格氏线虫三个品系染色体组型的研究

本文以精巢、卵巢和幼胚为材料,丙酸地衣红染色,用压片法制片,对格氏线虫NC513、85011和KG的染色体组型进行了研究。结果表明,它们的染色体数目均为雌性2N=10,雄性2N=9。其染色体组型均为:2N=4m+6t(♀),2N=4m+5t((?))。由此可见,它们都是属于格氏线虫的三个不同品系。     

蜘蛛染色体单一胚胎压片观察

利用单一胚胎压片法制备蜘蛛染色体取得了很好的结果。此法可以迅速确定蜘蛛染色体的性比,同时对于精巢特别小的蜘蛛染色体制备特别有用。所研究的蜘蛛染色体数目为:纵条蝇狮(Marpissa magister)2n=28()和26(),角园蛛(Araneus cornalus)2n=26()和24();2n=26和25();2n=24和33(),显示染色体多态型。     

蛾螺科三种螺的核型观察

本文介绍了蛾螺科三种螺的核型。水泡蛾螺(Buccinum pcmphigum)为2n=30,染色体的形态分类组成为16m+10sm+4st,NF=56;Plicifusus scissuratus为2n=34,染色体的形态分类组成为20m+10sm+4st,NF=64;香螺(Neptumea cumingi)为2n=60,染色体的形态分类组成为30m+22sm+8st,NF=112。 蛾螺科核型分析,显示贝类染色体数目及其形态与贝类进化有关。     

黄鳝体内寄生胃瘤线虫的染色体核型及G-带分析

采用常规空气干燥法制片,对寄生于黄鳝(Monopterus albus)体腔内的胃瘤线虫(Eustrongylidesignotus)染色体核型进行分析。结果表明:胃瘤线虫体细胞有12条染色体,为二倍体,核型公式为2n=12=10 m+2 sm。由5对常染色体和1对性染色体组成,性别决定模式为XX-XY,其中X、Y和1～4号染色体都为中着丝粒染色体,5号为亚中着丝粒染色体。每对染色体都有特定的G-带带型。     

黄精属细胞分类学研究——Ⅱ.四川金佛山地区黄精属植物核型

本文对四川金佛山地区4种黄精属植物的核型进行了研究,其结果为:滇黄精:2n=26=6m+12sm(2SAT)+8st(2SAT);距药黄精:2n=26=10m+4sm+12st;垂叶黄精:2n=30=14m(2SAT)+4sm+10st+2t、2n=28=14m+6sm+6st+2t;湖北黄精:2n=30=12m+8sm+10st、2n=28=6m+10sm+10st+2t、2n=22=2m+12sm 8st。通过与其它地区黄精属植物染色体数目与形态的比较,发现本地区所有种类的染色体数目普遍偏高,无论在染色体基数或染色体形态上都比较接近喜马拉雅山地区分布的种类。从实验结果进一步看出了黄精属的染色体变异是相当明显的,并主要表现为非整倍性变异;在有些情况下,染色体数目与结构的变异能与某些形态学特征相联系。     

百合科六属十五种植物的细胞学研究

本文对云南西北部百合科6属15种的染色体和核型进行了报道。 (1)Clintonia udensis Trautv．et Mey间期核属于浓密分散型,前期染色体属于渐变型,分裂中期体细胞染色体2n=14=8m+4sm+2st(2SAT),核型不对称性属于2A型;(2)鹿药属四个种间期核属于复杂中央微粒型,前期染色体属于中间型,分裂中期体细胞染色体分别为Smilacina henryi(Baker)Wang et Tang,2n=36=12m+16sm+6st+2t(2SAT), 核型不对称性属于2C型;Smilacina fusca Wall., 2n=36=14m(2SAT)+12sm+10st(2SAT), 核型不对称性属于2B型; Smilacina tatsienensis(Franch．)Wang et Tang, 2n=36=22m+2sm+2st(2SAT), 核型不对称性属于2C型;Smilacina atropurpurea(Franch．)Wang et Tang,2n=36=18m+6sm(2SAT)+12st,核型不对称性属于2C型;(3)黄精属四个种的间期核属于复杂中央微粒型,前期染色体属于中间型,分裂中期体细胞染色体分别为Polygonatum kingianum Coll．et Hesml．,2n=30=12m(2SAT) +6sm+lst+2t, 核型不对称性属于2C型; Polygonatum cirrhifolium(Wall．) Royal,2n=30=10m+4sm+12st+4t, 3C型; Polygonatum curvistylum Hua, 2n=78=24m(2SAT)+14sm(6SAT)+40st, 核型不对称性属于3C 型; Polygonatum cathcartii Baker,2n=32=12m+6sm+10st+2t+2bs,核型不对称性属于2C型;(4)百合属,假百合属,豹子花属三个属的间期核和前期染色体形态相似,都属于复杂中央微粒型,前期染色体属于中间型,分裂中期体 细胞染色体分别为Lilium henricii Franch,2n=24=2m(2SAT)+2sm+10st+10t,核型不对称性属于3A型;Lilium bakerianum Coll．et Hesml．var． rubrum Stearn, 2n=24=4m (2SAT)+10st+10t(2SAT),核型不对称性属于3A型;Nomocharis bilouensis Liang 2n=24=2m(2SAT)+2sm+12st+8t,核型不对称性属于3A型;Nomocharis pardanthina Franch．,2n=24=4m(2SAT)+12st (2SAT)+8t,核型不对称性属于3A型;Nomocharis sauluensis Balf, f.,2n=24=4m(2SAT)+10st(2SAT)+10t,核型不对称性属于3B型;Notholirion campanulatum Cotton et Stearn2n=24=2m(2SAT)+2sm+14st(2SAT)+6t,核型不对称性属于3A型。     

黄精属细胞分类学研究Ⅱ.四川金佛山地区黄精属植物核型

本文对四川金佛山地区4种黄精属植物的核型进行了研究,其结果为:滇黄精:2n=26=6m+12sm(2SAT)+8st(2SAT);距药黄精:2n=26=10m+4sm+12st;垂叶黄精:2n=30=14m(2SAT)+4sm+10st+2t、2n=28=14m+6sm+6st+2t;湖北黄精:2n=30=12m+8sm+10st、2n=28=6m+10sm+10st+2t、2n=22=2m+12sm 8st。通过与其它地区黄精属植物染色体数目与形态的比较,发现本地区所有种类的染色体数目普遍偏高,无论在染色体基数或染色体形态上都比较接近喜马拉雅山地区分布的种类。从实验结果进一步看出了黄精属的染色体变异是相当明显的,并主要表现为非整倍性变异;在有些情况下,染色体数目与结构的变异能与某些形态学特征相联系。     

国产毛茛属三种植物的核型研究

对国产三种毛茛属 (Ranunclus)植物进行了核型研究 ,其中昆明毛茛 (RanunculuskunmingensisW .T .Wang)染色体数目 2n=1 4及核型 2n =1 4 =6m +4sm +4st为首次报道 ;匍枝毛茛 (R .repenceL .)核型公式为 2n =4x =3 2 =8m +1 2sm +1 0st+2t,它是由两个不同的染色体组组成 ;刺果毛茛 (R .muricatusL .)核型公式为 2n=8x=64=1 0m +2 2sm +2 8st+4t,它也是由两个不同的染色体组组成     

几种重楼的染色体核型研究

作者对重楼属(Paris)的几个种:球药隔重楼(P.fargesii),毛重楼(P.mairei),花叶重搂(P.marmorata),黑籽重楼(P.thibetica),海南重楼(P.dunniana),巴山重搂(P.bashanensis),以及多叶重楼(P.polyphylla)的两个变种狭叶重楼(var.stenophylla)和华重楼(var.chinensis)的染色体核型进行了研究,发现种间及种内不同居群(population)间的核型都存在不同程度的差别。核型简式为:球药隔重楼K(2n)=2x=10=6m+2t(SAT)+2t+3bs,毛重楼K(2n)=2x=10=6m+4t+1bs,花叶重楼K(2n)=2x=10=6m+4t,黑籽重楼K(2n)=2x=10=2m+4m(SAT)+4t,海南重楼K(2n)=2X=10=6m+2t(SAT)+2t,巴山重楼K(2n)=2x=10=6m+4st,狭叶重楼K(2n)=2x=10=6m+1st+3t,华重楼K(2n)=2x=10=6m+4t。     

珍珠菜属三种植物的核型研究

对国产三种珍珠菜属 (Lysimachia)植物进行了核型研究 ,其中点腺过路黄 (LysimachiahemsleyanaMaxim .)染色体核型 2n =2 2 =2m +4sm +8st+8t,聚花过路黄 (L .congestifloraHesmsl.)核型 2n =2 4=2m +2sm +1 0st+1 0t及山萝过路黄 (L .melampyroidesR .Knuth)染色体数目 2n =2 2 ,核型 2n =2 2 =4m +6sm +4st+8t,为首次报道。本文还分析了黄连花亚属 (subgen.Lysimachia) 2组 8种植物的核型 ,结果表明黄连花组(sect.Lysimachia)核型类型 1A ,过路黄组 (sect.Nummularia)核型类型 3A或 3B。     

新线虫与粘虫相互关系的研究

本文给出了一个简单的描述新线虫(Neoaplectana feltiae)和粘虫(Mythimna separata)相互关系的模型.在实验室的不同条件下作了一系列的感染试验.结果表明影响感染率的因子是温度、线虫的密度、接触时间(即维持湿度和水膜的时间)和粘虫的龄期.通过非线性逐步回归和麦夸脱方法分别构造了描述这些因子的数学模型.在河南驻马店作了不同剂量的田间感染试验.结果表明该线虫作为一种生物防治剂具有一定的潜在作用.本文所获得的模型是用实验室的资料构造的,用田间试验结果检验,较成功地模拟了发生在田间自然条件下的感染过程.它告诉我们怎样由实验室到田间通过模拟模型在计算机上的运转来模拟一个动态过程,也揭示了在实验室和田间其感染的机制是内在相关的.     

Effect of neoaplectanid and heterorhabitid nematodes (Nematoda: Rhabditoidea) on the millipede Oxidus gracilis

At high dosages, infective-stage juveniles of Neoaplectana carpocapsae and Heterorhabditis heliothidis were able to penetrate into and kill the garden millipede. Nematode development was inhibited by host defense reactions which consisted of encapsulation and enmeshment in tracheoles and connective tissue surrounding the millipede's midgut. Foreign bacteria quickly entered the millipede's hemocoel at death and out-competed the nematode's symbiotic bacteria, Xenorhabdus sp. The dauer stages of an unidentified rhabditid nematode were associated with the living millipede. These nematodes reproduced on the millipede's cadaver.     

Laboratory infection of terrestrial isopods (Crustacea: Isopoda) with neoaplectanid and heterorhabditid nematodes (Rhabditida: Nematoda)

Under laboratory conditions, the nematodes Neoaplectana carpocapsae and Heterorhabditis heliothidis were able to infect and develop inside the hemocoel of terrestrial isopods belonging to the genus Porcellio. Armidillidium vulgare was also infected by N. carpocapsae, but this host was less susceptible than Porcellio. Results show that, under suitable ecological conditions, it would be feasible to utilize N. carpocapsae as a biological control agent of sowbugs (Porcellio spp.). This is the first report showing the ability of neoaplectanids and heterorhabditids to invade representatives of the Crustacea.     

The effect of sand particle size on Steinernema feltiae sensu Filipjev (1934) (=N. bibionis Bovien) activity against Galleria mellonella larvae

Activity of an isolate of Steinernema feltiae in different fractions of sand was measured by the mortality of host Galleria mellonella larvae. No deaths were recorded in particles less than 600 μ across. Maximum activity occurred with 700–800 μ size particles. Activity was also limited with a sand fraction containing particles of 1000–1100 μ. Host mortality in mixtures of two sand fractions varied. Generally, the addition of either small particles (500–700 μ) or large ones (1000–1100 μ) to fractions of the mid-range (700–1000 μ) reduced the percentage kill of host larvae. Polynomial regression models fitted to data from single-phase experiments could be used to predict accurately mortality of G. mellonella larvae in two-phase mixtures of sand.     

Biological Control Potential of Neoaplectanid Nematodes

The neoaplectanids are among the most studied of all entomogenous nematodes. Because these nematodes kill their insect hosts, they are regarded as having excellent potential as biological control agents. While the host specificity of most entontogenous nematodes tends to limit their potential usefulness, the broad host range and high virulence of neoaplectanids make them attractive candidates for industrial development. Also, recent development of economical mass rearing procedures appears to make production on a commercial basis feasible. Infective stages may be stored for years trader various laboratory conditions. Although entomogenous nematodes, as parasites, are exempt from govermnent registration requirements, the mutualistic association of neoaplectanid nematodes with a bacterium will likely necessitate a detailed safety evaluation. Studies conducted to date indicate a lack of pathogenicity to mammals. Field trial success has been limited by the intolerance of infective stages to mffavorable environmental conditions, particularly low moisture. Applications against pests on exposed plant foliage have been especially disappointing. More encouraging anti consistent results have been obtained in more favorable environments, including soil and aquatic habitats, but the most promising treatment sites ntay be cryptic habitats where infective stages are shehered from environmental extremes. Cryptic habitats also exploit the ability of neoaplectanids to actively seek out hosts in recessed places where conventional insecticide applications are intpractical.     

Interaction between Neoaplectana carpocapsae (Nematoda: Steinernematidae) and Apanteles militaris (Hymenoptera: Bracondiae), a parasitoid of the armyworm, Pseudaletia unipuncta

The DD-136 strain of Neoaplectana carpocapsae adversely affected the development of immature stages of Apanteles militaris, a gregarious internal parasitoid of the armyworm, Pseudaletia unipuncta. The adverse effect of the nematode-bacterium complex was indirect, i.e., the infection by the nematode killed the host before A. militaris could complete its development. However, if armyworms containing 10- or 11-day-old A. militaris were exposed to dauer juveniles in Petri dishes, 48.1 and 94.4%, respectively, produced normal cocoons. If hosts containing 9- or 10-day-old A. militaris were fed dauer juveniles, 42.6 and 73.4% of the armyworms, respectively, produced A. militaris which formed normal cocoons. Cocoon-spinning A. militaris larvae were infected by the nematode. After cocoon formation was completed, the dauer juveniles could not penetrate the cocoon and infect the pupa. However, pupae in cocoons which had been deliberately cut open at one end became infected. A. militaris adults were infected when exposed to dauer juveniles in Petri dishes. After 3 days of exposure to dauer juveniles, 25.0, 44.2, and 7.0% of the adults in three trials were alive, whereas 100, 100, and 96.7% of the control adults were alive. Examination of dead adults in the nematode treatment showed that 67.6% contained nematodes. N. carpocapsae developed and reproduced in unparasitized armyworms, in armyworms containing 9-day-old A. militaris, and in those from which A. militaris had emerged. Production of dauer juveniles was significantly higher in unparasitized armyworms and in armyworms containing 9-day-old A. militaris than in those from which A. militaris had emerged.