Pleistocene glacial oscillations and associated tectonic processes are believed to have influenced the historical abundances and distribution of organisms in the Asia Northwest Pacific (ANP). Accumulating evidence indicates that factors shaping tempospatial population dynamics and distribution patterns of marine taxa vary with biogeographical latitude, pelagic behaviour and oceanographic regimes. To detect what kinds of historical and contemporary factors affected genetic connectivity, phylogeographic profiles of littoral macroalga Sargassum horneri in the ANP were analysed based on mitochondrial (Cox3) and chloroplast (rbcL) data sets. Five distinct clades were recovered. A strong signature of biogeographical structure was revealed (Φ(CT) = 0.487, P < 0.0001) derived from remarkable differentiation in clade distribution, as clade I is restricted to Chinese marginal seas (Yellow-Bohai Sea, East China Sea and South China Sea), whereas clades II-V are discontinuously scattered around the main Islands of Japan. Furthermore, two secondary contact regions were identified along the south Japan-Pacific coastline. This significant differentiation between the two basins may reflect historical glacial isolation in the northwestern Pacific, which is congruent with the estimates of clade divergence and demographic expansion during the late Quaternary low sea levels. Analysis of molecular variance and the population-pair statistic F(ST) also revealed significant genetic structural differences between Chinese marginal seas and the Japanese basin. This exceptional phylogeographic architecture in S. horneri, initially shaped by historical geographic isolation during the late Pleistocene ice age and physical biogeographical barriers, can be complicated by oceanographic regimes (ocean surface currents) and relocating behaviour such as oceanic drifting.
Dongfang no.7 (Saccharina japonica) was bred and maintained by hybridizing gametophytes, self-crossing the best individuals, selecting the best self-crossing line and seedling-raising from yearly reconstructed sporophytes. It increased the air dry yield by 43.2% in average over 2 widely farmed controls. Dongfang no.7 was seedling-raised from bulked sporophytes reconstructed from its representative gametophyte clones. Such strategy ensured it against variety contamination due to possible cross fertilization and occasional mixing and inbred depletion due to self-crossing number-limited sporophytes year after year. It derived from an intraspecific hybrid through 4 rounds of self-crossing and selection and retained a certain degree of genetic heterozygosity, thus being immune to inbred depletion due to purification of unknown detrimental alleles. Most importantly, it can be farmed in currently available system as the seedlings for large scale culture can be raised from reconstructed Dongfang no.7 sporophytes. Breeding and maintaining Dongfang no.7 provided a model that other varieties of kelp (S. japonica) and brown algae may follow during their domestication.
Heat shock protein 70 (Hsp70) is one of the important members of heat shock protein (Hsp) families and plays essential roles in folding nascent protein, translocation, refolding denatured protein, protein degradation, adverse stress resistance, and so on. In this study, homologous cloning coupled with the rapid amplification of cDNA ends was used to clone full-length cytosolic heat shock protein 70 of Enteromorpha prolifera (designed as EPHsp70). Bioinformatics was used to analyze structural feature, homologous relationship, and phylogenetic position of EPHsp70. The full length of EPHsp70 cDNA was 2,265 bp, with a 5′ untranslated region of 65 bp, a 3′ untranslated region of 217 bp, and an open-reading frame of 1,983 bp encoding a polypeptide of 660 amino acids with an estimated molecular weight of 71.39 kDa and an estimated isoelectric point of 5.03. EPHsp70 had five degenerate repeats of tetrapeptide GGMP and three typical Hsp70 signature motifs. The C-terminus amino acid sequence of cytosolic EPHsp70 was EEVD, and the conservation of EPHsp70 of N-terminus was higher than that of C-terminus. The homology between EPHsp70 and the cytosolic Hsp70s of other algae and land plants was more than 70%.Keywords Enteromorpha prolifera . Heat shock protein 70 . Molecular cloningUnder inherently stressful environment, intertidal seaweeds have to face different stress factors such as high temperature, low temperature, ultraviolet radiation, and desiccation with the turning tides and alterations caused by diurnal, seasonal, and meteorological variations. In the process of adaptation, seaweeds must make appropriately physiological and biochemical changes in order to deal with environmental stresses, at the same time, seaweeds upregulate expression of stress genes and downregulate expression of protein synthesis-related genes to resist abiotic stresses (Collén et al. 2007). Organisms respond to stress at the cellular level with the rapid synthesis of a number of so-called stress proteins (heat shock proteins (Hsps)). Investigations of stress response in nonmobile organisms such as seaweeds are especially interesting because they are unable to escape from unfavorable conditions. Therefore, it is meaningful to study the role of Hsps in adverse stress resistance mechanism of seaweeds. Stress responses have been studied in few species of seaweeds to date (Vayda and Yuan 1994;Lewis et al. 1998;Ireland et al. 2004;Li and Brawley 2004;Roeder et al. 2005;Collén et al. 2007; Henkel and Hofmann 2008a, b;Fu et al. 2009).Hsps are highly conserved throughout evolution and play an essential role in protecting cells, folding and translocating nascent proteins, refolding denatured proteins, disassembling already formed protein aggregates, and so on under both stress and nonstress conditions (Nelson et al
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