高油酸花生新品种宇花91的选育

宇花91是青岛农业大学选育的高油酸花生新品种。以普通油酸含量品种鲁花11号为母本,F435型高油酸花生品种开农1715为父本配置杂交组合。利用PCR产物测序法筛选获得F_1代真杂种,对F_2代单株提取叶片基因组DNA,利用PCR产物测序法筛选基因型纯合的单株个体。对当代收获的单株籽粒利用近红外法多粒模型测定油酸、亚油酸含量,筛选油酸含量在80%以上且油酸亚油酸比值在10.0以上的单株种植成株行,随后利用系谱法进行选择育种。宇花91荚果为普通型小果,网纹较细、较明显,百果重148.06 g,百仁重63.31 g,果皮薄,出米率75.15%。籽仁长椭圆形,种皮粉红色、无裂纹,内种皮白色。籽仁蛋白质含量26.57%,脂肪含量52.72%,油酸含量80.40%,亚油酸含量2.50%,棕榈酸含量5.57%,油酸亚油酸比值32.16。苗期生长旺盛,封垄早,结果集中,中抗叶斑病和青枯病。2017年参加山东省夏播多点试验,平均荚果产量215.79 kg/667 m~2,比对照花育20号增产15.27%;平均籽仁产量157.33kg/667m~2,比对照花育20号增产21.64%。2018年通过国家花生品种登记,登记号:GPD花生(2018) 370210,适于在山东花生产区种植。     

美国花生微核心种质资源纯化系的引进与表型评价

花生种质资源是花生新品种选育和重要农艺性状遗传研究的基础材料。引进国外优异花生种质资源,并对其进行鉴定和评价对发掘优良花生种质、丰富我国花生资源遗传多样性以及合理利用种质资源进行遗传改良具有重要意义。本研究于2014-2015年连续2年在河北保定对104份引进的美国花生微核心种质资源纯化系进行了农艺性状考察和抗病性鉴定。鉴定结果表明,美国微核心种质纯化系多为匍匐型,主茎高变异范围为24.50~89.50 cm,侧枝长为39.37~99.23 cm,单株果数和单株果重分别为8.75~46.33个和8.49~29.54 g,百果重为80.76~216.72 g,单株粒数为18.25~58.00个,单株粒重为9.89~33.36 g,百仁重为25.52~74.18 g,出仁率为52.58%~76.08%。抗病性鉴定表明,部分美国微核心种质资源纯化系高抗褐斑病和网斑病,性状优良。该研究结果为花生新品种选育与遗传研究提供了优异材料和参考信息。     

白色种皮花生皮色及农艺性状遗传的研究

为育成白色种皮的高产花生品种,了解白色种皮的遗传规律,用自育的白皮1号品种与在福建省生产上推广的红皮良种粤油116、汕油对和泉花10号进行杂交,杂种F1植株的种皮全为红色．F2红皮植株与白皮植株的分离比例符合15:1的分离规律,红皮F2代的F3代株系中,有4/15株系符合红：白为3:1的分离比例。由此推断白皮性状是两对隐性基因控制,白皮性状与产量性状没有连锁。主要农艺性状的遗传力顺序为：单株结果数＞单株饱果重和生物产量＞单株饱果数。经F3代、F4和F5代的株系鉴定,选出稳定、综合性状优良的重组类型;再经过产量鉴定和多点比较试验,选出了丰产性较好的二个品种参加福建省花生新品种区域试验．     

花生种质资源表型性状的综合评价及指标筛选

分析花生种质资源表型性状的变异规律,构建花生种质资源的综合评价体系,筛选最优的评价指标。本研究以40份花生种质资源的17个表型性状为研究对象,利用变异系数与Shannon-Weaver指数对表型性状的多样性进行分析,采用聚类分析、主成分分析以及逐步回归分析对花生种质资源进行了综合评价和鉴定指标的筛选。结果表明:17个表型性状的变异系数变化范围为4.15%~31.82%,油酸、亚油酸以及蔗糖含量等性状变异丰富,出仁率、粗脂肪及蛋白质含量等性状较稳定;多样性指数变化范围为1.39~2.06,主茎高、百仁重及蛋白质含量等性状分布比较均匀,油酸、亚油酸及棕榈酸等性状分级及分布较不均匀。聚类分析把40份花生种质资源分为4个类群。主成分分析把17个表型性状归为5个主成分(累计贡献率80.41%,反映出17个表型性状的大部分信息),依次为花生籽粒含油量因子、籽粒含糖量因子及丰产性因子,以上因子可以较准确的评价花生种质。花生种质表型性状的综合评价由F值大小判定,F值均值为0.73,开农176的F值最高,阜花12号的F值最低。由逐步回归分析筛选出8个表型性状:单株鲜果重、百果重、出仁率、粗脂肪、蛋白质含量、棕榈酸、油酸和蔗糖含量。花生种质资源遗传多样性较丰富,综合评价F值可以为花生种质资源评价提供参考,筛选的8个表型性状可以作为花生种质资源性状评价指标。     

富γ-氨基丁酸水稻种质筛选及与子粒性状相关性分析

利用高效液相色谱法,测定了108份水稻种质资源材料子粒中的γ-氨基丁酸含量,分析了不同种质资源材料间γ-氨基丁酸含量差异及与子粒性状的相关性,以γ-氨基丁酸含量差异较大的高粱稻-1与宁农黑粳配制杂交组合,测定亲本、杂交F1及216个F2子粒中的γ-氨基丁酸含量,分析其含量与相对胚重和子粒性状的相关性及变异系数,估算各性状的广义遗传力。结果表明:108份种质资源材料子粒中的γ-氨基丁酸含量变异范围为2.39~12.03 mg/100g,,平均含量为6.30±1.99 mg/100g,变异系数为31.59%;不同水稻种质资源材料子粒中的γ-氨基丁酸含量与粒厚、千粒重呈极显著的负相关;杂交F1子粒γ-氨基丁酸含量为8.39±0.11 mg/100g,介于双亲之间;F2单株子粒中的γ-氨基丁酸含量总体呈偏正态分布,且出现明显的超亲现象,说明水稻子粒中的γ-氨基丁酸含量是由多基因控制的数量性状遗传;杂交F2子粒中的γ-氨基丁酸含量与相对胚重呈极显著的正相关,与粒厚、千粒重呈极显著的负相关,与粒长呈显著的负相关;F2单株子粒中的γ-氨基丁酸含量、粒厚和千粒重的广义遗传力相对较高,分别为98.12%、91.99%、96.37%,在育种中对这些性状可进行早期选择。     

高油酸花生（Arachis hypogaea L.）杂交后代ahFAD2B的基因鉴评

本研究利用等位基因特异性PCR技术(AS-PCR,allele-specific PCR)对高油酸父本CTWE与4个低油酸母本组配的330个杂交后代进行分子鉴评,其中230个获得了539 bp的特异性条带。白沙1016×CTWE、海花1号×CTWE、冀0212-2×CTWE以及远杂9847×CTWE的真杂种百分率分别为83.3%、50.0%、57.1%和50.0%。本研究采用单粒近红外光谱分析法对F2:3家系进行检测,结果表明远杂9847×CTWE、白沙1016×CTWE、冀0212-2×CTWE以及海花1号×CTWE的F2:3家系中,全部为高油酸类型的家系分别为9个、8个、2个和3个,推断F2群体中,基因型为FAD2B-m/FAD2B-m的个体的比例为9.47%、4.17%、3.39%和3.37%。4个杂交组合高油酸性状的遗传在P=0.05水平上符合2对基因的遗传模式。本研究结果对于高油酸性状的分子鉴定、高油酸花生新品种的培育以及育种效率的提高具有一定的参考价值。     

高油酸花生(Arachis hypogaea L.)杂交后代ahFAD2B基因的分子标记辅助选择

本研究利用等位基因特异性PCR技术(AS-PCR,allele-specific PCR)对高油酸父本CTWE与4个低油酸母本组配的330个杂交后代进行分子鉴评,其中230个获得了539 bp的特异性条带。白沙1016×CTWE、海花1号×CTWE、冀0212-2×CTWE以及远杂9847×CTWE的真杂种百分率分别为83.3%、50.0%、57.1%和50.0%。本研究采用单粒近红外光谱分析法对F2:3家系进行检测,结果表明远杂9847×CTWE、白沙1016×CTWE、冀0212-2×CTWE以及海花1号×CTWE的F2:3家系中,全部为高油酸类型的家系分别为9个、8个、2个和3个,推断F2群体中,基因型为FAD2B-m/FAD2B-m的个体的比例为9.47%、4.17%、3.39%和3.37%。4个杂交组合高油酸性状的遗传在P=0.05水平上符合2对基因的遗传模式。本研究结果对于高油酸性状的分子鉴定、高油酸花生新品种的培育以及育种效率的提高具有一定的参考价值。     

龙生型高油酸花生种质油酸亚油酸含量及其比值的遗传分析

应用植物数量性状主基因+多基因混合遗传模型,对2个龙生型花生高油酸种质与低油酸珍珠豆型品种杂交组合F2的油酸、亚油酸含量及其比值(O/L值)进行遗传分析,结果表明:花生油酸、亚油酸含量的遗传均表现为1对主基因加性-显性模型。控制油酸含量主基因的加性、显性效应值和遗传率在组合I中分别为8.6281、-2.0164和65.26%,在组合II中则分别为10.6638、1.0652和71.39%;控制亚油酸含量主基因的加性、显性效应值和遗传率在组合I中分别为8.0327、1.2858和73.64%,在组合II中则分别为9.0885、-1.0826和71.59%。O/L值的遗传表现为2对主基因加性-显性-上位性模型。2对主基因的加性效应值分别为0.6855、0.6814(组合I)和1.6842、0.8835(组合II),显性效应值分别为-0.6838、0.024(组合I)和-1.6559、-0.5127(组合II);加性×加性效应(i)、加性×显性效应(jab)、显性×加性效应(jba)、显性×显性效应(l)分别为0.6812、0.024、-0.6803、-0.0244(组合I)和0.8822、-0.5124、-0.8594、0.496(组合II);组合I、II主基因遗传率分别为82.57%和88.64%。     

花生AhFAD2基因抑制表达的转基因后代分析

FAD2(Δ~(12) fatty acid desaturase,Δ~(12)FAD或FAD2)是催化油酸在脂肪酸碳链Δ~(12)位脱氢生成亚油酸的关键酶。在花生中,FAD2酶活性下降或失活可提高籽粒中油酸的相对含量,改善花生籽粒及制品的品质和氧化稳定性。通过将种子特异性表达Lectin启动子和Ca MV35S启动子驱动的倒位重复Ah FAD2基因RNAi干扰结构转入花生,获得了以丰花1号(FH1)和花育23(HY23)为受体、携带上述2种转化结构、稳定遗传的花生转基因纯合体株系,转基因花生主要农艺性状与非转基因对照基本一致。实时荧光定量分析发现,各转基因株系发育种子中Ah FAD2基因的转录水平普遍下调。气相色谱法进一步测定了部分转基因后代株系种子的脂肪酸含量及组成,籽粒中油酸含量分别平均提高了15.09%(HY23为受体)、36.40%(FH1为受体),相应地,亚油酸含量平均下降了16.19%、29.81%,油亚比平均增加了38.02%、98.10%。各转基因株系的油酸含量显著提高;且在以FH1为受体的转基因株系后代籽粒以及种子特异性启动子驱动的转化结构中,RNAi的抑制效果更明显。通过RNAi技术抑制花生FAD2基因的表达,可以有效提高花生籽粒油酸含量。该技术体系可以为花生品质育种提供借鉴。     

保水剂对露地栽培花生产量和品质的影响

该研究设置覆膜和露地施用不同量保水剂处理(75kg·km~(-2)、150kg·km~(-2)、225kg·km~(-2)),以露地栽培为对照,研究不同保水剂用量和覆膜对花生荚果成熟饱满度、产量和营养品质的影响,为旱地花生合理使用保水剂及开发新型节水栽培技术提供理论依据。结果显示:(1)保水剂施用量在75～225kg·hm~(-2),花生荚果产量较对照提高3.48%～16.01%,且随施用量增加呈先增加后降低的趋势,其中150kg·hm~(-2)保水剂处理的花生产量最高,但与覆膜处理差异不显著。(2)覆膜显著增加了花生成熟饱满度,饱果率和饱仁率分别比对照增加14.62%和14.11%;成熟饱满度随保水剂用量增加呈先增加后降低的趋势,且150kg·hm~(-2)保水剂处理最高,饱果率和饱仁率分别比对照增加10.99%和15.99%。(3)覆膜和保水剂均增加了花生脂肪、油酸含量和油酸/亚油酸(O/L)比值,普通样品(能够形成产量的籽仁)的增幅显著大于标准样品(饱满一致的籽仁),且150kg·hm~(-2)处理的普通样品分别比露地栽培提高了9.66%、12.27%和23.08%,但与覆膜处理差异不显著。研究表明,施用150kg·hm~(-2)保水剂可显著提高花生成熟饱满度、产量和品质,主要通过提高普通样品的营养成分来改善品质,与覆膜效果基本一致。     

Inheritance of quantitative traits in crosses between two Pisum sativum subspecies with particular reference to their breeding value

The experimental study was conducted during the period of 2008-2010 at the experimental field of the Institute of Forage Crops in Pleven. The hybridization scheme included direct and back crosses covering four varieties of forage pea (Pisum sativum L.), namely two spring ones, Usatii 90 and Kamerton from Ukraine, and a winter one from Bulgaria, Pleven 10. There was analyzed the inheritance of quantitative traits such as plant height, height to first pod, pod number per plant, seed number per plant, seed number per pod, seed weight per plant and number of fertile nodes per plant of parental components (P1 and P2) and both first (F1) and second (F2) hybrid generations. The cross Usatii 90 x Pleven 10 showed the highest real heterosis effect for plant height (8.26%), pods per plant (158.79%), seeds per plant (272.16%), seeds per pod (42.09%), seed weight per plant (432.43%) and number of fertile nodes per plant (117.14%). The cross Pleven 10 x Usatii 90 had the highest real heterosis effect height to first pod (11.06%). In F2 plants, the strongest depression for plant height (5.88%), seeds per plant (57.88%), seeds per pod (55.93%) and seed weight per plant (55.99%) was in the cross Usatii 90 x Pleven 10, for height to first pod (1.47%) in the cross Kamerton x Pleven 10 and for number of fertile nodes per plant (15.91%) in the cross Pleven 10 x Usatii 90. The highest positive degree of transgression for number of fertile nodes per plant (165.64%) and seed weight per plant (162.10%) was in the cross Pleven 10 x Kamerton and for pod number per plant (102.54%) and seeds per plant (99.13%) in Kamerton x Pleven 10. The stability of the characters was determined. Low variability in F1 and F2 was found in plant height (3.97-6.85%). Variability of number seeds per plant in F1 was highest (11.86-33.23%). For all other traits, the variability varied from average to high. A lower narrow-sense heritability coefficient was observed for plant height, height to first pod, pods per plant, seeds per plant and seed weight per plant (from 0.001 to 0.230). In few cases, such as in fertile nodes per plant (0.39 and 0.81) and seeds per pod (0.44), the coefficients ofbroad-sense heritability were higher.     

白藜芦醇在几种植物中各部位的分布

采用液相色谱研究白藜芦醇在紫斑牡丹、花生和巨峰葡萄几种经济植物各部位的分布情况。结果表明紫斑牡丹籽和果荚的含量远高于花生和巨峰葡萄。花生白藜芦醇含量最低。紫斑牡丹、花生和巨峰葡萄各部位白藜芦醇分布情况如下：紫斑牡丹叶、紫斑牡丹侧枝、紫斑牡丹茎和紫斑牡丹根中均不含有白藜芦醇,而紫斑牡丹籽和紫斑牡丹果荚中含有白藜芦醇,其中紫斑牡丹籽白藜芦醇含量为0.87‰,紫斑牡丹果荚白藜芦醇含量为0.26‰。花生叶、花生胚乳和花生胚芽中均不含有白藜芦醇,而花生侧枝、花生壳、花生皮、花生茎、花生侧根、花生主根中含有白藜芦醇含有白藜芦醇,其含量为花生侧枝3 mg·kg^-1、花生茎11 mg·kg^-1、花生壳12 mg·kg^-1、花生皮15 mg·kg^-1、花生侧根5 mg·kg^-1、花生主根10 mg·kg^-1。经检测发现葡萄肉,葡萄皮,葡萄籽,葡萄蒂四部分中含有白藜芦醇,其中葡萄肉白藜芦醇含量为0.017‰,葡萄皮白藜芦醇含量为0.028‰,葡萄籽白藜芦醇含量为0.005‰,葡萄蒂和其邻近枝白藜芦醇含量为0.12‰。检测说明这几种植物中花生皮、花生壳、葡萄皮、葡萄籽、葡萄蒂、牡丹籽、牡丹荚具有一定的药用价值和经济价值。     

Inheritance of a one-seeded pod trait in peanut

Normally, the cultivated peanut (Arachis hypogaea L.) has predominantly 2 seeds per pod or more. Two seeds per pod are predominantly found in A. hypogaea L. subsp. hypogaea var. hypogaea (the botanical classification of the US runner and virginia market types) and in subsp. fastigiata var. vulgaris (the US spanish market type); whereas, predominantly 3 or more seeds per pod are found in subsp. fastigiata vars. fastigiata (the US valencia market type), peruviana (not marketed in the United States), and aequatoriana (not marketed in the United States), and in subsp. hypogaea var. hirsuta (not marketed in the United States). However, recently, predominantly 1 seed per pod selections were found within a Georgia cross population. Crosses involving the 1-seeded pod selection were made to determine its inheritance. The F(1), F(2), and F(3) data indicated that any 2 of 3 duplicate recessive genes designated, osp(1), osp(2), and osp(3), control the 1-seeded pod trait in peanut.     

Seed coat cell turgor in chickpea is independent of changes in plant and pod water potential

Turgor pressure in cells of the pod wall and the seed coat of chickpea (Cicer arietinum L.) were measured directly with a pressure probe on intact plants under initially dry soil conditions, and after the plants were irrigated. The turgor pressure in cells of the pod wall was initially 0.25 MPa, and began to increase within a few minutes of irrigation. By 2-4 h after irrigation, pod wall cell turgor had increased to 0.97 MPa. This increase in turgor was matched closely by increases in the total water potential of both the pod and the stem, as measured by a pressure chamber. However, turgor pressure in cells of the seed coat was relatively low (0.10 MPa) and was essentially unchanged up to 24 h after irrigation (0.13 MPa). These data demonstrate that water exchange is relatively efficient throughout most of the plant body, but not between the pod and the seed. Since both the pod and the seed coat are vascularized tissues of maternal origin, this indicates that at least for chickpea, isolation of the water relations of the embryo from the maternal plant does not depend on the absence of vascular or symplastic connections between the embryo and the maternal plant.     

湖南省饭豆地方种质资源表型多样性评价

依托"第三次全国农作物种质资源普查与收集行动"项目,开展了湖南省饭豆种质资源的考察收集与评价鉴定,并筛选了优异种质,为湖南省饭豆种质资源创新和品种选育提供参考。结果表明,收集到的76份地方资源主要分布在湘西湘南山区,0~600 m的中低海拔地区。15项农艺性状表型分析显示其遗传多样性丰富;主成分分析将15个农艺性状分为4个主成分,其主要与株高、籽粒大小、产量、花色粒色相关,累计贡献率68.330%;聚类分析将76份资源分为2大类群,第Ⅰ类群蔓生、无限结荚,第Ⅱ类群直立、有限结荚,第Ⅰ类群又分为2个亚群,类群Ⅰ-1株型较小,单株产量较低,籽粒较大,类群Ⅰ-2株型较大,单株产量较高,籽粒较小。根据聚类分析结果及数量性状极值和质量性状变异类型提取出22份饭豆特异种质,并从中筛选出3类可以代表类群特征的资源:直立适合密植机收的资源,大粒型优质资源,高产、高生物量的粮肥两用资源。     

Effects of simulated acid rain on oilseed rape (Brassica napus) physiological characteristics at flowering stage and yield

A pot experiment was conducted to study the effects of different acidity simulated acid rain on the physiological characteristics at flowering stage and yield of oilseed rape (B. napus cv. Qinyou 9). Comparing with the control (pH 6.0), weak acidity (pH = 4.0-5.0) simulated acid rain stimulated the rape growth to some extent, but had less effects on the plant biomass, leaf chlorophyll content, photosynthetic characteristics, and yield. With the further increase of acid rain acidity, the plant biomass, leaf chlorophyll content, photosynthetic rate, antioxidative enzyme activities, and non-enzyme antioxidant contents all decreased gradually, while the leaf malonyldialdehyde (MDA) content and relative conductivity increased significantly. As the results, the pod number per plant, seed number per pod, seed weight, and actual yield decreased. However, different yield components showed different sensitivity to simulated acid rain. With the increasing acidity of simulated acid rain, the pod number per plant and the seed number per pod decreased significantly, while the seed weight was less affected.     

两种酚酸类物质对花生根部土壤养分、酶活性和产量的影响

为探讨连作花生土壤中酚酸类物质的累积与花生连作障碍的关系,通过大田盆栽试验,研究了对羟基苯甲酸、肉桂酸对花生花针期(出苗后45 d)、结荚初期(出苗后75 d)、结荚末期(出苗后105 d)根部土壤养分、酶活性及产量的影响.结果表明: 经两种酚酸类物质处理后,花生根部土壤养分和酶活性均发生了明显的变化,以在花针期受到的影响最大,土壤碱解氮、有效磷、有效钾和土壤脲酶、蔗糖酶、中性磷酸酶活性均显著降低;到花生结荚初期和结荚末期,两种物质对土壤养分、酶活性的抑制作用有减弱趋势.初始含量相同时,肉桂酸的化感作用相对较强.高浓度(80 mg·kg^-1干土)对羟基苯甲酸、肉桂酸处理分别使每盆花生荚果产量降低了45.9%、52.8%,单株结果数降低了46.2%、48.9%.     

氮、磷、钾肥不同用量对花生生理特性及产量品质的影响

在田间条件下研究了氮、磷、钾肥不同用量对花生叶片生理特性及产量品质的影响.结果表明:与不施肥处理相比,花生分别单独施用氮、磷、钾肥可提高叶片叶绿素、可溶性蛋白质含量和光合速率,增加SOD、POD和CAT活性,降低MDA积累量,以施N300～450kg.hm-2、施P5O2150～225kg.hm-2、施K2O300～450kg.hm-2的效果最显著;对叶片光合性能的改善,氮肥的作用主要在前期,磷在中后期,钾肥前后期比较一致.施肥可显著提高花生荚果产量,随施氮量的增加花生产量显著提高,施磷、钾肥以中等施肥量(P5O2150kg.hm-2、K2O300kg.hm-2)花生产量最高,钾肥的增产作用大于氮、磷肥.少量施用磷、钾肥(P2O575kg.hm-2、K2O150kg.hm-2)可显著增加花生籽仁蛋白质和脂肪含量,少量施用氮肥(N150kg.hm-2)可显著增加蛋白质含量,大量施用氮肥(N450kg.hm-2)才可显著增加脂肪含量;磷肥对提高籽仁蛋白质和脂肪含量效果明显,氮肥对增加蛋白质含量作用较大,钾肥主要提高了可溶性糖含量.施用氮、磷、钾肥可增加花生籽仁的赖氨酸、蛋氨酸和油酸、亚油酸含量,提高油酸/亚油酸比值,从而改善花生营养品质,延长花生制品的货价寿命.