番茄WOX转录因子家族的鉴定及其进化、表达分析

WUSCHEL相关的同源异型盒(WUSCHEL-related homeobox,WOX)是一类植物特异的转录因子家族,具有调控植物干细胞分裂分化动态平衡等重要功能。本研究利用番茄(Solanum lycopersicum)基因组数据,通过建立隐马尔科夫模型并进行检索,鉴定了番茄10个WOX转录因子家族成员。多序列比对发现,番茄WOX转录因子家族成员具有高度保守的同源异型结构域;以拟南芥WOX转录因子家族成员序列为参照,通过邻接法、极大似然法、贝叶斯法重建了系统发育树,三者呈现出类似的拓扑结构,番茄和拟南芥WOX转录因子家族共25个成员被分为3个进化支(Clade)和9个亚家族(Subgroup);利用MEME和GSDS对WOX转录因子家族成员的蛋白保守结构域和基因结构进行了分析,同一亚家族内的WOX转录因子家族成员的保守结构域的种类、组织形式以及基因结构具有高度的一致性;利用Perl和Orthomcl对家族成员的染色体定位和同源性关系进行分析,结果表明串联重复的SlWOX3a和SlWOX3b可能来源于一次复制事件;利用番茄转录组数据和qRT-PCR进行表达分析,结果显示家族成员在不同组织中的表达存在差异,暗示了WOX家族的不同成员在功能上可能具有多样性。本研究对番茄WOX转录因子家族成员进行GO(Gene Ontology)注释和比较分析,结果表明该家族成员作为转录因子,可能在组织器官发育、细胞间通讯等过程中发挥作用。     

Ossification of the posterior longitudinal ligament related genes identification using microarray gene expression profiling and bioinformatics analysis

Ossification of the posterior longitudinal ligament (OPLL) is a kind of disease with physical barriers and neurological disorders. The objective of this study was to explore the differentially expressed genes (DEGs) in OPLL patient ligament cells and identify the target sites for the prevention and treatment of OPLL in clinic. Gene expression data GSE5464 was downloaded from Gene Expression Omnibus; then DEGs were screened by limma package in R language, and changed functions and pathways of OPLL cells compared to normal cells were identified by DAVID (The Database for Annotation, Visualization and Integrated Discovery); finally, an interaction network of DEGs was constructed by string. A total of 1536 DEGs were screened, with 31 down-regulated and 1505 up-regulated genes. Response to wounding function and Toll-like receptor signaling pathway may involve in the development of OPLL. Genes, such as PDGFB, PRDX2 may involve in OPLL through response to wounding function. Toll-like receptor signaling pathway enriched genes such as TLR1, TLR5, and TLR7 may involve in spine cord injury in OPLL. PIK3R1 was the hub gene in the network of DEGs with the highest degree; INSR was one of the most closely related genes of it. OPLL related genes screened by microarray gene expression profiling and bioinformatics analysis may be helpful for elucidating the mechanism of OPLL.     

Genome-wide identification and expression profiling analysis of brassinolide signal transduction genes regulating apple tree architecture

Brassinolide (BR) is crucial for regulating plant architecture. Apple dwarfing rootstocks are used to control apple tree size. However, information regarding the effects of BR on apple trees is limited. In addition, the molecular mechanism underlying the dwarfing of apple rootstocks is poorly understood. To elucidate the role of BR signal transduction genes in controlling apple tree architecture, five BR receptor kinase 1 (BRI1), nine BR-signaling kinase 1 (BSK1), two BRI1 KINASE INHIBITOR 1 (BKI1), and seven BR-insensitive 2 (BIN2) genes were analyzed. Bioinformatic analyses revealed that gene duplication events likely contributed to the expansion and evolution of the identified genes. Nine homologs between apple and Arabidopsis thaliana were also identified, and their expression patterns in different tissues were characterized. Exogenous BR treatments increased the primary shoot length and altered the expression of BR signal transduction genes (MdBRI1-5, MdBSK3-8, MdBKI1–2, MdBIN1–4, and MdBIN6/7). The scion of Fuji/Malling 9 (M.9) trees exhibited inhibited growth compared with that of Fuji/Fuji trees. The Fuji/M.9 trees had lower levels of the positive regulators of BR signaling (MdBRI1-5,MdBSK1, MdBSK4/7, and MdBSK6) and higher levels of the negative regulators (MdBIN5-7) compared with the Fuji/Fuji trees. Thus, the above-mentioned genes may help to regulate apple tree size in response to BR. In addition, MdBRI1–5, MdBSK1, MdBSK4/7, MdBSK6, and MdBIN5–7 have important roles in different grafting combinations. Our results may provide the basis for future analyses of BR signal transduction genes regarding their potential involvement in the regulation of plant architecture.     

Genome-wide methylation profiling of ADPKD identified epigenetically regulated genes associated with renal cyst development

Autosomal dominant polycystic kidney disease (ADPKD) is a common human genetic disease characterized by the formation of multiple fluid-filled cysts in bilateral kidneys. Although mutations in polycystic kidney disease 1 (PKD1) are predominantly responsible for ADPKD, the focal and sporadic property of individual cystogenesis suggests another molecular mechanism such as epigenetic alterations. To determine the epigenomic alterations in ADPKD and their functional relevance, ADPKD and non-ADPKD individuals were analyzed by unbiased methylation profiling genome-wide and compared with their expression data. Intriguingly, PKD1 and other genes related to ion transport and cell adhesion were hypermethylated in gene-body regions, and their expressions were downregulated in ADPKD, implicating epigenetic silencing as the key mechanism underlying cystogenesis. Especially, in patients with ADPKD, PKD1 was hypermethylated in gene-body region and it was associated with recruitment of methyl-CpG-binding domain 2 proteins. Moreover, treatment with DNA methylation inhibitors retarded cyst formation of Madin-Darby Canine Kidney cells, accompanied with the upregulation of Pkd1 expression. These results are consistent with previous studies that knock-down of PKD1 was sufficient for cystogenesis. Therefore, our results reveal a critical role for hypermethylation of PKD1 and cystogenesis-related regulatory genes in cyst development, suggesting epigenetic therapy as a potential treatment for ADPKD.     

Genome-wide annotation and expression profiling of cell cycle regulatory genes in Chlamydomonas reinhardtii

Eukaryotic cell cycles are driven by a set of regulators that have undergone lineage-specific gene loss, duplication, or divergence in different taxa. It is not known to what extent these genomic processes contribute to differences in cell cycle regulatory programs and cell division mechanisms among different taxonomic groups. We have undertaken a genome-wide characterization of the cell cycle genes encoded by Chlamydomonas reinhardtii, a unicellular eukaryote that is part of the green algal/land plant clade. Although Chlamydomonas cells divide by a noncanonical mechanism termed multiple fission, the cell cycle regulatory proteins from Chlamydomonas are remarkably similar to those found in higher plants and metazoans, including the proteins of the RB-E2F pathway that are absent in the fungal kingdom. Unlike in higher plants and vertebrates where cell cycle regulatory genes have undergone extensive duplication, most of the cell cycle regulators in Chlamydomonas have not. The relatively small number of cell cycle genes and growing molecular genetic toolkit position Chlamydomonas to become an important model for higher plant and metazoan cell cycles.     

Genome-wide identification and expression analysis of extensin genes in tomato

Extensins (EXTs) are major protein components in plant cell walls that play crucial roles in higher plants. The function of EXTs has been reported in several plants but is limited in tomato, especially in fruit ripening. In this study, we identified 83 EXTs in tomato, and divided them into seven groups. The gene intron-exon structure and protein-motif composition of SlEXTs were similar within each group but different among groups. SlEXT genes showed different expression patterns in roots, leaves, flowers and fruits, and some SlEXT gene expressions in flowers could be regulated by treatments of auxin, gibberellic acid and jasmonic acid. In particular, SlSEXT8 had higher and increased expression during tomato fruit ripening, and its expression could be induced by ethylene, suggesting SlSEXT8 may be involved in tomato fruit softening. The result provides insights into the function of EXTs, and will facilitate to further study EXT roles in tomato fruit ripening.     

Catecholamine release and uptake in the mouse prefrontal cortex

Monitoring the release and uptake of catecholamines from terminals in weakly innervated brain regions is an important step in understanding their importance in normal brain function. To that end, we have labeled brain slices from transgenic mice that synthesize placental alkaline phosphatase (PLAP) on neurons containing tyrosine hydroxylase with antibody-fluorochrome conjugate, PLAP-Cy5. Excitation of the fluorochrome enables catecholamine neurons to be visualized in living tissue. Immunohistochemical fluorescence with antibodies to tyrosine hydroxylase and dopamine beta-hydroxylase revealed that the PLAP labeling was specific to catecholamine neurons. In the prefrontal cortex (PFC), immunohistochemical fluorescence of the PLAP along with staining for dopamine transporter (DAT) and norepinephrine transporter (NET) revealed that all three exhibit remarkable spatial overlap. Fluorescence from the PLAP antibody was used to position carbon-fiber microelectrodes adjacent to catecholamine neurons in the PFC. Following incubation with L-DOPA, catecholamine release and subsequent uptake was measured and the effect of uptake inhibitors examined. Release and uptake in NET and DAT knockout mice were also monitored. Uptake rates in the cingulate and prelimbic cortex are so slow that catecholamines can exist in the extracellular fluid for sufficient time to travel approximately 100 microm. The results support heterologous uptake of catecholamines and volume transmission in the PFC of mice.     

小鼠耳芥PEBP基因家族全基因组鉴定及表达分析

PEBP (phosphatidylethanolamine-binding protein)家族包含保守的磷脂酰乙醇胺结合蛋白结构域,其中FT和TFL1蛋白构成植物成花素–反成花素系统调控植物的开花时间和株型结构被广泛关注。小鼠耳芥(Arabidopsis pumila)是早春短命植物,生长在古尔班通古特沙漠南缘荒漠地带,对环境具有较好的适应性。本研究对小鼠耳芥PEBP基因家族进行全基因组鉴定,发现其基因组包含11个PEBP基因(1个MFT、2个FT、2个TSF、2个TFL1、2个CEN和2个BFT),均由4个外显子与3个内含子组成。共线性分析表明,小鼠耳芥与拟南芥(A. thaliana)、琴叶拟南芥(A. lyrata) PEBP基因间存在11对共线性关系,PEBP家族在小鼠耳芥基因组中发生了明显的扩张,并且ApPEBP基因复制类型为全基因组复制/片段复制。组织表达分析发现ApMFT在种子中高表达,ApFT和ApBFT主要在花和果荚中表达,ApTFL1在茎尖中高表达,但ApCEN在根中高表达。进一步分析了6个ApPEBP基因在4种非生物胁迫下的表达特征,发现在10%PEG6000...     

Genome-wide analysis and expression profiling of the phospholipase D gene family in Gossypium arboreum

The plant phospholipase D(PLD)plays versatile functions in multiple aspects of plant growth,development,and stress responses.However,until now,our knowledge concerning the PLD gene family members and their expression patterns in cotton has been limited.In this study,we performed for the first time the genome-wide analysis and expression profiling of PLD gene family in Gossypium arboretum,and finally,a total of 19 non-redundant PLD genes(GaPLDs)were identified.Based on the phylogenetic analysis,they were divided into six well-supported clades(α,β/γ,δ,ε,ζ and φ).Most of the GaPLD genes within the same clade showed the similar exon-intron organization and highly conserved motif structures.Additionally,the chromosomal distribution pattern revealed that GaPLD genes were unevenly distributed across 10 of the 13 cotton chromosomes.Segmental duplication is the major contributor to the expansion of Ga PLD gene family and estimated to have occurred from19.61 to 20.44 million years ago when a recent large-scale genome duplication occurred in cotton.Moreover,the expression profiling provides the functional divergence of GaPLD genes in cotton and provides some new light on the molecular mechanisms of GaPLDα1 and GaPLDδ2 in fiber development.     

Genome-wide gene expression analysis in mouse embryonic stem cells

Embryonic stem cell studies have generated great interest, due to their ability to form a wide variety of matured cells. However, there remains a poor understanding of mechanisms regulating the cell state of embryonic stem cells (ESCs) and of the genes they express during early differentiation. Gene expression analysis may be a valuable tool to elucidate either the molecular pathways involved in self-renewal and pluripotency, or early differentiation and to identify potential molecular therapy targets. The aim of this study was to characterize at the molecular level the undifferentiated mouse ESC state and the early development towards embryoid bodies. To attempt this issue, we performed CodeLink Mouse Uniset I 20K bioarrays in a well-characterized mouse ESC line, MES3, 3- and 7 day-old embryoid bodies and we compared our findings with those in adult tissue cells. Gene expression results were subsequently validated in a commercial stem cell line, CGR8 (ATCC). Significance Analysis of Microarrays (SAM) was used to identify statistically significant changes in microarray data. We identified 3664 genes expressed at significantly greater levels in MES3 stem cells than in adult tissue cells, which included 611 with 3-fold higher gene expression levels versus the adult cells. We also investigated the gene expression profile during early embryoid body formation, identifying 2040 and 2243 genes that were up-regulated in 3- and 7- day-old embryoid bodies, respectively. Our gene expression results in MES3 cells were partially confirmed in CGR8 cells, showing numerous genes that are expressed in both mouse stem cells. In conclusion, our results suggest that commonly expressed genes may be strong candidates for involvement in the maintenance of a pluripotent and undifferentiated phenotype and in early development.     

谷子 MADS-box基因家族的鉴定和表达分析

MADS-box基因是真核生物中一类重要的转录因子,参与调控多项植物的生长发育过程。然而关于谷子穗发育的MADS-box基因研究比较少。本研究使用序列相似性检索,在Phytozome 13.0数据库中筛选并且鉴定出了68个谷子MADS家族成员,并对这些家族成员的物理化学性质、系统发育树、染色体定位、表达谱等进行了全面的分析。结果表明,谷子MADS家族成员在染色体上分布不均匀,可以分为5个亚族。通过组织特异性表达谱分析得到,多数MADS基因在穗中表达量要高于其他器官。此外利用转录组测序技术对发育初期的谷穗和成熟期的谷穗进行了转录组测序分析,筛选到数个与谷穗分生组织发育相关MADS-box基因。为进一步揭示MADS-box基因在谷子穗发育过程中的作用奠定了重要的基础。