21α,26-dihydroxy-D:A-friedooleanan-3-one from Salacia reticulata var. Diandra (celastraceae)

Carbon-13 NMR has been used to detect the position of angular methyl oxygenation and determine the structure of 21α,26-dihydroxy-D:A-friedooleanan-3-one, a new trioxygenated friedooleanane from Salacia reticulata var. diandra and the assignment has been confirmed chemically.     

Molecular systematics of Lachancea yeasts

This work presents the results of molecular-genetic investigation of a new yeast genus, Lachancea Kurtzman (2003). Analysis of rRNA sequences and molecular karyotyping have shown genetic homogeneity of the genus Lachancea. Yeasts of this genus have an identical haploid number of chromosomes equal to eight, whereas limiting chromosome sizes significantly differ in various species. The largest range of chromosome bands was registered in L. cidri strains (400-2800 kb), while the smallest was found in L. waltii (1400-2800 kb). The intra- and interspecies polymorphism of Lachancea chromosomes is discussed.     

Structural analysis of the 26S proteasome by cryoelectron tomography

The 26S proteasome is the key enzyme of intracellular protein degradation in eukaryotic cells. It is a multisubunit complex of 2.5 MDa confining the proteolytic action to an inner compartment with tightly controlled access. Structural studies of this intriguing molecular machine have been hampered by its intrinsic instability and its dynamics. Here we have used an unconventional approach to obtain a three-dimensional structure of the holocomplex uncompromised by preparation-induced alterations and unbiased by any starting model. We have performed a tomographic reconstruction, followed by averaging over approx. 150 individual reconstructions, of Drosophila 26S proteasomes suspended in a thin layer of amorphous ice.     

Mouse homologue of yeast Prp19 interacts with mouse SUG1, the regulatory subunit of 26S proteasome

Yeast Prp19 has been shown to involve in pre-mRNA splicing and DNA repair as well as being an ubiquitin ligase. Mammalian homologue of yeast Prp19 also plays on similar functional activities in cells. In the present study, we isolated mouse SUG1 (mSUG1) as binding partner of mouse Prp19 (mPrp19) by the yeast two-hybrid system. We confirmed the interaction of mPrp9 with mSUG1 by GST pull-down assay and co-immunoprecipitation assay. The N-terminus of mPrp19 including U-box domain was associated with the C-terminus of mSUG1. Although, mSUG1 is a regulatory subunit of 26S proteasome, mPrp19 was not degraded in the proteasome-dependent pathway. Interestingly, GFP-mPrp19 fusion protein was co-localized with mSUG1 protein in cytoplasm as the formation of the speckle-like structures in the presence of a proteasome inhibitor MG132. In addition, the activity of proteasome was increased in cells transfected with mPrp19. Taken together, these results suggest that mPrp19 involves the regulation of protein turnover and may transport its substrates to 26S proteasome through mSUG1 protein.     

MiR-26b是前列腺癌中的抑癌微RNA

microRNAs（又称miRNAs或miRs）是一类长度为19-24个核苷酸的单链非编码RNA分子。miRNA通过与其靶向的mRNA分子序列特异性互补配对,调节mRNA表达水平,抑制转录后的蛋白翻译。miRNA在肿瘤中既可作为致癌因子也可作为抑癌因。本研究前期已报道miR-26b在前列腺癌细胞系中低表达,并且抑制细胞自噬。本研究进一步全面揭示miR-26b对前列腺肿瘤细胞的作用。我们发现过表达miR-26b能够在体外抑制前列腺癌细胞的增殖和侵袭,并抑制裸鼠体内原位异种前列腺肿瘤的生长。为了探究miR-26b对前列腺癌细胞增殖和侵袭的潜在调控机制,我们进行了表达谱芯片鉴定miR-26b调控基因。表达谱芯片分析表明,在前列腺癌细胞系PC-3中过表达miR-26b后,显著上调的基因57个,显著下调的基因55个（变化倍数均大于2,且P值小于0.05）。差异基因的功能多与细胞增殖、凋亡调控、蛋白磷酸化和泛素化修饰调控过程相关,并且富集在多种信号通路中,例如TNF和TGF-β信号通路。在这些筛选出的基因中,CEACAM6表达水平下调2.17倍;序列分析及实验验证表明,CEACAM6的3’UTR区存在miR-26b的互补序列,是miR-26b的直接靶标。本研究证明了miR-26b能够靶向结合抑制CEACAM6的表达,从而抑制前列腺癌细胞在体外和体内的细胞增殖和侵袭活性,miR-26b是前列腺癌中的抑癌microRNA。     

Systematic position of Asteropyrum (Ranunculaceae) inferred from chloroplast and nuclear sequences

Sequences of chloroplast gene rbcL and partial nuclear 26S rDNA were used to evaluate phylogenetic relationships of Asteropyrum. Four primary clades were recognized in Ranunculaceae, corresponding to subfamilies Hydrastidoideae, Coptidoideae, Thalictroideae, and Ranunculoideae. Our results place Asteropyrum in Ranunculoideae, sister to the tribe Actaeeae, which includes Beesia, Cimicifuga, and Eranthis. This is supported by chromosome characters, including chromosome size and basic number, and the stainability of prophase chromosomes and interphase nuclei. Our results do not support previous placements of Asteropyrum in either Coptidoideae or Thalictroideae. Considering its uniqueness in a few characters (e.g. simple peltate leaves, accumulating benzylisoquinoline alkaloids, vessel elements with only typical scalariform perforation plates), we recognize Asteropyrum as a monotypic tribe of Ranunculoideae, Asteropyreae W. T. Wang et C. Y. Chang.