稻属Oryza rufipogon和Oryza nivara的遗传多样性和居群分化研究

普通野生稻(Oryza rufipogon Griff.)和尼瓦拉野生稻(O. nivara Sharma et Shastry)是亚洲栽培稻的最近缘野生种，是亚洲栽培稻育种和遗传改良的重要基因库。由于人类的破坏、生境片段化及亚洲栽培稻的遗传渐渗等因素，这两种野生稻处于濒危状态而急需保护。本文用微卫星标记研究中国普通野生稻居群的遗传多样性和居群分化，用核基因序列研究了全分布区的普通野生稻和尼瓦拉野生稻的遗传变异及模式，同时发现了巴布亚新几内亚普通野生稻的特殊分子变异。主要结果如下： 取自中国普通野生稻四个主要分布区的12个天然居群，共237份个体材料，利用10对微卫星引物对遗传多样性进行比较研究。结果表明这些居群的遗传多样性处于中高水平，其中每个位点的等位基因数之在2至18之间不等，平均10.6个，多态位点比率P从最低40.0%最高100%，平均为83.3%。观察杂合度在 (HO) 0.163-0.550变化，平均为0.332, 期望杂合度(HE) 在0.164- 0.648，平均 0.413，从地区来看，广西居群的遗传多样性水平是最高的，其次是广东、海南居群，江西的最低。这些结果与以前用其他分子标记得到的结果基本一致。但是本研究得到的居群间遗传分化却相对较高，分化系数RST为 0.5199，θ为 0.491，这表明一半左右的遗传变异存在于居群之间。两两居群之间的分化系数(pairwise θ)与地理距离呈正相关(r = 0.464)，这表明中国普通野生稻居群之间的遗传分化是由于地理的隔离造成的。造成目前这种遗传结构和分化模式的主要原因在于普通野生稻生境的破坏和生境的片段化。 选择6个普通野生稻居群，5个尼瓦拉野生稻居群共11个居群105个个体材料为研究对象，取样覆盖两个野生稻的主要分布区，用核基因片段Lhs1研究了这两种野生稻的序列水平的变异，探讨了它们的遗传结构和基因流方向。结果表明，普通野生稻的核苷酸多样性，无论在居群还是物种水平上，均显著高于尼瓦拉野生稻的。在居群水平上，普通野生稻的核苷酸多样性(Hd = 0.712; θsil = 0.0017)是尼瓦拉野生稻的2-3倍(Hd = 0.306; θsil = 0.0005)。AMOVA的结果表明，尼瓦拉野生稻居群之间的遗传分化(78.2%)显著高于普通野生稻居群间的分化(52.3%)。造成这种不同层次的遗传多样性和完全不同的遗传分化模式的原因在于这两种野生稻差异显著的生活史和交配系统。普通野生稻是多年生、异交的野生种，营养与有性繁殖混合，尼瓦拉野生稻为一年生的自交种，靠种子繁殖。模拟分析表明，二者之间的基因流方向是单向的，明显是从自交的尼瓦拉野生稻到异交的普通野生稻，基因流在这两个野生 稻遗传多样性模式的形成上，扮演至关重要的角色。 对于稻属A基因组物种的进化和多样性来说, 巴布亚新几内亚(PNG)是个很重要的地方。我们用两个核基因和一个叶绿体基因，对巴布亚新几内亚的普通野生稻样品进行了序列分析，结果发现来自巴布亚新几内亚北部Sepik河谷的普通野生稻样品在核基因Os0053位点和叶绿体基因序列上与其他地区的样品有很大的差异。巴布亚新几内亚北部的普通野生稻在Os0053位点上杂合的，其中一条等位基因与普通野生稻基本一致，另一条等位基因则与A基因组的另一个物种O. meridionalis基本一致，证明巴布亚新几内亚北部的普通野生稻实际上是亚洲典型普通野生稻与澳洲野生稻O. meridionalis种间进行天然渐渗杂交的后代。这个结果从分子序列上验证了前人有关巴布亚新几内亚北部的普通野生稻是比较特殊的观点。

体细胞无性系变异与烟草抗黑胫病细胞突变体的筛选

体细胞无性系变异是植物组织培养过程中发生的一种较为普遍的现象，这种现象在遗传学理论和育种实践上都很值得研究。应用这种变异进行筛选人们已经获得了一大批生产上有广泛意义的细胞突变体。但对于无性系变异发生的机理，人们虽然也进行了详细研究，提出了不少假说，但一直未能给出一个较为全面的解释。有些解释仍然建立在推测的基础上，有待进一步的研究。在这些解释中，利用转座子活化进行解释是最使人感兴趣的一种，也是较有说服力的一种。我们的实验分为两个部分，一是对无性系变异发生与转座子的关系进行了初步的探索,一是利用体细胞无性系变异筛选烟草黑胫病细胞突变体的应用进行了研究。 对转座因子的转活性进行分析，通常采用标记基因的表型检测。本实验用农杆菌双元载体pSLJ721（Ac∷GUS）转化烟草（品种：红花大金元）， 然后对转基因烟草的愈伤组织进行GUS酶活性的组织化学分析。通过GUS活性变化来分析转座活性。结果表明组织培养可以增强转座子的活性。间接证明转座子活化是体细胞无性系变异的原因之. 本论文实验方面的另一部分是体细胞无性系变异在烟草抗黑茎病研究上的应用。烟草黑茎病是由烟草致病疫霉引起的一种烟草主要病害。首先从云南地区黑胫病病区分离、纯化黑胫病（Phytophythora parasitica via. Nicotina）病原菌，同时利用红花大金元为实验对象，以组织培养中自然发生的元性系变异为基础，以50％以及80％的黑胫病病菌粗毒素为选择压力，筛选出抗黑胫病毒素的烟草株系，用离体叶片法和茎部接种法进一步鉴定其对黑胫病病菌的抗性。最后进行田间检测以期获得综合性状优良的抗黑胫病细胞突变体。另外我们还利用随机引物扩增多态DNA（RAPD）分析技术，对选择到的九个抗病株系和六株对照的DNA进行分析。在使用的70种随机引物中，共有57个引物产生可检测扩增产物，产生306条搁增带，其中有多态性的条带数为51条，突变体的平均RAPD条带变异率为1.85％，其中有两个RAPD条带（CYA－17－100和Sangon03-350）为突变体所特有，可初步判断为抗黑胫病的RAPD标记。对突变体和对照植株叶片水溶性蛋白SDS电泳观察到一些条带的变异，但没有找到突变体特异的共同条带。

PEFCSH 的建立及在基因组特异序列克隆上的应用

基因组特异序列是跟踪外源染色质、鉴定易位系的特异探针。本文介绍一种带反馈控制的PCR增效减法杂交（PEFCSH），证明可高效克隆基因组特异序列。 带PCR接头的黑麦DNA片段与固定化的小麦ssDNA杂交，同源的片段将被吸附。用PCR扩增吸附的DNA，可监测杂交液中与小麦同源的DNA，确定是否还要再杂交。5轮连续杂交后，杂交液中的DNA几乎全为黑麦特异DNA，纯化后，用PCR扩增到方便操作的数量。经检测，PEFCSH片段99%为黑麦基因组特异性序列，富集度超过230倍。 PEFCSH片段克隆后检测：插入片段在120bp～2000bp，峰值250bp左右;306个克隆中301个显黑麦特异性，表明了PEFCSH的高效性。Tomita等曾用普通减法杂交富集黑麦特异序列，所得克隆只有6.3%为黑麦特异。 与数据库对比，分离片段有的为新序列，更多的与已知的黑麦特异重复序列同源。用其中一条作探针进行Southern杂交，小麦不显带，黑麦显阶梯型带，说明它是特异性串联重复序列。 PEFCSH有如下特点：1. 实时监测杂交液中非特异DNA，首次引入反馈控制，确保杂交达到预期效果。2. 用PCR制备Tester只需少量样品就可以分离特异序列。3. 采用固相减法杂交，大大简化Test与Driver的分离。4. 用PCR克服常规减法杂交操作性差的弱点。5. 富集特异单链和双链DNA，减少特异序列丢失。6. 适用于大多数分离两组相关核酸中的差异成分。

Fecundity, egg deposition, and mortality of market squid (Lolilgo opalescens)

Loligo opalescens live less than a year and die after a short spawning period before all oocytes are expended. Potential fecundity (EP), the standing stock of all oocytes just before the onset of spawning, increased with dorsal mantle length (L), where EP = 29.8L. For the average female squid (L of 129 mm), EP was 3844 oocytes. During the spawning period, no oogonia were produced; therefore the standing stock of oocytes declined as they were ovulated. This decline in oocytes was correlated with a decline in mantle condition and an increase in the size of the smallest oocyte in the ovary. Close agreement between the decline in estimated body weight and standing stock of oocytes during the spawning period indicated that maturation and spawning of eggs could largely, if not entirely, be supported by the conversion of energy reserves in tissue. Loligo opalescens, newly recruited to the spawning population, ovulated about 36% of their potential fecundity during their first spawning day and fewer ova were released in subsequent days. Loligo opalescens do not spawn all of their oocytes; a small percentage of the spawning population may live long enough to spawn 78% of their potential fecundity. Loligo opalescens are taken in a spawning grounds fishery off California, where nearly all of the catch are mature spawning adults. Thirty-three percent of the potential fecundity of L. opalescens was deposited before they were taken by the fishery (December 1998−99). This observation led to the development of a management strategy based on monitoring the escapement of eggs from the fishery. The strategy requires estimation of the fecundity realized by the average squid in the population which is a function of egg deposition and mortality rates. A model indicated that the daily total mortality rate on the spawning ground may be about 0.45 and that the average adult may live only 1.67 days after spawning begins. The rate at which eggs escape the fishery was modeled and the sensitivity of changing daily rates of fishing mortality, natural mortality, and egg deposition was examined. A rapid method for monitoring the fecundity of the L. opalescens catch was developed.

Recruitment season, size, and age of young American eels (Anguilla rostrata) entering an estuary near Beaufort, North Carolina

Net catches from 1985–86 to 1994–95 at Pivers Island, North Carolina, indicated that glass-eel stage American eels (Anguilla rostrata) were recruited to the estuary from November to early May, with peak numbers in January, February, and March. There was no declining trend in recruitment over the years of sampling. Except for one year, there was no clear seasonal decrease in mean length. But shorter glass eels were older than longer glass eels, as judged by age within the glass eel growth zone of the otolith, suggesting that smaller fish took longer to arrive. The mean age of glass eels collected from the lower estuary and a freshwater site 9.5 km upriver differed by 8.4 d (36.2 vs. 44.6, respectively). Outer increments (30–35) of the otolith growth zone of glass eels from North Carolina were significantly wider than corresponding increments of otoliths from New Brunswick. Mean total ages of North Carolina, New Jersey, and New Brunswick elvers were 175.4, 201.2, and 209.3 d, corresponding to mean lengths of 55.9, 60.9, and 58.1 mm TL, respectively. The mean durations of glass-eel growth zones (44.6, 62.3, and 69.8) were in close agreement with those from previous studies, but total ages were not. This suggested that perhaps some finer (leptocephalus stage) increments were not detected by light microscopy, differences occurred in seasonal increment deposition, or absorption of the otolith material may have taken place during metamorphosis, rendering the aging of larvae inaccurate. Judging from the long recruitment period and seasonal uniformity in both mean age and length found in our study, the spawning period of American eels may be somewhat more protracted than previously considered.