Evolution of errantiviruses of <Emphasis Type="Italic">Drosophila melanogaster</Emphasis>. Strategy 2: From retroviruses to retrotransposons

Drosophila melanogaster retrotransposons of the gypsy group are considered to be potential errantiviruses. Their infectivity is caused by the functional activity of the third open reading frame (ORF3) encoding the Env protein, which was probably captured from baculoviruses. Mobile genetic elements (MGEs) of the gypsy group can be conventionally divided into three subgroups: with three ORFs, with a defective ORF3, and without the ORF3. To establish the patterns of evolution of gypsy retrotransposons in D. melanogaster, the members of the three subgroups were examined. Structural analysis of retrotransposons opus and rover, which carry a defective ORF3, as well as retrotransposons Burdock, McClintock, qbert, and HMS-Beagle, which lack the ORF3, suggests that the evolution of these MGEs followed the pattern of loosing the ORF3. At the same time, an MGE of the same subgroup, Transpac, may be an ancestral form, which had acquired the env gene and gave rise to the first errantiviruses. The capture of the ORF3 by retrotransposons provided their conversion to a fundamentally new state. However, the ORF3 in the genome is not subjected to strong selective pressure, because it is not essential for intragenomic transpositions. Because of this, the process of its gradual loss seems quite natural.     

The first complete <Emphasis Type="Italic">Mag</Emphasis> family retrotransposons discovered in <Emphasis Type="Italic">Drosophila</Emphasis>

A retrotransposon of the Mag family was found in the Drosophila simulans genome for the first time. We also identified novel transposable elements representing the Mag family in seven Drosophila species. The high similarity between the 3’ and 5’ long terminal repeats in the found copies of transposable elements indicates that their retrotransposition has occurred relatively recently. Thus, the Mag family of retrotransposons is quite common for the genus Drosophila.     

Study of the Interaction between HP1 Family Proteins and Untranslated Regulatory Regions of the <Emphasis Type="Italic">Gypsy</Emphasis> Retrotransposons in <Emphasis Type="Italic">Drosophila melanogaster</Emphasis>

In vitro interaction between recombinant protein paralogs (HP1a, HP1b, and HP1c) of the HP1 family and 5′-untranslated regulatory regions of the gypsy retrotransposon group in Drosophila melanogaster—gypsy, Springer, Tirant, ZAM, Rover, and 17.6—was studied. Using competitive DNA, the conditions that enable specific binding with a matrix were identified. It was found that HP1 family proteins efficiently bind to the 5′-untranslated regulatory region of retrotransposons with tandem repeats. It was found that repeats are absolutely necessary for HP1a to bind to the 5′-untranslated region of the Tirant and ZAM mobile genetic elements. The absence of repeats (ZAM) or the presence of fewer than two repeats (Tirant) makes such interaction impossible. Thus, the presence of tandem repeats in the 5′-untranslated region of the gypsy retrotransposons is an important tool for regulating their transposition by heterochromatin proteins.     

Long terminal repeat retrotransposons of <Emphasis Type="Italic">Mus musculus</Emphasis>

Background

Long terminal repeat (LTR) retrotransposons make up a large fraction of the typical mammalian genome. They comprise about 8% of the human genome and approximately 10% of the mouse genome. On account of their abundance, LTR retrotransposons are believed to hold major significance for genome structure and function. Recent advances in genome sequencing of a variety of model organisms has provided an unprecedented opportunity to evaluate better the diversity of LTR retrotransposons resident in eukaryotic genomes.

Results

Using a new data-mining program, LTR_STRUC, in conjunction with conventional techniques, we have mined the GenBank mouse (Mus musculus) database and the more complete Ensembl mouse dataset for LTR retrotransposons. We report here that the M. musculus genome contains at least 21 separate families of LTR retrotransposons; 13 of these families are described here for the first time.

Conclusions

All families of mouse LTR retrotransposons are members of the gypsy-like superfamily of retroviral-like elements. Several different families of unrelated non-autonomous elements were identified, suggesting that the evolution of non-autonomy may be a common event. High sequence similarity between several LTR retrotransposons identified in this study and those found in distantly-related species suggests that horizontal transfer has been a significant factor in the evolution of mouse LTR retrotransposons.

     

Horizontal transfer of the C-termini of <Emphasis Type="Italic">tccC</Emphasis> genes in <Emphasis Type="Italic">Photorhabdus</Emphasis> and <Emphasis Type="Italic">Xenorhabdus</Emphasis>

The high molecular weight insecticidal toxin complexes (Tcs), including four toxin-complex loci (tca, tcb, tcc and tcd), were first identified in Photorhabdus luminescens W14. Each member of tca, tcb or tcc is required for oral toxicity of Tcs. However, the sequence sources of the C-termini of tccC3, tccC4, tccC6 and tccC7 are unknown. Here, we performed a whole genome survey to identify the orthologs of Tc genes, and found 165 such genes in 14 bacterial genomes, including 40 genes homologous to tccC1-7 in P. luminescens TT01. The sequence sources of the C-termini of tccC2-6 were determined by sequence analysis. Further phylogenetic investigations suggested that the C-termini of 6 tccC genes experienced horizontal gene transfer events.     

<Emphasis Type="Italic">BcMF11</Emphasis> and its homologous sequences may form a lncRNA family in <Emphasis Type="Italic">Brassica</Emphasis> diploids

BcMF11 is a long non-coding RNA that has been identified in Brassica rapa and shown to be involved in pollen development. Here, when re-cloned the gene sequence, multiple paralogous copies of BcMF11 were identified in B. rapa (A genome). Multiple paralogous copies of BcMF11 were also found in B. nigra (B genome) and Brassica oleracea (C genome), the other two primary diploids of Brassica U triangle. While in the early diverging Brassicaceae lineage including Arabidopsis thaliana, no BcMF11 homolog was found. Phylogenetic analysis showed that the BcMF11 homologous sequences cloned from A genome or C genome could be clustered into a separate branch, respectively. However, there was no distinct cluster defined for BcMF11 homologous sequences cloned from B genome. The expression of BcMF11 in B. rapa was investigated and revealed a different result in the previous study. In addition, 12 expressed sequence tags from B. napus and B. rapa showing high similarities with BcMF11 were identified in the NCBI database, which further verified that rather than the useless repeat fragments in the genome, the BcMF11 homologous genes could transcribe. It is possible that BcMF11 and its homologous sequences may form a large gene family which might be originated in the recent ancestral lineage of Brassica.     

Detection of <Emphasis Type="Italic">Streptococcus pyogenes</Emphasis> virulence genes in <Emphasis Type="Italic">Streptococcus dysgalactiae</Emphasis> subsp. <Emphasis Type="Italic">equisimilis</Emphasis> from Vellore,India

Streptococcus dysgalactiae subsp. equisimilis (SDSE), belonging to the group C and G streptococci, are human pathogens reported to cause clinical manifestations similar to infections caused by Streptococcus pyogenes. To scrutinize the distribution of gene coding for S. pyogenes virulence factors in SDSE, 255 isolates were collected from humans infected with SDSE in Vellore, a region in southern India, with high incidence of SDSE infections. Initial evaluation indicated SDSE isolates comprising of 82.35% group G and 17.64% group C. A multiplex PCR system was used to detect 21 gene encoding virulence-associated factors of S. pyogenes, like superantigens, DNases, proteinases, and other immune modulatory toxins. As validated by DNA sequencing of the PCR products, sequences homologous to speC, speG, speH, speI, speL, ssa and smeZ of the family of superantigen coding genes and for DNases like sdaD and sdc were detected in the SDSE collection. Furthermore, there was high abundance (48.12% in group G and 86.6% in group C SDSE) of scpA, the gene coding for C5a peptidase in these isolates. Higher abundance of S. pyogenes virulence factor genes was observed in SDSE of Lancefield group C as compared to group G, even though the incidence rates in former were lower. This study not only substantiates detection of S. pyogenes virulence factor genes in whole genome sequenced SDSE but also makes significant contribution towards the understanding of SDSE and its increasing virulence potential.     

Complete chloroplast genome sequence of <Emphasis Type="Italic">Capsicum</Emphasis><Emphasis Type="Italic">baccatum</Emphasis> var. <Emphasis Type="Italic">baccatum</Emphasis>

Molecular markers derived from the complete chloroplast genome can provide effective tools for species identification and phylogenetic resolution. Complete chloroplast (cp) genome sequences of Capsicum species have been reported. We herein report the complete chloroplast genome sequence of Capsicum baccatum var. baccatum, a wild Capsicum species. The total length of the chloroplast genome is 157,145 bp with 37.7 % overall GC content. One pair of inverted repeats, 25,910 bp in length, was separated by a small single-copy region (17,974 bp) and large single-copy region (87,351 bp). This region contains 86 protein-coding genes, 30 tRNA genes, 4 rRNA genes, and 11 genes contain one or two introns. Pair-wise alignments of chloroplast genome were performed for genome-wide comparison. Analysis revealed a total of 134 simple sequence repeat (SSR) motifs and 282 insertions or deletions variants in the C. baccatum var. baccatum cp genome. The types and abundances of repeat units in Capsicum species were relatively conserved, and these loci could be used in future studies to investigate and conserve the genetic diversity of the Capsicum species.     

<Emphasis Type="Italic">Hsp70</Emphasis> genes of the <Emphasis Type="Italic">Megaphragma amalphitanum</Emphasis> (Hymenoptera: Trichogrammatidae) parasitic wasp

Miniaturization is an evolutionary process that is widely represented in both invertebrates and vertebrates. Miniaturization frequently affects not only the size of the organism and its constituent cells, but also changes the genome structure and functioning. The structure of the main heat shock genes (hsp70 and hsp83) was studied in one of the smallest insects, the Megaphragma amalphitanum (Hymenoptera: Trichogrammatidae) parasitic wasp, which is comparable in size with unicellular organisms. An analysis of the sequenced genome has detected six genes that relate to the hsp70 family, some of which are apparently induced upon heat shock. Both induced and constitutively expressed hsp70 genes contain a large number of introns, which is not typical for the genes of this family. Moreover, none of the found genes form clusters, and they are all very heterogeneous (individual copies are only 75–85% identical), which indicates the absence of gene conversion, which provides the identity of genes of this family in Drosophila and other organisms. Two hsp83 genes, one of which contains an intron, have also been found in the M. amalphitanum genome.     

Identification of candidate genes of QTLs for seed weight in <Emphasis Type="Italic">Brassica napus</Emphasis> through comparative mapping among <Emphasis Type="Italic">Arabidopsis</Emphasis> and <Emphasis Type="Italic">Brassica</Emphasis>species

Background

Map-based cloning of quantitative trait loci (QTLs) in polyploidy crop species remains a challenge due to the complexity of their genome structures. QTLs for seed weight in B. napus have been identified, but information on candidate genes for identified QTLs of this important trait is still rare.

Results

In this study, a whole genome genetic linkage map for B. napus was constructed using simple sequence repeat (SSR) markers that covered a genetic distance of 2,126.4 cM with an average distance of 5.36 cM between markers. A procedure was developed to establish colinearity of SSR loci on B. napus with its two progenitor diploid species B. rapa and B. oleracea through extensive bioinformatics analysis. With the aid of B. rapa and B. oleracea genome sequences, the 421 homologous colinear loci deduced from the SSR loci of B. napus were shown to correspond to 398 homologous loci in Arabidopsis thaliana. Through comparative mapping of Arabidopsis and the three Brassica species, 227 homologous genes for seed size/weight were mapped on the B. napus genetic map, establishing the genetic bases for the important agronomic trait in this amphidiploid species. Furthermore, 12 candidate genes underlying 8 QTLs for seed weight were identified, and a gene-specific marker for BnAP2 was developed through molecular cloning using the seed weight/size gene distribution map in B. napus.

Conclusions

Our study showed that it is feasible to identify candidate genes of QTLs using a SSR-based B. napus genetic map through comparative mapping among Arabidopsis and B. napus and its two progenitor species B. rapa and B. oleracea. Identification of candidate genes for seed weight in amphidiploid B. napus will accelerate the process of isolating the mapped QTLs for this important trait, and this approach may be useful for QTL identification of other traits of agronomic significance.

     

Structural organization characteristics of the <Emphasis Type="Italic">DIP1</Emphasis> gene in <Emphasis Type="Italic">Drosophila melanogaster</Emphasis> strains mutant for the <Emphasis Type="Italic">flamenco</Emphasis> gene

Molecular cloning of the DIP1 gene located in the 20A4-5 region has been performed from the following strains with the flamenco phenotype: flam ^SS (SS) and flam ^MS (MS) characterized by a high transposition rate of retrotransposon gypsy (mdg4), flam ^{py + (P)} carrying the insertion of a construction based on the P element into the region of the flamenco gene, and flamenco ⁺. The results of restriction analysis and sequencing cloned DNA fragments has shown that strains flam ^SS , flam ^MS considerably differ from flam ^{py + (P)}, and flamenco ⁺ in the structure of DIP1. Strains flam ^SS and flam ^MS have no DraI restriction site at position 1765 in the coding region of the gene, specifically, in the domain determining the signal of the nuclear localization of the DIP1 protein. This mutation has been found to consist in a nucleotide substitution in the recognition site of DraI restriction endonuclease, which is transformed from TTTAAA into TTTAAG and, hence, is not recognized by the enzyme. This substitution changes codon AAA into AAG and is translationally insignificant, because both triplets encode the same amino acid, lysine. The DIP1 gene of strains flam ^SS and flam ^MS has been found to contain a 182-bp insertion denoted IdSS (insertion in DIP1 strain SS); it is located in the second intron of the gene. The IdSS sequence is part of the open reading frame encoding the putative transposase of the mobile genetic element HB1 belonging to the Tc1/mariner family. This insertion is presumed to disturb the conformations of DNA and the chromosome, in particular, by forming loops, which alters the expression of DIP1 and, probably, neighboring genes. In strains flamenco ⁺ and flam ^{py + (P)}, the IdSS insertion within the HB1 sequence is deleted. The deletion encompasses five C-terminal amino acid residues of the conserved domain and the entire C-terminal region of the putative HB1 transposase. The obtained data suggest that DIP1 is involved in the control of gypsy transpositions either directly or through interaction with other elements of the genome.     

<Emphasis Type="Italic">HB</Emphasis> mobile element in the <Emphasis Type="Italic">Drosophila melanogaster</Emphasis> genome: Structural and functional analyses

The structure was analyzed for 60 annotated copies of the mobile genetic element (MGE) HB from the Drosophila melanogaster genome. The genomic distribution of HB copies was studied, and preferential insertion sites (hot spots) were identified, which presumably amount to several kilobases. Structural analysis of the open reading frame (ORF) and terminal repeats of HB was performed. All 26 HB copies retaining the ORF sequence have a stop codon in the same position. Consequently, the HB ORF proved indeed to code for an enzyme of 148 amino acid residues, relatively small for Tc1-family transposases. The ORF consensus sequence was established. HB{}1185 was identified as the only HB copy potentially coding for a functional protein. All 37 repeat-containing HB copies were analyzed. Of these, only four had functional terminal sequences, lacking, however, a functional transposase gene. A new 7762-bp copy of MGE roo was found in the D. melanogaster genome; the copy was earlier unavailable from databases and represents an insert in the HB{}1605 sequence.     

Polymorphism of <Emphasis Type="Italic">yellow</Emphasis> locus in <Emphasis Type="Italic">Drosophila melanogaster</Emphasis> mutants from natural populations

We have studied the molecular characteristics of the yellow locus (y; 1–0.0), which determines the body color of phenotypically wild-type and mutant alleles isolated in different years from geographically distant populations of Drosophila melanogaster. According to the Southern blot, data restriction maps of the yellow locus of all examined strains differ from one another, as well as from Oregon stock. FISH analysis shows that, in the neighborhood of the yellow locus in the X chromosome, neither P nor hobo elements are found in y^1–775 stock, while only hobo is found in these region in y^1–859 and y^1–866 stocks, only the P element is found in y⁺sn⁸⁴⁹ stock, and both elements are found in y^1–719 stock. Thus, all yellow mutants studied are of independent origin. Locus yellow located on the end of X chromosome (region 1A5–8 on the cytologic map) carries significantly more transposon than retrotransposon induced mutations compared to the white locus (region 3C2). It is possible that, at the ends of Drosophila melanogaster chromosomes, transposons are more active than retrotransposons.     

Mutation processes in natural populations of <Emphasis Type="Italic">Drosophila melanogaster</Emphasis> and <Emphasis Type="Italic">Hirundo rustica</Emphasis> from radiation-contaminated regions of Ukraine

Natural populations of Drosophila melanogaster and Hirundo rustica from regions of Ukraine exhibiting different levels of radiation contamination are investigated. Genetic monitoring was performed with respect to such parameters as the frequency of visible sex-linked mutations, frequency of gonad reduction in Drosophila, and rate of interphase manifestations of chromosomal instability in the erythrocytes of the birds. The results attest to a possible opposite dependence of the level of chromosomal instability among swallows and that of the rate of lethal mutations in the sex chromosome of Drosophila on the density of radiation contamination.     

A novel chimeric prophage vB_LdeS-phiJB from commercial <Emphasis Type="Italic">Lactobacillus delbrueckii</Emphasis> subsp. <Emphasis Type="Italic">bulgaricus</Emphasis>

Prophage vB_LdeS-phiJB (phiJB) was induced by mitomycin C and UV radiation from the Lactobacillus delbrueckii subsp. bulgaricus SDMCC050201 isolated from a Chinese yoghurt sample. It has an isometric head and a non-contractile tail with 36,969 bp linear double-stranded DNA genome, which is classified into the group a of Lb. delbrueckii phages. The genome of phiJB is highly modular with functionally related genes clustered together. Unexpectedly, there is no similarity of its DNA replication module to any phages that have been reported, while it consists of open-reading frames homologous to the proteins of Lactobacillus strains. Comparative genomic analysis indicated that its late gene clusters, integration/lysogeny modules and DNA replication module derived from different evolutionary ancestors and integrated into a chimera. Our results revealed a novel chimeric phage of commercial Lb. delbrueckii and will broaden the knowledge of phage diversity in the dairy industry.     

<Emphasis Type="Italic">In vivo</Emphasis> RNAi screen identifies candidate signaling genes required for collective cell migration in <Emphasis Type="Italic">Drosophila</Emphasis> ovary

Collective migration of loosely or closely associated cell groups is prevalent in animal development, physiological events, and cancer metastasis. However, our understanding of the mechanisms of collective cell migration is incomplete. Drosophila border cells provide a powerful in vivo genetic model to study collective migration and identify essential genes for this process. Using border cell-specific RNAi-silencing in Drosophila, we knocked down 360 conserved signaling transduction genes in adult flies to identify essential pathways and genes for border cell migration. We uncovered a plethora of signaling genes, a large proportion of which had not been reported for border cells, including Rack1 (Receptor of activated C kinase) and brk (brinker), mad (mother against dpp), and sax (saxophone), which encode three components of TGF-β signaling. The RNAi knock down phenotype was validated by clonal analysis of Rack1 mutants. Our data suggest that inhibition of Src activity by Rack1 may be important for border cell migration and cluster cohesion maintenance. Lastly, results from our screen not only would shed light on signaling pathways involved in collective migration during embryogenesis and organogenesis in general, but also could help our understanding for the functions of conserved human genes involved in cancer metastasis.