唐鱼精巢的组织学观察

应用光学显微镜对唐鱼Tanichthys albonubes精巢的组织结构进行了观察.结果表明,唐鱼的精巢属于小叶型结构.性成熟唐鱼的精巢呈乳白色,长条状,左右各一,合并成“Y”型.小叶间质把精巢分成许多精小叶,每个精小叶由数个精小囊组成,精子就在精小囊中形成.同一精小叶内的精小囊不一定同步发育,但同一精小囊中的生精细胞发育是同步的.唐鱼的精子发生和形成过程经历了初级精原细胞、次级精原细胞、初级精母细胞、次级精母细胞、精子细胞和成熟精子6个阶段.精巢内同时存在初级精原细胞和次级精原细胞两种类型的精原细胞.     

卵胎生硬骨鱼褐菖You精巢的周期发育

研究了卵胎生硬骨鱼褐菖Ｙｏｕ（Ｓｅｂａｓｔｉｓｃｕｓ ｍａｒｍｏｒｄｔｕｓ）的精巢结构和生殖周期。褐菖Ｙｏｕ精巢属于小叶型。每年８～９月,精巢处于精原细胞增殖期。初级精原细胞分裂增殖,产生次级精原细胞。后者和支持细胞组成精小囊。１０月～翌年、月进入精子发生期。精小囊中的生殖细胞进一步发育,逐渐形成精子。２～７月是精子退化吸收期,精巢中仅有初级精原细胞和残余的精子。在生殖季节,精子经由输出管和输精管     

卵胎生硬骨鱼褐菖(鱼良)鲉精巢的周期发育

研究了卵胎生硬骨鱼褐菖(鱼良)鲉(Sebastiscus marmoratus)的精巢结构和生殖周期.褐菖(鱼良)鲉精巢属于小叶型.每年8～9月,精巢处于精原细胞增殖期.初级精原细胞分裂增殖,产生次级精原细胞.后者和支持细胞组成精小囊.10月～翌年1月进入精子发生期.精小囊中的生殖细胞进一步发育,逐渐形成精子.2～7月是精子退化吸收期,精巢中仅有初级精原细胞和残余的精子.在生殖季节,精子经由输出管和输精管运至尿殖突,通过体内受精方式送入雌鱼生殖道.     

粗糙沼虾精巢发育的组织学

利用光镜技术,对粗糙沼虾精巢发育进行了研究,根据精子发生过程中每种生殖细胞所占的比例和发生的次序,并结合精巢的形态特征,把精巢发育过程分为五个时期,即精原细胞期,精母细胞期,精细胞期,成熟精子期及退化期,精原细胞期,精巢小,透明乳白色,生精小管内的生殖细胞以精原细胞为主;精母细胞期;精巢体积增大,半透明乳白色,主要由处于初级精母细胞的次级精母细胞阶段的生殖细胞组成;精细胞期,精巢体积继续增大,颜色加深,生精小管内的生殖细胞以精细胞为主;成熟精子期,精巢体积可达最大,紫红色,生精小管内充满着成熟的精子,退化期;精巢体积减小,半透明乳白色,生精小管内的成熟精子几乎排空。     

大黄鱼的精子发生

应用电子显微镜技术观察了大黄鱼（Pseudosciaena crcea）的精子发生过程。其发生经历了初级精原细胞、次级精原细胞、初级精母细胞、次级精母细胞和精子细胞阶段,精子细胞再经过精子形成过程成为精子。在精原细胞阶段,部分核仁物质排出核外,成为拟染色体。拟染色体的主要成分是核糖体。在精子发生中,拟染色体逐渐扩散到生精细胞的胞质中。成熟分裂的前期Ⅰ,同源染色体经历了联会复合体形成和解体的变化。在精子形成过程中,精子细胞先形成鞭毛,随后细胞核逐渐浓缩。     

秦岭北坡中国林蛙精巢显微结构的年周期变化

用光镜观察了秦岭北坡中国林蛙(Ranachensinensis)精巢显微结构的年周期变化,结合精巢系数的变化探讨其生殖规律。结果显示,秦岭北坡中国林蛙的生精周期属于非连续型。精巢系数的变化与精子发生的活动周期相一致。精子发生从每年5月开始,翌年4月结束,历时1年。生精周期可划分为5个时期。Ⅰ期,精原细胞增殖期,5～7月,精巢系数最小,精原细胞进行有丝分裂;Ⅱ期,精母细胞成熟分裂期,8～9月,精巢系数最大,精原细胞、精母细胞和精子细胞在生精小管内共存;Ⅲ期,精子形成期,9～1 0月,精子细胞变态形成精子;Ⅳ期,成熟精子贮存越冬期,1 1月至翌年2月,成熟精子贮存在生精小管中;V期,精子排放期,翌年3～5月,精巢系数显著下降,成熟精子从生精小管脱离,通过输精管道排出体外。     

山羊精子发生不同阶段的显微与超微结构观察

应用光镜和透射电镜技术研究山羊精子发生不同阶段各级生精细胞显微、超微结构及山羊精子分化成熟过程。结果表明：山羊精子发生经历了精原细胞、初级精母细胞、次级精母细胞、精子细胞及变态精子阶段发育成成熟的精子。精原细胞期核呈椭圆形,染色质凝集成团分布于核质中,线粒体开始出现;精母细胞期有高尔基体分布;精子细胞经过核质浓缩、线粒体迁移等过程发育成成熟精子,成熟的山羊精子头部细长,核质高度浓缩,中段膨大,线粒体丰富。线粒体、中心粒对精子变态发生起重要作用,同时观察到头部与中段脱落的畸形精子。     

短额负蝗精子发生过程中SBA受体的动态分布

用常规组织学方法观察短额负蝗Atractomorpha sinensis Bolivar精子发生过程中生精细胞的显微结构,并以大豆凝集素(soybean agglutinin,SBA)为探针利用凝集素细胞化学方法研究该过程中N-乙酰半乳糖复合物的分布变化。结果表明,短额负蝗精子发生经历了精原细胞增殖期、初级精母细胞期、次级精母细胞期、精子细胞形成期和精子成熟期5个时期,在这5个时期中各期生精细胞的大小、形态、核染色体等变化明显。在整个精子发生过程中,N-乙酰半乳糖复合物出现于精原细胞期,并于精母细胞期发生明显的修饰和变化,精子形成期和成熟期没有N-乙酰半乳糖复合物的表达。提示,N-乙酰半乳糖复合物的修饰和变化与短额负蝗生精细胞的生长和分化密切相关。     

异源四倍体银鲫外周血和精巢的组织学特征

通过比较D系三倍体银鲫(Carassius auratus gibelio Bloch)与异源四倍体银鲫,我们发现异源四倍体的外周血与精巢组织跟三倍体银鲫存在明显差异。HE染色结果表明,异源四倍体银鲫外周血红细胞有明显的分裂倾向。利用流式细胞术对D系三倍体银鲫与异源四倍体银鲫外周血的DNA直方图进行比较,结果表明异源四倍体外周血的DNA直方图有两个主峰。此外,我们观察到异源四倍体银鲫精巢的三种类型,其中Ⅰ型精巢可以产生正常精子,Ⅱ型可观察到精小囊结构,但不能产生精子,Ⅲ型精巢未发育出精小囊结构。进一步用银鲫Vasa抗体对精巢切片进行组织免疫荧光共聚焦显微分析,结果表明,Ⅰ型精巢的生殖细胞完成了减数分裂,能观察到精原细胞、初级精母细胞、次级精母细胞,以及大量位于精小管中间的精子细胞和精子;而Ⅱ型精巢的生殖细胞不能完成第二次减数分裂,精小囊中存在大量的初级和次级精母细胞,没有精子细胞产生。研究丰富了对异源四倍体银鲫生物学性状的认识。     

半滑舌鳎精子发生和精子形成的超微结构

用电子显微镜对半滑舌鳎(Cynoglossus semilaevis)精子发生的过程及精子的超微结构进行了观察。半滑舌鳎精巢属于小叶型,精小叶由各期生精细胞和支持细胞构成。半滑舌鳎的精子发生经历了初级精原细胞、次级精原细胞、初级精母细胞、次级精母细胞和精子细胞,再经过精子形成过程发育成为精子。初级精母细胞成熟分裂的前期Ⅰ,同源染色体经历了联会复合体形成和解聚的变化。在精子形成的过程中,精细胞大致经历了核质浓缩、线粒体迁移及鞭毛的发生等过程。核质浓缩时,精细胞核内位于植入窝周围的染色质首先由细颗粒状浓缩成粗大颗粒状,然后细胞核其他部位的染色质也逐渐浓缩成粗大颗粒状。这些已浓缩成粗大颗粒状的染色质再进一步浓缩为电子密度高的均匀状物质。随着核质的浓缩,核外膜与核内膜之间的间隙增大形成核膜间隙,核内一些没有参与染色质浓缩的物质通过出芽形成囊泡,先排入核膜间隙,然后再外排到细胞质中。核浓缩过程中细胞核的体积和表面积都大大缩小;鞭毛的形成与细胞核的浓缩是同步进行的,当一对中心粒移近细胞核时,核膜凹陷形成植入窝,其周围染色质浓缩的同时,远端中心粒(基体)逐渐向后产生轴丝。成熟精子无顶体,头细长,主要为核占据,核凹窝发达,线粒体4-5个环绕在鞭毛基部形成袖套,尾细长,具侧鳍,尾部轴丝为"9 2"结构。     

Entwicklungsgeschichte und Ultrastruktur von Pollenkitt und Exine bei nahe verwandten entomophilen und anemophilen Angiospermensippen derAlismataceae,Liliaceae, Juncaceae,Cyperaceae, Poaceae undAraceae

Some closely related members of the monocotyledonous familiesAlismataceae, Liliaceae, Juncaceae, Cyperaceae, Poaceae andAraceae with variable modes of pollination (insect- and wind-pollination) were studied in relation to the ultrastructure of pollenkitt and exine (amount, consistency and distribution of pollenkitt on the surface of pollen grains). The character syndromes of pollen cementing in entomophilous, anemophilous and intermediate (ambophilous or amphiphilous) monocotyledons are the same in principal as in dicotyledons. Comparing present with former results one can summarize: 1) The pollenkitt is always produced in the same manner by the anther tapetum in all angiosperm sub-classes. 2) The variable stickiness of entomophilous and anemophilous pollen always depends on the particular distribution and consistency of the pollenkitt, but not its amount on the pollen surface. 3) The mostly dry and powdery pollen of anemophilous plants always contains a variable amount of inactive pollenkitt in its exine cavities. 4) A step-by step change of the pollen cementing syndrome can be observed from entomophily towards anemophily. 5) From the omnipresence of pollenkitt in all wind-pollinated angiosperms studied one can conclude that the ancestors of anemophilous angiosperms probably have been zoophilous (i.e. entomophilous) throughout.

     

Identification and Characterization of the First Equine Parainfluenza Virus 5

正Dear Editor,Parainfluenza virus 5 (PIV5), known as canine parainfluenza virus in the veterinary field, is a negative-sense,nonsegmented, single-stranded RNA virus belonging to the Paramyxoviridae family (Chen 2018). The virus was first reported in primary monkey kidney cells in 1954 (Hsiung1972), then it has been frequently discovered in various     

Pathogenic Characterization and Full Length Genome Sequence of a Reassortant Infectious Bursal Disease Virus Newly Isolated in Pakistan

<正>Dear Editor,Infectious bursal disease (IBD) is one of the most important diseases of the poultry. The IBD virus (IBDV), a nonenveloped virus belonging to the Birnaviridae family with a genome consisting of two segments of double-stranded RNA (segments A and B), targets B lymphocytes of bursa of Fabricious leading to immunosuppression. In Pakistan,poultry farming is the second biggest industry and IBD is the second biggest disease threating the poultry sector.However, there is limited genome information of IBDV     

Mink Circovirus Can Infect Minks,Foxes and Raccoon Dogs

正Dear Editor,Mink circovirus (MiCV), which is clustered in the genus Circovirus of the family Circoviridae, was first described in minks from farms in Dalian, China in 2013 (Lian et al.2014). The complete single-stranded circular genome of the virus is 1,753 nucleotides long and contains two major open reading frames (ORFs), designated ORF1 (Rep gene)and ORF2 (Cap gene)(Lian et al. 2014; Ge et al. 2018).Sequence analysis has shown that MiCV is most closely     

CypA Regulates AIP4-Mediated M1 Ubiquitination of Influenza A Virus

Cyclophilin A (CypA) is a peptidyl-prolyl cis/trans isomerase that interacts with the matrix protein (M1) of influenza A virus (IAV) and restricts virus replication by regulating the ubiquitin–proteasome-mediated degradation of M1. However,the mechanism by which CypA regulates M1 ubiquitination remains unknown. In this study, we reported that E3 ubiquitin ligase AIP4 promoted K48-linked ubiquitination of M1 at K102 and K104, and accelerated ubiquitin–proteasome-mediated degradation of M1. The recombinant IAV with mutant M1 (K102 R/K104 R) could not be rescued, suggesting that the ubiquitination of M1 at K102/K104 was essential for IAV replication. Furthermore, CypA inhibited AIP4-mediated M1 ubiquitination by impairing the interaction between AIP4 and M1. More importantly, both the mutations of M1 (K102 R/K104 R) and CypA inhibited the nuclear export of M1, indicating that CypA regulates the cellular localization of M1 via inhibition of AIP4-mediated M1 ubiquitination at K102 and K104, which results in the reduced replication of IAV.Collectively, our findings reveal a novel ubiquitination-based mechanism by which CypA regulates the replication of IAV.