The genetics of gene expression and gene mapping

A recent publication has shown that a significant portion of gene expression levels are under genetic control in different organisms, that there are hotspot regions in the genome that control the expression of many other genes, and how gene expression data can be used to localize genes that affect clinical traits.     

转录后水平沉默与基因表达

基因沉默是1个非常复杂和普遍的现象。转录后水平的基因沉默是指转基因在细胞核里能稳定转录,细胞质里却无相应的稳定态mRNA存在的现象。它往往被称为共抑制、静息作用或RNA干预等。本文介绍了转录后水平的基因沉默现象的发现、分子机理和应用等方面的进展。提出了克服转录后水平基因沉默的一些对策。     

Heterochromatin,gene position effect and gene silencing

Genomes of higher eukaryotes consist of two types of chromatin: euchromatin and heterochromatin. Heterochromatin is densely packed material typically localized in telomeric and pericentric chromosome regions. Euchromatin transferred by chromosome rearrangements in the vicinity of heterochromatin is inactivated and acquires morphological properties of heterochromatin in the case of position effect variegation. One of the X chromosomes in mammal females and all paternal chromosome set in coccides become heterochromatic. The heterochromatic elements of the genome exhibit similar structural properties: genetic inactivation, compaction, late DNA replication at the S stage, and underrepresentation in somatic cells. The genetic inactivation and heterochromatin assembly are underlain by a specific genetic mechanism, silencing, which includes DNA methylation and posttranslational histone modification provided by the complex of nonhistone proteins. The state of silencing is inherited in cell generations. The same molecular mechanisms of silencing shared by all types of heterochromatic regions, be it unique or highly repetitive sequences, suggest the similar organization of these regions. No type of heterochromatin is a permanent structure as they all are formed at the strictly definite stages of early embryogenesis. Based on the bulk of evidence accumulated today, heterochromatin can be regarded as a morphological manifestation of genetic silencing.     

金黄色葡萄球菌耐消毒剂基因及抗生素耐药相关基因检测

目的 了解温州地区临床分离的金黄色葡萄球菌(SA)的耐药特点,探讨SA中耐β-内酰胺类、氨基糖苷类、四环素类药物耐药基因及耐消毒剂基因(qacA)的存在情况.方法 采用聚合酶链式反应(PCR)法对SA进行β-内酰胺酶基因、氨基糖苷类修饰酶基因、四环素类基因和耐消毒剂基因检测.结果 PCR结果显示94株SA中耐药相关基因检出率mecA 53.2％、aac(6’)/aph(2")68.1％、aph(3’)-Ⅲ 37.2％、tetM 53.2％和qacA 7.4％,其中59株MRSA的耐药相关基因检出率分别为mecA 83.1％、aac(6’)/aph(2")86.4％、aph(3 ′)-Ⅲ 42.4％、tetM 76.4％和qacA 8.5％.结论 多数SA菌株存在耐β-内酰胺类、氨基糖苷类、四环素类等多种抗生素耐药基因,具有多重耐药特征,但尚未出现明显耐消毒剂状况.     

Reshaping of global gene expression networks and sex-biased gene expression by integration of a young gene

New genes originate frequently across diverse taxa. Given that genetic networks are typically comprised of robust, co-evolved interactions, the emergence of new genes raises an intriguing question: how do new genes interact with pre-existing genes? Here, we show that a recently originated gene rapidly evolved new gene networks and impacted sex-biased gene expression in Drosophila. This 4–6 million-year-old factor, named Zeus for its role in male fecundity, originated through retroposition of a highly conserved housekeeping gene, Caf40. Zeus acquired male reproductive organ expression patterns and phenotypes. Comparative expression profiling of mutants and closely related species revealed that Zeus has recruited a new set of downstream genes, and shaped the evolution of gene expression in germline. Comparative ChIP-chip revealed that the genomic binding profile of Zeus diverged rapidly from Caf40. These data demonstrate, for the first time, how a new gene quickly evolved novel networks governing essential biological processes at the genomic level.     

Comparative studies of gene expression and the evolution of gene regulation

The hypothesis that differences in gene regulation have an important role in speciation and adaptation is more than 40 years old. With the advent of new sequencing technologies, we are able to characterize and study gene expression levels and associated regulatory mechanisms in a large number of individuals and species at an unprecedented resolution and scale. We have thus gained new insights into the evolutionary pressures that shape gene expression levels and have developed an appreciation for the relative importance of evolutionary changes in different regulatory genetic and epigenetic mechanisms. The current challenge is to link gene regulatory changes to adaptive evolution of complex phenotypes. Here we mainly focus on comparative studies in primates and how they are complemented by studies in model organisms.     

Co-expression and immunity of Legionella pneumophila mip gene and immunoadjuvant ctxB gene

The mip gene of Legionella pneumophila and the ctxB gene of Vibrio cholerae were amplifiedby PCR respectively.The amplified cDNA was ligated to the pcDNA3.1(+)vector.The recombinant plasmidspcDNA3,1-mip and pcDNA3.1-ctxB were identified by restriction analysis and PCR,and further confirmedby sequencing analysis.NIH3T3 cells were transfected with pcDNA3.1-mip and pcDNA3.1-ctxB accordingto the Lipofection method.Transient and stable products of the co-expression of the mip gene and ctxB genewere detected by immunofluorescence and Western blotting.The results showed that NIH3T3 cells weresuccessfully transfected,and that the transiently and stably co-expressed products can be detected in thetransfected cells.To detect the humoral and cellular immune response in immunized mice induced by the co-immunization of the mip and ctxB genes,female BALB/c mice were immunized intramuscularly with pcDNA3.1-mip and pcDNA3.1-ctxB.The results showed that the specific antibody titer and the cytotoxic T-lymphocyteresponse for pcDNA3,1-mip immunization and co-immunization were increased compared with that ofpcDNA3.1(+) immunization.Furthermore,the specific antibody titer and cytotoxic T-lymphocyte responsefor co-immunization were increased compared with that of pcDNA3.1-mip immunization.Statistical analysisusing one-way analysis of variance(ANOVA)showed that there was a significant difference between thegroups(P<0.01).The results indicated that the ctxB gene enhanced the humoral and cellular immune responseto the mip gene immunization.These findings provide experimental evidence to support the development ofthe L.pneumophila DNA vaccine.     

纳豆激酶酶原基因和纳豆激酶基因的克隆及在大肠杆菌中表达

目的：构建可高效生产有活性的纳豆激酶的大肠杆菌工程菌。方法：将纳豆激酶酶原（pro-nattokinase,pro-NK)基因和纳豆激酶（natokinase,NK)基因,并分别克隆到表达融合蛋白的高效表达载体pJN上,构建出表达质粒pJNK1和pJNK2,并转化大肠杆菌BL21（DE3）。结果：IPTG诱导下,两个融合蛋白的表达量均达到30%,活性检测显示表达纳豆激酶酶原融合蛋白的菌株pJNK-1(BL)诱导后菌体破碎上清的溶栓活性比表达纳豆激酶融合蛋白的菌株pJNK-2(BL)高2-3倍,结论：纳豆激酶酶原融合蛋白部分自减切产生纳豆激酶成熟肽。     

Translational control of bacteriophage f1 gene II and gene X proteins by gene V protein

The gene II region of bacteriophage f1 DNA codes for two proteins, the 46 kd gene II protein and the 13 kd gene X protein, which results from an in-phase start at codon 300 of gene II. Using antigens II protein IgG, we show that the intracellular concentration of both proteins is controlled by the phage gene V protein. In wild-type f1-infected cells, the amount of gene II protein reaches a plateau of about 1500 molecules per cell at 20 min after infection, as measured by blot immunoassay. Similarly, the amount of gene X protein reaches a peak of about 500 molecules per cell around 10 min after infection. In contrast, when the gene V protein is inactive, both gene II and gene X proteins continue to accumulate at a high rate for at least 40 min after infection. This difference is caused by decreased synthesis of gene II and gene X proteins in the presence of gene V protein, which represses the translation of these two proteins.     

Multifunctional nanocomplexes for gene transfer and gene therapy

DNA formulated into aggregates with polycationic reagents are referred to by a variety of terms including non-viral vectors, synthetic vectors, lipoplexes, polyplexes and more recently nanoparticles. The capacity for delivery of multiple genes, genomic-sized constructs and siRNA delivery, with a diversity of possible formulations, as well as the possibilities of improved efficiency of in vivo gene deliveries, means that nanoparticles, or nanocomplexes to reflect self-assembling systems, will be investigated with increasing vigour in the coming years. This review briefly outlines the applications and challenges for nanoparticle technologies in the field of gene therapy then focuses on the development of a specific kind of formulation, receptor-targeted nanocomplex (RTN), that we have found to be particularly useful in our gene therapy research. An overriding guiding concept that has emerged in the development of synthetic nanodelivery systems is the idea to develop formulations and structures that mimic viruses, whilst retaining the safety elements of synthetic, non-viral systems. RTNs have been optimised and developed for airway epithelial transfection, leading towards gene therapy for cystic fibrosis and for vascular transfection in vein grafts used in bypass surgery. The modular design of the RTN platform further allows for the testing of specific hypotheses relating to the structure and functional role of components in the formation of stable particles and in the transfection pathway, leading to their ultimate disassembly in the nucleus.     

Dynamic gene amplification and function diversification of grass-specific O-methyltransferase gene family

The plant O-methyltransferases are dependent on S-Adenosyl-l-methionine, which can catalyze a variety of secondary metabolites. Here we identified different number of OMT genes from the respective grass genomes. Phylogenetic analysis showed that this OMT gene family is a grass-specific gene family that is different from COMT. Most of genes were expanded by tandem and segment duplication after the species split from their progenitor. Furthermore, genes from Group I and two clusters from group II are only present in Panicoideae, which included Bx10 and Bx7 involved in the benzoxazinoids pathway, suggesting these genes could participate in insect resistance in Panicoideae. Gene expression profiles showed that OMT genes were preferentially expressed in vegetative stages, especially in roots. These results revealed that this grass-specific OMT gene family could affect the development of vegetative stages, and be involved in the benzoxazinoids pathway or suberin biosynthesis that was different from COMT.