美味猕猴桃优良株系“实美”的砧木选择研究

美味猕猴桃优良株系“实美”的接穗嫁接于 1 0个不同种类的砧木上 ,观测其嫁接体的亲和力、生长特性、开花结果习性、抗逆性、产量、果实品质等。结果表明 :“实美”以中华猕猴桃桂海 4号为砧木 ,具有良好的亲和力 ,嫁接成活率达 1 0 0 % ,接合部位断裂率仅 5 % ;5年生植株保存率 1 0 0 % ,生长指数高达 0 .9,病死株率为 0 ;物候期相对稳定 ,萌芽率和结果枝率高 ;连续 3年的平均产量极显著地高于其它 9种砧木的产量 ;果实内含物丰富 ,品质优良。根据观测结果 ,可以认为中华猕猴桃桂海 4号是“实美”的优良砧木。     

猕猴桃嫁接试验

本文报道猕猴桃不同嫁接时期、嫁接方法和不同分类群的砧木试验结果,猕猴桃最适宜的嫁接时期是落叶后至翌年萌芽前,嫁接方法以切接为好,嫁接成活率均在90％以上。同种和同一分类群的砧穗间有良好的亲和力,嫁接均有较高的成活率。不同分类群间嫁接效果较差,如中华猕猴桃桂海4号嫁接于中华猕猴桃砧木上的成活率,生长情况均比嫁接其它分类群为砧的有显著差异。     

不同嫁接方法对猕猴桃成活率的影响

以野生美味猕猴桃1年生苗木作砧木,猕猴桃新品种金魁1年生枝条作接穗,进行不同嫁接方法试验。结果表明:舌接、单芽枝腹接成活率高达98.4%、96.1%,嫁接苗生长势旺,新苗基粗、新梢长度、新梢叶片数均显著高于其它几种嫁接苗。该法操作简便,是猕猴桃理想的嫁接方法,可在生产中推广应用。     

经济植物无性繁殖讲座(四) 提高嫁接成活率的新技术

砧木和 接穗的亲和 力、生活力 和嫁接技术 是嫁接成活的三个因素,缺一不可。 嫁接亲和力 亲和力是指砧木和接穗能够愈合生长成一个整体的能力,是嫁接繁殖中最重要而复杂的问题。根据有无亲和力可以分成三种类型。 有亲和力 植物亲缘关系近的亲和力强。同一个种内的不同品种间互相嫁接多数是亲和的。同一个属内种间嫁接有多数能成功。例如:     

核桃嫁接技术在提升核桃产量中的应用

核桃嫁接技术在保证嫁接成活率和提高核桃产量方面有着较为重要的作用。本文首先分析了影响嫁接成活率的因素,包括砧接穗的质量、砧木和接穗的亲和力、嫁接伤口流量、环境因素以及穗条的处理等。其次,对嫁接前的准备工作进行了介绍,包括砧木培育和选择接穗标准。最后,对嫁接过程中的关键技术进行了分析,包括劈接技术、削接穗技术和插接穗技术等。     

番茄‘Ls-89’和‘坂砧2号’幼苗活性氧代谢对南方根结线虫侵染的反应

为了解番茄(Lycopersicon esculentum)砧木幼苗活性氧代谢与抗南方根结线虫(Meloidogyne incognita)的关系,以高感品种‘Ls-89’与高抗品种‘坂砧2号’为材料,采用盆栽人工接种法,研究了南方根结线虫侵染对番茄砧木幼苗活性氧代谢的影响。结果表明,未接种南方根结线虫的番茄砧木幼苗,其根系与叶片活性氧水平及相关酶活性在品种间没有显著差异。接种南方根结线虫后,两品种幼苗根系与叶片的O_2·~–生成速率和H_2O_2含量均升高,且‘坂砧2号’显著高于‘Ls-89’,但‘Ls-89’的MDA含量则显著高于‘坂砧2号’。两品种幼苗根系与叶片的SOD活性均在侵染早期降低,以‘坂砧2号’降幅较大;但POD、CAT活性在侵染早期变化不大,至侵染中后期则显著升高。因此,番茄抗性品种砧木幼苗的膜脂抗氧化能力较强,活性氧水平较高,且SOD活性对南方根结线虫侵染敏感。     

提高沙田抽茎尖嫁接成活率的研究

研究了可以影响沙田抽茎嫁接成活率的部分因素。结果表明：当沙田抽接穗选择带4个叶原基的茎尖、枳壳砧木选择黑暗培养14d的实生苗或培养基中蔗糖浓度选择7．5％时各自的嫁接成活率较高,若在茎尖嫁接切口外缠绕parafilm胶可令成活率明显增加。若在培养基中加入GA3、6－BA和IBA则明显抑制嫁接成活率。GA3、6－BA和IBA处理接穗和砧木均可提高嫁接成活率,其中以10mg/LGA3处理效果最好,嫁接成活率可达45％;6－BA和IBA处理虽然也可提高嫁接成活率,但是同时又增加了接穗的脱落死亡率。     

提高沙田柚茎尖嫁接成活率的研究

研究了可以影响沙田柚茎尖嫁接成活率的部分因素。结果表明 :当沙田柚接穗选择带 4个叶原基的茎尖、枳壳砧木选择黑暗培养 1 4d的实生苗或培养基中蔗糖浓度选择 7.5 %时各自的嫁接成活率较高。若在茎尖嫁接切口外缠绕 parafilm胶可令成活率明显增加。若在培养基中加入 GA3、6-BA和 IBA则明显抑制嫁接成活率。GA3、6-BA和 IBA处理接穗和砧木均可提高嫁接成活率 ,其中以 1 0 mg/L GA3处理效果最好 ,嫁接成活率可达 45 % ;6-BA和 IBA处理虽然也可提高嫁接成活率 ,但是同时又增加了接穗的脱落死亡率。     

猕猴桃种间及种内杂交亲和性研究

以3个种的9个猕猴桃品种为试材,通过培养法比较它们的花粉活力,用荧光显微镜观察猕猴桃种间与种内杂交亲和性,并统计其亲和指数及坐果率,为猕猴桃的杂交育种以及最佳授粉树的选配提供依据.结果表明:猕猴桃花粉活力在种间表现为美味猕猴桃＞中华猕猴桃＞狗枣猕猴桃;中华猕猴桃和美味猕猴桃种间和种内杂交组合的柱头识别反应快,花粉在柱头粘附多、生长快且萌发率高、亲和性较强且坐果率较高,而用狗枣猕猴桃与中华猕猴桃和美味猕猴桃种间杂交的花粉在柱头上萌发生长发育缓慢,其亲和性弱,平均坐果率仅为19.81%;30个杂交组合中亲和指数最高的是'金阳'×'金阳'雄株,亲和指数为960.33,坐果率为95.56%,最低的是'狗枣'×'金阳'雄株,亲和指数201.60,坐果率为12.22%.研究发现,猕猴桃的种间亲和性小于种内亲和性,同种内不同品种间的亲和性与坐果率也不同.     

番茄抗青枯病种苗选育初步研究

通过大量收集野生茄科植物作为栽培番茄的嫁接砧木 ,进行嫁接试验并观察嫁接成活率。栽植各砧木苗、番茄实生苗及嫁接成活率较高的嫁接苗 ,观察比较它们在自然条件下青枯病的发病率 (如果自然条件下青枯病发病率低的地块 ,可考虑人工接种病原 )、植株生长情况、产量和品质等 ,筛选出 2种嫁接成活率高 ,抗青枯病能力强 ,并能保持或提高接穗果产量和品质的番茄嫁接砧木。为深入进行番茄抗青枯病种苗选育研究和生产实践奠定了基础。     

猕猴桃野生居群的SSR分析初报

采用SSR分子标记技术对我国猕猴桃的2个商业栽培物种——中华猕猴桃和美味猕猴桃的9个天然居群(共221个样)的遗传多样性进行了初步分析。通过对14对猕猴桃引物的筛选,8对重现性好的引物扩增结果表现出良好的多态性。在8个多态性位点上共获得222个等位基因。居群等位基因平均数A=17．3,多态位点百分率P-100,多态信息指数PIC为0．87～0．96,显示出我国的猕猴桃野生居群具有极高的遗传多样性。中华猕猴桃和美味猕猴桃野生居群拥有高比例的共同等位基因,反映出二者的亲缘关系极近。     

Hydraulic conductance and rootstock effects in grafted vines of kiwifruit

Whole-plant hydraulic conductance, shoot growth, and leaf photosynthetic properties were measured on kiwifruit vines with four clonal rootstocks to examine the relationship between plant hydraulic conductance and leaf stomatal conductance (gs) and to test the hypothesis that reduced hydraulic conductance can provide an explanation for reductions in plant vigour caused by rootstocks. The rootstocks were selected from four species of Actinidia and grafted with Actinidia chinensis var. chinensis 'Hort16A' (yellow kiwifruit) as the scion. Total leaf area of the scion on the least vigorous Actinidia rootstock, A. kolomikta, was 25% of the most vigorous, A. hemsleyana. Based on shoot growth and leaf area, the selections of A. kolomikta and A. polygama are low-vigour rootstocks, and A. macrosperma and A. hemsleyana are high-vigour rootstocks for A. chinensis. Whole-plant hydraulic conductance, the ratio of xylem sap flux to xylem water potential, was lower in the low-vigour rootstocks, reflecting their smaller size. However, leaf-area-specific conductance (Kl) and gs were both higher in the low-vigour rootstocks, the opposite of the expected pattern. Differences in Kl were found in the compartment from the roots to the scion stem, with no difference between rootstocks in the conductance of stems or leaves of the scion. There was no evidence that the graft union caused a significant reduction in hydraulic conductance of vines with low-vigour rootstocks. Leaf photosynthetic capacity did not vary between rootstocks, but photosynthesis and carbon isotope discrimination (Delta13C) under ambient conditions were higher in the low-vigour rootstocks because gs was higher. gs and Delta13C were positively correlated with Kl, although the mechanism for this relationship was not based on stomatal regulation of a similar xylem water potential because water potential varied between rootstocks. For Actinidia rootstocks, changes in Kl do not provide a direct explanation for changes in vigour of the scion. However, depending on the rootstock in question, changes in hydraulic conductance, biomass partitioning, and crown structure are involved in the response.     

中华猕猴桃和美味猕猴桃自然居群遗传结构及其种间杂交渐渗

 利用9对SSR引物对中华猕猴桃（Actinidia chinensis）和美味猕猴桃（A. deliciosa）两近缘种的5个同域分布复合体和各自1个非同域分布居群进行了遗传多样性、居群遗传结构的分析以及种间杂交渐渗的探讨。结果表明：1）两物种共有等位基因比例高达81.13%,物种特有等位基因较少（中华猕猴桃：13.27%,美味猕猴桃：5.61%）,但共享等位基因表型频率在两近缘种间存在差异,而且与各同域复合体中两物种样本的交错程度或间距存在关联;2）两种猕猴桃均具有极高遗传多样性,美味猕猴桃的遗传多样性（H_o＝0 .749, PIC＝0.818）都略高于中华猕猴桃（H_o＝0.686,PIC＝0.799）;3）两猕 猴桃物种均具有较低的Nei’s居群遗传分化度,但AMOVA分析结果揭示种内异域居群间（F_ST=0.091 5）和同域复合体种间（F_ST=0.111 5）均存在一定程度的遗传分化;中华猕猴桃居群遗传分化（G_ST=0.086; F_ST=0.212 1）高于美味猕猴桃（G_ST= 0.080;F_ST=0.142 0）;4）同域分布复合体两物种间的遗传分化（G_ST=0.020）低于物种内异域居群间的遗传分化（中华猕猴桃：G_ST=0.086; 美味猕猴桃：G_ST=0.080）,同域复合体物种间的基因流（N_m＝7.89 -29.75）远远高于 同种异域居群间（中华猕猴桃：N_m =2.663; 美味猕猴桃：N_m=2.880）; 5）居群UPGMA聚类揭示在同一地域的居群优先聚类,个体聚类结果显示多数个体聚在各自居群组内,但各地理居群并不按地理距离的远近聚类,这与Mantel相关性检测所揭示的居群间遗传距离与地理距离没有显著性相关的结果一致。进一步分析表明两种猕猴桃的遗传多样性和居群遗传结构不仅受其广域分布、远交、晚期分化等生活史特性的影响,同时还与猕猴桃的染色体基数高 (x=29)、倍性复杂和种间杂交等因素密切相关,其中两种猕猴桃的共享祖先多态性和同域分布种间杂交基因渗透对两猕猴桃的居群遗传结构产生了重要影响。     

猕猴桃属种间体细胞杂种

利用PEG融合方法,分别进行了中华猕猴桃(Actinidia chinensis var.chinensis)(2n=2x=58)子叶愈伤组织来源的原生质体与美味猕猴桃(A.deliciosa var.deiciosa)(2n=6x=174)子叶愈伤组织原生质体、以及狗枣猕猴桃(A.kolomikta)(2n=2x=58)叶肉原生质体种间原生质体融合。结果表明:中华猕猴桃与美味猕猴桃融合的1个克隆和中华猕猴桃与狗枣猕猴桃融合的4个克隆的RAPD谱带分别具有双亲特异的DNA谱带;经流式细胞仪分析,前者细胞核倍性推测为8倍体,后者细胞核为3倍体、4倍体和5倍体。初步鉴定这5个克隆是猕猴桃属种间体细胞杂种。     

中华猕猴桃硬毛变种学名订正

<正> 我们最近仔细研读了法国学者A.Chevalier在1940年和1941年连续发表的两篇文章,确认他在头篇文章中描述的Aetinidia latifolia Merr. var. deliciosa A. Chev. 和第二篇文章中改为Actinidia chinensis Planch.var. deliciosa A. Chev.的植物与梁畴芬1975年发表的Actinidia chinensis Planch. var. hispida C. F. Liang为同一植物。根据国际植物命名法规优先律,应承认A.Chevalier发表的名称为正名。 我们又研究了这一种植物与Actinidia chinensis Planch.相区别的特征,认为这种猕猴桃应被视为一个独立的物种。现特把它和它的两个变型作出如下的学名订正处理。     

用分支分析方法研究中华猕猴桃与美味猕猴桃的亲缘关系

本文根据形态特征和染色体资料,以毛花猕猴桃为外类群,用分支分析法研究美味猕猴桃与中华猕猴桃(含二倍体和四倍体)的亲缘关系,产生了三个步长相等的Wagner树。其中一树能较好地与现有地理分布和细胞学资料吻合。反映出中华猕猴桃二倍体衍生出四倍体类型,二者具有直接祖裔关系:美味猕猴桃与中华猕猴桃是已分支发展的两个分类群,但二者亲缘关系密切。可能属于同一物种复合体的两个近缘物种。     

‘LD-1'砧米良一号猕猴桃的耐涝性

猕猴桃是一类不耐涝的植物,为了解决猕猴桃的涝害问题,吉首大学近年来尝试用‘LD-1’作为猕猴桃的耐涝性砧木。该研究以米良一号实生苗砧米良一号猕猴桃和‘LD-1’砧米良一号猕猴桃为材料,观测根系淹水后叶片可溶性糖含量、丙二醛含量、叶绿素含量、可溶性蛋白质含量、SOD 活性和形态的变化规律,探讨了‘LD-1’砧米良一号猕猴桃的耐涝性。结果表明：(1)米良一号实生苗砧米良一号猕猴桃根系淹水后,可溶性糖含量6 d 后极显著(P<0.01)升高;丙二醛含量8 d 后显著(P<0.05)升高;叶绿素含量和可溶性蛋白质含量没有显著变化;SOD 活性6 d 后显著(P<0.05)升高,8 d 后不再有显著变化;叶片2 d 后出现轻度萎蔫,10 d后全部枯死。(2)‘LD-1’砧米良一号猕猴桃根系淹水后,可溶性糖的含量4 d 后显著(P<0.05)升高;丙二醛含量、叶绿素含量、可溶性蛋白质含量和 SOD 活性无显著变化;叶片10 d 后未出现显著的萎蔫和枯死现象,30 d 后仍正常。这说明米良一号实生苗砧米良一号猕猴桃耐涝性较弱,‘LD-1’砧米良一号猕猴桃耐涝性较强,‘LD-1’作砧木显著增强了米良一号猕猴桃的耐涝性。该研究结果为‘LD-1’在米良一号猕猴桃栽培上的应用提供了依据。     

Pepper Rootstock Graft Compatibility and Response to Meloidogyne javanica and M. incognita

Resistance of pepper species (Capsicum annuum, C. baccatum, C. chinense, C. chacoense, and C. frutescens), cultivars and accessions to the root-knot nematodes Meloidogyne incognita race 2 and M. javanica, and their graft compatibility with commercial pepper varieties as rootstocks were evaluated in growth chamber and greenhouse experiments. Most of the plants tested were highly resistant to M. javanica but susceptible to M. incognita. Capsicum annuum AR-96023 and C. frutescens accessions as rootstocks showed moderate and relatively high resistance to M. incognita, respectively. In M. incognita-infested soil in a greenhouse, AR-96023 supported approximately 6-fold less nematode eggs per gram root and produced about 2-fold greater yield compared to a nongrafted commercial variety. The commercial variety grafted on AR-96023 produced a yield as great as the non-grafted variety in the root-knot nematode-free greenhouse. Some resistant varieties and accessions used as rootstocks produced lower yields (P < 0.01) than that of the non-grafted variety in the noninfested greenhouse. Use of rootstocks with nematode-resistance and graft compatibility may be effective for control of root-knot nematodes on susceptible pepper.     

What drives interspecies graft union success? Exploring the role of phylogenetic relatedness and stem anatomy

The underlying mechanisms that determine whether two species can form a successful graft union (graft compatibility) remain obscure. Two prominent hypotheses are (1) the more closely related species are, the higher the graft success and (2) the vascular anatomy at the graft junction influences graft success. In this paper these two hypotheses are examined in a systematic way using graft combinations selected from a range of (a) phylogenetically close and more distant legume species, (b) species displaying different germination patterns and (c) scions and rootstocks possessing contrasting stem tissues and vascular patterns. Relatedness of species was not a good predictor of graft compatibility, as vascular reconnection can occur between distantly related species and can fail to occur in some more closely related species. Similarly, neither the stem tissues present at the graft junction nor the vascular anatomy correlated with the success of vascular reconnection. Relatedness and stem anatomy therefore do not appear to be the determining factors in successful vascular reconnection after grafting in legumes. These results are discussed in conjunction with other hypotheses such as the role of auxin.