基因棉花田间基因流监测

采用花粉粒染色法对转Bt基因棉的花粉漂移距离和强度进行了观测,并应用PCR法检测转Bt基因棉的基因流频率.花粉粒染色法监测结果表明：同株异花间的花粉散布频率显著高于异株异花间(P<0.01);靠近转Bt基因棉花粉染色区1 m处的平均花粉散布频率,在东、南、西、北4个方向分别为44.8%、48.9%、57.1%和21.5%,但随着距转基因棉田距离的增大,4个方向的平均花粉散布频率都呈下降趋势.PCR结果的统计分析表明,在25m内,花粉散布距离和方向对基因流频率有极显著影响(P<0.01),随着距转基因棉田距离的增大,基因流频率呈下降趋势,最远距离为25 m时的最高基因流频率为2.0%.     

转基因棉花的Bt基因流

通过两年实验检测转基因陆地棉品种间和海岛棉与陆地棉种间的Bt基因流.将转基因陆地棉国抗12号种植在12m×12m的样方内,周围分别种植非转基因陆地棉品种中棉所12号和海岛棉品种新海13号,在离转基因棉花不同距离选取样点,采集非转基因棉花种子,利用标记选择基因、Dot朎LISA和PCR扩增检测Bt基因流.结果表明在0～6m内陆地棉品种间显示较高频率的基因流,随着距离的增加Bt基因流降低,最大可达36m;提高样方内转基因棉花纯度,仅增加0～3m内基因流,对较远距离基因流无影响.海陆种间Bt基因流在0～6m内比陆地棉品种间低,但Bt基因流随距离增加下降幅度小,最远达72m.因此,在小规模转基因棉花环境释放实验,可选用同种不同品种棉花作为缓冲隔离带,并讨论了棉花转基因逃离至我国棉属种类的可能性.     

风向因素对转基因抗虫棉花基因漂移效率的影响

在转基因作物获准进行环境释放并实行大面积商品化推广的同时,基因漂移所引起的生态环境安全问题不容忽视。本研究以含有双价抗虫基因（Bt/CpTI）的转基因棉花SGK321为花粉供体材料,以常规非转基因棉花品种石远321、中棉35、吉扎1号为花粉受体材料,在温室中人工创造定向风和非定向风条件,应用PCR与蛋白检测相结合的方法,检测外源基因发生基因漂移的效率。结果表明：随着与转基因棉花SGK321距离的增加,外源基因转移至非转基因棉花的基因漂移频率呈现波动性变化。在定向风处理中,基因漂移频率在距离转基因棉花6.4 m处达到峰值33.33%,在测定范围内基因漂移最远距离为25.6 m;而在非定向风处理中,基因漂移频率在距离转基因棉花12.8 m处达到峰值36.67%,在测定范围内基因漂移最远距离为36 m。非定向风可显著提高转移至海岛棉吉扎1号的基因漂移频率。外源基因从SGK321转移至其非转基因亲本石远321的基因漂移频率显著高于转移至陆地棉中棉35和海岛棉吉扎1号的漂移频率。本研究可为转基因棉花的生态安全性分析提供一定的理论参考价值。     

风速对转基因棉花基因漂移的影响

在转基因作物全球商业化推广的20年间,公众对基因漂移生态安全问题的关注持续升温。本试验以转基因双价棉SGK321(Cry1Ac/Cp TI)为花粉供体,常规棉"石远321"和"中棉35"为花粉授体,借助PCR和蛋白检测技术,研究温室中3种风速(0.54、0.92和1.27 m·s-1)条件下的Cry1Ac基因漂移频率。结果表明:"石远321"作为花粉受体时,基因漂移频率受风速影响,低风速下最高,高风速下最低;"中棉35"作为花粉授体时,基因漂移频率整体较低,不受风速影响;基因漂移频率与所选择的花粉受体品种有关,"石远321"(转基因棉亲本)(10.63%)作为花粉受体时基因漂移频率高于"中棉35"(2.50%);转基因棉花基因漂移频率随着转基因作物种植区与非转基因作物之间距离的增加而下降。本试验为风介导的基因漂移的生态风险评估提供一定的理论参考。     

转Bt基因抗虫棉田棉铃虫消长规律及危害特点

通过对转 Bt基因抗虫棉田棉铃虫的系统调查研究表明 :(1)转 Bt基因抗虫棉对棉铃虫蛾、卵无抗性表现 ,田间落卵量与常规棉田无明显差异 ,相反 ,二代棉铃虫百株累计卵量倒比常规棉处理区增加了 2 16～ 2 74粒 ,增长幅度为 30 %～ 38% ;(2 )转 Bt基因抗虫棉对二代棉铃虫幼虫的抗性及控制作用较强 ,基本不用进行药剂防治 ,但对三代棉虫幼虫的抗性控制效果明显下降 ,田间 3龄以上幼虫平均达2 0～ 4 0头 /百株 ,多者达 6 0头以上 ,仍需进行必要的药剂防治 ;(3)棉铃虫在转 Bt基因抗虫棉株上的危害特点与常规棉株有明显的差异 ,表现在幼虫和危害症状均较隐蔽 ,不易被发现。     

转基因抗草甘膦抗虫棉对棉田冠层节肢动物群落的影响

【背景】随着转基因抗虫棉在我国的广泛种植,一种具有抗虫和耐除草剂（草甘膦）的双价棉被培育成功。这种转双价基因棉和转单价基因抗虫棉对棉田节肢动物群落结构的影响可能不同。因此,在该类转双价基因棉花进行环境释放之前,有必要研究其对棉田节肢动物群落的影响,评价其环境安全性。【方法】试验于2010年5月9日~9月23日和2011年5月10日~9月24日在河南省安阳市中国农业科学院棉花研究所试验农场进行,棉田类型有3种——转基因抗草甘膦抗虫棉田、转Bt棉田和常规棉田,每种棉田种植3个小区,每个小区面积为200 m2（8 m×25 m）。采用对角线5点取样方法,每5 d调查1次棉田的节肢动物群落,通过目测对节肢动物鉴定到属。【结果】抗草甘膦抗虫棉田、Bt棉田和常规棉田节肢动物群落、害虫亚群落和天敌亚群落的结构与组成无明显差异;抗草甘膦抗虫棉田害虫种群数量低于抗虫棉田和常规棉田,而其天敌种群数量与常规棉田相当,略低于Bt棉田;3种棉田节肢动物群落、害虫亚群落和天敌亚群落的多样性指数、均匀性指数均无明显差异。【结论与意义】种植转基因抗草甘膦抗虫棉花不会对棉田节肢动物群落组成造成显著影响。本研究为转基因抗草甘膦抗虫棉田的环境安全性评价提供了依据。     

转Bt基因棉田节肢动物群落营养层及优势功能团的组成与变化

1998年在河北南皮棉区转Bt基因棉棉田和常规棉综防田的生物群落变化的研究表明,与常规棉综防田相比,转Bt基因棉棉田的节肢动物种类增加30.7%,功能团多样性增加66.9%,天敌类和中性节肢动物类的丰富度分别增加97.6%和158.0%,害虫类的丰富度减少45.7%。就功能团的种群数量来看,主要害虫棉铃虫、蚜虫和蓟马种群数量分别减少98.9%、69.0%和72.6%;而次要害虫害蝽、粉虱、叶蝉类昆虫的种群数量分别增加了2.2、3.2和14.8倍,棉花生长中期,转Bt基因棉棉田中的基位物种丰富度大于中位和顶位物种;常规棉田中的差异则更大,出现天敌控制“空缺”。综合分析表明,转Bt基因棉棉田生态系统比常规棉综防田稳定;转Bt基因棉棉田的中性节肢动物和次要害虫在害虫－天敌的营养链中起到了重要的调控作用。     

Bt棉田边缘杂草带对棉田内叶螨发生的影响

2003～2004年,在冀南棉区系统研究了棉田边缘杂草带对棉田内叶螨发生的影响。试验设3个处理：转Bt基因棉化防田(使用杀螨剂控制棉叶螨且保留棉田边缘杂草)、转Bt基因棉对照田(保留棉田边缘杂草)和转Bt基因棉除草田(去除棉田边缘杂草)。结果表明,2003年6月28日～8月7日,处理间的叶螨发生量和有螨株率差异明显。2003年叶螨发生高峰期(7月28日),对照田的百株平均螨量达834头,分别是化防田、除草田的9.4倍和11.5倍;对照田的有螨株率的峰值为34.7%,分别高于化防田和除草田6.4%和12%;棉叶螨的总计值,对照田分别是化防田和除草田的5.8倍和5.5倍。2004年7月10日～8月29日,对照田的百株螨量和有螨株率明显高于除草田和化防田。2004年叶螨发生高峰期（8月10日）,对照田的百株平均螨量达1 222头,分别是化防田、除草田的4.3倍和23.4倍;对照田的有螨株率的峰值达100%,分别比除草田和化防田多75%和87%;棉叶螨的总计值,对照田分别是化防田和除草田的4.9和9.7倍。两年中,除草田和化防田的百株螨量和有螨株率峰值出现日期有所不同。对照田内,棉田边缘杂草至所调查的棉株距离同螨害指数呈显著(P＜0.05)或极显著(P＜0.01)的负相关。本研究表明,去除棉田边缘杂草的棉田,叶螨发生始期较晚且发生量较少;棉田边缘杂草到取样点的距离与棉叶螨的为害程度呈直线负相关,距离越近,叶螨的发生为害越重。     

两种防治措施下转Bt基因棉田绿盲蝽的发生与为害

2002年在河北省南皮县对2种防治措施下转Bt基因田绿盲蝽LyguslucorumMayre的发生与为害进行的系统调查表明,采用生物农药和低毒化学农药防治4次,Bt棉田绿盲蝽的发生为害较为严重,9月上旬发生高峰期种群密度为7.2头10株,显著高于防治指标,第2代绿盲蝽为害高峰期,叶片被害率为19.4%;采用当地棉农化学防治方法施用农药7次,Bt棉田绿盲蝽发生为害较轻,发生高峰期(8月中旬)种群密度为2.0头10株,第2代绿盲蝽为害高峰期,叶片被害率为4.8%。讨论指出绿盲蝽已成为转Bt基因棉生产中的重要问题,应加快绿盲蝽在转Bt基因棉田的生态调控研究。     

湖北棉区转Bt基因棉对棉铃虫的控制作用

2000-2001年通过田间系统调查,表明转Bt基因棉（品种为GK19）在湖北江汉平原棉区对棉铃虫抗性稳定。试验设3个处理：转Bt基因棉化防田（使用化学农药控制害虫）、转Bt基因棉自控田（依靠天敌控制害虫）及常规棉对照田（利用综合防治措施控制害虫）。从棉铃虫的第2代到第5代整个发生期内,即使在不进行化学防治的情况下,棉铃虫在Bt棉田的发生量也保持在极低的水平(最高百株虫量为12头)。室内饲养结果表明,转Bt基因棉对棉铃虫的生长发育（幼虫体重、蛹重）有较为明显的影响,使6龄幼虫体重减少25.6%,蛹重减少18.2%。棉铃虫幼虫取食转Bt基因棉组织后,发育迟缓,相对于常规棉喂养的整个发育历期延长17 d,使棉铃虫在田间的危害减少至少一个世代。另外,接虫试验表明,棉铃虫幼虫在常规棉上的取食时间是转Bt基因棉株上的6.1倍,极大地减轻了棉铃虫的危害程度。     

Measuring gene flow in the cultivation of transgenic cotton (Gossypium hirsutum L.)

Transgenic Bt cotton NewCott 33B and transgenic tfd A cotton TFD were chosen to evaluate pollen dispersal frequency and distance of transgenic cotton (Gossypium hirsutum L.) in the Huanghe Valley Cotton-producing Zone, China. The objective was to evaluate the efficacy of biosafety procedures used to reduce pollen movement. A field test plot of transgenic cotton (6×6 m) was planted in the middle of a nontransgenic field measuring 210×210 m. The results indicated that the pollen of Bt cotton or tfd A cotton could be dispersed into the environment. Out-crossing was highest within the central test plot where progeny from nontransgenic plants, immediately adjacent to transgenic plants, had resistant plant progeny at frequencies up to 10.48%. Dispersal frequency decreased significantly and exponentially as dispersal distance increased. The flow frequency and distance of tfd A and Bt genes were similar, but the pollen-mediated gene flow of tfd A cotton was higher and further to the transgenic block than that of Bt cotton (χ² = 11.712, 1 degree of freedom, p<0.001). For the tfd A gene, out-crossing ranged from 10.13% at 1 m to 0.04% at 50 m from the transgenic plants. For the Bt gene, out-crossing ranged from 8.16% at 1 m to 0.08% at 20 m from the transgenic plants. These data were fit to a power curve model: y=10.1321x ^−1.4133 with a correlation coefficient of 0.999, and y=8.0031x ^−1.483 with a correlation coefficient of 0.998, respectively. In this experiment, the farthest distance of pollen dispersal from transgenic cotton was 50 m. These results indicate that a 60-m buffer zone would serve to limit dispersal of transgenic pollen from small-scale field tests.     

Frequency and distance of pollen dispersal from transgenic oilseed rape (Brassica napus)

The objective of this study was to evaluate pollen dispersal inBrassica napus (oilseed rape). The selectable marker, used to follow pollen movement, was a dominant transgene (bar) conferring resistance to the herbicide glufosinate-ammonium. Transgenic and non-transgenic plants of the cultivar Westar were planted in a 1.1 ha field trial, with the transgenic plants in a 9 m diameter circle at the centre, surrounded by non-transgenic plants to a distance of at least 47 m in all directions. A 1 m circle of non-transgenic plants was sown in the centre of the transgenic area to allow estimation of the level of pollen dispersal when plants were in close contact. Honeybee hives were placed at the trial site to optimize the opportunity for cross-pollination. During the flowering period, regular observations were made of the number of plants flowering and the number and type of insects present in 60 1 m² areas. These areas were located uniformly around the plot at distances of 1, 3, 6, 12, 24, 36 and 47 m from the edge of the 9 m circle of transgenic plants. Seed samples were harvested from each of the 7 distances so that approximately 20% of the circumference of the plot was sampled at each distance. The centre non-transgenic circle was also sampled. Plants were grown from the seed samples and sprayed with glufosinate to estimate the frequency of pollen dispersal at each distance. In order to screen enough samples to detect low frequency cross-pollination events, seed samples were tested in the greenhouse and on a larger scale in the field. Results were confirmed by testing progeny for glufosinate resistance and by Southern blot analysis. The estimated percentage of pollen dispersal in the non-transgenic centre circle was 4.8%. The frequency was estimated to be 1.5% at a distance of 1 m and 0.4% at 3 m. The frequency decreased sharply to 0.02% at 12 m and was only 0.00033% at 47 m. No obvious directional effects were detected that could be ascribed to wind or insect activity.     

Pollen dispersal from two field trials of transgenic cotton in the Namoi Valley,Australia

The testing of transgenic crops in the field is a necessary part of the validation of genetically engineered cultivars, but in the early stages of testing, biosafety procedures must be carefully monitored to ensure that the modified plants do not have deleterious effects on the environment. This study was carried out over two seasons to determine the effectiveness of containment procedures under australian environmental conditions by measuring the dispersal of pollen amay from a test plot of transgenic cotton into a surrounding buffer field of non-transgenic cotton plants whose function was to act as a sink for pollen carried by nectar feeding and pollen-gathering insects. Dispersal was estimated by measuring the frequency of the dominant selectable marker transgene, neomycin phosphotransferase (NptII) in the progeny of the buffer plants. The presence of nptii was determined by a sensitive radioactive enzyme assay. Pollen dispersal was low in both years, but increased with an increase in the size of the source plot in the second year. In the first year outcrossing averaged from 0.15% of progeny at 1 m to below 0.08% at 4 m from the test plot. Outcrossing was highest within the central test plot where progeny from non-transgenic control plants, immediately adjacent to transgenic plants, had transgenic progeny at frequencies of up to 1.7%. In the second year, with a bigger source of transgenic plants, outcrossing declined on average from 0.4% at 1 m to below 0.03% at 16 m into the buffer zone. These results indicate that 20 m buffer zones would serve to limit dispersal of transgenic pollen from small-scale field tests.     

Astylus atromaculatus (Coleoptera: Melyridae): abundance and role in pollen dispersal in Bt and non-Bt cotton in South Africa

In South Africa, modified Bt (Cry1 Ac) cotton cultivars and organic ones coexist. This raises the question of the risk of dissemination of genetically modified (GM) pollen to non-GM crops by visiting insects. We inventoried the flower-visiting insects in Bt and non-Bt cotton fields of the South African Highveld region and investigated their role in pollen dispersal. Their diversity and abundance varied slightly among sites, with Astylus atromaculatus as the predominant insect on both Bt and non-Bt cotton flowers. The other major flower-visiting species were Apis mellifera and solitary Apidae. No differences were found in the abundance of each taxum between Bt and non-Bt cotton except for Scoliidae and Nitidulidae, which were scarce overall (<0.5%) but more abundant on the non-Bt flowers in the central area of the field at one site. The pollen load on A. atromaculatus was as high as on Apis mellifera. Cage tests showed that A. atromaculatus can pollinate female cotton plants by transferring pollen from male donor plants. In the field, the flight range of this insect was generally short (25 m), but it can occasionally reach up to 200 m or even more. This study therefore highlights that A. atromaculatus, commonly regarded as a pest, could be an unexpected but efficient pollinator. Because its population density can be high, this species could mediate unwanted cotton pollen flow when distances between coexiting fields are not sufficient.     

Gene flow in maize fields with different local pollen densities

The development of maize (Zea mays L.) varieties as factories of pharmaceutical and industrial compounds has renewed interest in controlling pollen dispersal. The objective of this study was to compare gene flow into maize fields of different local pollen densities under the same environmental conditions. Two fields of approximately 36 ha were planted with a nontransgenic, white hybrid, in Ankeny, Iowa, USA. In the center of both fields, a 1-ha plot of a yellow-seeded stacked RR/Bt transgenic hybrid was planted as a pollen source. Before flowering, the white receiver maize of one field was detasseled in a 4:1 ratio to reduce the local pollen density (RPD). The percentage of outcross in the field with RPD was 42.2%, 6.3%, and 1.3% at 1, 10, and 35 m from the central plot, respectively. The percentage of outcross in the white maize with normal pollen density (NPD) was 30.1%, 2.7%, and 0.4%, respectively, at these distances. At distances greater than 100 m, the outcross frequency decreased below 0.1 and 0.03% in the field with RPD and NPD, respectively. A statistical model was used to compare pollen dispersal based on observed outcross percentages. The likelihood ratio test confirmed that the models of outcrossing in the two fields were significantly different (P is practically 0). Results indicated that when local pollen is low, the incoming pollen has a competitive advantage and the level of outcross is significantly greater than when the local pollen is abundant. This journal paper of the Iowa Agricultural and Home Economics Experiment Station, Ames, Iowa, Project No. 3638, was supported by Hatch Act, State of Iowa fund and by a USDA-CREES BRA Grant.     

Long‐distance dispersal in a fire‐ and livestock‐protected savanna

Savannas are highly diverse and dynamic environments that can shift to forest formations due to protection policies. Long‐distance dispersal may shape the genetic structure of these new closed forest formations. We analyzed eight microsatellite loci using a single‐time approach to understand contemporary pollen and effective seed dispersal of the tropical tree, Copaifera langsdorffii Desf. (Fabaceae), occurring in a Brazilian fire‐ and livestock‐protected savanna. We sampled all adult trees found within a 10.24 ha permanent plot, young trees within a subplot of 1.44 ha and open‐pollinated seeds. We detected a very high level of genetic diversity among the three generations in the studied plot. Parentage analysis revealed high pollen immigration rate (0.64) and a mean contemporary pollen dispersal distance of 74 m. In addition, half‐sib production was 1.8 times higher than full‐sibs in significant higher distances, indicating foraging activity preference for different trees at long distances. There was a significant and negative correlation between diameter at breast height (DBH) of the pollen donor with the number of seeds (r = ?0.640, P‐value = 0.032), suggesting that pollen donor trees with a higher DBH produce less seeds. The mean distance of realized seed dispersal (recruitment kernel) was 135 m due to the large home range dispersers (birds and mammals) in the area. The small magnitude of spatial genetic structure found in young trees may be a consequence of overlapping seed shadows and increased tree density. Our results show the positive side of closed canopy expansion, where animal activities regarding pollination and seed dispersal are extremely high.     

Gene flow from transgenic to nontransgenic soybean plants in the Cerrado region of Brazil

Evaluation of transgenic crops under field conditions is a fundamental step for the production of genetically engineered varieties. In order to determine if there is pollen dispersal from transgenic to nontransgenic soybean plants, a field release experiment was conducted in the Cerrado region of Brazil. Nontransgenic plants were cultivated in plots surrounding Roundup Ready transgenic plants carrying the cp4 epsps gene, which confers herbicide tolerance against glyphosate herbicide, and pollen dispersal was evaluated by checking for the dominant gene. The percentage of cross-pollination was calculated as a fraction of herbicide-tolerant and -nontolerant plants. The greatest amount of transgenic pollen dispersion was observed in the first row, located at one meter from the central (transgenic) plot, with a 0.52% average frequency. The frequency of pollen dispersion decreased to 0.12% in row 2, reaching 0% when the plants were up to 10 m distance from the central plot. Under these conditions pollen flow was higher for a short distance. This fact suggests that the management necessary to avoid cross-pollination from transgenic to nontransgenic plants in the seed production fields should be similar to the procedures currently utilized to produce commercial seeds.     

Investigating Pollen and Gene Flow of WYMV-Resistant Transgenic Wheat N12-1 Using a Dwarf Male-Sterile Line as the Pollen Receptor

Pollen-mediated gene flow (PMGF) is the main mode of transgene flow in flowering plants. The study of pollen and gene flow of transgenic wheat can help to establish the corresponding strategy for preventing transgene escape and contamination between compatible genotypes in wheat. To investigate the pollen dispersal and gene flow frequency in various directions and distances around the pollen source and detect the association between frequency of transgene flow and pollen density from transgenic wheat, a concentric circle design was adopted to conduct a field experiment using transgenic wheat with resistance to wheat yellow mosaic virus (WYMV) as the pollen donor and dwarf male-sterile wheat as the pollen receptor. The results showed that the pollen and gene flow of transgenic wheat varied significantly among the different compass sectors. A higher pollen density and gene flow frequency was observed in the downwind SW and W sectors, with average frequencies of transgene flow of 26.37 and 23.69% respectively. The pollen and gene flow of transgenic wheat declined dramatically with increasing distance from its source. Most of the pollen grains concentrated within 5 m and only a few pollen grains were detected beyond 30 m. The percentage of transgene flow was the highest where adjacent to the pollen source, with an average of 48.24% for all eight compass directions at 0 m distance. Transgene flow was reduced to 50% and 95% between 1.61 to 3.15 m, and 10.71 to 20.93 m, respectively. Our results suggest that climate conditions, especially wind direction, may significantly affect pollen dispersal and gene flow of wheat. The isolation-by-distance model is one of the most effective methods for achieving stringent transgene confinement in wheat. The frequency of transgene flow is directly correlated with the relative density of GM pollen grains in air currents, and pollen competition may be a major factor influencing transgene flow.     

Fat-tailed gene flow in the dioecious canopy tree species Fraxinus mandshurica var. japonica revealed by microsatellites

Pollen flow, seed dispersal and individual reproductive success can be simultaneously estimated from the genotypes of adults and offspring using stochastic models. Using four polymorphic microsatellite loci, gene flow of the wind-pollinated and wind-seed-dispersed dioecious tree species, Fraxinus mandshurica var. japonica, was quantified in a riparian forest, in northern Japan. In a 10.5-ha plot, 74 female adults, 76 male adults and 292 current-year seedlings were mapped and genotyped, together with 200 seeds. To estimate dispersal kernels of pollen and seeds, we applied normal, exponential power, Weibull, bivariate t-distribution kernels, and two-component models consisting of two normal distribution functions, one with a small and one with a large variance. A two-component pollen flow model with a small contribution (26.1%) from short-distance dispersal (sigma = 7.2 m), and the rest from long-distance flow (sigma = 209.9 m), was chosen for the best-fitting model. The average distance that integrated pollen flows inside and outside the study plot was estimated to be 196.8 m. Tree size and flowering intensity affected reproduction, and there appeared to be critical values that distinguished reproductively successful and unsuccessful adults. In contrast, the gene flow model that estimated both pollen and seed dispersal from established seedlings resulted in extensive seed dispersal, and the expected spatial genetic structures did not satisfactorily fit with the observations, even for the selected model. Our results advanced small-scale individual-based parentage analysis for quantifying fat-tailed gene flow in wind-mediated species, but also clarified its limitations and suggested future possibilities for gene flow studies.     

黑河上游灌丛建群种中国沙棘自由授粉子代父本分析和花粉流

利用SSR分子标记对中国沙棘（Hippophae rhamnoides ssp. sinensis Rousi）自由授粉的种子进行父本分析,研究其子代的父本来源和花粉散布模式。结果显示：在80%的置信水平上,193个子代中有104个个体可以确定花粉来源;在20个确定的父本中,16个为中国沙棘,4个为肋果沙棘（H.neurocarpa S.W.Liu et T.N.He）。传粉格局分析结果显示,中国沙棘有效花粉散布范围为3~71 m,平均距离为20.4 m,2株母本分别有87.23%和78.95%的有效花粉来自距其30 m的范围之内,研究结果表明中国沙棘自然种群以近距离传粉为主。此外,在黑河上游沙棘杂交带中,中国沙棘子代中的肋果沙棘花粉平均贡献率达到14.84%,表明中国沙棘与肋果沙棘存在较高的种间当代花粉流。