Reduced incompatibility in the production of second generation hybrids between two Magnolia species revealed by Bayesian gene dispersal modeling.

PREMISE OF THE STUDY: Hybrid zones are areas where gene flow between related species is currently occurring, so information on the compatibility between related species and their hybrids is essential for predicting the dynamics of such zones generated by introgressive hybridization. In this study, we quantified the compatibility among Magnolia stellata, M. salicifolia, and their hybrids in a hybrid zone using gene dispersal modeling. METHODS: After determining the genealogical classes of adult trees in the hybrid zone, the paternity of 574 open-pollinated seeds from 37 known maternal trees was analyzed with microsatellite markers. A neighborhood-based Bayesian gene dispersal model developed by us for estimating compatibility was then applied to the paternity data. KEY RESULTS: When M. stellata or M. salicifolia were mothers, interspecific mating to produce F1 hybrids yielded significant incompatibility, but backcrossing with F1 hybrids did not. Furthermore, when F1 hybrids became mothers, no significant incompatibility resulted from backcrossing to parental species or intra-F1 mating to produce F2 hybrids. The estimated proportion of F1 hybrids in the outcrossed seeds (1.7%) in the hybrid zone was much lower than that in the adult trees (14.0%). CONCLUSIONS: While it is difficult to obtain F1 hybrids, their low incompatibility makes it easy to produce advanced generation hybrids, once they have been successfully obtained. Although the production of F1 seeds is rare, heterosis and/or weak selection pressure in an empty niche between the parental species' niches may have contributed to the increased proportion of adult F1 hybrids in the hybrid zone.

Developmental expression and evolution of muscle-specific microRNAs conserved in vertebrates.

microRNAs (miRs) are small non-coding RNA molecules expressed in a tissue-specific manner in numerous organisms. Among them, miR-1, miR-206, and miR-133, which are encoded as bicistronic gene clusters in the genome, play major roles in the control of vertebrate myogenesis. To address how the gene organization and function of these miRs evolved, we identified their homologues in the cyclostomes, the chondrichthyans and the teleosts, and examined their patterns of expression during development. It was suggested that the chondrichthyans and the cyclostome lampreys possess fewer miR-1/miR-133 genes than the medaka. The medaka additionally possessed the miR-206 gene which was not found in the genomes of chondrichthyans and lampreys. In contrast, the number and genomic organization of medaka miR-1(206)/miR-133 were similar to those found in mammals. In the lamprey, shark and medaka, miR-1 and miR-133 were expressed in both skeletal and cardiac muscle cells in adults, a developmental feature traced back to chordate invertebrates such as ascidians. We further examined the expression of these miRs in different muscle tissues in medaka embryos. miR-206 was expressed in both the tail and pectoral fin muscles, whereas miR-1, which shares the similar nucleotide sequence with miR-206, was not detectable in the embryonic pectoral fins. Comparison of the relative positions with the neighboring protein-coding genes showed high conservation of synteny between the miR-1(206)/miR-133 clusters in a single species, as well as across the vertebrate taxa. Our results suggest that, after the gene duplications, these muscle-specific miRs acquired differential regulatory functions and have contributed to the establishment of diverse and complex musculature of vertebrates.

Characterization of the compact bicistronic microRNA precursor, miR-1/miR-133, expressed specifically in Ciona muscle tissues.

Muscle-specific miR-1/206 and miR-133 families have been suggested to play fundamental roles in skeletal and cardiac myogenesis in vertebrates. To gain insights into the relationships between the divergence of these miRs and muscular tissue types, we investigated the expression patterns of miR-1 and miR-133 in two ascidian Ciona species and compared their genomic structures with those of other chordates. We found that Ciona intestinalis and Ciona savignyi each possess a single copy of the miR-1/miR-133 cluster, which is only 350 nucleotide long. During embryogenesis, Ciona miR-1 and miR-133 are generated as a single continuous primary transcript accumulated in the nuclei of the tail muscle cells, starting at the gastrula stage. In adults, mature miR-133 and miR-1 are differentially expressed in the heart and body wall muscle. Expression of the reporter gene linked to the 850-bp upstream region of the predicted transcription start site confirmed that this region drives the muscle-specific expression of the primary transcript of miR-1/miR-133. In many deuterostome lineages, including that of Ciona, the miR-1/133 cluster is located in the same intron of the mind bomb (mib) gene in reverse orientation. Our results suggest that the origin of genomic organization and muscle-specific regulation of miR-1/133 can be traced back to the ancestor of chordates. Duplication of this miR cluster might have led to the remarkable elaboration in the morphology and function of skeletal muscles in the vertebrate lineage.

The pyrE Gene as a Bidirectional Selection Marker in Bifidobacterium Longum 105-A.

We constructed a deletion mutant of the pyrE gene in Bifidobacterium longum 105-A. A pyrE knockout cassette was cloned into pKKT427, a Bifidobacterium-Escherichia coli shuttle vector, and then introduced into B. longum 105-A by electroporation. The transformants were propagated and spread onto MRS plates containing 5-fluoroorotic acid (5-FOA) and uracil. 5-FOA-resistant mutants were obtained at a frequency of 4.7 × 10(-5) integrations per cell. To perform pyrE gene complementation, the pyrE gene was amplified by PCR and used to construct a complementation plasmid (pKKT427-pyrE (+)). B. longum 105-A ∆pyrE harboring this plasmid could not grow on MRS plates containing 5-FOA, uracil and spectinomycin. We also developed a chemically defined medium (bifidobacterial minimal medium; BMM) containing inorganic salts, glucose, vitamins, isoleucine and tyrosine for positive selection of pyrE transformants. B. longum 105-A ∆pyrE could not grow on BMM agar, but the same strain harboring pKKT427-pyrE (+) could. Thus, pyrE can be used as a counterselection marker in B. longum 105-A and potentially other Bifidobacterium species as well. We demonstrated the effectiveness of this system by constructing a knockout mutant of the xynF gene in B. longum 105-A by using the pyrE gene as a counterselection marker. This pyrE-based selection system will contribute to genetic studies of bifidobacteria.

Identification of MIWI-associated Poly(A) RNAs by immunoprecipitation with an anti-MIWI monoclonal antibody.

MIWI is one of the PIWI subfamily of proteins mainly expressed in mouse germ cells, and associates with pachytene piRNAs. MIWI has been thought to play an essential role in spermatogenesis and spermiogenesis via biogenesis and/or stability of pachytene piRNAs, retrotransposon silencing, and post-transcriptional regulation of target mRNAs. However, MIWI's detailed role and function are not well understood. In this study, we produced an anti-MIWI mouse monoclonal antibody and identified MIWI-associated poly(A) RNAs by immunoprecipitation from adult mouse testes lysates. Approximately 70% of the MIWI-associated poly(A) RNAs were known mRNAs and 30% of them were unknown non-coding RNAs. These poly(A) RNAs contained piRNA-encoding RNAs transcribed from piRNA cluster regions and piRNA-encoding mRNA, such as Aym1 mRNA. Mature piRNAs specifically encoded in these piRNA-encoding RNAs were generated in pachytene spermatocytes and not detected in Miwi-deficient (Miwi-/-) testes. Moreover, MIWI associated with a large number of known mRNAs whose expression levels were increased in pachytene spermatocytes, and the expression of these mRNAs was decreased in Miwi-/- testes at 20 days postpartum when pachytene spermatocytes were most abundant. These results strongly suggest that MIWI is involved in pachytene piRNA biogenesis and the positive regulation of target mRNA metabolism in pachytene spermatocytes via association with pachytene piRNA precursors and target mRNAs.

A targeted gene knockout method using a newly constructed temperature-sensitive plasmid mediated homologous recombination in Bifidobacterium longum.

Bifidobacteria are the main component of the human microflora. We constructed a temperature-sensitive (Ts) plasmid by random mutagenesis of the Bifidobacterium-Escherichia coli shuttle vector pKKT427 using error-prone PCR. Mutant plasmids were introduced into Bifidobacterium longum 105-A and, after screening approximately 3,000 colonies, candidate clones that grew at 30 °C but not at 42 °C were selected. According to DNA sequence analysis of the Ts plasmid, five silent and one missense mutations were found in the repB region. The site-directed mutagenesis showed only the missense mutation to be relevant to the Ts phenotype. We designated this plasmid pKO403. The Ts phenotype was also observed in B. longum NCC2705 and Bifidobacterium adolescentis ATCC15703. Single-crossover homologous-recombination experiments were carried out to determine the relationship between the length of homologous sequences encoded on the plasmid and recombination frequency: fragments greater than 1 kb gave an efficiency of more than 10(3) integrations per cell. We performed gene knockout experiments using this Ts plasmid. We obtained gene knockout mutants of the pyrE region of B. longum 105-A, and determined that double-crossover homologous recombination occurred at an efficiency of 1.8 %. This knockout method also worked for the BL0033 gene in B. longum NCC2705.

Genomic organization and embryonic expression of miR-430 in medaka (Oryzias latipes): insights into the post-transcriptional gene regulation in early development.

MicroRNAs (miRNAs, miRs) are short noncoding RNA molecules that negatively control the target mRNAs by binding to the 3' untranslated region (UTR). Previous studies have demonstrated that miR-430 is encoded by a clustered multigene family and is abundantly expressed in early development. In zebrafish, miR-430 is needed to suppress primordial germ cell (PGC)-specific genes, such as nanos1, in somatic cells. However, the molecular characteristics of the miR-430 family in other teleost species have not been reported, and it is unclear whether such a function of miR-430 in PGC specification is a conserved feature of animals or not. In medaka (Oryzias latipes), a distantly related teleost, it has been suggested that PGC might be established in a different mode of specification from that of zebrafish. We characterized 16 miR-430 precursors in the medaka genomic sequence. These miR-430 genes form clusters on chromosome 4, which might share its evolutionary origin with that of the very large miR-430 clusters in zebrafish chromosome 4. However, none of the medaka miR-430 genes are identical to the zebrafish miR-430 paralogs. Medaka miR-430 expression starts during epiboly and decreases after axis formation. Functional analysis using reporter gene constructs showed that miR-430 repressed protein expression by binding to the 3'UTR of zebrafish TDRD7. Consistently, the 3'UTR of medaka TDRD7 contains at least two significant candidates for the putative miR-430 binding site. The ubiquitous and early expression of medaka miR-430 and its ability to downregulate GFP:TDRD7 reporter mRNA imply that miR-430 has a conserved role in early embryogenesis. Smaller copy numbers of miR-430 genes and relatively brief expression in medaka might represent the characteristics of this miRNA family in the common ancestor of teleosts. Changes in the relationships between miR-430 and the target mRNA might be related to differences in the localization patterns of PGC-related genes in medaka and zebrafish.

Synthesis of Biaryls via a Nickel(0)-Catalyzed Cross-Coupling Reaction of Chloroarenes with Arylboronic Acids.

The cross-coupling reaction of arylboronic acid with chloroarenes to give biaryls was carried out in high yields at 70-80 degrees C in the presence of a nickel(0) catalyst and K(3)PO(4) (3 equiv) in dioxane or benzene. The nickel(0) catalyst in situ prepared from NiCl(2).L (L = dppf, 2PPh(3)) (3-10 mol %) and 4 equiv of BuLi at room temperature was recognized to be most effective. The reaction can be applicable to a wide range of chloroarenes having an electron-withdrawing or an electron-donating group such as 4-NC, 4-CHO, 2- or 4-CO(2)Me, 4-COMe, 4-NHAc, 4-Me, 4-OMe, 4-NH(2), and 4-NMe(2). The Hammett's plot of the substituent effect of chloroarenes revealed that the reaction involves a rate-determining oxidative addition of chloroarenes to the nickel(0) complex.