油桐尺蠖单粒包埋核型多角体病毒(BusuNPV)BamHI-H片段的序列分析

对油桐尺蠖单粒包埋核型多角体病毒(Buzura suppressaria single-nucleocapsid nucleopolyhedrovirus, BusuNPV)基因组中BamHI-H片段的序列进行分析,该片段全长2 422 bp,包括三个开放阅读框:p47基因(AcMNPV ORF40的同源区)的5′端,完整的组织蛋白酶基因(cathepsin)(AcMNPV ORF127的同源区)和p74基因(AcMNPV ORF138的同源区)的3′端.序列比较分析表明,BusuNPV的这三个基因与其它杆状病毒的同源基因具有相同的结构保守区.BusuNPV基因组BamHI-H片段上这三个基因的排列顺序完全不同于AcMNPV相应基因的排列顺序.     

斜纹夜蛾核多角体病毒（SpltNPV）基因组EcoRI—G片段的序列分析

斜纹夜蛾核多角体病毒 (SpltNPV)基因组EcoRI G片段全长 745 0bp ,包括 7个开放读码框 :vp39、lef 4、cg30、p91、vp33、tlp2 0、AcMNPVORF81同源基因和一个同源区 (hr)。基因组排列比较分析发现 ,这些基因在基因组中的排列 ,在所有已知序列的杆状病毒中都比较保守     

小鼠锌指蛋白基因ZF-12的克隆与基因结构以及5′端启动子活性的分析

人类锌指蛋白ZNF191为类krueppel转录因子,其可能与神经精神病、心血管疾病和肝癌等疾病的发生或发展有关,为了采用基因敲除模型来探讨它的生理功能,克隆和定位其在模式生物（小鼠）中的同源基因,并阐明其结构特征是必需的。通过筛选小鼠λ噬菌体基因组文库,获得了它在小鼠中的同源基因ZF－12基因组全长片段。序列分析表明：该基因含有4个外显子和3个内含子,内含子都遵循GT／AG的剪接模式;第91密码子处存在单核苷酸多态性;可能存在2种大小不同的3′端的非翻译区（3′－UTR）;与锌指蛋白基因Zfp-35相连锁,可将其定位于18号染色体的B3－C带上或附近;5′端上游存在1个约250bp高度富含GC的启动子序列。ZF－12基因的5′端系列缺失荧光素酶基因报告载体的瞬时转染实验表明:其上游序列（-762～ 70bp）具有启动子转录活性,在更上游的序列（－824～-762bp)上可能存在负调控元件。这项研究结果为进一步的基因敲除研究奠定了基础。     

中国棉铃虫核多角体病毒基因组 Xba I-I片段的序列分析

报道了棉铃虫单核衣壳核多角体病毒(HaSNPV)XbaI-I片段的序列结构.该片段在基因组上定位于18.4～22.8 m.u., 包括8个完整的开放阅读框架和p47的5′端部分序列其中ubiquitin, 39K/pp31, lef-11, p47, Ac34, Ac38和Lsel25 homologue 7个基因是杆状病毒的同源基因, 另外两个orf507和orf1 080是HaSNPV的特有基因,且具有典型的早期表达基因启动子的特征,经软件分析发现这两个基因推导的产物具有典型的跨膜压结构.序列比较分析表明, ubiquitin基因与其它杆状病毒的同源基因有相同的保守区, 39K/pp31具有和其它杆状病毒同源基因不同的启动子结构.     

斜纹夜蛾核型多角体病毒BamHI—J片段序列分析

报道了斜纹夜蛾核型多角体病毒（SpltMNPV)BamHI-J片段的序列结构。该片段定位于SpltMNPV基因组25.8-29.9图单位（msp unit）,包括4个完整的开放读码框,几丁质酶基因（chiA）的3′端部分序列和一个同源区（hr）的部分序列。4个完整的读码框包括lef-8基因,杆状病毒J结构域蛋白基因（baculovirus J domain protein gene,bjdp),ORF570和ORF165。序列分离表明：ORF570与毒蛾核型多角体病毒（Lymantria dispar MNPV）的解旋酶－2基因有31％的氨基酸同源性。ORF165为SpltMNPV特有。J结构域蛋白在其他杆状病毒基因组中尚未见报道,其氨基酸序列N端存在J结构域,推断该蛋白质具有与DnaJ蛋白类似特征。lef-8基因编码的氨基酸与已报道的杆状病毒基因组中的lef-8基因编码的氨基酸具有高的同源性,且其C端具有与其他杆状病毒LEF－8类似的保守序列CIKICGIHGQKG。     

中国棉铃虫核多角体病毒基因组XbaI—I片段的序列分析

报道了棉铃虫单核衣壳核多角体病毒 (HaSNPV)XbaI I片段的序列结构。该片段在基因组上定位于 18.4～2 2 .8m .u .,包括 8个完整的开放阅读框架和 p47的 5′端部分序列 :其中ubiquitin ,39K/pp31,lef - 11,p47,Ac34 ,Ac38和Lsel2 5homologue 7个基因是杆状病毒的同源基因 ,另外两个orf5 0 7和orf10 80是HaSNPV的特有基因 ,且具有典型的早期表达基因启动子的特征 ,经软件分析发现这两个基因推导的产物具有典型的跨膜压结构。序列比较分析表明 ,ubiquitin基因与其它杆状病毒的同源基因有相同的保守区 ,39K/pp31具有和其它杆状病毒同源基因不同的启动子结构     

斜纹夜蛾核多角本病毒（SpltNPV）基因组4.73Kb片段的？…

报道了斜纹夜蛾核多角体病毒（Ｓｐｏｄｏｐｔｅｒａ ｌｉｔｕｒａ ｎｕｃｌｅｏｐｏｌｙｈｅｄｒｏｖｉｒｕｓ,ＳｐｌｔＮＰＶ）基因组ＥｃｏＲＩ－Ｅ片段中长４７３０ｂｐ的序列分析结果。该序列上含有完整的ＳｐｌｔＮＰＶ ｏｄｖ－ｅ６６基因,一个开入读码框ＯＲＦ １０８６（ＡｃＭＮＰＶＯＲＦ１０９的同源区）和一类似亮氨酸拉链蛋白的基因（命名为ｐ３４基因）。序列比较分析表明,ＳｐｌｔＮＰＶ ｏｄｖ－ｅ６６基因     

中国棉铃虫单粒包埋核多角体病毒（HaSNPV）HindⅢ-Ⅰ片段的序列分析与基因排列研究

对中国棉铃虫单粒包埋核多角体病毒（HaSNPV)基因组中的HindⅢ-Ⅰ片段的序列进行分析,该片段全长7501nt,包括10个开放阅读框：AcMNPV ORF111的同源基因（Ac 111),晚期表达因子2（lef-2）基因,病毒核壳结构蛋白p24基因、gp16基因、多角体包膜蛋白（polyhedron envelope protein,pep)基因、AcMNPV ORF63的同源基因（Ac63),38.7kD基因,晚期表达因子1（lef-1) 基因,及两个特有基因HaSNPV orf591和HasSNPV orf435。基因组的排列比较分析发现与AcMNPV有较大区别。     

蓖麻蚕rDNA基因核骨架结合区在酵母中的自主复制功能

蓖麻蚕核糖体ＲＮＡ基因（ｒＤＮＡ）５′－非转录间隔区有长约１ｋｂ的核骨架结合区ＳＡＲ（ｓｃａｆｏｌｄ－ａｓｓｏｃｉａｔ－ｅｄｒｅｇｉｏｎ）［１］。本文对该ＳＡＲ元件的酵母自主复制功能进一步研究,证明该ＳＡＲ５′端６８８ｂｐ含有１２个ＡＣＳ（ＡＲＳ的核心序列）同源序列,但无ＡＲＳ活性,而其３′端仅３个ＡＣＳ同源序列,但对酵母的转化率比全片段还高４０～５０倍。体外结合实验证明,蓖麻蚕ｒＲＮＡ基因的ＳＡＲ能专一地同酵母核骨架结合,提示ＡＲＳ的功能体现与核骨架结合紧密相关。ｒＲＮＡ基因ＳＡＲ与ＡＲＳ的功能在进化上可能是很保守的。在此基础上可进一步分析ＳＡＲ中与ＤＮＡ复制相关的正调及负调元件。     

丙肝病毒融合抗原基因NS3-C定点整合入衣藻叶绿体基因组的研究

用ＰＣＲ 方法从丙型肝炎病毒（ＨＣＶ） ｃＤＮＡ 文库中克隆了两段ＤＮＡ 片段,即ＨＣＶ 基因组非结构ＮＳ３区抗原基因（约０．７ ｋｂ）和核心抗原Ｃ区抗原基因（约０．６ ｋｂ）的ｃＤＮＡ 片段。在两段ｃＤＮＡ 间加入连接肽Ｓｅｒ－ Ｐｒｏ－ Ｇｌｙ－ Ｓｅｒ 的密码子序列,构建成融合抗原基因ＮＳ３－ Ｃ。将该融合基因与衣藻叶绿体基因ａｔｐＡ 的启动子和ｒｂｃＬ 基因的３′末端连接,得到丙肝病毒融合抗原基因ＮＳ３－ Ｃ表达盒,再将该表达盒与选择标记基因ａａｄＡ 表达盒和衣藻叶绿体基因组同源片段连接,构建成衣藻叶绿体转化载体ｐＳＳ６。基因枪法转化衣藻叶绿体,经壮观霉素筛选获得转化再生的单藻落,对转基因衣藻的ＰＣＲ 和Ｓｏｕｔｈｅｒｎ 杂交分析表明,融合抗原基因ＮＳ３－ Ｃ已整合到衣藻叶绿体基因组中。     

Identification, characterization and phylogenic analysis of conserved genes within the odvp-6e/odv-e56 gene region of Choristoneura fumiferana granulovirus

The genes that are located within the odvp-6e/odv-e56 region of the Choristoneura fumiferana granulovirus (ChfuGV) were identified by sequencing the 11 kb BamHI restriction fragment on the ChfuGV genome. The global GC content that was calculated from the data obtained from this genomic region was 34.96%. The open-reading frames (ORFs), located within the odvp-6e/odv-e56 region, are presented and compared to the equivalent ORFs that are located at the same region in other GVs. This region is composed of 14 ORFs, including three ORFs that are unique to ChfuGV with no obvious homologues in other baculoviruses as well as eleven ORFs with homologues to granuloviral ORFs, such as granulin, CfORF2, pk-1, ie-1, odv-e18, p49, and odvp-6e/odv-e56. In this study, the conceptual products of seven major conserved ORFs (granulin, CfORF2, IE-1, ODV-E18, p49 and ODVP-6E/ODV-E56) were used in order to construct phylogenetic trees. Our results show that granuloviruses can be grouped in 2 distinct groups as follows: Group I; Choristoneura fumiferana granulovirus (ChfuGV), Cydia pomonella granulovirus (CpGV), Phthorimaea operculella granulovirus (PhopGV), and Adoxophyes orana granulovirus (AoGV). Group II; Xestia c-nigrum granulovirus (XcGV), Plutella xylostella granulovirus (PxGV), and Trichoplusia ni granulovirus (TnGV). The ChfuGV conserved proteins are most closely related to those of CpGV, PhopGV, and AoGV. Comparative studies, performed on gene arrangements within this region of genomes, demonstrated that three GVs from group I maintain similar gene arrangements.     

Size and complexity of the nuclear genome of the ectomycorrhizal fungus Paxillus involutus

The basidiomycete Paxillus involutus is forming ectomycorrhizal symbiosis with a broad range of forest trees. Reassociation kinetics on P. involutus nuclear DNA indicated a haploid genome size of 23 Mb including 11% of repetitive DNA. A similar genome size (20 Mb) was estimated by genomic reconstruction analysis using three single copy genes. To assess the gene density in the P. involutus genome, a cosmid containing a 33-kb fragment of genomic DNA was sequenced and used to identify putative open reading frames (ORFs). Twelve potential ORFs were predicted, eight displayed significant sequence similarities to known proteins found in other organisms and notably, several homologues to the Podospora anserina vegetative incompatibility protein (HetE1) were found. By extrapolation, we estimate the total number of genes in the P. involutus haploid genome to approximately 7700.     

Genome Sequence and Analysis of Buzura suppressaria Nucleopolyhedrovirus: A Group II Alphabaculovirus

The genome of Buzura suppressaria nucleopolyhedrovirus (BusuNPV) was sequenced by 454 pyrosequencing technology. The size of the genome is 120,420 bp with 36.8% G+C content. It contains 127 hypothetical open reading frames (ORFs) covering 90.7% of the genome and includes the 37 conserved baculovirus core genes, 84 genes found in other baculoviruses, and 6 unique ORFs. No typical baculoviral homologous repeats (hrs) were present but the genome contained a region of repeated sequences. Gene Parity Plots revealed a 28.8 kb region conserved among the alpha- and beta-baculoviruses. Overall comparisons of BusuNPV to other baculoviruses point to a distinct species in group II Alphabaculovirus.     

粘虫核型多角体病毒一个新基因的序列和结构研究

本文报道ＴｓＮＰＶＤＮＡＥｃｏＲＶ／ＸｈｏＩ的５．５ｋｂ片段的克隆及其物理图谱。测定了其中一个８１９ｂＰ片段的全序列。在长３４６ｂｐ的完整ＯＲＦ的５’端除有ＴＡＴＡｂｏｘ和ＣＡＡＴｂｏｘ以外,还发现有典型的早期基因启动子元件ＡＣＧＴ和ＧＣ单元以及晚期基因的转录起始保守序列ＴＴＡＡＧ。预测的ＯＲＦ产物为１１４个氨基酸、分子量为１３ｋＤ的蛋白质,故命名为ｐ１３蛋白。在ｐ１３基因的Ｃ端和Ｎ端分别有一个亮氨酸拉链和两个类亮氨酸拉链结构（我们称为亮氨酸转型结构和ＬＶＴ重复结构〕．从终止密码起有一个双发卡环结构,ｐ１３基因的５’端调控单元及其排列与ＢｍＮＰＶ和ＡｃＮＰＶ的细胞序死抑制基因（ｐ３５）十分相似,但ｐ１３基因与已经发现的杆状病毒基因序列和氨基酸序列没有同源性．因此,这是一个新的早晚期基因,其调控元件可能具有重要功能。     

Sequential Partially Overlapping Gene Arrangement in the Tricistronic S1 Genome Segments of Avian Reovirus and Nelson Bay Reovirus: Implications for Translation Initiation

Previous studies of the avian reovirus strain S1133 (ARV-S1133) S1 genome segment revealed that the open reading frame (ORF) encoding the final sigmaC viral cell attachment protein initiates over 600 nucleotides distal from the 5' end of the S1 mRNA and is preceded by two predicted small nonoverlapping ORFs. To more clearly define the translational properties of this unusual polycistronic RNA, we pursued a comparative analysis of the S1 genome segment of the related Nelson Bay reovirus (NBV). Sequence analysis indicated that the 3'-proximal ORF present on the NBV S1 genome segment also encodes a final sigmaC homolog, as evidenced by the presence of an extended N-terminal heptad repeat characteristic of the coiled-coil region common to the cell attachment proteins of reoviruses. Most importantly, the NBV S1 genome segment contains two conserved ORFs upstream of the final sigmaC coding region that are extended relative to the predicted ORFs of ARV-S1133 and are arranged in a sequential, partially overlapping fashion. Sequence analysis of the S1 genome segments of two additional strains of ARV indicated a similar overlapping tricistronic gene arrangement as predicted for the NBV S1 genome segment. Expression analysis of the ARV S1 genome segment indicated that all three ORFs are functional in vitro and in virus-infected cells. In addition to the previously described p10 and final sigmaC gene products, the S1 genome segment encodes from the central ORF a 17-kDa basic protein (p17) of no known function. Optimizing the translation start site of the ARV p10 ORF lead to an approximately 15-fold increase in p10 expression with little or no effect on translation of the downstream final sigmaC ORF. These results suggest that translation initiation complexes can bypass over 600 nucleotides and two functional overlapping upstream ORFs in order to access the distal final sigmaC start site.     

Identification and mapping of the gene encoding the glycoprotein complex gp82-gp105 of human herpesvirus 6 and mapping of the neutralizing epitope recognized by monoclonal antibodies.

Monoclonal antibodies (MAbs) 2D4, 2D6, and 13D6 against human herpesvirus 6 (HHV-6) variant A strain GS recognized virion envelope glycoprotein complex gp82-gp105 and neutralized the infectivity of HHV-6 variant A group isolates. A 624-bp genomic fragment (82G) was identified from an HHV-6 strain GS genomic library constructed in the lambda gt11 expression system by immunoscreening with MAb 2D6. Rabbit antibodies against the fusion protein expressed from the genomic insert recognized glycoprotein complex gp82-gp105 from HHV-6-infected cells, thus confirming that the genomic fragment is a portion of the gene(s) that encodes gp82-gp105. This genomic insert hybridized specifically with viral DNAs from HHV-6 variant A strains GS and U1101 under high-stringency conditions but hybridized with HHV-6 variant B strain Z-29 DNA only under low-stringency conditions. DNA sequence analysis of the insert revealed a 167-amino-acid single open reading frame with an open 5' end and a stop codon at the 3' end. Hybridization studies with HHV-6A strain U1102 DNA localized the gp82-gp105-encoding gene to the unique long region near the direct repeat at the right end of the genome. To locate the neutralizing epitope(s) recognized by the MAbs, a series of deletions from the 3' end of the gene were constructed with exonuclease III, and fusion proteins from deletion constructs were tested for reactivity with MAbs in a Western immunoblot assay. Sequencing of deletion constructs at the reactive-nonreactive transition point localized the epitope recognized by the three neutralizing MAbs within or near a repeat amino acid sequence (NIYFNIY) of the putative protein. This repeat sequence region is surrounded on either side by two potential N-glycosylation sites and three cysteine residues.