Pigeonpea improvement: An amalgam of breeding and genomic research     

Sameer Kumar Chanda Venkata  Ganga Rao Nadigatla Veera Prabha Rama  Rachit K. Saxena  Kulbhushan Saxena  Hari D. Upadhyaya  Moses Siambi  Said N. Silim  Kothapally Narasimha Reddy  Anupama J. Hingane  Mamta Sharma  Shivali Sharma  Stephen Dominic Lyimo  Rose Ubwe  Meshack Makenge  Kananji Gad  Paul Kiprotich Kimurto  Manuel Amane  Kennedy Kanenga  Yuventino Obong  Emanuel Monyo  Chris Ojiewo  Nagesh Kumar Mallela Venkata  Jaganmohan Polineni Rao  Prashanthi Lakkireddy  Sudhakar Chourat  Indraprakash Singh  Sobhan Sajja  Shruthi Hirikara Beliappa  Rajeev K. Varshney 《Plant Breeding》2019,138(4):445-454

In the past five decades, constant research has been directed towards yield improvement in pigeonpea resulting in the deployment of several commercially acceptable cultivars in India. Though, the genesis of hybrid technology, the biggest breakthrough, enigma of stagnant productivity still remains unsolved. To sort this productivity disparity, genomic research along with conventional breeding was successfully initiated at ICRISAT. It endowed ample genomic resource providing insight in the pigeonpea genome combating production constraints in a precise and speedy manner. The availability of the draft genome sequence with a large‐scale marker resource, oriented the research towards trait mapping for flowering time, determinacy, fertility restoration, yield attributing traits and photo‐insensitivity. Defined core and mini‐core collection, still eased the pigeonpea breeding being accessible for existing genetic diversity and developing stress resistance. Modern genomic tools like next‐generation sequencing, genome‐wide selection helping in the appraisal of selection efficiency is leading towards next‐generation breeding, an awaited milestone in pigeonpea genetic enhancement. This paper emphasizes the ongoing genetic improvement in pigeonpea with an amalgam of conventional breeding as well as genomic research.  相似文献   

Perspectives on validation in digital soil mapping of continuous attributes—A review     

Kristin Piikki  Johanna Wetterlind  Mats Sderstrm  Bo Stenberg 《Soil Use and Management》2021,37(1):7-21

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茶氨酸合成酶基因的SNP挖掘和遗传定位   总被引：1，自引：0，他引：1  

李小杰  马建强  姚明哲  陈亮 《茶叶科学》2017,37(3)

茶氨酸合成酶(Theanine synthetase,TS)基因是茶树茶氨酸代谢过程中的关键酶基因。本研究以氨基酸含量差异明显的亲本及其杂交所得F_1子代为研究材料,克隆TS基因的c DNA序列,挖掘其SNPs位点,并成功将杂合SNP位点定位在遗传连锁群上。研究结果显示,通过序列比对在亲本间检测到3个SNPs,验证得到1个杂合的位点SNP735。将此位点成功转化为dCAPS标记,该标记在子代中的基因型分离比为1∶1,利用该群体已构建的茶树遗传图谱进行遗传定位,将dCAPS标记定位在连锁群LG03上,相邻标记为TM299和TM517。联合此标记及其相邻标记与游离氨基酸总含量和茶氨酸含量进行统计分析,表明具有显著的相关性。  相似文献   

Digital mapping of soil ecosystem services in Scotland using neural networks and relationship modelling—Part 1: Mapping of soil classes     

Matt J. Aitkenhead  Malcolm C. Coull 《Soil Use and Management》2019,35(2):205-216

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抗旱节水小麦分子遗传育种研究进展     

刘莉  裴磊  卫云宗 《分子植物育种》2020,(1):282-295

干旱缺水等自然灾害会导致小麦产量年度间变幅较大,尤其在小麦主产区黄淮地区更为严重。小麦抗旱节水育种是应对干旱的重大措施。本综述对小麦抗旱节水常规育种、抗旱节水分子遗传育种相关性状QTL定位、抗旱相关功能基因克隆鉴定、转基因等方面的研究进展进行了综述。水旱亲本杂交与异地交叉选择是卓有成效的常规育种方法,通过分子标记鉴定了关于根重、根长、胚芽鞘、高水分利用效率等相关性状的大量QTL;42个抗旱相关基因被克隆并进行基因功能分析和验证,均从不同代谢通路上影响着小麦抗旱性;14个来自不同供体的抗旱相关基因被研究者导入小麦品种后,转基因小麦植株的抗旱能力均得到不同程度的提高,部分植株在产量和其它抗逆性方面也得到提高。以上研究进展为抗旱节水小麦分子设计育种提供了理论依据和发展方向。  相似文献   

福建省林木良种繁育概况及今后工作设想     

邱进清 《福建林业科技》1996,(Z1)

本文介绍了福建省林木种质资源的收集保存、研究利用，优良家系选育，树种内种源研究，高世代种子园研究，乡土树种栽培驯化，外来树种引种，提高种子园种子产量所采取的措施，无性繁殖技术等林木良种繁育概况；并就林木育种工作存在的问题及今后工作设想提出建设性意见。  相似文献   

一种适合稻区紫云英生产实际的紫云英加工调制方式   总被引：1，自引：0，他引：1  

闫景彩  屠敏仪  王继成 《草业科学》2001,18(1):78-80,F003

将紫云英鲜草分离为草汁、细渣、纤维状渣；以粉状能量精料为载体吸收汁液；3种制品都以晾晒的方式进行干燥。晾晒时，3种制品综合占场面积较原草减少近90％；3种制品均可在一个晴日内风干，比原草干燥速度提高一倍余；细渣品质与国标一级苜蓿草粉相当；“二次拌汁料”、“三次拌汁料”之粗蛋白、粗纤维含量符合生长肥育猪饲养标准；加工方式切合稻区紫云英生产实际及产区综合条件，有推广价值，且易推广。  相似文献   

In situ radiometric mapping of soil erosion and field-moist bulk density on cultivated fields     

A.N. Tyler  D.A. Davidson  I.C. Grieve 《Soil Use and Management》2001,17(2):88-96

Abstract. Recent developments in in situγ ray spectrometry offer a new approach to measuring the activity of radionuclides such as ¹³⁷Cs and ⁴⁰K in soils, and thus estimating erosion or deposition rates and field moist bulk density (ρ_m). Such estimates would be rapid and involve minimal site disturbance, especially important where archaeological remains are present. This paper presents the results of a pilot investigation of an eroded field in Scotland in which a portable hyper pure germanium (HPGe) detector was used to measure γ ray spectra in situ. The gamma (γ) photon flux observed at the soil surface is a function of the ¹³⁷Cs inventory, its depth distribution characteristics and ρ_m. A coefficient, Q_Cs, derived from the forward scattering of ¹³⁷Cs γ ray photons within the soil profile relative to the ¹³⁷Cs full energy peak (662 keV), was used to correct the in situ calibration for changes in the ¹³⁷Cs vertical distribution in the ploughed field, a function of tillage, soil accumulation and ρ_m. Based on only 8 measurements, the agreement between in situγ ray spectrometry and soil sample measurements of ¹³⁷Cs inventories improved from a non significant r²=0.05 to a significant r²=0.62 (P<0.05). Erosion and deposition rates calculated from the corrected in situ¹³⁷Cs measurements had a similarly good agreement with those calculated from soil cores. Mean soil bulk density was also calculated using a separate coefficient, Q_K, derived from the forward scattering γ photons from ⁴⁰K within the soil relative to the ⁴⁰K full energy peak (1460 keV). Again there was good agreement with soil core measurements (r²=0.64; P<0.05). The precision of the in situ¹³⁷Cs measurement was limited by the precision with which Q_Cs can be estimated, a function of the low ¹³⁷Cs deposition levels associated with the weapons testing fallout and relatively low detector efficiency (35%). In contrast, the precision of the in situ ρ_m determination was only limited by the spatial variability associated with soil sampling.  相似文献   

Genetic Engineering Approaches to Pig Production*     

B. Brenig  G. Brem 《Reproduction in domestic animals》1991,26(1):14-21

Modern biotechnology promises a number of new applications in animal breeding and production. Although conventional pig breeding has achieved a high level of efficiency and productivity numerous problems have been encountered with animal health and the loss of meat quality. Selection based on phenotypic performance data of individual animals does not take into account the importance of specific genes and their relevance within a complex regulatory system. In most cases it is therefore difficult to trace back the genetic origins of clinically important disorders. The application of genetic engineering techniques in pig production will facilitate diagnosis, improvement of productivity, and animal health by allowing direct genetic manipulation. Attention must be focussed on the physical and genetic analysis of the procine genome. The isolation and characterisation of genes, DNA-markers, polymorphic DNA-fragments, and their chromosomal assignment will be important prerequisites and tools for the elucidation of genetic disorders. Especially the detection of heterozygous carriers of recessive disorders and their elimination from the breeding stock will increase selection accuracy and decrease the generation intervals. But also the rapid and simple detection of infectious diseases, which is sometimes difficult if not impossible at present, will improve animal health and welfare. Although the production of transgenic animals either by DNA-microinjection into zygotes or the use of embryonal stem cells manipulated in vitro is less straightforward than DNA-based diagnosis it will play an important role in the direct manipulation of the porcine genome and genes. Breeding programmes including the use of transgenic livestock have already been developed. There is no doubt that genetic engineering has reached a degree of practical feasibility, allowing it to play an important role in pig breeding in particular and animal production in general.  相似文献   

沙棘定向培育的试验研究   总被引：1，自引：0，他引：1  

周效明  董相军 《沙棘》2004,17(3):11-15

在内蒙古克什克腾旗对引进和选优的沙棘品种进行了13年的区域性试验，筛选出无刺、高V-C型、高氨基酸型、大果等10个有较高经济价值的沙棘优良类型，在筛选的基础上，结合生化测定，在不同立地条件下，定向栽培，推广面积达3000hm^2。  相似文献