Genome-wide analysis of gene expression in human embryonic tooth germ

While numerous genes that play important regulatory roles during tooth development in mice have been identified, little is known about gene expression profile and their function during human odontogenesis. To unveil expression profile of odontogenic genes in humans, we conducted genome-wide gene expression analysis by microarray assays to analyze differential gene expression between tooth germ and lip tissue from 11-week old human fetuses. We identified 167 genes that are strongly expressed in the cap stage tooth germ as compared to the lip tissue. Among them, 145 genes were further identified by gene ontology enrichment analysis that are highly represented in multiple gene ontology classes, include extracellular components, sequence-specific DNA binding proteins, Wnt-protein binding molecules, system development, organogenesis, and cell differentiation. Sixty-seven genes that are known to be associated with mammalian tooth development and tooth abnormalities were identified. Real-time PCR was further employed to validate microarray data. Moreover, in situ hybridization assay demonstrated tooth type specific expression of ISL1 and BARX1 in the incisor, canine, and molar respectively, consistent with microarray results. Our results represent a set of reliable data that could provide a solid base for future elaboration of molecular mechanisms underlying human tooth development.     

Ultrastructure of inclusion bodies in annulus cells in the degenerating human intervertebral disc

The rough endoplasmic reticulum (rER) of the cell has an architectural editing function that checks whether protein structure and three-dimensional assembly have occurred properly prior to export of newly synthesized material out of the cell. If these have been faulty, the material is retained within the rER as an inclusion body. Inclusion bodies have been identified previously in chondrocytes and osteoblasts in chondrodysplasias and osteogenesis imperfecta. Inclusion bodies in intervertebral disc cells, however, have only recently been recognized. Our objectives were to use transmission electron microscopy to analyze more fully inclusion bodies in the annulus pulposus and to study the extracellular matrix (ECM) surrounding cells containing inclusion bodies. ECM frequently encapsulated cells with inclusion bodies, and commonly contained prominent banded aggregates of Type VI collagen. Inclusion body material had several morphologies, including relatively smooth, homogeneous material, or a rougher, less homogeneous feature. Such findings expand our knowledge of the fine structure of the human disc cell and ECM during disc degeneration, and indicate the potential utility of ultrastructural identification of discs with intracellular inclusion bodies as a screening method for molecular studies directed toward identification of defective gene products in degenerating discs.     

Interleukin 1-beta upregulates brain-derived neurotrophic factor,neurotrophin 3 and neuropilin 2 gene expression and NGF production in annulus cells

The relationship between disc cells, nerves and pain production in the intervertebral disc is poorly understood. Neurotrophins, signaling molecules involved in the survival, differentiation and migration of neurons, and neurite outgrowth, are expressed in non-neuronal tissues including the disc. We hypothesized that three-dimensional exposure of human disc cells to the proinflammatory cytokine IL-1ß in vitro would elevate neurotrophin gene expression levels and production of nerve growth factor (NGF). Cells isolated from Thompson grade III and IV discs were cultured for 14 days under control conditions or with addition of 10² pM IL-1ß; mRNA was isolated and conditioned media assayed for NGF content. IL-1ß exposure in three-dimensional culture significantly increased expression of neurotrophin 3, brain-derived neurotrophic factor, and neuropilin 2 compared to controls. IL-1ß-exposed cells showed significantly increased NGF production compared to controls. Findings support our hypothesis, expand previous data concerning expression of neurotrophins, and provide the first documented expression of neurotrophin 3 and neuropilin 2. Our results have direct translational relevance, because they address the primary clinical issue of low back pain and open the possibility of novel analgesic therapies using specific small-molecular antagonists to neurotrophins.     

Genome-wide identification, phylogeny and expression analysis of the lipoxygenase gene family in cucumber

Plant lipoxygenase (LOX) is involved in growth and developmental control processes, through the biosynthesis of regulatory molecules and defense responses to pathogens, wounding and stress. To date, few LOX proteins and little tissue expression profiling have been reported in detail for cucumber (Cucumis sativus L.). Recent completion of the cucumber genome sequence now permits genome-wide analysis of the LOX gene family in cucumber as well as comparison with LOX in Arabidopsis and rice. We identified 23 candidate LOX genes in the cucumber genome; phylogenetic analysis indicated that these LOX members cluster into two groups, designated types 1 and 2, as expected from previous studies. Sequence analysis showed that five binding sites of iron, including two consensus histidines in the LOX domain, are highly conserved in the cucumber LOX proteins. Analysis of chromosomal localization and genome distribution suggested that tandem duplication and/or polyploidal duplication contributed to the expansion of the cucumber LOX gene family. Based on intron/exon structure analysis, only a few of the extant intron patterns existed in the ancestor of monocots and eudicots. Expression data showed widespread distribution of the cucumber LOX gene family within plant tissues, suggesting that they perform different functions in different tissues.     

Genome-wide estimation of gender differences in the gene expression of human livers: Statistical design and analysis

Background

Gender differences in gene expression were estimated in liver samples from 9 males and 9 females. The study tested 31,110 genes for a gender difference using a design that adjusted for sources of variation associated with cDNA arrays, normalization, hybridizations and processing conditions.

Results

The genes were split into 2,800 that were clearly expressed (expressed genes) and 28,310 that had expression levels in the background range (not expressed genes). The distribution of p-values from the 'not expressed' group was consistent with no gender differences. The distribution of p-values from the 'expressed' group suggested that 8 % of these genes differed by gender, but the estimated fold-changes (expression in males / expression in females) were small. The largest observed fold-change was 1.55. The 95 % confidence bounds on the estimated fold-changes were less than 1.4 fold for 79.3 %, and few (1.1%) exceed 2-fold.

Conclusion

Observed gender differences in gene expression were small. When selecting genes with gender differences based upon their p-values, false discovery rates exceed 80 % for any set of genes, essentially making it impossible to identify any specific genes with a gender difference.

     

桃WRKY基因家族全基因组鉴定和表达分析

WRKY转录因子是植物中最大的转录调控家族之一,在生物和非生物胁迫以及植物生长和发育过程中起着重要调控作用.本文利用HMMER 3.0软件,使用WRKY保守域全蛋白序列(Pfam数据库编号:PF03106)鉴定桃(Prunus persica L.)基因组中的WRKY基因;利用DNAMAN 5.0,WebLogo 3,MEGA5.1,MapInspect和MEME等软件对其蛋白序列进行生物信息学分析.本文共鉴定得到61个桃WRKY基因.进化树分析结果显示,桃WRKY蛋白分为Ⅰ,Ⅱ和Ⅲ类型,类型Ⅰ分为Ⅰ-C亚组和Ⅰ-N亚组,类型Ⅱ分为Ⅱ-a,II-b,II-c,II-d和II-e亚组.WRKY结构域分析显示,WRKY结构域高度保守,绝大多数都含有WRKYGQK七肽和锌指结构.染色体定位分析显示,桃WRKY基因分布于8条染色体中,呈不均匀分布.内含子和外显子结构分析表明,WRKY基因结构进化高度保守.保守元件分析表明,桃WRKY基因家族包含5个保守元件,元件1,2和3为WRKY盒,元件4,5为未知盒.桃WRKY基因家族都包含有WRKY盒,类型Ⅰ中含有2个WRKY盒;II-d亚组中含有未知元件5.半定量和荧光定量PCR结果显示,16个WRKY基因均在桃的根,茎,叶,花和果中表达,但其相对表达水平不同.     

Genome-wide identification and expression analysis of the TaYUCCA gene family in wheat

Molecular Biology Reports - Auxin is an important endogenous hormone in plants. The YUCCA gene encodes a flavin monooxygenase, which is an important rate-limiting enzyme in the auxin synthesis...     

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.     

葡萄生长素响应基因家族生物信息学鉴定和表达分析

生长素响应基因家族能调节植物体内生长素平衡和生长素信号途径。文章采用生物信息学方法检索获得葡萄(Vitisvinifera L.)基因组数据库中的生长素响应基因,通过分析其染色体定位、基因共线性和系统进化,发现葡萄基因组含有25个AUX_IAA基因、19个ARF基因、9个GH3基因、42个LBD基因。这些生长素响应基因不均匀分布在葡萄的19条染色体上,部分家族基因在染色体上形成基因簇。葡萄芯片数据结果表明,生长素响应基因在葡萄不同时期的果实和叶芽中均有表达,尤其在果实转色期、叶芽萌发或休眠期表达量急剧变化。研究结果为葡萄生长素响应基因在叶片和果实发育过程中的功能研究提供参考。