银杏LEAFY同源基因的时空表达

以银杏雄株、雌株成年树和还未开过花的幼树的根、茎、叶,雌株幼果和不同时期的雄花芽、雌花芽为材料,利用同位素标记,制备Ginlfy和GinNdly两个特异探针,进行Northern分子杂交,研究银杏LFY同源基因Ginlfy、GinNdly在银杏不同器官,花芽不同生长发育时期的时空表达情况。结果显示,无论是幼树,还是成年的雌株、雄株,Ginlfy基因在各个器官,如根、茎、叶、雌花芽、雄花芽、幼果以及雌花芽、雄花芽的不同发育时期都有表达,属组成型表达,而GinNdly基因只在叶和不同时期的雄花芽、雌花芽中表达,其他器官都不表达,属特异性表达。银杏双拷贝LFY同源基因中的GinNdly基因可能与开花关系更为密切。 Abstract: Expressions of Ginlfy and GinNdly gene were studied by northern blotting in different organs and stages of Ginkgo Biloba. Ginlfy gene was expressed in different organs such as root, stem, leaf of juvenile tree, male tree and female tree, and in different stages of male flower bud and female flower bud. It was inferred that Ginlfy gene could be expressed constitutionally. GinNdly gene was only expressed in leaf of juvenile tree, male tree and female tree and in different stages of male flower bud and female flower bud, while GinNdly gene was not expressed in the other organs. Therefore it was thought that GinNdly gene could be expressed differentially and be a close relation to development of flower.     

福建省输入性D8基因型麻疹病毒分子流行病学特征

为分析福建省输入性D8基因型麻疹病毒分子流行病学特征,采集咽拭子标本采用实时荧光定量反转录-聚合酶链反应(Real-time RT-PCR)筛查麻疹病毒核酸.用反转录-聚合酶链反应(RT-PCR)扩增麻疹病毒核酸筛查阳性咽拭子及Vero/Slam细胞培养阳性产物,对麻疹病毒核蛋白(Nucleoprotein,N)羧基(COOH)端634个核苷酸(Nucleotides,nt)片段进行测序分析,构建系统进化树.最终分离获得1株麻疹病毒株,26条麻疹病毒N蛋白羧基末端450个nt序列.亲缘性分析发现,所有福建麻疹毒株与WHOD8基因型参考株(MVi/Manchester.GBR/30.94)在亲缘关系树上同属一个大分支,两者核苷酸序列和氨基酸(Amino acid,aa)序列同源性分别为96.4％～99.1％和96.7％～98.0％.其中2014年的福建毒株 MVs/Fujian.CHN/28.14和 MVs/Fujian.CHN/30.14与越南胡志明市2014年分离株MVs/HoChiMinh.VNM/11.14及美国纽约2013年分离株MVs/New.York.USA/19.13的nt同源性为 100％;2019年的毒株MVs/Fujian.CHN/25.19与泰国龙仔厝府2018年分离株MVs/Samut.Sakhon.THA/8.18的nt同源性为100％;而剩余的23个监测毒株则与日本神户2019年分离株MVs/KobeC.JPN/28.19的核苷酸同源性和氨基酸同源性最高,分别为99.6％～100.0％和99.3％～100.0％.在病毒N蛋白羧基端150个氨基酸位点上,福建株与WHO D8参考株存在3～5个氨基酸位点差异.而与现用的疫苗株(Shanghai-191)相比,存在17～19个氨基酸变异位点,其中有14个氨基酸位点为所有福建株共有的变异位点,这些位点的变异总体上未对编码蛋白的氨基酸造成明显改变.结论是福建省成功分离获得1株D8基因型麻疹毒株.D8基因型为福建省发现的输入性麻疹基因型,病毒N蛋白羧基端氨基酸位点上与疫苗株相比均出现了差异位点.     

北京等四地区呼吸道合胞病毒分离株G蛋白基因的比较分析

为了解我国不同地区呼吸道合胞病毒（ＲＳＶ）感染特征是否与基因变异有关,对北京、广州、长春和河北四个地区不同流行特征中分离的ＲＳＶ毒株的Ｇ蛋白基因进行了序列分析。结果表明,该Ｇ蛋白基因同国外Ａ型亚原型株（Ａ２株）间存在显著差异,Ａ２株同分离株间的核苷酸同源性为９２．７－９３．６％,氨基酸同源性只有８８．３－８９．９％。分离株间的核苷酸同湃性为９６．０－９８．９％,氨基酸同源性９２．６－９７．７％。氨     

家蚕核型胸角体病毒酪氨酸蛋白磷酸酯酶基因的克隆及在大肠杆菌中表达

采用PCR方法克隆了家蚕核型多角体病毒中国镇江株（BmNPV-JZstrain）的酪氨酸蛋白磷酸酯酶基因（ptp),测定了该基因的核苷酸序列。比较了与相关病毒相应基因的同源性,并将该基因插入到原核表达质粒在大肠杆菌中进行了表达。该基因的编码部分由507个核苷酸组成,编码168个氨基酸残基的蛋白多肽,其中含有酪氨酸蛋白磷酸酶酯催化部位的“HC”基序。该基因与苜蓿银纹夜蛾核型多角体病毒（AcMNPV)ptp基因和BmNPV-T3株（日本）拟为ptp基因核苷酸序列的同源性分别为96．8％和98．2％,蛋白质氨基酸序列的同源性分别为97．0％和97．6％。将该基因插入到温度诱导型表达质粒pBV221的温控启动子PRPL之后,在大肠杆菌JM109中表达了具有催化活性的蛋白质,分子量约为19KD,表达产物能催化对硝基酚磷酸钠（PNPP）的脱磷酸反应,这种催化作用可被钒酸钠和ZnCl2抑制。     

蜱传脑炎病毒东北株E蛋白的核酸和氨基酸序列

从我国东北林区死者脑组织中,分离到蜱传脑炎病毒ＨＬＪ－１株,测定了它的Ｅ蛋白基因序列和推导的氨基酸序列,以及Ｅ蛋白抗原位点反应图谱。将该株与远东亚型Ｓｏｆｙｎ株和中欧亚型Ｎｅｕｄｅｒｆｌ株做了同源性比较,ＨＬＪ－１株与Ｓｏｆｙｎ株Ｅ蛋白基因的核苷酸及氨基酸的同源性分别为９４．３％和９８．８％;与Ｎｅｕｄｏｅｒｆｌ的核苷酸和氨基酸的同源性分别为８３．７％和９６％。在Ｅ蛋白的核苷酸序列中,ＨＬＪ－１和     

猪戊型肝炎病毒swCH-GS189株ORF2基因的克隆及序列分析

为进行猪戊型肝炎病毒(HEV)ORF2基因特征研究,参照GenBank中已发表的戊型肝炎病毒(HEV)核酸序列,设计了一对扩增HEV ORF2基因的引物,利用RT-PCR等方法克隆出了一株猪戊型肝炎病毒甘肃分离株GS189的ORF2基因cDNA片段.序列测定结果表明,swCH-GS189株的ORF2基因长2 025 bp,编码674个氨基酸,与GenBank中公布的其它毒株间的核苷酸序列同源性为79.1%～91.8%,推导的氨基酸序列同源性为89.5%～98.8%.系统发育进化树结果表明,该分离株为基因IV型.     

狂犬病病毒aG株全基因组序列测定及遗传稳定性分析

目的探究狂犬病病毒(Rabies virus,RV)aG株全基因组序列特征及遗传稳定性。方法严格按疫苗生产工艺进行传代,提取主种子批、工作种子批及疫苗原液病毒RNA,通过RT-PCR技术扩增全基因组各片段基因,然后分别将其克隆到p GEM-T载体中,并进行序列测定;采用DNAStar软件包对aG株与Gen Bank中4aGV参考株(JN234411)以及18株基因1型RV参考株进行同源性分析。结果 aG株全基因组由11 925个核苷酸组成,共编码3 600个氨基酸。疫苗原液与主种子批全基因组核苷酸和氨基酸同源性均为100%,而工作种子批与主种子批的核苷酸与氨基酸同源性分别为99.97%和99.92%;aG株与4aGV参考株全基因组核苷酸与推导的氨基酸同源性均为99.9%,其与18株基因1型参考株核苷酸与氨基酸序列同源性分别为84.2%~97.6%和93.7%~98.3%;aG株传代病毒与4aGV参考株全基因组氨基酸序列高度保守,且各主要功能区未发生变异。结论狂犬病病毒aG株在实验室长期生产传代过程中,全基因组遗传特性稳定。     

中国柯萨奇病毒A组16型部分VP1区序列测定及系统进化分析

利用1999～2004年连续6年从中国深圳及北京地区分离的柯萨奇病毒A组16型(Coxsackievirus A16,Cox．A16)毒株的部分VP1区基因序列进行分析和研究,试图找出中国Cox．A16的种系进化规律和分型依据。6株Cox．A16病毒部分VP1区核苷酸和氨基酸同源性均较高,相互间核苷酸同源性为94．5％～98．0％,氨基酸同源性为97．8％～100％。6株中国分离株与Cox．A16国际参考株相比,部分VP1区核苷酸同源性高于78．2％,氨基酸同源性高于为93．3％。基因系统进化分析表明,中国大陆分离的6株Cox．A16与中国台湾流行株Tainan-5079-98(AF177911),与4株日本分离株、瑞典株及美国株GA95—2095(AF081613)、PA94—5753(AF081628)的关系均较近,核苷酸同源性大于93．3％。了解我国Cox．A16流行株的遗传学背景和种系进化关系,对有效地预防和控制Cox．A16流行有重要意义。     

Cloning and characterization of a FLORICAULA/LEAFY ortholog, PFL, in polygamous papaya

The homologous genes FLORICAULA （FLO） in Antirrhinum and LEAFY （LFY） in Arabidopsis are known to regulate the initiation of flowering in these two distantly related plant species. These genes are necessary also for the expression of downstream genes that control floral organ identity. We used Arabidopsis LFY cDNA as a probe to clone and sequence a papaya ortholog of LFY, PFL. It encodes a protein that shares 61% identity with the Arabidopsis LFY gene and 71% identity with the LFY homologs of the two woody tree species： California sycamore （Platanus racemosa） and black cottonwood （Populus trichocarpa）. Despite the high sequence similarity within two conserved regions, the N-terminal proline-rich motif in papaya PFL differs from other members in the family. This difference may not affect the gene function of papaya PFL, since an equally divergent but a functional LFY ortholog NEEDLY of Pinus radiata has been reported. Genomic and BAC Southern analyses indicated that there is only one copy of PFL in the papaya genome. In situ hybridization experiments demonstrated that PFL is expressed at a relatively low level in leaf primordia, but it is expressed at a high level in the floral meristem. Quantitative PCR analyses revealed that PFL was expressed in flower buds of all three sex types - male, female, and hermaphrodite with marginal difference between hermaphrodite and unisexual flowers. These data suggest that PFL may play a similar role as LFY in flower development and has limited effect on sex differentiation in papaya.     

Regulatory networks that function to specify flower meristems require the function of homeobox genes PENNYWISE and POUND-FOOLISH in Arabidopsis

Flowering is a major developmental phase change that transforms the fate of the shoot apical meristem (SAM) from a leaf-bearing vegetative meristem to that of a flower-producing inflorescence meristem. In Arabidopsis, floral meristems are specified on the periphery of the inflorescence meristem by the combined activities of the FLOWERING LOCUS T (FT)–FD complex and the flower meristem identity gene, LEAFY ( LFY ). Two redundant functioning homeobox genes, PENNYWISE ( PNY ) and POUND-FOOLISH ( PNF ), which are expressed in the vegetative and inflorescence SAM, regulate patterning events during reproductive development, including floral specification. To determine the role of PNY and PNF in the floral specification network, we characterized the genetic relationship of these homeobox genes with LFY and FT . Results from this study demonstrate that LFY functions downstream of PNY and PNF. Ectopic expression of LFY promotes flower formation in pny pnf plants, while the flower specification activity of ectopic FT is severely attenuated. Genetic analysis shows that when mutations in pny and pnf genes are combined with lfy , a synergistic phenotype is displayed that significantly reduces floral specification and alters inflorescence patterning events. In conclusion, results from this study support a model in which PNY and PNF promote LFY expression during reproductive development. At the same time, the flower formation activity of FT is dependent upon the function of PNY and PNF.     

An exploration of LEAFY expression in independent evolutionary origins of rosette flowering in Brassicaceae

Whereas most Brassicaceae produce flowers on an elongated inflorescence, a few lineages produce flowers directly from the vegetative rosette on elongated pedicels. Knowing the extent to which independent origins of rosette flowering involve the same developmental and genetic mechanisms could clarify the constraints acting on plant architectural evolution. Prior work in Idahoa, Ionopsidium, and Leavenworthia suggested that changes in the activity or expression of the flower meristem identity gene, LEAFY (LFY), played a role in all three origins of rosette flowering. Here we studied the developmental morphology of L. crassa and immunolocalization of LFY protein in Leavenworthia and Ionopsidium to further compare independent origins of rosette flowering. Leavenworthia crassa differs from Ionopsidium and Idahoa in producing ebracteate flowers. Flowers are, however, associated with "squamules," here interpreted as stipules of a cryptic bract. LFY was detected in L. crassa flower primordia but not in inflorescence meristems. In contrast, the rosette flowering Io. acaule accumulated LFY protein in the inflorescence meristem, whereas its inflorescence-flowering close relative, Io. prolongoi, did not. Thus, although different cases of rosette flowering likely entailed modifications of the same meristem identity program, distinct developmental genetic mechanisms appear to be involved in each case.     

Structural basis for LEAFY floral switch function and similarity with helix-turn-helix proteins

The LEAFY (LFY) protein is a key regulator of flower development in angiosperms. Its gradually increased expression governs the sharp floral transition, and LFY subsequently controls the patterning of flower meristems by inducing the expression of floral homeotic genes. Despite a wealth of genetic data, how LFY functions at the molecular level is poorly understood. Here, we report crystal structures for the DNA-binding domain of Arabidopsis thaliana LFY bound to two target promoter elements. LFY adopts a novel seven-helix fold that binds DNA as a cooperative dimer, forming base-specific contacts in both the major and minor grooves. Cooperativity is mediated by two basic residues and plausibly accounts for LFY's effectiveness in triggering sharp developmental transitions. Our structure reveals an unexpected similarity between LFY and helix-turn-helix proteins, including homeodomain proteins known to regulate morphogenesis in higher eukaryotes. The appearance of flowering plants has been linked to the molecular evolution of LFY. Our study provides a unique framework to elucidate the molecular mechanisms underlying floral development and the evolutionary history of flowering plants.     

LATE MERISTEM IDENTITY2 acts together with LEAFY to activate APETALA1

The switch from producing vegetative structures (branches and leaves) to producing reproductive structures (flowers) is a crucial developmental transition that significantly affects the reproductive success of flowering plants. In Arabidopsis, this transition is in large part controlled by the meristem identity regulator LEAFY (LFY). The molecular mechanisms by which LFY orchestrates a precise and robust switch to flower formation is not well understood. Here, we show that the direct LFY target LATE MERISTEM IDENTITY2 (LMI2) has a role in the meristem identity transition. Like LFY, LMI2 activates AP1 directly; moreover, LMI2 and LFY interact physically. LFY, LMI2 and AP1 are connected in a feed-forward and positive feedback loop network. We propose that these intricate regulatory interactions not only direct the precision of this crucial developmental transition in rapidly changing environmental conditions, but also contribute to its robustness and irreversibility.     

The rubber tree (Hevea brasiliensis Muell. Arg.) homologue of the LEAFY/FLORICAULA gene is preferentially expressed in both male and female floral meristems

The rubber tree (Hevea brasiliensis Muell. Arg.) is an important source of natural rubber in tropical regions and, as with many woody species, shows a long juvenile phase. To understand the genetic and molecular mechanisms underlying the reproductive process in rubber trees, H. brasiliensis RRIM600 flower and inflorescence development have been characterized, the rubber tree FLORICAULA/LEAFY (FLO/LFY) orthologue, HbLFY, cloned, and its expression patterns were analysed during vegetative and reproductive development. The rubber tree, similar to other Euphorbiaceae species, produces lateral inflorescences containing male, female, and bisexual flowers. HbLFY is expressed in lateral meristems that give rise to inflorescences and in all flower meristems, consistent with a role in reproductive development. Complementation studies using Arabidopsis lfy mutants indicated that the biological function of LFY might be conserved among Brassicaceae and Euphorbiaceae species.