pool. We show that a disproportionate amount of Gag is translated from 5′UTR intron-spliced mRNAs, demonstrating a role for the 5′UTR intron in the regulation of gag translation. To further characterize the effects of the HIV-2 5′UTR on translation, we fused wild-type, spliced, or mutant leader RNA constructs to a luciferase reporter gene and assayed their translation in reticulocyte lysates. These assays confirmed that leaders lacking the 5′UTR intron increased translational efficiency compared to that of the unspliced leader. In addition, we found that removal or mutagenesis of the C-box, a pyrimidine-rich sequence located in the 5′UTR intron and previously shown to affect RNA dimerization, also strongly influenced translational efficiency. These results suggest that the splicing of both the 5′UTR intron and the C-box element have key roles in regulation of HIV-2 gag translation in vitro and in vivo.