Evolution of Full-Length and Deleted Forms of the Mariner-LikeElement, Botmar1, in the Genome of the Bumble Bee, Bombus terrestris (Hymenoptera: Apidae)

Mariner-like elements (MLE) are Class II transposable elements that are very widespread among eukaryotic genomes. One MLE belonging to the mauritiana subfamily, named Botmar1, has been identified in the genome of the bumble bee, Bombus terrestris. gDNA hybridization with the Botmar1 transposase ORF revealed that about 230 elements are present in each haploid genome of B. terrestris that consist entirely of 1.3- and 0.85-kbp elements. The analysis of their sequences revealed that there are two Botmar1 subfamilies of similar ages in the Bombus terrestris genome: one is composed entirely of 1.3-kpb elements, whereas the second comprises both completed and deleted elements. Our previous data indicated that the internally deleted form, which correspond to the 0.85-kbp Botmar1-related elements occur in other distantly related hymenopteran genomes. Because the presence of similar 1.3- and 0.85-kbp Botmar1-related elements in some distantly related hymenopteran species cannot be explained by horizontal transfers, the nucleic acid sequence properties of these elements were further investigated. We found that certain structural properties in their nucleic acid sequence might explain the occurrence of 0.85-kbp Botmar1-related elements presenting similarly located internal deletions in hymenopteran genomes.Reviewing Editor: Dr. Yves Van de Peer     

Comparative sequence analysis of the SALT OVERLY SENSITIVE1 orthologous region in Thellungiella halophila and Arabidopsis thaliana

To provide a framework for studies to understand the contribution of SALT OVERLY SENSITIVE1 (SOS1) to salt tolerance in Thellungiella halophila, we sequenced and annotated a 193-kb T. halophila BAC containing a putative SOS1 locus (ThSOS1) and compared the sequence to the orthologous 146-kb region of the genome of its salt-sensitive relative, Arabidopsis thaliana. Overall, the two sequences were colinear, but three major expansion/contraction regions in T. halophila were found to contain five Long Terminal Repeat retrotransposons, MuDR DNA transposons and intergenic sequences that contribute to the 47.8-kb size variation in this region of the genome. Twenty-seven genes were annotated in the T. halophila BAC including the putative ThSOS1 locus. ThSOS1 shares gene structure and sequence with A. thaliana SOS1 including 11 predicted transmembrane domains and a cyclic nucleotide-binding domain; however, different patterns of Simple Sequence Repeats were found within a 540-bp region upstream of SOS1 in the two species.     

Cloning the dapA dapB cluster of the lysine-secreting bacterium Corynebacterium glutamicum

Summary The genes encoding the two successive enzymes of the lysine biosynthetic pathway, dihydrodipicolinate synthase (dapA) and dihydrodipicolinate reductase (dapB), have been isolated from Corynebacterium glutamicum by heterologous complementation of Escherichia coli mutants. The two genes reside on a single 3.8-kb chromosomal fragment. They were subcloned as non overlapping fragments on an E. coli/C. glutamicum shuttle vector and introduced into C. glutamicum. This resulted in overexpression of both enzyme activities which was irrespective of the orientation of the inserts and comparable to that obtained with the large 3.8-kb fragment. Therefore, both genes are located in close proximity to each other on the C. glutamicum chromosome, but are apparently independently transcribed.     

小桐子YABBY全基因组家族成员的鉴定、表达和可变剪接分析

为发掘能源植物小桐子(Jatropha curcas)的YABBY转录因子,以最新公布的小桐子基因组序列为参考,在全基因组层面鉴定出5个亚家族的7个YABBY基因,同一亚家族的成员具有相似的氨基酸序列、基因结构和保守基序组成。YAB2和FIL/YAB3亚家族的2个旁系同源基因对(JcYAB2A/JcYAB2B、JcYAB1/JcYAB3)具有良好的共线性关系,表明片段复制或全基因组复制是小桐子YABBY家族扩张的主要方式。纯化选择是进化的主要动力,而YAB2亚家族成员可能在进化中经历了更明显的功能分化。基因表达模式和蛋白互作预测分析表明JcYAB2B和JcYAB3可能在种子的发育过程中起到重要的调控作用;同时,细胞分裂素、干旱或高盐胁迫处理抑制了大多数JcYABs成员的基因表达。此外,转录组测序结合q RT-PCR分析表明,低温处理有效诱导JcYAB2A和JcYAB2B的基因表达模式发生变化,并伴随着新的、截短的可变剪接转录本的动态积累。因此,推测JcYABs可能通过剪接体的功能竞争或功能互补参与低温响应的调节,这些结果有助于更好地了解YABBY家族成员的功能分化并阐明可变剪接如何调控...     

苹果DREB转录因子家族全基因组鉴定与分析

DREB转录因子属于AP2/ERF转录因子家族,能够与DRE/CRT顺式作用元件特异性结合,调控与逆境应答基因的表达,因而在植物应对低温、干旱、高盐等逆境胁迫中发挥重要作用。该研究利用苹果全基因组数据,通过生物信息学手段鉴定苹果DREB转录因子家族成员,并分析DREB转录因子家族保守域特点与功能及表达情况。结果表明:从苹果全基因组中共鉴定出60个DREB转录因子家族成员,与拟南芥和水稻相比基本一致,通过引入拟南芥DREB基因进行系统发生分析,进一步可以将其细分为6个亚组;结构域和保守元件分析表明,DREB基因家族含有一个AP2保守结构域;染色体定位表明,苹果DREB基因分布于11条染色体上,部分基因存在串联复制现象;基因结构分析显示,该亚家族基因不含内含子。利用同源拟南芥RNA-Seq数据分析结果表明,DREB转录因子家族对低温、ABA调节等非生物胁迫具有调控作用,同时在DREB亚家族中每个亚组响应不同的非生物胁迫;通过分析DREB基因在不同组织中的表达情况,结果显示DREB基因在植物根部中的表达量最强,其次是叶。     

Concomitant regulation of Mu1 transposition and Mutator activity in maize

Summary The mutagenic activity of the maize transposable element system Mutator can be lost by outcrossing to standard, non-Mutator lines or by repetitive intercrossing of genetically diverse Mutator lines. Lines losing Mutator mutagenic activity in either manner retain high copy numbers (10–15 per diploid genome) of the Mutator-associated Mu transposable elements. Frequent transposition of Mu1-related elements is observed only in active Mutator lines, however. The loss of Mutator activity on intercrossing is correlated with an increase in the copy number of Mu1-like elements to 40–50 per diploid genome, implying a self-encoded or self-activated negative regulator of Mu1 transposition. The outcross loss of Mutator activity is only weakly correlated with a low Mu element copy number and may be due to the loss of a positive regulatory factor encoded by a subset of Mu1-like elements. Transposition of Mu elements in active Mutator lines generates multiple new genomic positions for about half the elements each plant generation. The appearance of Mu1-like elements in these new positions is not accompanied by equally high germinal reversion frequencies, suggesting that Mu1 may commonly transpose via a DNA replicative process.     

New insights into <Emphasis Type="Italic">Oryza</Emphasis> genome evolution: high gene colinearity and differential retrotransposon amplification

An ∼247-kb genomic region from FF genome of wild rice Oryza brachyantha, possessing the smallest Oryza genome, was compared to the orthologous ∼450-kb region from AA genome, O. sativa L. ssp. japonica. 37 of 38 genes in the orthologous regions are shared between japonica and O. brachyantha. Analyses of nucleotide substitution in coding regions suggest the two genomes diverged ∼10 million years ago. Comparisons of transposable elements (TEs) reveal that the density of DNA TEs in O. brachyantha is comparable to O. sativa; however, the density of RNA TEs is dramatically lower. The genomic fraction of RNA TEs in japonica is two times greater than in O. brachyantha. Differences, particularly in RNA TEs, in this region and in BAC end sequences from five wild and two cultivated Oryza species explain major genome size differences between sativa and brachyantha. Gene expression analyses of three ObDREB1 genes in the sequenced region indicate orthologous genes retain similar expression patterns following cold stress. Our results demonstrate that size and number of RNA TEs play a major role in genomic differentiation and evolution in Oryza. Additionally, distantly related O. brachyantha shares colinearity with O. sativa, offering opportunities to use comparative genomics to explore the genetic diversity of wild species to improve cultivated rice. Electronic supplementary material The online version of this article (doi:) contains supplementary material, which is available to authorized users. Data deposition: Sequence data from this article were deposited with GenBank Library under accession number DQ810282. Shibo Zhang and Yong Qiang Gu contributed equally to the work     

Isolation of Escherichia coli mRNA and Comparison of Expression Using mRNA and Total RNA on DNA Microarrays

Bacterial messenger RNA (mRNA) is not coherently polyadenylated, whereas mRNA of Eukarya can be separated from stable RNAs by virtue of polyadenylated 3′-termini. We have developed a method to isolate Escherichia coli mRNA by polyadenylating it in crude cell extracts with E. coli poly(A) polymerase I and purifying it by oligo(dT) chromatography. Differences in lacZRNA levels were similar with purified mRNA and total RNA in dot blot hydridizations for cultures grown with or without gratuitous induction of the lactose operon. More broadly, changes in gene expression upon induction were similar when cDNAs primed from mRNA or total RNA with random hexanucleotides were hydridized to DNA microarrays for the E. coli genome. Comparable signal intensities were obtained with only 1% as much oligo(dT)-purified mRNA as total RNA, and hence in vitro poly(A) tailing appears to be selective for mRNA. These and additional studies of genome-wide expression with DNA microarrays provide evidence that in vitro poly(A) tailing works universally for E. coli mRNAs.