茄子栽培种砧用种质农业生物学性状及嫁接适用性研究

青枯病是热带亚热带地区普遍发生的一种土传病害,为选配具有优良抗病性和嫁接适用性的茄子砧木杂交组合,该研究对国内外11份茄子栽培种砧用种质进行农业生物学评价和青枯病抗病性鉴定,研究了不同砧用种质对嫁接苗生长的影响。结果表明:供试砧用种质中,果型为卵圆形5份、倒卵形2份、长卵圆4份;幼果颜色紫色7份、淡紫色1份、绿色1份、淡绿色2份;老熟果实颜色均为黄色;种质J14、J15、J16、J17的主茎紫色,其余均为绿色;J61的花瓣白色,其余均为紫色或淡紫色。供试砧木种质与接穗Rf的嫁接成活率均在80%以上,最高达97%。采用苗期伤根-浸根接种法鉴定砧木种质对青枯病的抗病性,有9份砧用种质自根苗表现高抗(HR),病情指数为3.67~12.33,其中6份砧木种质(BC01、BC03、BC04、BC06、J15、J16)嫁接感病接穗后表现抗病(R),病情指数为16.67~21.00。砧用种质能显著改善接穗的生长,其中,BC01、BC03、BC04、BC06、J15、J16的嫁接苗的生物量增长率显著高于其他种质的嫁接苗。综合试验结果显示茄子栽培种砧用种质农业生物学性状表现多样性,可区分为不同生态类型。抗病砧木种质嫁接高感病接穗的防病效果显著,种质BC01、BC03、BC04、BC06、J15、J16高抗青枯病,嫁接高感病品种表现抗青枯病,可作为配制抗青枯病砧木杂交组合的候选亲本。     

嫁接西瓜对西瓜枯萎病菌侵染的防御机制研究

为了揭示嫁接提高西瓜抗枯萎病的机制,该研究以嫁接西瓜为材料,采用扫描电镜观察了枯萎病菌侵染下寄主的组织结构变化,荧光定量分析了相关防卫基因的表达,比较了嫁接西瓜对枯萎病菌侵染的抗感反应。结果显示:(1)枯萎病菌侵染后,与自根西瓜相比,嫁接西瓜的根部木质部导管通过快速形成膜状物、侵填体及细胞壁增厚阻塞菌丝入侵;自根西瓜防御反应较嫁接西瓜晚,严重侵染时薄壁细胞降解,导管组织脱落导致维管系统空洞,从而使植株呈现萎蔫症状,该现象在嫁接西瓜中没有发现。(2)枯萎病菌侵染后,嫁接西瓜比自根西瓜具有较高的防卫基因表达水平,其中:嫁接西瓜中,CHI、APX和PPO基因的表达随枯萎病菌侵染时间的延长而升高,而PAL呈现先升高后降低的表达趋势,但仍高于本底表达;自根西瓜中,仅PPO基因在枯萎病菌侵染后表达上调,而其他基因的表达则是先升高后降低,与嫁接西瓜中的PAL基因表达一致。研究表明,嫁接植株一方面通过快速的组织结构响应,另一方面从转录水平提高了相关防卫基因的表达,最终使植株具有抗病性;推测防御基因在嫁接植株与枯萎病菌互作中的强烈诱导响应可能是嫁接植株抗病的分子机制之一。     

绿豆种质资源枯萎病抗性鉴定及抗性资源筛选北大核心CSCD

绿豆枯萎病是影响绿豆产量最严重的病害之一。筛选苗期抗性资源,培育抗病品种对枯萎病防治具有重要意义。本研究采用剪根浸根接种法,对来自全国18个省市及国外的215份绿豆核心种质资源和85份绿豆新品系进行了苗期枯萎病抗性鉴定。结果显示,不同地区种质间的枯萎病抗性水平存在差异。国内产区中,东北、华东、华中地区约50%的种质具有枯萎病抗性;华北地区抗枯萎病种质占比40.4%;西北、西南和华南地区种质抗病水平较高;国外材料抗病种质占比40.0%。本研究共筛选出17份高抗(HR)枯萎病种质资源,并利用部分材料建立了枯萎病抗性研究RIL群体;6份高抗高代品系材料,在田间全生育期表现高抗且农艺性状优异。本研究期望为今后抗枯萎病绿豆新品种选育及抗性遗传相关研究提供优异资源和理论依据。     

秋海棠抗性育种初探

通过杂交育种提高秋海棠植物抗病性等抗逆能力。采用抗病亲本与具观赏性的易感病亲本杂交,F1自交两代使抗病性状纯合稳定,获得具观赏性、抗病的类型。连续回交将抗病性转移到具可看性而易感病的亲本中,培育出目的新品种;根据亲本性状互补的原则,结合杂种优势F1的利用,选择秋海棠属内不同组、不同生态型,抗逆性差异显著的原始材料进行远缘杂交,选育出观赏价值高、抗逆能力强的适应型新品种。通过30多个亲本组合的杂交选育,对6个典型组合亲本、子代的性状及表型分析研究,以及子代群体生长势、病情指数、抗性等级的测定,对秋海棠属植物的抗性育种作了初步探讨。     

18份广东香蕉种质对枯萎病的抗性评价

【背景】香蕉枯萎病是世界性的香蕉毁灭性病害,尚无有效药剂防控,筛选抗病品种是目前理想的防治方法。【方法】采用组培苗伤根接种法,研究了18份香蕉种质对香蕉枯萎病菌4号生理小种的抗性水平,并根据病情指数进行抗性分级。【结果】在供试的18份香蕉种质中,2份(东莞大蕉、抗枯5号)高抗,2份(碧盛、大丰)抗病,3份(抗枯1号、粉杂、农科1号)中抗,7份(粤优抗1号、广东-741、泰国B9、大蕉、台湾8号、海贡蕉、威廉斯8818)感病,4份(巴西、广东2号、广粉1号、粉蕉)高感。【结论与意义】不同香蕉种质对香蕉枯萎病菌4号生理小种的抗病性存在较大差异,本研究初步筛选出7份抗枯萎病的香蕉种质,为香蕉枯萎病抗病育种提供了依据,为病区种植香蕉品种提供了有效参考。     

细胞壁羟脯氨酸和游离脯氨酸与棉花对枯萎病抗性的关系

氟乐灵处理能推迟棉苗枯萎病症状的出现、降低发病株率和病情指数,说明氟乐灵处理能提高棉酋对枯萎病的抗性。在健康棉苗中,抗病品种（中棉１２）细胞壁结合的羟脯氨酸含量显著高于感病品种（６０３７）,但游离脯氨酸含量无明显差异。在氟乐灵处理和未处理而接种棉枯萎病菌的两个处理中,两个品种的细胞壁结合的羟脯氨酸和游离脯氨酸含量均高于各自的健康株对照,而且抗病品种中的含量都高于感病品种,说明细胞壁结合的羟脯氨酸和游禹脯氨酸的积累是氟乐灵诱发的抗病性表现及棉苗受枯萎病菌侵染后抗性反应的生化机制之一。     

芝麻营养生长期枯萎病抗性鉴定技术研究

芝麻枯萎病是芝麻主要真菌病害之一,由尖孢镰刀菌芝麻专化型(FOS,Fusarium oxysporum f.sp.sesami)引起,主要在苗期和成株期发生。为精准评价营养生长时期(2对真叶~现蕾)芝麻种质对FOS菌株的抗性水平,试验分析了FOS菌液浓度、蘸根接菌时间、致病力等条件下芝麻种质枯萎病病症及病情指数变化规律,建立了营养生长期芝麻枯萎病抗性精准鉴定方法。结果表明,1×10^6 cfu/mL^5×10^6 cfu/mL浓度下,植株蘸根接菌处理1~2周即可发病;第4周样本枯萎病病情指数趋于稳定。上述方法反映不同芝麻种质营养生长期对FOS菌株的抗性水平以及不同FOS菌株的致病力。营养生长期芝麻枯萎病发生可分为0~4级共5个等级。采用上述鉴定方法对42份芝麻种质进行抗枯萎病鉴定结果显示,野生种Sesamum radiatum Thonn.ex Hornem.高抗枯萎病(DI=0),而S.angustifolium(Oliv.)Engl.高感枯萎病(DI=100)。40份栽培种资源中,高感(HS)种质比例极高(55%),抗病种质比例较低(27.5%)。研究结果为深入开展芝麻抗枯萎病遗传机理分析提供了技术支持。     

分子标记辅助选育抗水稻条纹叶枯病的‘红血糯’种质

为了改良水稻‘红血糯’品种对条纹叶枯病的抗性,将‘秦稻2号’、‘香糯Q33’、‘青香糯’作为抗性的供体亲本配制杂交组合;同时选取了ST10、H21和STS11-43等3对显性分子标记用于亲本和F2群体田间抗病性的分子标记辅助检测。结果显示:(1)不同分子标记在亲本中的多态性不同,标记H21和STS11-43只有在‘红血糯’和‘香糯Q33’之间具有多态性,标记ST10在‘红血糯’与‘秦稻2号’、‘香糯Q33’、‘青香糯’之间都有多态性。(2)各个分子标记在不同杂交组合F2群体的室内分子检测显示,部分F2单株携带抗性基因条带,也有个别单株含有杂合抗病基因条带。(3)田间发病抗性检测显示,含有抗性基因的植株基本不发病,携带抗性基因的单株与田间发病情况调查结果基本相符,但对含有杂合抗病基因条带的抗病单株,其还需2~3代田间观察,纯化抗病基因。研究表明,分子检测结果与田间抗病性检测结果相符,3种分子标记可以用于‘红血糯’杂交后代的分子标记辅助检测,为改良‘红血糯’的条纹叶枯病抗性育种提供了可行的方法。     

大蒜根系分泌物的化感作用

以苍山白蒜和蔡家坡紫蒜为材料,采用水培方法收集根系分泌物,研究了2个大蒜品种的根系分泌物对莴苣种子发芽和幼苗生长及对黄瓜枯萎病菌、西瓜枯萎病菌的化感效应.结果表明:2个大蒜品种的根系分泌物对莴苣种子发芽和幼苗生长均表现为低浓度(0.1、0.2 g·mL-1)促进、高浓度(0.4、0.6 g·mL-1)抑制,高浓度时蔡家坡紫蒜的抑制作用大于苍山白蒜;对黄瓜枯萎病菌和西瓜枯萎病菌的菌丝生长及孢子萌发均表现为抑制作用,随着根系分泌物浓度的提高,抑制作用增强,其中黄瓜枯萎病菌较敏感,且蔡家坡紫蒜的抑制作用大于苍山白蒜.     

离体筛选抗枯萎病辣椒新种质

以2个辣椒(Capsicum annuum L.)自交系子叶诱导产生的愈伤组织为材料,辣椒枯萎菌粗毒素为选择剂,筛选抗枯萎病辣椒新种质.结果表明,枯萎菌粗毒素对辣椒子叶愈伤组织诱导、生长及不定芽分化具有明显的抑制作用,且随着粗毒素浓度的增加,抑制作用增强;在枯萎菌粗毒素质量浓度为0.60 g·L-1条件下,筛选、鉴定并获得了抗枯萎病辣椒体细胞变异无性系,且成功再生抗性植株.从而证明,离体筛选抗枯萎病辣椒新种质的方法是可行的.     

Suppression of Fusarium wilt of watermelon by a bio-organic fertilizer containing combinations of antagonistic microorganisms

Fusarium wilt of watermelon commonly occurs in locations where the crop has been grown for many seasons. Its occurrence results in a severely decreased watermelon crop. The goal of this study was to assess the capability of a new product (bio-organic fertilizer) to control the wilt in Fusarium-infested soil. Pot experiments were conducted under growth chamber and greenhouse conditions. The results showed that the fertilizer controlled the wilt disease. Compared with control pots, the incidence rates of Fusarium wilt at 27 and 63 days following treatment of the plants with the bio-organic fertilizer at a rate of 0.5% (organic fertilizer + antagonistic microorganisms, including 3 × 10⁹ CFU g⁻¹ Paenibacillus polymyxa and 5 × 10⁷ CFU g⁻¹ Trichoderma harzianum) were reduced by 84.9 and 75.0%, respectively, in both the growth chamber and greenhouse settings. The activities of antioxidases (catalase, superoxide dismutase and peroxidase) in watermelon leaves increased by 38.9, 150 and 250%, respectively. In the roots, stems and leaves, the activity of β-1,3-glucanase (pathogenesis-related proteins) increased by 80, 1140 and 100% and that of chitinase increased by 240, 80, and 20%, respectively, while the contents of malondialdehyde fell by 56.8, 42.1 and 45.9%, respectively. These results indicate that this new fertilizer formula is capable of protecting watermelon from Fusarium oxysporum f.sp. niveum. The elevated levels of defense-related enzymes are consistent with the induction and enhancement of systemic acquired resistance of plant.

Management Fusarium wilt on melon and watermelon by Penicillium oxalicum

The potential of the biological control fungus Penicillium oxalicum to suppress wilt caused by Fusarium oxysporum f. sp. melonis and F. oxysporum f. sp. niveum on melon and watermelon, respectively, was tested under different growth conditions. The area under disease progress curve of F. oxysporum f. sp. melonis infected melon plants was significantly reduced in growth chamber and field experiments. In glasshouse experiments, it was necessary to apply P. oxalicum and dazomet in order to reduce Fusarium wilt severity in melons caused by F. oxysporum f. sp. melonis. For watermelons, we found that P. oxalicum alone reduced the area under the disease progress curve by 58% in the growth chamber experiments and 54% in the glasshouse experiments. From these results, we suggested that P. oxalicum may be effective for the management of Fusarium wilt in melon and watermelon plants.     

Effects of Commercial and Indigenous Microorganisms on Fusarium Wilt Development in Chickpea

The purpose of this research was to determine whetherBacillus subtilis,nonpathogenicFusarium oxysporum,and/orTrichoderma harzianum,applied alone or in combination to chickpea (Cicer arietinumL.) cultivars ‘ICCV 4’ and ‘PV 61’ differing in their levels of resistance to Fusarium wilt, could effectively suppress disease caused by the highly virulent race 5 ofFusarium oxysporumf. sp.ciceris.Seeds of both cultivars were sown in soil amended with the three microbial antagonists, alone or in combination, and 7 days later seedlings were transplanted into soil infested with the pathogen. All three antagonistic microorganisms effectively colonized the roots of both chickpea cultivars, whether alone or in combination, and significantly suppressed Fusarium wilt development. In comparison with the control, the incubation period for the disease was delayed on average about 3 days and the final disease severity index and standardized area under the disease progress curve were reduced significantly between 14 and 33% and 16 and 42%, respectively, by all three microbial antagonists. Final disease incidence only was reduced byB. subtilis(18–25%) or nonpathogenicF. oxysporum(18%). The extent of disease suppression was higher and more consistent in ‘PV 61’ than in ‘ICCV 4’ whether colonized byB. subtilis,nonpathogenicF. oxysporum,orT. harzianum.The combination ofB. subtilis+T. harzianumwas effective in suppressing Fusarium wilt development but it did not differ significantly from treatments with either of these antagonists alone. In contrast, the combination ofB. subtilis+ nonpathogenicF. oxysporumtreatment was not effective but either antagonist alone significantly reduced disease development.     

Molecular mapping of wilt resistance genes in chickpea

Fusarium wilt is a widespread and serious chickpea disease caused by the soil-borne fungus Fusarium oxysporum f.sp. ciceri (Foc). We evaluated an F₉ recombinant inbred line population of chickpea for resistance to three Foc races (1, 2 and 3) in pot culture experiments and identified flanking and tightly linked DNA markers for the resistance genes. The simple sequence repeat markers H3A12 and TA110 flanked the Foc1 locus at 3.9 and 2.1 cM, respectively, while Foc2 was mapped 0.2 cM from TA96 and 2.7 cM from H3A12. The H1B06y and TA194 markers flanked the Foc3 locus at 0.2 and 0.7 cM, respectively. These markers were also validated using 16 diverse chickpea genotypes. Identification of tightly linked flanking markers for wilt resistance genes will be useful for their exploitation in breeding programs and to understand the mechanism of resistance and evolution of the genes. S. J. M. Gowda and P. Radhika contributed equally to this study.     

西瓜抗枯萎病育种分子标辅助选择的研究

将西瓜野生种质ＰＩ２９６３４１抗枯萎病生理小种１的抗性基因连锁的ＲＡＰＤ标记ＯＰＰ０１．７００进行克隆、测序,Ｓｏｕｔｈｅｒｎ杂交证明此标记为１个单拷贝,并转化为ＳＣＡＲ标记,简化了ＳＣＡＲ扩增产物的检测技术。上述技术在抗病转育后代造反中得到了很好的应用,初步建立了西瓜抗枯萎病育种分子标记辅助选择技术系统。     

Development of SCAR markers linked to powdery mildew (<Emphasis Type="Italic">Uncinula necator</Emphasis>) resistance in grapevine (<Emphasis Type="Italic">Vitis vinifera</Emphasis> L. and <Emphasis Type="Italic">Vitis</Emphasis> sp.)

Sequence-characterized amplified regions markers (SCARs) were developed from six randomly amplified polymorphic DNA (RAPD) markers linked to the major QTL region for powdery mildew (Uncinula necator) resistance in a test population derived from the cross of grapevine cultivars “Regent” (resistant) × “Lemberger”(susceptible). RAPD products were cloned and sequenced. Primer pairs with at least 21 nucleotides primer length were designed. All pairs were tested in the F1 progeny of “Regent” × “Lemberger”. The SCAR primers resulted in the amplification of specific bands of expected sizes and were tested in additional genetic resources of resistant and susceptible germplasm. All SCAR primer pairs resulted in the amplification of specific fragments. Two of the SCAR markers named ScORA7-760 and ScORN3-R produced amplification products predominantly in resistant individuals and were found to correlate to disease resistance. ScORA7-760, in particular, is suitable for marker-assisted selection for powdery mildew resistance and to facilitate pyramiding powdery mildew resistance genes from various sources.     

甘蔗与斑茅BC1分子鉴定、抗黑穗病和花叶病初步评价

为了解甘蔗(Saccharum)与斑茅(Erianthus arundinaceus)杂交后代作为抗病亲本的利用价值,通过特异引物PCR鉴定出78份甘蔗与斑茅杂交BC_1真实杂种;通过人工接种花叶病毒和黑穗病菌,初步评价了甘蔗和斑茅杂交BC_1的抗病表现。结果表明,甘蔗和斑茅杂交BC_1的抗花叶病具有普遍性,而黑穗病抗性则出现分离。初步筛选出BC_1无性系YCE01-48、YCE01-71、YCE01-105、YCE01-125、YCE02-184和YCE01-118可同时抗花叶病和黑穗病,有望成为甘蔗杂交利用的高抗病源亲本。     

Tolerance to higher temperature byAspergillus nidulans and its possible implication in biological control of wilt disease of pigeon-pea

Summary During the course of studies on the ecology ofFusarium udum Butler, the incitant of wilt disease of pigeon-pea (Cajanus cajan (L.) Millsp.),Aspergillus nidulans was found to tolerate higher temperatures of summer, and other species includingF. udum were suppressed in field soil. The population ofA. nidulans increased in the soil incubated at 40±2°C at pH6 and 7 while the population ofF. udum was highly suppressed. The wilt disease of pigeon-pea was significantly suppressed at 38±2°C in the soil having a mixture of the inocula ofF. udum andA. nidulans whereas at lower temperature (25±2°C) no significant impact ofA. nidulans on the disease was found. On the basis of this study an integrated use of higher temperature, alkaline pH andA. nidulans has been suggested for biological control of wilt disease of pigeon-pea.     

Overexpression of defense response genes in transgenic wheat enhances resistance to Fusarium head blight

Fusarium head blight (FHB) of wheat, caused by Fusarium graminearum and other Fusarium species, is a major disease problem for wheat production worldwide. To combat this problem, large-scale breeding efforts have been established. Although progress has been made through standard breeding approaches, the level of resistance attained is insufficient to withstand epidemic conditions. Genetic engineering provides an alternative approach to enhance the level of resistance. Many defense response genes are induced in wheat during F. graminearum infection and may play a role in reducing FHB. The objectives of this study were (1) to develop transgenic wheat overexpressing the defense response genes α-1-purothionin, thaumatin-like protein 1 (tlp-1), and β-1,3-glucanase; and (2) to test the resultant transgenic wheat lines against F. graminearum infection under greenhouse and field conditions. Using the wheat cultivar Bobwhite, we developed one, two, and four lines carrying the α-1-purothionin, tlp-1, and β-1,3-glucanase transgenes, respectively, that had statistically significant reductions in FHB severity in greenhouse evaluations. We tested these seven transgenic lines under field conditions for percent FHB disease severity, deoxynivalenol (DON) mycotoxin accumulation, and percent visually scabby kernels (VSK). Six of the seven lines differed from the nontransgenic parental Bobwhite line for at least one of the disease traits. A β-1,3-glucanase transgenic line had enhanced resistance, showing lower FHB severity, DON concentration, and percent VSK compared to Bobwhite. Taken together, the results showed that overexpression of defense response genes in wheat could enhance the FHB resistance in both greenhouse and field conditions.