Original birthplace of cultivated common buckwheat inferred from genetic relationships among cultivated populations and natural populations of wild common buckwheat revealed by AFLP analysis

The genetic relationships among seven cultivated populations and eight natural populations of wild common buckwheat were analyzed using amplified fragment length polymorphism (AFLP). The genetic distance was estimated for each pair of the 15 populations based on the AFLP data, and a phylogenetic tree was constructed using the neighbor-joining (NJ) method based on the genetic distance. All the cultivated populations were grouped in a cluster. The natural populations were grouped into two clusters composed of (1) the Sanjiang group (three populations from eastern Tibet and one population from Adong village of Yunnan province) and (2) two populations from Yunnan province and two populations from Sichuan province. The Sanjiang group is more closely related to cultivated populations. These results indicate that the direct ancestor of common buckwheat was natural populations of wild common buckwheat from the Sanjiang area.     

Distinction between cultivated and wild chicory gene pools using AFLP markers

The cultivation area of industrial chicory, Cichorium intybus L. cv Sativum, coincides with the natural distribution area of its wild relative, C. intybus L., which could lead to gene flow between wild and cultivated types. The genetic diversity within and between the two types has therefore been studied using AFLP genotyping of samples from 12 wild populations collected in Belgium and ten commercial varieties. The genotyping of 233 individuals allowed the identification of 254 AFLP markers. Similar levels of genetic diversity were observed within wild populations and cultivated varieties, suggesting the absence of any strong bottleneck in the history of the cultivated types. The phylogenetic analysis pointed to a monophyletic origin of cultivated varieties as compared to the local wild populations studied, hence the two types of chicory form two separate gene pools. The genotyping of some individuals sampled in ruderal sites clearly showed that they belong to the cultivated gene pool, which suggests the existence of feral or weedy types. The low differentiation observed among wild populations indicates that gene flow might be important in this species.     

Gene flow between cultivated and wild sunflowers

With the development of transgenic crops, concern has been expressed regarding the possible escape of genetically-engineered genes via hybridization with wild relatives. This is a potential hazard for sunflowers because wild sunflowers occur as weeds in fields where cultivated sunflowers are grown and hybridization between them has been reported. In order to quantify the potential for gene escape, two experimental stands of sunflower cultivars were planted at two sites with different rainfall and altitude profiles. Populations of wild plants were planted at different distances from each cultivar stand. An allele homozygous in the cultivar (6Pgd-3-a), but absent in the wild populations, was used as a molecular marker to document the incidence and rate of gene escape from the cultivar into the wild populations of sunflowers. Three-thousand achenes were surveyed to determine the amount of gene flow from the cultivated to the wild populations. The marginal wild populations (3 m from the cultivar) showed the highest percentage (27%) of gene flow. Gene flow was found to decrease with distance; however, gene flow occurred up to distances of 1000 m from the source population. These data suggest that physical distance alone will be unlikely to prevent gene flow between cultivated and wild populations of sunflowers.     

Evidence for gene flow between wild and cultivated Medicago sativa (Leguminosae)based on allozyme markers andquantitative traits

Genetic differentiation between co-occurring crops and their wild relatives will be greatly modified by crop-to-weed gene flow and variation between human and natural selective pressures. The maintenance of original morphological features in most natural populations of Medicago sativa in Spain questions the relative extent of these antagonistic forces. In this paper, we measured and compared the pattern of population differentiation within and among the wild and cultivated gene pool with respect to both allozymes and quantitative traits. Patterns of diversity defined three kinds of natural populations. First, some populations were intermediate with respect to both allozymes and quantitative traits. This suggests that crop-to-weed gene flow may have created hybrid populations in some locations. Second, some populations were different from all the cultivated landraces with respect to both allozymes and quantitative traits. This probably results from variable gene flow in space and in time, due to demographic stochasticity in either natural or cultivated populations. Third, differentiation from cultivated landraces was only achieved for the quantitative traits but not for allozymes in two populations. This suggests that natural selection in some locations may oppose gene flow to establish cultivated traits into the natural introgressed populations.     

Distinction between wild and cultivated enset (Ensete ventricosum) gene pools in Ethiopia using RAPD markers

In southwest Ethiopia, the cultivation area of Ensete ventricosum (enset) overlaps with the natural distribution area of this species. Analyses of genetic diversity were undertaken using RAPD to provide information for conservation strategies as well as evidence of possible gene flow between the different gene pools, which can be of interest for future improvement of cultivated enset. The extent of RAPD variation in wild enset was investigated in 5 populations in the Bonga area (Kefficho administrative region) and 9 cultivated clones. Comparisons were also made with some Musa samples of potential relevance for crop improvement. Nine oligonucleotide primers amplified 72 polymorphic loci. Population differentiation was estimated with the Shannon index (G'(ST)=0.10), Nei's G(ST) (0.12) and AMOVA (Phi(ST)=0.12), and appears to be relatively low when compared with outbreeding, perennial species in general. Cluster analysis (UPGMA) and principal component analysis (PCA) similarly indicated low population differentiation, and also demonstrated that cultivated clones essentially clustered distinctly from wild enset samples, suggesting that the present-day cultivated enset clones have been introduced to domestication from a limited number of wild progenitors. In addition, subsequent gene flow between wild and cultivated enset may have been prohibited by differences between modes of propagation and harvesting time; cultivated enset is propagated vegetatively through sucker production and the plant is generally harvested before maturity or flower set, thereby hindering pollination by wild enset or vice versa. A significant correlation was not found between genetic and geographical distances. The relatively high total RAPD diversity suggests that wild enset populations in the Bonga area harbour genetic variability which could potentially act as a source for useful or rare genes in the improvement of cultivated enset. As expected, E. ventricosum was clearly differentiated from the analysed Musa samples, that clustered in accordance with the present morphology- and molecular marker-based taxonomy of the genus.     

Genetic differentiation and gene flow between wild and cultivated Prunus avium: An analysis of molecular genetic evidence at a regional scale

The presence of conspecific wild-type and cultivar populations has been a common landscape feature for centuries. As orchards generally continue to expand towards the natural forest, two important issues are raised: the potential reduction of cultivar genetic diversity compared to wild populations and the extent of gene flow between the two population types. These questions were addressed in a study of Prunus avium in northern Greece using nine simple sequence repeat loci to analyse genetic variation in 93 wild-type individuals and 21 cultivars representing the local cultivated germplasm. Results showed a significant reduction of genetic diversity parameters in the cultivated germplasm compared to natural populations. Bayesian, frequency-based and Markov chain – Monte Carlo analyses have revealed that the wild and cultivar groups are genetically divergent and that realized between-group gene flow is almost completely absent. This result was further verified by a principal component analysis showing a clear separation of the two groups in low multivariate space after a principal coordinate analysis. The significant disjunction in flowering time and a considerable geographic distance between the two groups could primarily account for the absence of substantial gene flow. These findings indicate that local wild cherry can provide a source of genetic variation for future breeding in the genetically restricted cultivar group.     

荞麦属种间13S球蛋白基因序列比较研究

荞麦13S球蛋白是荞麦种子中的一类主要贮藏蛋白。本研究选用荞麦属植物甜荞栽培种及其野生类型、苦荞栽培种及其野生类型、毛野荞、左贡野荞、细柄野荞和硬枝万年荞6个种共44份材料,进行PCR特异性扩增、测序得到荞麦13S球蛋白基因的保守片段序列。对序列进行差异分析,结果发现44份供试材料13S球蛋白基因片段的285个排列位点中不变位点为24个,多态性位点S为261个(含简约信息位点数198个和单型可变位点63个),序列总突变位点Eta为503个。野生甜荞种内13S球蛋白基因序列差异明显高于栽培甜荞,但野生苦荞种内13S球蛋白基因序列差异仅稍高于栽培苦荞。推测其一方面可能与繁殖方式有关,另一方面可能与荞麦驯化过程中通常只有少数野生型群体被驯化有关。系统聚类分析发现栽培甜荞与野甜荞亲缘关系近,与左贡野荞亲缘关系次之;栽培苦荞与野苦荞亲缘关系近,与毛野荞亲缘关系次之;细柄野荞和硬枝万年荞的13S蛋白基因片段序列差异较小,说明其亲缘关系较近。上述结果为荞麦属种间遗传多样性与进化关系研究提供了理论依据。     

Phylogenetic relationships among wild and cultivated Tartary buckwheat (Fagopyrum tataricum Gaert.) populations revealed by AFLP analyses

Phylogenetic relationships among cultivated landraces and natural populations of wild subspecies of Tartary buckwheat were investigated at the individual level by constructing a phylogenetic tree based on amplified fragment length polymorphism (AFLP) markers. Seven individuals from seven cultivated landraces and 35 individuals from 21 natural populations of wild subspecies were utilized for AFLP analyses. Three groups were recognized: (1) all cultivated landraces and wild subspecies from northern Pakistan, central and eastern Tibet, and northwestern Yunnan, (2) wild subspecies from central and southern Sichuan, (3) wild subspecies from northern Sichuan and eastern Tibet. It was concluded that cultivated Tartary buckwheat probably originated in eastern Tibet or northwestern Yunnan in China.     

Tracing back seed and pollen flow within the crop-wild Beta vulgaris complex: genetic distinctiveness vs. hot spots of hybridization over a regional scale

Hybrids between transgenic crops and wild relatives have been documented successfully in a wide range of cultivated species, having implications on conservation and biosafety management. Nonetheless, the magnitude and frequency of hybridization in the wild is still an open question, in particular when considering several populations at the landscape level. The Beta vulgaris complex provides an excellent biological model to tackle this issue. Weed beets contaminating sugar beet fields are expected to act as a relay between wild populations and crops and from crops-to-crops. In one major European sugar beet production area, nine wild populations and 12 weed populations were genetically characterized using cytoplasmic markers specific to the cultivated lines and nuclear microsatellite loci. A tremendous overall genetic differentiation between neighbouring wild and weed populations was depicted. However, genetic admixture analyses at the individual level revealed clear evidence for gene flow between wild and weed populations. In particular, one wild population displayed a high magnitude of nuclear genetic admixture, reinforced by direct seed flow as evidenced by cytoplasmic markers. Altogether, weed beets were shown to act as relay for gene flow between crops to wild populations and crops to crops by pollen and seeds at a landscape level.     

Differentiation between natural and cultivated populations of Medicago sativa (Leguminosae) from Spain: analysis with random amplified polymorphic DNA (RAPD) markers and comparison to allozymes

The conservation of a crop's wild relatives as genetic resources requires an understanding of the way genetic diversity is maintained in their populations, notably the effect of crop-to-wild gene flow. In this study, the amount of differentiation between natural and cultivated populations of Medicago sativa was analysed using random amplified polymorphic DNA (RAPD) markers and an extension of the AMOVA procedure adapted to autotetraploid organisms. Simulations of structured populations were performed to test whether AMOVA provides estimates of population structure in autotetraploids that can be directly compared to those obtained for allozyme data. Simulations showed that straight phi-statistics allow a good estimation of population differentiation when unbiased allelic frequencies are used to correct the conditional expectations of squared genetic distances. But such unbiased estimates can not be practically guaranteed, and population structure is notably overestimated when some populations are fixed for the presence of amplified fragments. However, removing fixed loci from the data set improves the statistical power of the test for population structure. The genetic variation of 15 natural and six cultivated populations of M. sativa was analysed at 25 RAPD loci and compared to estimates computed with allozymes on the same set of populations. Although RAPD markers revealed less within-population genetic diversity than allozymes, the quantitative and qualitative patterns of population structure were in full agreement with allozymes. This confirmed the conclusions drawn from the allozymic survey: crop-to-wild gene flow occurred in many locations, but some other mechanisms opposed cultivated traits to be maintained into natural populations.     

Inferences from mitochondrial DNA patterns on the domestication history of alfalfa (Medicago sativa)

The evolutionary history of a wild-cultivated complex is the outcome of different factors, among which are the domestication of the cultivated form, its geographical and demographic expansion, as well as gene flow between natural and cultivated populations. To clarify this history for alfalfa (Medicago sativa), we adopted a phylogeographical approach based on a sample of natural and cultivated populations of the M. sativa species complex. This sample was characterized for mtDNA variation through restriction fragment length polymorphisms. Twenty-two mitotypes were identified in the whole data set (155 individuals). In the wild pool from the presumed area of origin (Near East to Central Asia), the diversity was high but the absence of geographical differentiation hinders a more precise location of the centre of domestication. Within the cultivated alfalfa, the geographical structure suggests strongly the existence of at least two independent routes of dissemination of alfalfa from its centre of origin. In particular, original mitotypes detected in some regions suggest that wild populations not sampled in this study, and located outside the presumed area of domestication, may have contributed to the diversity of the cultivated pool. Finally, analysis of the mtDNA variation shows that natural populations collected in Spain constitute an endemic wild pool now introgressed partially by cultivated alfalfa.     

Gene flow from cultivated rice (Oryza sativa) to its weedy and wild relatives

BACKGROUND AND AIMS: Transgene escape through gene flow from genetically modified (GM) crops to their wild relative species may potentially cause environmental biosafety problems. The aim of this study was to assess the extent of gene flow between cultivated rice and two of its close relatives under field conditions. METHODS: Experiments were conducted at two sites in Korea and China to determine gene flow from cultivated rice (Oryza sativa L.) to weedy rice (O. sativa f. spontanea) and common wild rice (O. rufipogon Griff.), respectively, under special field conditions mimicking the natural occurrence of the wild relatives in Asia. Herbicide resistance (bar) and SSR molecular finger printing were used as markers to accurately determine gene flow frequencies from cultivated rice varieties to their wild relatives. KEY RESULTS: Gene flow frequency from cultivated rice was detected as between approx. 0.011 and 0.046 % to weedy rice and between approx. 1.21 and 2.19 % to wild rice under the field conditions. CONCLUSIONS: Gene flow occurs with a noticeable frequency from cultivated rice to its weedy and wild relatives, and this might cause potential ecological consequences. It is recommended that isolation zones should be established with sufficient distances between GM rice varieties and wild rice populations to avoid potential outcrosses. Also, GM rice should not be released when it has inserted genes that can significantly enhance the ecological fitness of weedy rice in regions where weedy rice is already abundant and causing great problems.     

The origin and fate of morphological intermediates between wild and cultivated soybeans in their natural habitats in Japan

The spread of transgenes into the genome of wild soybean is a concern when transgenic and wild soybeans are planted sympatrically. The objectives of this study were to investigate the origin and fate of morphological intermediates between wild and cultivated soybeans in their natural habitats in Japan. Twenty nuclear microsatellite and two chloroplast dCAPS markers were used to evaluate genetic variation of 468 wild, 17 intermediate, and 12 cultivated soybean samples collected from six sites between 2003 and 2006. Allelic differentiation of microsatellite markers between wild and cultivated soybeans was sufficient to detect their hybrids. Based on levels of observed heterozygosity, intermediate soybean plants were from two generations: either F₁ or an early segregating generation. Genetic admixture analysis and parentage assignment analysis revealed that the parents of all intermediate soybean plants could be assigned to a particular wild soybean plant and late‐maturing cultivar. The chloroplast DNA haplotypes revealed that all intermediate soybean plants originated from gene flow from cultivated to wild soybeans at all sites. Based on monitoring at both the phenotypic and molecular levels, hybrids quickly disappeared from natural habitats, and secondary gene flow from these plants to wild soybean was not detected. Thus, while gene flow from transgenic soybean into wild soybean can occur, gene introgression appears to be rare in natural habitats in Japan. This is the first report on the detection of gene flow from cultivated to wild soybean at the molecular level.     

Genetic diversity and population structure of<Emphasis Type="Italic">Kalopanax pictus</Emphasis> (Araliaceae)

Kalopanax pictus (Araliaceae) is a long-lived woody species primarily distributed throughout East Asia. This species is regarded as medically and ecologically important in Korea. We used starch gel electrophoresis to investigate its allozyme variation and genetic structure in samples from Korean populations (both natural and cultivated). Our analysis of 10 enzymes revealed 18 loci, of which 10 were polymorphic (35.6%). Genetic diversity at the species and population levels were 0.200 and 0.149, respectively, with the mean for cultivated populations (0.124) being lower than for natural (wild) populations (0.181). Asexual and sexual reproduction modes, perennial habitat, and longevity all were possible factors contributing to such high diversity. An indirect estimate of the number of migrants per generation (N _m = 1.08) indicated that gene flow was not extensive among these Korean populations. Therefore, we suggest that geographical distance as well as reproductive isolation between wild and cultivated plants may play roles in shaping the population structure of this species.     

Local scale patterns of gene flow and genetic diversity in a crop–wild–weedy complex of sorghum (Sorghum bicolor (L.) Moench) under traditional agricultural field conditions in Kenya

Little information is available on the extent and patterns of gene flow and genetic diversity between cultivated sorghum and its wild related taxa under local agricultural conditions in Africa. As well as expanding knowledge on the evolutionary and domestication processes for sorghum, such information also has importance in biosafety, conservation and breeding programmes. Here, we examined the magnitude and dynamics of crop–wild gene flow and genetic variability in a crop–wild–weedy complex of sorghum under traditional farming in Meru South district, Kenya. We genotyped 110 cultivated sorghum, and 373 wild sorghum individuals using a panel of ten polymorphic microsatellite loci. We combined traditional measures of genetic diversity and differentiation with admixture analysis, population assignment, and analyses of spatial genetic structure to assess the extent and patterns of gene flow and diversity between cultivated and wild sorghum. Our results indicate that gene flow is asymmetric with higher rates from crop to wild forms than vice versa. Surprisingly, our data suggests that the two congeners have retained substantial genetic distinctness in the face of gene flow. Nevertheless, we found no significant differences in genetic diversity measures between them. Our study also did not find evidence of isolation by distance in cultivated or wild sorghum, which suggests that gene dispersal in the two conspecifics is not limited by geographic distance. Overall our study highlights likely escape and dispersal of transgenes within the sorghum crop–wild–weedy complex if genetically engineered varieties were to be introduced in Africa’s traditional farming systems.     

Habitat features and genetic integrity of wild grapevine Vitis vinifera L. subsp. sylvestris (C.C. Gmel.) Hegi populations: A case study from Sicily

Wild grapevine represents a valuable genetic resource for both future breeding programmes of cultivated grape and conservation of biological diversity in natural environments. In Sicily, the knowledge of this species is quite scarce and fragmentary. Therefore, in order to assess the presence and the genetic quality of wild grapevine in the island, eight populations from different locations were investigated. Their habitats were characterized and the genetic diversity was measured by microsatellite markers in order to evaluate possible relationships between genetic features and the ecological behaviour of populations.With the exception of one population found in a scree-type habitat, all the others were present in flooded areas. Grapevine populations growing in riparian habitats were characterized by low inter- and intra-population variability. Conversely, the scree-type population proved to be the most compact and distinctive, as well as the most genetically isolated. Interestingly, together with other two populations from the northern mountain range of the island, this scree-type grapevine population was genetically rather distant from local domestic accessions, suggesting a weak gene exchange with the cultivated grapevines in Sicily. On the contrary, the other populations showed evidences of probable introgression events, as a result of either gene flow between domestic and wild plants, or of possible secondary domestication/genetic improving processes, based on the use of native wild material.     

PCR method for detecting trace amounts of buckwheat (Fagopyrum spp.) in food

Buckwheat often causes severe allergic reactions, even when its ingestion level is extremely low. Therefore, buckwheat is listed in several countries as a common food allergen. In addition to common buckwheat and Tartarian buckwheat that are cultivated and consumed widely, wild buckwheat may be potentially allergenic. Food containing undeclared buckwheat poses a risk to patients with the buckwheat allergy. We describe in this report a PCR method to detect buckwheat DNA by using primers corresponding to the internal transcribed spacer region and the 5.8S rRNA gene. The method is buckwheat-specific and compatible with both cultivated and wild buckwheat of the Fagopyrum spp. Its sensitivity was sufficient to detect 1 ppm (w/w) of buckwheat DNA spiked in wheat DNA. This method should benefit food manufacturers, clinical doctors, and allergic patients by providing information on the presence of buckwheat contamination in food.     

Search for the wild ancestor of buckwheat III. The wild ancestor of cultivated common buckwheat, and of tatary buckwheat

By surveying wild Fagopyrum species and their distribution in southern China and the Himalayan hills, I arrived at the conclusion that the newly discovered subspecies F. esculentum ssp. ancestralis Ohnishi is the wild ancestor of cultivated common buckwheat, while previously known wild tatary buckwheat,F. tataricum ssp. potanini Batalin is the wild ancestor of tatary buckwheat. Their original birthplace is revealed to be northwestern corner of Yunnan province for common buckwheat judging from the distribution of wild ancestor, and to be the northwest part of Sichuan province for tatary buckwheat judging from allozyme variability in wild tatary buckwheat. F. cymosum is not the ancestor of cultivated buckwheat; it is only distantly related to cultivated buckwheat, in morphology, isozymes and cpDNA. Several genetic, ecological and taxonomic categories which should be taken into consideration in examining the origin of buckwheat were discussed. Key Words: Fagopyrum esculentum ssp. ancestralis; Fagopyrum tataricum ssp. potanini; southern China theory of origin of buckwheat. Contribution from Plant Germ-Plasm Institute, Faculty of Agriculture, Kyoto University. No. 78.     

长吻(鱼危)养殖群体与野生群体遗传多样性分析

长吻(鱼危)(Leiocassis longirostris)是中国土著珍稀鱼类。近年来, 由于江河水利工程、环境污染及人类生产活动已经对江河的渔业资源造成了难以逆转的破坏, 长吻(鱼危)的渔业资源已逐渐枯竭。目前, 长吻(鱼危)在四川、广东等地实现适度规模养殖。以四川眉山、湖北石首和安徽淮南3个人工养殖长吻(鱼危)群体及4个长江野生长吻(鱼危)群体(重庆段、武汉段、安庆段和南京段)为实验材料, 利用线粒体DNA (mtDNA)控制区序列作为分子标记对135个个体的遗传结构进行了分析。结果表明, 在790 bp 的同源序列中, 长吻(鱼危) 3个养殖种群共检测到变异位点27个, 占全部序列的3.42%, 66个个体共检测到18种单倍型; 在野生群体中, 69个个体共检测到35个变异位点和36个单倍型, 长吻(鱼危)野生群体平均单倍型多样性和平均核苷酸多样性(Hd=0.9736±0.0070, Pi=0.0087±0.0015)高于长吻(鱼危)养殖群体(Hd=0.8867±0.0013, Pi=0.0056±0.0013); 群体间的遗传分化水平较低(F_st值为0.0014—0.1125)。采用邻接法(NJ法)和统计简约原理对所有单倍型进行系统发育树和统计简约网状图的构建, 结果表明: 各群体内的个体均不能分别构成独立的分支, 而是相互交叉聚在一起。分析结果表明, 长吻(鱼危)养殖群体与野生群体之间的基因交流充分, 未出现遗传分化, 但相对长吻(鱼危)野生群体, 长吻(鱼危)养殖种群多态性偏低。     

Impact of gene flow from cultivated beet on genetic diversity of wild sea beet populations

Gene flow and introgression from cultivated plants may have important consequences for the conservation of wild plant populations. Cultivated beets (sugar beet, red beet and Swiss chard: Beta vulgaris ssp. vulgaris) are of particular concern because they are cross-compatible with the wild taxon, sea beet (B.vs. ssp. maritima). Cultivated beet seed production areas are sometimes adjacent to sea beet populations; the numbers of flowering individuals in the former typically outnumber those in the populations of the latter. In such situations, gene flow from cultivated beets has the potential to alter the genetic composition of the nearby wild populations. In this study we measured isozyme allele frequencies of 11 polymorphic loci in 26 accessions of cultivated beet, in 20 sea beet accessions growing near a cultivated beet seed production region in northeastern Italy, and 19 wild beet accessions growing far from seed production areas. We found one allele that is specific to sugar beet, relative to other cultivated types, and a second that has a much higher frequency in Swiss chard and red beet than in sugar beet. Both alleles are typically rare in sea beet populations that are distant from seed production areas, but both are common in those that are near the Italian cultivated beet seed production region, supporting the contention that gene flow from the crop to the wild species can be substantial when both grow in proximity. Interestingly, the introgressed populations have higher genetic diversity than those that are isolated from the crop. The crop-to-wild gene flow rates are unknown, as are the fitness consequences of such alleles in the wild. Thus, we are unable to assess the long-term impact of such introgression. However, it is clear that gene flow from a crop to a wild taxon does not necessarily result in a decrease in the genetic diversity of the native plant.