宽翅曲背蝗两个地理种群等位酶的比较

采用水平淀粉凝胶电泳技术及应用等位酶分析方法,研究我国河北黄骅、辽宁葫芦岛宽翅曲背蝗两个自然种群的遗传多样性和遗传分化。在检测的11种酶15个酶基因座位中,Adk-I、Fbp-I、Mdh-2和G3pd-I基因座位的等位基因少,而Fbp-2、Mdh-I和Me-I基因座位的等位基因多。对每个基因座位的各基因型进行χ^2检验,除Mdh-I在辽宁葫芦岛种群、Adk-I在河北黄骅种群分别符合Hardy-Weinberg平衡外,其余绝大多数基因座位的基因型频率显著偏离Hardy-Weinberg平衡。两个种群之间存在明显的遗传多样性和分化：多态位点百分率分别为100％和93．3％,等位基因平均数分别为3．1和2．5,平均杂合度观测值分别为0．086和0．061。与其他非迁飞性蝗虫如中华稻蝗(Oxya chinensis)比较,这种蝗虫种群的平均杂合度较低但遗传多态性较高。结果表明：该蝗虫较强的跳跃能力可使个体暴露于各种不同环境,有利于维持种内遗传多态性的动态平衡,而种群保持较高的遗传多态性能增强该物种在不同栖息地的生存和繁殖能力。F-统计量表明两个种群之间的遗传分化相对较小,但这种分化显著高于迁飞性蝗虫如东亚飞蝗(Locusta migratoria manilensis)。Nei的遗传一致度(I)和Roger的遗传距离(D)的结果分析揭示了两个种群之间较高的遗传一致度(I=0．904)和较小的遗传距离(D=0．256)。然而,在一些酶基因座位如Aep-I(Fst=0．462)和Pgi-I(Fst=0．182),F-统计值相对较大,遗传分化比较明显。     

中国东亚飞蝗两个种群遗传分化的研究

采用水平淀粉凝胶电泳技术,分析了我国河北平山、辽宁葫芦岛两个蝗区东亚飞蝗自然种群的遗传结构。在酶谱分析的19个位点中,多数位点的等位基因数目较少,而位点Aat—l、Pgi和Mdh—2的等位基因数目相对较多。由于杂合子数目较少而使每个基因位点的平均杂合度降低(Ho=0．024和0．028)。对每个位点的各基因型进行x^2检验,绝大多数位点的基因型频率偏离Hardy—Weinberg平衡。较低的Fst值(Fst=0．021)表明两个种群的遗传分化程度不高。两个种群间较高的遗传一致度(I=0．991)和较小的遗传距离(D=0．092)也证实了上述结果。由此推测,该蝗虫较强的迁飞能力有可能增强种群间的基因交流,降低种群间的遗传分化。然而,在一些等位酶指标如位点Ao-2、Fbp—l、Mdh—2的等位基因频率分布、每个位点的平均等位基因数(A=2．5和2．7)和多态位点百分率(P=52．6％和57．9％)等,两个种群之间呈现出明显的差异。这也许与两个种群之间不同的生态环境条件和较远的地理距离有关。     

中华稻蝗四个种群的遗传分化

采用水平淀粉凝胶电泳技术研究中华稻蝗(Oxya chinensis)四个种群的12个基因座位,探讨其遗传分化.这四个种群分别采自内蒙古呼和浩特、山西代县、山西太原和陕西西安.Ck和Mdh-2在四个种群中均为单态,其余的基因座位至少在一个种群内有两个以上的等位基因;在Ldh和Mdh-1的等位基因频率呈现梯度分布趋势.多态基因座位百分率(P)和平均每个基因座位的等位基因数目(A)分别为58.3%-66.7%和2.2-2.8,平均杂合度为Ho=0.173-0.240.除Gpi,Hk-2,Idh,Ldh和Mdh-1在部分蝗虫种群符合Hardy-Weinberg平衡外,其余绝大多数基因座位的基因型频率显著偏离Hardy-Weinberg平衡.四个种群间FST平均值不存在显著差异(FST=0.0510,P＞0.05),结合高的Nei's遗传一致度(I＞0.97)可知,种群之间遗传分化不明显.我们认为人类的农业活动可能促进了种群间的基因交流,从而降低了分化程度[动物学报50(2)187-192,2004].     

山西省8种蝗虫8个种群的遗传学研究

采用水平淀粉凝胶电泳技术,对采自山西省蝗虫区系的优势种类;斑腿蝗科（Catantopidae）,斑翅蝗科（Oe-dipodidae）和网翅蝗科（Arcypteridae）3科7属8种蝗虫的11种酶进行了检测,共辨析出17个酶基因座位,并计算出等位基因频率和遗传距离,等位基因频率分析表明：Ao-I、Est-3,G3pd-1、Idh-2和Mdh-2基因座位的等位基因少,等位基因数目在种间变化较小,故推断其进化速率较慢,利用这些基因座位的保守特征,可作为分子标记研究较高级阶元的系统发育关系,而Gpi-1,Ldh-1和Me-1基因座位的等位基因多,等位基因数目在种内和种间差异较大,可以用作种,属间及种群间遗传结构的比较研究。对每个基因座位的各基因型进行χ^2检验,除Acp-1,Adk-1,Ao-1和Ao-2在部分蝗虫中符合Hardy-Weinberg平衡外,其余绝大多数基因座位的基因型频率显著偏离H-W平衡。在所研究的8种蝗虫中,多态位点百分率普遍较高（P=64.7%～94.1%）,但由于杂合子数目较少而使每个基因座位的平均杂合度降低（Ho=0.024～0.087）,对多态位点百分率分析发现：迁飞能力是影响蝗虫种间遗传变异的因素之一,具有迁飞能力的蝗虫（P=88.2%～94.1%）较非迁飞性蝗虫（P=64.7%～94.1%）表现出较高的遗传多态性,但也有例外,如中华稻蝗（Oxya chinensis）的P值高达94.1%,上述结果表明：由于迁飞行为可使个体暴露于各种不同环境,故而种群保持较高的遗传多态性能增强该物种在不同栖息地的生存和繁殖能力,因此,迁飞有利于维持迁飞性蝗虫遗传多态性的动态平衡。根据Nei的遗传一致度（I）和Roger的遗传距离（D）进行分析,结果与基于形态特征确定的分类阶元系统关系基本相符;即同属的小翅雏蝗（Chorthippus fallax）和白纹雏蝗（Chorthippus albonemus）具有最高的遗传一致度（I=0.813）和最小的遗传距离（D=0.336）,同位不同属间遗传一致度（I=0.798～0.559）和遗传距离（D=0.398～0.474）居中,科之间I值最小（I=0.523～0.479）,D值最大（D=0.505～0.523）,利用UPGMA对I值和D值进行聚类,所得两种聚类图在同属种间和同科属间的关系一致,但在科间关系有所差别,Roger的遗传距离（D）聚类树图表明：斑腿蝗科物种和斑翅蝗科物种间表现出较小的遗传距离（D=0.505）,而网翅蝗科与以上两科的遗传距离也极为接近（D=0.523）,综上所述,等位酶分析能较好地反映蝗虫同属种间和同科属间的亲缘关系,若能断更高阶元的系统发生,则需结合其他性状进行综合分析。     

中国4种蝗虫不同种群的遗传分化

采用水平淀粉凝胶电泳技术,应用等位酶分析方法对采自我国山西、江苏、河北等地不同蝗区优势蝗虫种类3科4种8个种群的12种酶18个酶位点进行了检测,比较了4种蝗虫种群水平的等位基因频率变化和它们之间的遗传距离。等位基因频率分析表明：中华稻蝗和笨蝗各位点等位基因丰富,而长翅素木蝗和短额负蝗各位点等位基因较少。在所研究的4种蝗虫8个种群中,多态位点百分率普遍较高(P＝53．3％—100．0％),由于杂合子数目较少而使每个位点的平均杂合度观察值偏低(H。＝0．034—0．139)。受迁飞能力、繁殖方式和活动范围的限制,4种蝗虫的平均杂合度观察值表现出一定的差异：笨蝗较高(H。＝0．089—0．139),其次是中华稻蝗(H。＝0．073—0．090),而长翅素木蝗(H。＝0．0488—0．068)和短额负蝗(H。＝0．034—0．050)相对较低。除Adk-1、Ao-1、Idh-1、Ldh-1、Ldh-2和Me-1在部分蝗虫种群符合Hardy-Weinberg平衡外,其余绝大多数位点的基因型频率显著偏离H—W平衡,但短额负蝗的多个位点符合或接近H—W平衡,表明该种蝗虫在自然种群结构方面明显有别于其他种类。从4种蝗虫的F—统计量(Fst)看,笨蝗种群间基因分化程度最高(Fst＝0．32),其次是短额负蝗(Fst＝0．31),而中华稻蝗相对较低(Fsl＝0．20),长翅素木蝗种群间基因分化程度最低(Fsl＝0．18),利用非加权算术平均法(UPGMA)对I值和D值进行聚类,所得聚类树也证实了这种遗传分化差异,上述结果反映了迁飞能力、适应性和环境因子对不同蝗虫遗传分化的影响。Nei的遗传距离(D)和遗传一致度(I)进行的聚类分析基本符合传统形态学、细胞学等研究结果：即同属于斑腿蝗科的中华稻蝗和长翅素木蝗遗传距离最小(D＝0．559),遗传一致度最高(I＝0．576)。在3个科中,癞蝗科和锥头蝗科之间呈现较小的遗传距离(D＝0．776)和较高的遗传一致度(I＝0．776),而这两科与斑腿蝗科之间的遗传距离相对较大(D＝0．908),遗传一致度相对较低(I＝0．406)。等位酶分析能较好地反映蝗虫不同物种的亲缘关系和种内不同种群之间的遗传分化程度。     

华北2蝗区东亚飞蝗种群遗传结构的比较研究

利用水平淀粉凝胶电泳对采自天津北大港和河北黄骅两个相临蝗区的东亚飞蝗（Locusta migratoria manilensis)种群进行等位酶基因频率分析,比较了这两个种群的遗传结构,等位酶酶谱分析表明,19个基因座中4个基因座（Mdh-l,Pgm,Adk,G3pd)的等位基因频率变化很小,常见等位基因的频率均高于0．95,其他基因座有2－4个等位基因,但是两个种群的等位基因频率除两个基因座（Fbp,Got-2)外都很相似,多态位点的27个χ2检验表明,由于常见等位基因纯合子的高频率的和相应杂合子的缺乏,仅有北大港种群的2个基因座（Pgi,Got-1)符合Hardy-Weinberg平衡,在每个种群内的蝗虫存在明显的遗传变异,但在种群间遗传结构极为相似,多态位点的百分数P分别为73．7％和78．9％,每个基因座的平均等位基因数A为2．9和3．1,平均每个基因座的实际杂合度几乎相等（约为0．138）,F－统计量（FST＝0．053）也表明了两个种群间的遗传 一致性,遗传相似性系数（I）高达0．938,这些结果提示,这两个种群可能属于1 个大种群,在两个种群的一定位点上的遗传多态性和分化可能都与迁飞因素有关,因为东亚飞蝗的高度扩散能力有利于遗传结构的连续分布,高度的迁飞能力也导致个体暴露于各种不同的环境,而在种群水平上的遗传为异能增强种群在各种生态条件生存和繁殖能力,因此,迁飞有利于维持东亚飞蝗种群的遗传多态性的动态平衡。     

不同地理飞蝗种群的遗传多样性

用GenBank中飞蝗Locusta migratoriaL.的序列来设计微卫星引物,并对这些引物的有效性进行验证。结果表明,在所设计的3对引物中,只有1对为有效引物,可扩增出微卫星位点。序列分析表明本位点是一个不连续的重复微卫星位点。该多态微卫星位点含有14个等位基因,不同飞蝗地理种群的等位基因数目、大小和频率都存在较大的差异。对该位点各等位基因型进行χ2检验,基因型频率的观察和期望杂合度分别为0.4578和0.8836,该位点不属于Hardy-Weinberg平衡位点(χ2=733.12,P=0.0000)。该微卫星位点表现出高度的多态性说明是分析飞蝗种群遗传多样性的优良分子遗传标记。     

高原鼠兔四个地理种群的遗传多样性与遗传分化

采用7 个多态微卫星DNA 标记分析了4 个高原鼠兔地理种群(海晏种群、西大滩东种群、西大滩西种群和昆仑山种群)的遗传多样性和遗传分化。采用多态信息含量(PIC)、期望杂合度(H_e )、观测杂合度(H_o)、基因流(N_m )和基因分化系数(F_st )对种群及物种的遗传多样性水平进行分析;计算各种群间的遗传距离(GD)、遗传相似度(GI)以及遗传距离与地理距离的相关系数,并进行UPGMA 聚类分析。研究结果显示,高原鼠兔的遗传多样性在小哺乳动物中处于较高水平, 其H_e 和H_o 的平均值分别为0. 5332 和0. 6003, 其F_st 为0. 0975,即有9. 75% 的变异存在于种群之间,即变异主要存在于种群内部。4 个种群间的杂合度与多态信息含量均无显著差异,说明它们的遗传多样性水平基本相当。海晏种群与其余3 个种群的遗传分化均达到了中度分化水平(F_st = 0.1043),而另3 个种群间几乎没有分化(F_st = 0. 0253)。Mantel test 结果表明地理距离与遗传距离间没有显著的相关性。     

基于微卫星的中国红火蚁种群遗传结构的研究

[背景]自入侵中国之后,红火蚁已给农林业、健康卫生、生态环境等造成了危害。红火蚁在中国的入侵、扩散路径及方式等仍然是待解决的问题。[方法]利用微卫星分子标记,对来自国内14个地区和国外1个地区共15个红火蚁地理种群的遗传多样性水平及种群遗传结构进行了研究。[结果]应用7对微卫星引物共检测到28个等位基因,15个红火蚁种群在各微卫星位点的基因型频率均符合Hardy-Weinberg平衡。各种群的平均表观杂合度HO、预期杂合度HE、Shannon信息指数Ⅰ、基因多样性指数Nei＇s和多态位点百分率P分别为0.2848、0.2708、0.3174、0.2629和43.63%,研究结果表明这15个红火蚁种群具有比较丰富的遗传多样性。种群间平均分化系数FST为0.4258,说明有42.58%的变异来源于种群间,表明红火蚁各种群之间有较高程度的分化,且遗传分化可能是由地理隔离和基因流障碍（Nem=0.7442）共同引起。遗传距离D显示,河源种群与其他种群间的遗传距离均相对高于其他各种群间的遗传距离,表明河源种群与其他地理种群之间存在较大的遗传差异,可能是较为原始的类型。[结论与意义]短距离的种群主要通过自然扩散方式传播,地理距离与亲缘关系有一定的相关性;长距离的种群主要依靠人为传播,因此地理距离与遗传距离不成正比。对于长距离的入侵事件,监控与检疫是关键的预防措施。     

实验兔三个封闭群微卫星DNA多态性遗传分析

目的 对日本大耳白兔、青紫蓝兔、新西兰兔三个封闭群体开展群体遗传学分析.方法 利用10个微卫星位点,进行Hardy-Weinberg平衡(HWE)检验,统计三个种群的基因频率、观测杂合度、期望杂合度、F值和遗传距离.结果 青紫蓝品种在12L1E11位点,新西兰品种在INRACCDDV0087位点与INRACCDDV0203位点,日本大耳白兔在Sat12位点与INRACCDDV0203,P＜0.05,显著偏离HWE,多数表现为杂合子缺陷;三个群体在Sat13、So144、6L1F10、7L1F1、12L4A1、INRACCDDV0016点上均符合HWE;各位点平均等位基因数5.9,种群整体基因频率差别较大,其范围为0 -0.9060;三个种群的平均观测杂合度为0.6204,平均期望杂合度为0.6178;群体间分化系数(Fst)平均为0.0750,日本大耳白兔和青紫蓝兔遗传距离最近为0.1223,青紫蓝兔与新西兰兔遗传距离最远为0.1934.结论 三个种群的遗传结构均表现出遗传稳定性和均一性,在10个微卫星位点上呈现高度多态性,种群间遗传分化明显.     

GENETIC DIVERSITY AND POPULATION STRUCTURE IN CAMELLIA JAPONICA L. (THEACEAE)

Camellia japonica is a widespread and morphologically diverse tree native to parts of Japan and adjacent islands. Starch gel electrophoresis was used to score allelic variation at 20 loci in seeds collected from 60 populations distributed throughout the species range. In comparison with other plant species, the level of genetic diversity within C. japonica populations is very high: 66.2% of loci were polymorphic on average per population, with a mean number of 2.16 alleles per locus; the mean observed and panmictic heterozygosities were 0.230 and 0.265, respectively. Genotypic proportions at most loci in most populations fit Hardy-Weinberg expectations. However, small heterozygote deficiencies were commonly observed (mean population fixation index = 0.129). It is suggested that the most likely cause of the observed deficiencies is population subdivision into genetically divergent subpopulations. The overall level of population differentiation is greater than is typically observed in out-breeders: The mean genetic distance and identity (Nei's D and I) between pairs of populations were 0.073 and 0.930, respectively, and Wright's Fst was 0.144. Differences among populations appeared to be manifested as variation in gene frequencies at many loci rather than variation in allelic composition per se. However, the patterns of variation were not random. Reciprocal clinal variation of gene frequencies was observed for allele pairs at six loci. In addition, principal components analysis revealed that populations tended to genetically cluster into four regions representing the geographic areas Kyushu, Shikoku, western Honshu, and eastern Honshu. There was a significant relationship between genetic and geographic distance (r = 0.61; P < 0.01). Analysis of variance on allozyme frequencies showed that there was approximately four times as much differentiation among populations within regions, as among regions. It is likely that the observed patterns of population relationships result from the balance between genetic drift in small subpopulations and gene flow between them.     

Genetic variation at minisatellite loci D1S7, D4S139, D5S110 and D17S79 among three population groups of eastern India

Genetic variation at four minisatellite loci D1S7, D4S139, D5S110 and D17S79 in three predominant population groups of eastern India, namely Brahmin, Kayastha and Garo, are reported in this study. The Brahmin and Kayastha are of Indo-Caucasoid origin while the Garo community represents the Indo-Mongoloid ethnic group. The methodology employed comprised generation of HaeIII-restricted fragments of isolated DNA, Southern blotting, and hybridization using chemiluminescent probes MS1, pH30, LH1 and V1 for the four loci. All four loci were highly polymorphic in the population groups. Heterozygosity values for the four loci ranged between 0.68 and 0.95. Neither departure from Hardy-Weinberg expectations nor evidence of any association across alleles among the selected loci was observed. The gene differentiation value among the loci is moderate (G_ST = 0.027). A neighbour-joining tree constructed on the basis of the generated data shows very low genetic distance between the Brahmin and Kayastha communities in relation to the Garo. Our results based on genetic distance analysis are consistent with results of earlier studies based on serological markers and linguistic as well as morphological affiliations of these populations and their Indo-Caucasoid and Indo-Mongoloid origin. The minisatellite loci studied here were found to be not only useful in showing significant genetic variation between the populations but also to be suitable for human identity testing among eastern Indian populations.     

High levels of genetic polymorphism in the insular endemic herb Jepsonia malvifolia.

Jepsonia malvifolia is a long-lived perennial herb endemic to the Channel Islands of southern California and Guadalupe Island, Mexico. Twelve populations of J. malvifolia on San Clemente Island were surveyed for their genotype at 21 allozyme loci, revealing high levels of genetic polymorphism. For all individuals across San Clemente Island, 95.2% of loci are polymorphic with A(p) = 2.90 and H(e) = 0.179. Populations averaged 60.2% polymorphic loci with A(p) = 2.42 and H(e) = 0.158. Most variation is found within rather than among populations (G(ST) = 0.101), although differentiation among populations is significant. Genetic identities range from 0.936 to 0.999 with mean I = 0.975. There is no significant relationship between genetic and geographic distance. Gene flow among populations is Nm = 9.5 based on private alleles and Nm = 2.2 based on F(ST). Outcrossing rates based on fixation indices average t = 0.753, indicating a primarily outcrossed mating system. The genetic variation observed is unusually high for an insular endemic herb and indicates that J. malvifolia is unlikely to be endangered by genetic factors.     

Allozyme variation in the endangered insular endemic Castilleja grisea

BACKGROUND AND AIMS: Genetic diversity in Castilleja grisea, an endangered, perennial herb endemic to San Clemente Island, California was investigated. Subsequent to the elimination of goats from the island in 1992, many populations of C. grisea have reappeared and have been increasing in size. METHODS: Nineteen populations were surveyed for their genotype at 19 allozyme loci. KEY RESULTS: At the taxon level, 57.9 % of loci are polymorphic with A(P) = 3.09 and H(E) = 0.137. Populations averaged 33.0 % polymorphic loci with A(P) = 2.43 and H(E) = 0.099. Most variation is found within rather than among populations (G(ST) = 0.128), although differentiation among populations is significant. Genetic identities range from I = 0.960 to I = 1.000 with mean I = 0.990. There is no significant relationship between genetic and geographic distance. Gene flow among populations is Nm = 2.50 based on private alleles and Nm = 1.70 based on F(ST). Outcrossing rates based on fixation indices average t = 1.01, indicating a primarily out-crossed mating system. CONCLUSIONS: The observed genetic variation is moderately high, unusually so for an insular endemic species, suggesting that C. grisea may not have lost substantial genetic variation during 150 years of overgrazing, and indicating that it is unlikely to be endangered by genetic factors.     

四种松毛虫不同地理种群遗传多样性的等位酶分析

【目的】采用等位酶电泳技术对中国松毛虫属Dendrolimus 4种共9个地理种群进行遗传多样性和遗传分化研究。【方法】对6种等位酶系统乳酸脱氢酶（LDH）、苹果酸脱氢酶（MDH）、苹果酸酶（ME）、乙醇脱氢酶（ADH）、甲酸脱氢酶（FDH）、谷氨酸脱氢酶（GDH）进行聚丙烯酰胺凝胶电泳分析。【结果】在4种松毛虫9个地理居群中共检测到10个基因位点,其中4个位点为多态位点,检测到17个等位基因; 种群总体水平多态位点比率P=40%,平均有效基因数A=1.700,平均期望杂合度He=0.151,种群平均遗传距离为0.001～0.285; 其中马尾松毛虫指名亚种Dendrolimu punctatus Walker 6个居群的遗传分化度Fst=0.265,基因流Nm=0.692。4种松毛虫之间遗传关系最近的是落叶松毛虫D. superans Butler和马尾松毛虫的地理亚种赤松毛虫D. punctatus spectabilis Butler,遗传关系最远的是落叶松毛虫D. superans Butler和云南松毛虫D. houi Lajonquiere。【结论】 马尾松毛虫居群间遗传分化程度较大,基因交流较少,遗传漂变已经成为导致该物种种群分化的主要原因之一;遗传距离与地理距离存在一定相关性。     

RAPD analysis of genetic diversity and population structure of Elymus sibiricus (Poaceae) native to the southeastern Qinghai-Tibet Plateau, China

Genetic diversity of Elymus sibiricus (Poaceae) was examined in eight populations from the southeast Qinghai-Tibet Plateau. We detected 291 RAPD polymorphic loci in 93 samples. The percentage of polymorphic bands (PPB) was 79%. Genetic diversity (H(E)) was 0.264, effective number of alleles (N(E)) was 1.444, Shannon's information index (H(O)) was 0.398, and expected Bayesian heterozygosity (H(B)) was 0.371. At the population level, PPB = 51%, N(E) = 1.306, H(E) = 0.176, I = 0.263, and H(B) = 0.247. A high level of genetic differentiation was detected based on Nei's genetic diversity analysis (G(ST) = 32.0%), Shannon's index analysis (33.7%), and the Bayesian method (θ(B) = 33.5%). The partitioning of molecular variance by AMOVA demonstrated significant genetic differentiation within populations (60%) and among populations (40%). The average number of individuals exchanged between populations per generation (N(m)) was 1.06. The populations were found to share high levels of genetic identity. No significant correlation was found between geographic distance and pairwise genetic distance (r = 0.7539, P = 0.9996). Correlation analysis revealed a significant correlation (r = 0.762) between RAPD H(E) found in this study and ISSR H(E) values from a previous study.     

Microsatellite analysis of genetic diversity and population genetic structure of a wild rice (<Emphasis Type="Italic">Oryza rufipogon</Emphasis> Griff.) in China

Genetic diversity and population genetic structure of natural Oryza rufipogon populations in China were studied based on ten microsatellite loci. For a total of 237 individuals of 12 populations collected from four regions, a moderate to high level of genetic diversity was observed at population levels with the number of alleles per locus ( A) ranging from 2 to 18 (average 10.6), and polymorphic loci ( P) from 40.0% to 100% (average 83.3%). The observed heterozygosity ( H(O)) varied from 0.163 to 0.550 with the mean of 0.332, and the expected heterozygosity ( H(E)) from 0.164 to 0.648 with the mean of 0.413. The level of genetic diversity for Guangxi was the highest. These results are in good agreement with previous allozyme and RAPD studies. However, it was unexpected that high genetic differentiation among populations was found ( R(ST) = 0.5199, theta = 0.491), suggesting that about one-half of the genetic variation existed between the populations. Differentiation (pairwise theta) was positively correlated with geographical distance ( r = 0.464), as expected under the isolation by distance model. The habitat destruction and degradation throughout the geographic range of O. rufipogon may be the main factor attributed to high genetic differentiation among populations of O. rufipogon in China.