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.     

Most meiotic CAG repeat tract-length alterations in yeast are<Emphasis Type="Italic"> SPO11</Emphasis> dependent

The expansion of trinucleotide repeat sequences associated with hereditary neurological diseases is believed from earlier studies to be due to errors in DNA replication. However, more recent studies have indicated that recombination may play a significant role in triplet repeat expansion. CAG repeat tracts have been shown to induce double-strand breaks (DSBs) during meiosis in yeast, and DSB formation is dependent on the meiotic recombination machinery. The rate of meiotic instability is several fold higher than mitotic instability. To determine whether DSB repair is responsible for the high rate of repeat tract-length alterations, the frequencies of meiotic repeat-tract instability were compared in wild-type and spo11 mutant strains. In the spo11 background, the rate of meiotic repeat-tract instability remained at the mitotic level, suggesting that meiotic alterations of CAG repeat tracts in yeast occur by the recombination mechanism. Several of these meiotic tract-length alterations are due to DSB repair involving use of the sister chromatid as a template.     

Functional analysis of a cryptic promoter from <Emphasis Type="Italic">Arabidopsis thaliana</Emphasis> reveals bidirectionality

Cryptic promoter elements play a significant role in evolution of plant gene expression patterns and are prospective tools for creating gene expression systems in plants. In a previous report, a 452 bp promoter fragment designated as cryptic root-specific promoter (AY601849) was identified immediately upstream to T-DNA insertion, in the intergenic region between divergent genes SAHH1 and SHMT4, in T-DNA tagged mutant M57 of Arabidopsis thaliana. In silico analysis of 452 bp promoter revealed typical eukaryotic promoter architecture, presence of root-specific motifs and other cis-regulatory motifs responsible for the spatial and temporal expression. GUS expression driven by 452 bp in M57 was developmentally as well as light-regulated. The AT-rich 452 bp promoter does not show homology to any known sequences. The 452 bp promoter was further proved cryptic and detailed molecular characterization of the promoter carried out through serial 5′ and 3′ deletion analysis, by cloning the promoter fragments upstream to promoter-less GUS vector. A 279 bp fragment obtained by deleting 173 bp from 5′ end of 452 bp was capable of driving root-specific expression, similar to that of full-length promoter. Further, root tip-specific, root-specific and core-regulatory motifs for root-specific expression were identified at positions 173–227, 251–323 and 408–452 bp, respectively, from the 5′ end of 452 bp. The 452 bp promoter was equally functional in inverse orientation, hence bidirectional and symmetric. In heterologous systems, such as Brassica juncea and Oryza sativa, the promoter activity was not significant since GUS was not visually detected in transient assays.     

Functional conservation of the<Emphasis Type="Italic"> Sex-lethal</Emphasis> sex determining promoter,<Emphasis Type="Italic"> Sxl-Pe</Emphasis>, in<Emphasis Type="Italic"> Drosophila virilis</Emphasis>

The primary sex determination signal in Drosophila melanogaster, the ratio of X chromosomes to autosomes, sets the activity state of the switch gene, Sex-lethal ( Sxl), by regulating the establishment promoter, m-Sxl-Pe. We have identified and characterized the establishment promoter, v-Sxl-Pe, of the distantly related species Drosophila virilis. Like melanogaster, the virilis Sxl-Pe is organized into four sub-domains: the Sxl-Pe mRNA leader and exon E1 of Sxl protein, the core promoter, the sex-specific element and the augmentation element. The core promoter and sex-specific element of v-Sxl-Pe show considerable sequence similarity to m-Sxl-Pe and contain target sites for components of the X/A signaling system. While the augmentation element of v-Sxl-Pe also has sequence motifs that could function as target sites for the X/A signaling system, it shows little similarity to the melanogaster augmentation element. Functional studies reveal that v-Sxl-Pe drives sex-specific expression in D. melanogaster embryos and that the activity of the virilis promoter is controlled by known components of the melanogaster X/A counting system. Although v-Sxl-Pe responds appropriately to the melanogaster sex determination signal, it is less active than Sxl-Pe from melanogaster. Unexpectedly, the reduced activity is due to differences in the activity of the conserved core promoter, while the non-conserved augmentation element functions effectively. These findings suggest that low-affinity target sites for the X/A counting system are critical for the functioning of Sxl-Pe.     

DNA double-strand break repair in <Emphasis Type="Italic">Caenorhabditis elegans</Emphasis>

Faithful repair of DNA double-strand breaks (DSBs) is vital for animal development, as inappropriate repair can cause gross chromosomal alterations that result in cellular dysfunction, ultimately leading to cancer, or cell death. Correct processing of DSBs is not only essential for maintaining genomic integrity, but is also required in developmental programs, such as gametogenesis, in which DSBs are deliberately generated. Accordingly, DSB repair deficiencies are associated with various developmental disorders including cancer predisposition and infertility. To avoid this threat, cells are equipped with an elaborate and evolutionarily well-conserved network of DSB repair pathways. In recent years, Caenorhabditis elegans has become a successful model system in which to study DSB repair, leading to important insights in this process during animal development. This review will discuss the major contributions and recent progress in the C. elegans field to elucidate the complex networks involved in DSB repair, the impact of which extends well beyond the nematode phylum.     

Properties of natural double-strand-break sites at a recombination hotspot in Saccharomyces cerevisiae

This study addresses three questions about the properties of recombination hotspots in Saccharomyces cerevisiae: How much DNA is required for double-strand-break (DSB) site recognition? Do naturally occurring DSB sites compete with each other in meiotic recombination? What role does the sequence located at the sites of DSBs play? In S. cerevisiae, the HIS2 meiotic recombination hotspot displays a high level of gene conversion, a 3''-to-5'' conversion gradient, and two DSB sites located approximately 550 bp apart. Previous studies of hotspots, including HIS2, suggest that global chromosome structure plays a significant role in recombination activity, raising the question of how much DNA is sufficient for hotspot activity. We find that 11.5 kbp of the HIS2 region is sufficient to partially restore gene conversion and both DSBs when moved to another yeast chromosome. Using a variety of different constructs, studies of hotspots have indicated that DSB sites compete with one another for DSB formation. The two naturally occurring DSBs at HIS2 afforded us the opportunity to examine whether or not competition occurs between these native DSB sites. Small deletions of DNA at each DSB site affect only that site; analyses of these deletions show no competition occurring in cis or in trans, indicating that DSB formation at each site at HIS2 is independent. These small deletions significantly affect the frequency of DSB formation at the sites, indicating that the DNA sequence located at a DSB site can play an important role in recombination initiation.     

<Emphasis Type="Italic">Ty</Emphasis>1<Emphasis Type="Italic">/copia</Emphasis>- and <Emphasis Type="Italic">Ty</Emphasis>3<Emphasis Type="Italic">/gypsy</Emphasis>-like DNA sequences in <Emphasis Type="Italic">Helianthus </Emphasis>species

Two repeated DNA sequences isolated from a partial genomic DNA library of Helianthus annuus, p HaS13 and p HaS211, were shown to represent portions of the int gene of a Ty3 /gypsy retroelement and of the RNase-Hgene of a Ty1 /copia retroelement, respectively. Southern blotting patterns obtained by hybridizing the two probes to BglII- or DraI-digested genomic DNA from different Helianthus species showed p HaS13 and p HaS211 were parts of dispersed repeats at least 8 and 7 kb in length, respectively, that were conserved in all species studied. Comparable hybridization patterns were obtained in all species with p HaS13. By contrast, the patterns obtained by hybridizing p HaS211 clearly differentiated annual species from perennials. The frequencies of p HaS13- and p HaS211-related sequences in different species were 4.3x10(4)-1.3x10(5) copies and 9.9x10(2)-8.1x10(3) copies per picogram of DNA, respectively. The frequency of p HaS13-related sequences varied widely within annual species, while no significant difference was observed among perennial species. Conversely, the frequency variation of p HaS211-related sequences was as large within annual species as within perennials. Sequences of both families were found to be dispersed along the length of all chromosomes in all species studied. However, Ty3 /gypsy-like sequences were localized preferentially at the centromeric regions, whereas Ty1/ copia-like sequences were less represented or absent around the centromeres and plentiful at the chromosome ends. These findings suggest that the two sequence families played a role in Helianthusgenome evolution and species divergence, evolved independently in the same genomic backgrounds and in annual or perennial species, and acquired different possible functions in the host genomes.     

Phylogenetic analysis of <Emphasis Type="Italic">IRIS</Emphasis> L. from China on chloroplast <Emphasis Type="Italic">TRN</Emphasis>L-F sequences

Phylogenetic relationships among the six Iris subgenera were reconstructed by chloroplast trnL-F sequences data using maximum likelihood. The entire matrix of aligned bases analyzed includes 1043 characters and the length of all sequences varied from 747 bp to 893 bp, and mutation sites accounted for 18.79% of the total length. The cluster analysis results accorded well with the subgeneric classification of Chinese Iris species. Results suggested rhizomes and sepals lacking ornament are ancestral characters, and subg. Xyridion and subg. Limniris are more primordial than another four subgenera. Subgenus Nepalensis and subg. Xyridion were resolved as monophyletic.     

Two active bamboo <Emphasis Type="Italic">mariner</Emphasis>-like transposable elements (<Emphasis Type="Italic">Ppmar1</Emphasis> and <Emphasis Type="Italic">Ppmar2</Emphasis>) identified as the transposon-based genetic tools for mutagenesis

Bamboo is one of the most important non-timber forest species in the world, but their molecular breeding lags far behind in contrast to other economic plants. Regarding the difficulties of hybridization and gene modification, the transposon-based insertional mutagenesis might be an alternative, feasible way for molecular breeding of bamboo. A systematic search for potential active transposons identified two full-length mariner-like elements (MLEs) (Ppmar1 and Ppmar2) from moso bamboo in the previous study. Both MLEs contain perfect terminal inverted repeats (TIRs) and a full-length intact transposase. Two transposases contain intact DNA-binding motifs and a DD39D catalytic domain which indicates that Ppmar1 and Ppmar2 are likely active. Here, we deployed a heterologous transposition system of Arabidopsis thaliana to study the transposition activity of Ppmar1 and Ppmar2. The results show that both MLEs could transpose in A. thaliana. Excisions of Ppmar1 and Ppmar2 are usually unperfect as they leave 1–4 bp in excision sites. The reinsertions of both Ppmar1 and Ppmar2 occur at TA dinucleotides and prefer to insert into the TA-rich regions. The insertion sites are dispersed and non-linked. Two active bamboo transposons identified here not only could be applied to construction of the bamboo mutant libraries but also would provide another choice for other plant transposon-based gene tagging.     

Site-specific deletions in the tomato genome by the CinH-<Emphasis Type="Italic">RS2</Emphasis> and ParA-<Emphasis Type="Italic">MRS</Emphasis> recombination systems

We have tested the CinH-RS2 and ParA-MRS site-specific deletion systems in tomato (Solanum lycopersicum L.). The ParA-MRS system is derived from the broad-host-range plasmid RK2, where the 222 aa ParA recombinase recognizes a 133 bp multimer resolution site (MRS). The CinH-RS2 system is derived from Acinetobacter plasmids pKLH2 and pKLH204, where the 188 amino acid CinH recombinase recognizes a 113-bp recombination site known as RS2. In this study, target lines containing a DNA segment flanked by recombination sites were crossed to recombinase-expressing lines producing CinH or ParA recombinase. CinH-mediated recombination of RS2 substrates was detected in 2 of 3 F₁ plants that harbor both the target and recombinase loci. On the other hand, recombination mediated by ParA was not detected among F₁ plants, but was found among 13 of 47 F₂ plants. These data show that both systems can mediate site-specific DNA deletion in the tomato genome, and, upon further refinement, can provide additional molecular tools for tomato improvement through precise genome manipulation. As the target construct also contains additional recombination sites for site-specific integration by other recombination systems, these tomato lines could be used for future testing of gene stacking through site-specific integration.     

Pollen-Specific Expression of <Emphasis Type="Italic">Oryza sativa Indica</Emphasis> Pollen Allergen Gene (<Emphasis Type="Italic">OSIPA</Emphasis>) Promoter in Rice and <Emphasis Type="Italic">Arabidopsis</Emphasis> Transgenic Systems

Earlier, a pollen-specific Oryza sativa indica pollen allergen gene (OSIPA), coding for expansins/pollen allergens, was isolated from rice, and its promoter—upon expression in tobacco and Arabidopsis—was found active during the late stages of pollen development. In this investigation, to analyze the effects of different putative regulatory motifs of OSIPA promoter, a series of 5′ deletions were fused to β-glucuronidase gene (GUS) which were stably introduced into rice and Arabidopsis. Histochemical GUS analysis of the transgenic plants revealed that a 1631 bp promoter fragment mediates maximum GUS expression at different stages of anther/pollen development. Promoter deletions to −1272, −966, −617, and −199 bp did not change the expression profile of the pollen specificity. However, the activity of promoter was reduced as the length of promoter decreased. The region between −1567 and −199 bp was found adequate to confer pollen-specific expression in both rice and Arabidopsis systems. An approximate 4-fold increase in the GUS activity was observed in the pollen of rice when compared to that of Arabidopsis. As such, the OSIPA promoter seems promising for generation of stable male-sterile lines required for the production of hybrids in rice and other crop plants.