Activation of a C. elegans Antennapedia homologue in migrating cells controls their direction of migration.

Anterior-posterior patterning in insects, vertebrates and nematodes involves members of conserved Antennapedia-class homeobox gene clusters (HOM-C) that are thought to give specific body regions their identities. The effects of these genes on region-specific body structures have been described extensively, particularly in Drosophila, but little is known about how HOM-C genes affect the behaviours of cells that migrate into their domains of function. In Caenorhabditis elegans, the Antennapedia-like HOM-C gene mab-5 not only specifies postembryonic fates of cells in a posterior body region, but also influences the migration of mesodermal and neural cells that move through this region. Here we show that as one neuroblast migrates into this posterior region, it switches on mab-5 gene expression; mab-5 then acts as a developmental switch to control the migratory behaviour of the neuroblast descendants. HOM-C genes can therefore not only direct region-specific patterns of cell division and differentiation, but can also act within migrating cells to programme region-specific migratory behaviour.     

Identifying Micro RNA and Gene Expression Networks Using Graph Communities

Integrative network analysis is powerful in helping understand the underlying mechanisms of genetic and epigenetic perturbations for disease studies.Although it becomes clear that micro RNAs,one type of epigenetic factors,have direct effect on target genes,it is unclear how micro RNAs perturb downstream genetic neighborhood.Hence,we propose a network community approach to integrate micro RNA and gene expression profiles,to construct an integrative genetic network perturbed by micro RNAs.We apply this approach to an ovarian cancer dataset from The Cancer Genome Atlas project to identify the fluctuation of micro RNA expression and its effects on gene expression.First,we perform expression quantitative loci analysis between micro RNA and gene expression profiles via both a classical regression framework and a sparse learning model.Then,we apply the spin glass community detection algorithm to find genetic neighborhoods of the micro RNAs and their associated genes.Finally,we construct an integrated network between micro RNA and gene expression based on their community structure.Various disease related micro RNAs and genes,particularly related to ovarian cancer,are identified in this network.Such an integrative network allows us to investigate the genetic neighborhood affected by micro RNA expression that may lead to disease manifestation and progression.     

水杨酸对烟草GRPs基因表达的影响

通过RT-PCR得到富含甘氨酸RNA结合蛋白（GRPs）基因片段,利用northern杂交技术对水杨酸诱导不同时间不同烟草GRPs基因的表达模式进行研究.结果表明：水杨酸能诱导烟草GRPs基因上调表达,3 h达到最高,然后开始下降;但3个TMV抗性不同的供试烟草增加幅度不同,基因表达幅度与抗性有一定关系,抗性强的红花大金元表达增幅大于抗性较弱的云烟85.本研究明确了水杨酸诱导下烟草该基因的表达谱,揭示了SA诱导烟草不同抗性的品种的幅度不同,并且发现诱导后3 h为关键点,表明GRPs基因可作为烟草水杨酸代谢途径中的一个标记基因研究其途径对逆境的应答.     

Structural insights into mRNA recognition from a PIWI domain-siRNA guide complex

RNA interference and related RNA silencing phenomena use short antisense guide RNA molecules to repress the expression of target genes. Argonaute proteins, containing amino-terminal PAZ (for PIWI/Argonaute/Zwille) domains and carboxy-terminal PIWI domains, are core components of these mechanisms. Here we show the crystal structure of a Piwi protein from Archaeoglobus fulgidus (AfPiwi) in complex with a small interfering RNA (siRNA)-like duplex, which mimics the 5' end of a guide RNA strand bound to an overhanging target messenger RNA. The structure contains a highly conserved metal-binding site that anchors the 5' nucleotide of the guide RNA. The first base pair of the duplex is unwound, separating the 5' nucleotide of the guide from the complementary nucleotide on the target strand, which exits with the 3' overhang through a short channel. The remaining base-paired nucleotides assume an A-form helix, accommodated within a channel in the PIWI domain, which can be extended to place the scissile phosphate of the target strand adjacent to the putative slicer catalytic site. This study provides insights into mechanisms of target mRNA recognition and cleavage by an Argonaute-siRNA guide complex.     

Structural basis for gene regulation by a thiamine pyrophosphate-sensing riboswitch

Riboswitches are metabolite-sensing RNAs, typically located in the non-coding portions of messenger RNAs, that control the synthesis of metabolite-related proteins. Here we describe a 2.05 angstroms crystal structure of a riboswitch domain from the Escherichia coli thiM mRNA that responds to the coenzyme thiamine pyrophosphate (TPP). TPP is an active form of vitamin B1, an essential participant in many protein-catalysed reactions. Organisms from all three domains of life, including bacteria, plants and fungi, use TPP-sensing riboswitches to control genes responsible for importing or synthesizing thiamine and its phosphorylated derivatives, making this riboswitch class the most widely distributed member of the metabolite-sensing RNA regulatory system. The structure reveals a complex folded RNA in which one subdomain forms an intercalation pocket for the 4-amino-5-hydroxymethyl-2-methylpyrimidine moiety of TPP, whereas another subdomain forms a wider pocket that uses bivalent metal ions and water molecules to make bridging contacts to the pyrophosphate moiety of the ligand. The two pockets are positioned to function as a molecular measuring device that recognizes TPP in an extended conformation. The central thiazole moiety is not recognized by the RNA, which explains why the antimicrobial compound pyrithiamine pyrophosphate targets this riboswitch and downregulates the expression of thiamine metabolic genes. Both the natural ligand and its drug-like analogue stabilize secondary and tertiary structure elements that are harnessed by the riboswitch to modulate the synthesis of the proteins coded by the mRNA. In addition, this structure provides insight into how folded RNAs can form precision binding pockets that rival those formed by protein genetic factors.     

Specification of limb development in the Drosophila embryo by positional cues from segmentation genes

Limb development in Drosophila requires the activity of a proximo-distal pattern-forming system, in addition to the antero-posterior and dorso-ventral pattern-forming systems that subdivide the embryo. Several lines of genetic evidence indicate that the Distal-less gene plays an important part in specifying proximo-distal positional information. The Distal-less locus encodes a homoeodomain-containing protein, which suggests that Distal-less may exert its activity through differential regulation of subordinate genes. The spatially restricted pattern of Distal-less expression allows direct visualization of the limb primordia during early embryogenesis. Here I report that from their inception, the leg primordia span the parasegment boundary. The segment polarity gene wingless seems to have a key part in defining the positions at which leg primordia will develop along the antero-posterior axis of the embryo. This analysis allows a direct molecular visualization of the compartments that subdivide the limb primordia into discrete developmental domains.     

Unravelling the dynamics of RNA degradation by ribonuclease II and its RNA-bound complex

RNA degradation is a determining factor in the control of gene expression. The maturation, turnover and quality control of RNA is performed by many different classes of ribonucleases. Ribonuclease II (RNase II) is a major exoribonuclease that intervenes in all of these fundamental processes; it can act independently or as a component of the exosome, an essential RNA-degrading multiprotein complex. RNase II-like enzymes are found in all three kingdoms of life, but there are no structural data for any of the proteins of this family. Here we report the X-ray crystallographic structures of both the ligand-free (at 2.44 A resolution) and RNA-bound (at 2.74 A resolution) forms of Escherichia coli RNase II. In contrast to sequence predictions, the structures show that RNase II is organized into four domains: two cold-shock domains, one RNB catalytic domain, which has an unprecedented alphabeta-fold, and one S1 domain. The enzyme establishes contacts with RNA in two distinct regions, the 'anchor' and the 'catalytic' regions, which act synergistically to provide catalysis. The active site is buried within the RNB catalytic domain, in a pocket formed by four conserved sequence motifs. The structure shows that the catalytic pocket is only accessible to single-stranded RNA, and explains the specificity for RNA versus DNA cleavage. It also explains the dynamic mechanism of RNA degradation by providing the structural basis for RNA translocation and enzyme processivity. We propose a reaction mechanism for exonucleolytic RNA degradation involving key conserved residues. Our three-dimensional model corroborates all existing biochemical data for RNase II, and elucidates the general basis for RNA degradation. Moreover, it reveals important structural features that can be extrapolated to other members of this family.     

Domain-specific recruitment of amide amino acids for protein synthesis

The formation of aminoacyl-transfer RNA is a crucial step in ensuring the accuracy of protein synthesis. Despite the central importance of this process in all living organisms, it remains unknown how archaea and some bacteria synthesize Asn-tRNA and Gln-tRNA. These amide aminoacyl-tRNAs can be formed by the direct acylation of tRNA, catalysed by asparaginyl-tRNA synthetase and glutaminyl-tRNA synthetase, respectively. A separate, indirect pathway involves the formation of mis-acylated Asp-tRNA(Asn) or Glu-tRNA(Gln), and the subsequent amidation of these amino acids while they are bound to tRNA, which is catalysed by amidotransferases. Here we show that all archaea possess an archaea-specific heterodimeric amidotransferase (encoded by gatD and gatE) for Gln-tRNA formation. However, Asn-tRNA synthesis in archaea is divergent: some archaea use asparaginyl-tRNA synthetase, whereas others use a heterotrimeric amidotransferase (encoded by the gatA, gatB and gatC genes). Because bacteria primarily use transamidation, and the eukaryal cytoplasm uses glutaminyl-tRNA synthetase, it appears that the three domains use different mechanisms for Gln-tRNA synthesis; as such, this is the only known step in protein synthesis where all three domains have diverged. Closer inspection of the two amidotransferases reveals that each of them recruited a metabolic enzyme to aid its function; this provides direct evidence for a relationship between amino-acid metabolism and protein biosynthesis.     

Inability of CD8 alpha' polypeptides to associate with p56lck correlates with impaired function in vitro and lack of expression in vivo

T-cell accessory molecules, particularly CD4 and CD8, seem to be involved in the control of T-cell activation by antigen. Precisely how such molecules operate is not fully understood, but evidence to date suggests a dual role, as receptors binding ligands on stimulator cells and by direct or indirect involvement in intracellular signalling events. In mouse, truncated 'tailless' CD8 molecules occur naturally (CD8 alpha' polypeptides) and although they are expressed on the surface of thymocytes, they are not expressed on the surface of mature T cells. In this study, we show that truncated CD8 molecules are impaired in their ability to interact with the protein tyrosine kinase, p56lck, and have decreased ability to restore immune responsiveness in vitro. Our data support a dual function for CD8 molecules correlated with expression of external domains and cytoplasmic domains, respectively. Both functions appear to be critical for a competent immune system in vivo.     

Revealing the world of RNA interference

The recent discoveries of RNA interference and related RNA silencing pathways have revolutionized our understanding of gene regulation. RNA interference has been used as a research tool to control the expression of specific genes in numerous experimental organisms and has potential as a therapeutic strategy to reduce the expression of problem genes. At the heart of RNA interference lies a remarkable RNA processing mechanism that is now known to underlie many distinct biological phenomena.     

盐生杜氏藻和衣藻双结构域NAD+-GPD基因的生物信息学分析

盐生杜氏藻（Dunaliella salina）是极端耐盐的单细胞真核绿藻,依赖于NAD的3－磷酸甘油脱氢酶（NAD+-GPD）是盐生杜氏藻调渗物质——甘油合成的关键酶.盐生杜氏藻NAD+-GPD基因是第一个被发现含双结构域（SerB和GPD）的GPD基因.而双结构域可能是盐生杜氏藻具有极强耐盐性和快速合成甘油的关键.通过与莱茵衣藻基因组数据库比对,发现莱茵衣藻（Chlamydomonas reinhardtii）中也存在具有SerB和GPD结构域的NAD+-GPD基因序列.在对两个物种NAD+-GPD基因的基因结构、mRNA组成成分、编码蛋白及其理化性质和编码蛋白结构的分析中,发现二者具有较高的相似性.针对目前仅在盐藻和衣藻中发现含SerB和GPD结构域的NAD+-GPD基因这一现象,分别对SerB和GPD结构域同源基因的系统进化进行了分析.