Assessing the effects of vegetation and precipitation on soil erosion in the Three-River Headwaters Region of the Qinghai-Tibet Plateau,China

Soil erosion in the Three-River Headwaters Region (TRHR) of the Qinghai-Tibet Plateau in China has a significant impact on local economic development and ecological environment. Vegetation and precipitation are considered to be the main factors for the variation in soil erosion. However, it is a big challenge to analyze the impacts of precipitation and vegetation respectively as well as their combined effects on soil erosion from the pixel scale. To assess the influences of vegetation and precipitation on the variation of soil erosion from 2005 to 2015, we employed the Revised Universal Soil Loss Equation (RUSLE) model to evaluate soil erosion in the TRHR, and then developed a method using the Logarithmic Mean Divisia Index model (LMDI) which can exponentially decompose the influencing factors, to calculate the contribution values of the vegetation cover factor (C factor) and the rainfall erosivity factor (R factor) to the variation of soil erosion from the pixel scale. In general, soil erosion in the TRHR was alleviated from 2005 to 2015, of which about 54.95% of the area where soil erosion decreased was caused by the combined effects of the C factor and the R factor, and 41.31% was caused by the change in the R factor. There were relatively few areas with increased soil erosion modulus, of which 64.10% of the area where soil erosion increased was caused by the change in the C factor, and 23.88% was caused by the combined effects of the C factor and the R factor. Therefore, the combined effects of the C factor and the R factor were regarded as the main driving force for the decrease of soil erosion, while the C factor was the dominant factor for the increase of soil erosion. The area with decreased soil erosion caused by the C factor (12.10×10³ km²) was larger than the area with increased soil erosion caused by the C factor (8.30×10³ km²), which indicated that vegetation had a positive effect on soil erosion. This study generally put forward a new method for quantitative assessment of the impacts of the influencing factors on soil erosion, and also provided a scientific basis for the regional control of soil erosion.     

山羊TNNT3基因可变剪切及其对骨骼肌细胞分化的作用

【目的】快速骨骼肌肌钙蛋白T（fast skeletal troponin T3,TNNT3）作为肌钙蛋白(troponin, Tn)家族成员,调节横纹肌收缩、参与骨骼肌的生长发育并影响家畜肉质性状。通过获得山羊TNNT3基因的可变剪切体,分析山羊TNNT3基因可变剪切的表达模式及其在肌细胞分化中的作用,深入解析TNNT3基因在山羊骨骼肌生长发育过程中的作用机制。【方法】基于NCBI已公布山羊TNNT3基因（NM_001314210.1）和牛TNNT3基因（XM_010821200）mRNA序列,使用软件Primer Premier 6.0设计引物,以简州大耳羊胚胎期和出生后7个阶段骨骼肌为试验材料,克隆测序获得山羊TNNT3基因的CDS区可变剪切体,利用软件ORF Finder、EditSeq、DNAMAN、ClustalW和MEGA_X_10.1.8等对序列进行生物信息学分析;进一步设计实时荧光定量（real-time PCR,RT-qPCR）及半定量引物,研究TNNT3基因剪切体在7个不同组织（背最长肌（longissimus dorsi muscle,LD）、半膜肌（semimembranosus muscle,SM）、心、肝、脾、肺、肾）和7个发育阶段（胚胎期E75、E90、E105和出生后B3、B45、B150、B300）肌肉组织（背最长肌和半膜肌）中表达模式;此外,对转录本TNNT3_3进行体外编码能力检测确定其具有编码蛋白的能力,并在山羊骨骼肌卫星细胞（skeletal muscle satellite cells,MuSCs）中过表达,观察细胞形态变化以及检测标志基因的表达变化,研究其对山羊MuSCs分化的作用。【结果】①TNNT3（NM_001314210.1）CDS区全序列主要含有18个外显子,其中外显子16/17相互排斥,转录后单一表达。克隆发现山羊TNNT3基因 5个新转录本（TNNT3_1—5）,其外显子数分别是15、15、20、16、14。②生物信息学分析结果显示山羊TNNT3基因核苷酸序列和氨基酸序列与绵羊、牛、猪等哺乳动物具有很高的一致性,而与鱼类和爬行类动物的一致性较低,说明TNNT3基因序列在哺乳动物高度保守。③TNNT3 mRNA在背最长肌、半膜肌、心、肝、脾、肺、肾7个组织中都有表达,其中在骨骼肌中高度富集(P < 0.01),心脏及肺次之,其余组织中较低;TNNT3 mRNA在背最长肌和半膜肌中的表达始终处于一个动态变化中,胚胎期TNNT3在半膜肌的表达量高于背最长肌（P<0.05）;出生后则背最长肌中高于半膜肌（P<0.05）。④山羊TNNT3基因转录本TNNT3_3重复出现保守的外显子9—11（138bp）,体外翻译实验显示其可编码蛋白且蛋白大小与预期基本相符（37 kD）;相较于对照组,在山羊MuSCs中过表达该转录本使肌分化标志基因Myomaker、MyoG和MyH4 mRNA极显著升高(P < 0.01)。【结论】获得了山羊TNNT3基因具有完整CDS区5个新可变剪切体,TNNT3主要在肌肉组织（背最长肌和半膜肌）中高表达,在哺乳动物中高度保守且促进成肌分化。初步表明TNNT3基因在动物肌肉生长发育中具有重要的生物学功能。     

河西绿洲区大棚甘蓝产量、品质和养分吸收对不同水肥组合的响应

为探明河西绿洲区塑料大棚甘蓝适宜的水肥管理模式,通过田间小区试验,设定3个施肥量(F_1:N、P_2O_5、K_2O含量为320,160,210kg/hm~2;F_2:N、P_2O_5、K_2O含量为260,120,157.5kg/hm~2,F_3:N、P_2O_5、K_2O含量为200,80,105kg/hm~2)和2个灌水频率(H_1:6d/次,H_2:9d/次),共6个处理,分析甘蓝农艺性状、产量、品质和叶球养分吸收及水肥利用效率对不同施肥量和灌水频率的响应规律。结果表明:H_1处理水平下叶球全氮、磷、钾含量随施肥量增加逐渐升高,H_2处理水平下氮、磷含量随施肥量增加先升高后降低,而钾含量却在随施肥量增加逐渐升高,同一灌水条件下肥料偏生产力随施肥量的减少而升高;同一施肥水平下,叶球中的全氮、磷、钾含量及吸收量高灌水频率大于低灌水频率处理,而肥料偏生产力的变化则相反。水肥耦合作用下,甘蓝叶球纵横径、生物产量和干物质量均H_2F_1处理最高,叶球紧实度、干鲜重比、单球重、经济产量和经济系数均H_2F_2最大,而叶球中心柱长和帮叶比H_2F_3处理最小。灌溉频率和施肥量对甘蓝叶球品质影响显著,且两因素的交互作用达到显著水平,其中硝酸盐含量H_1F_1最高、可溶性糖含量H_2F_1最高、Vc含量H_2F_2处理最大。水肥耦合后全氮和全磷含量及两者吸收量均以H_2F_2最大,全钾及吸收量H_2F_1最高。随着施肥量的增加,水分利用效率也逐渐升高,H_2F_1水分利用效率显著高于其他处理。综合分析表明,水肥耦合对河西绿洲区塑料大棚甘蓝叶球的农艺性状、产量、品质和养分吸收及水分利用率的影响显著,且灌溉频率的影响大于施肥量。H_2F_2处理(灌水频率9d/次,施肥量N、P_2O_5、K_2O为260,120,157.5kg/hm~2)是河西绿洲区塑料大棚甘蓝农艺性状、产量、品质、养分吸收以及水肥利用效率方面最佳的水肥组合模式。     

Genomewide association analysis of salt tolerance in soybean [Glycine max (L.) Merr.]

Salinity is a common abiotic stress causing soybean [Glycine max (L.) Merr.] yield loss worldwide. The use of tolerant cultivars is an effective and economic approach to coping with this stress. Towards this, research is needed to identify salt‐tolerant germplasm and better understand the genetic and molecular basis of salt tolerance in soybean. The objectives of this study were to identify salt‐tolerant genotypes, to search for single‐nucleotide polymorphisms (SNPs) and QTLs associated with salt tolerance. A total of 192 diverse soybean lines and cultivars were screened for salt tolerance in the glasshouse based on visual leaf scorch scores after 15–18 days of 120 mM NaCl stress. These genotypes were further genotyped using the SoySNP50K iSelect BeadChip. Genomewide association mapping showed that 62 SNP markers representing six genomic regions on chromosomes (Chr.) 2, 3, 5, 6, 8 and 18, respectively, were significantly associated with salt tolerance (p < 0.001). A total of 52 SNP markers on Chr. 3 are mapped at or near the major salt tolerance QTL previously identified in S‐100 (Lee et al., 2014). Three SNPs on Chr. 18 map near the salt tolerance QTL previously identified in Nannong1138‐2 (Chen, Cui, Fu, Gai, & Yu, 2008). The other significant SNPs represent four putative minor QTLs for salt tolerance, newly identified in this study. The results above lay the foundation for fine mapping, cloning and molecular breeding for soybean salt tolerance.     

通过GbF3’H基因单独沉默及其与GbCHI和GbDFR基因共沉默研究其在海岛棉中抗枯萎病功能

【目的】通过沉默海岛棉GbF3’H基因及共沉默GbF3’H、GbCHI和Gb DFR基因,研究其在海岛棉抗枯萎病中的作用。【方法】以海岛棉抗病材料06-146为研究对象,GhCLA1基因为阳性对照,空载体为阴性对照,构建海岛棉TRV2-Gb F3’H沉默载体,协同课题组前期构建的TRV2-CHI和TRV2-DFR载体,利用病毒诱导的基因沉默技术(Virus-induced gene silencing,VIGS)分别进行Gb F3’H基因单独沉默以及GbF3’H、GbCHI和Gb DFR这3种基因共沉默试验。通过实时荧光定量聚合酶链式反应(Quantitative real time-polymerase chain reaction,q RT-PCR)分析各处理样品中基因沉默情况;设置室内接种枯萎病菌试验测定病情指数,分析各沉默材料对枯萎病的抗性差异。【结果】q RT-PCR结果显示,海岛棉GbF3’H基因沉默后其在海岛棉根、茎和叶中的表达量比空载体对照低,Gb F3’H、GbCHI和GbDFR这3种基因共沉默后其在海岛棉根、茎和叶中的表达量均比空载体对照低。病情指数调查结果显示,野生型<空载体对照相似文献   

玉米田养鹅对土壤理化性状、杂草多样性及玉米生长的影响

为探究"玉米田养鹅"对农田生态系统杂草多样性、土壤理化性质及玉米生长状况的影响,以林芝市八一镇章麦村试验田为研究对象,运用对比方法,研究玉米田养鹅(Raising geese in cornfield,RGC)和对照(Control,CK)土壤理化性质、杂草多样性及玉米生长的异同,旨在通过田间状态的描述和中间状态的研究,为以后优化玉米田调控措施提供依据。结果表明:1)RGC处理有19种杂草,其中以菊科植物最多,对照组仅有9种。不同功能群杂草密度相差很大,双子叶一年生或越年生被子植物功能群杂草密度远远高于其他5种功能群;RGC处理提高了杂草群落Shannon-Wiener和Simpson多样性指数,但降低了Pielou均匀度指数和Margalef物种丰富度指数;2)RGC处理土壤含水率较对照高1.27%,与对照相比差异不显著(P0.05);3)随着土层加深,RGC和对照土壤紧实度均呈逐渐增加趋势,且RGC对紧实度影响显著;4)对照土壤碱解氮含量为86.48mg/kg,略高于RGC处理2.67mg/kg(P0.05),速效钾含量为161.07mg/kg,略高于RGC处理28.66mg/kg(P0.05),而RGC的土壤中速效磷含量为120.98mg/kg,是对照(106.25mg/kg)的1.14倍(P0.05)。结论:RGC处理增加了农田系统杂草数量、种类和生物量,提高了生物多样性,使土壤紧实度明显减小、土壤含水率增加及土壤养分含量出现差异,且玉米各项农艺性状低于对照。     

四个猕猴桃品种在南京地区引种栽培表现

猕猴桃果实风味独特，富含维生素C，享有“水果之王”的美称，近年来发展迅速。江苏省气候适合猕猴桃的生长，栽培面积逐年增加，本文对四个猕猴桃优良品种‘青皮红香’、‘早鲜’、‘翠香’和‘晚红’在南京地区的引种栽培表现进行了观测。四个猕猴桃品种果实各具特点，且与其他地区的表现有所差异，‘青皮红香’果皮无毛，红肉，但在南京果肉为绿色，其他果皮品质也不佳；‘早鲜’成熟早，在南京8月中旬即可成熟，耐贮藏，果实重量达到91.03 g，且维生素C含量较高，为82.13 mg/100g，但口味偏酸；‘翠香’果皮易剥落，果肉翠绿，可溶性糖含量（9.56%）和糖酸比（8.25）较高，口味佳；‘晚红’果肉绿，果心周围具红色，可溶性固形物含量高达19.11，但果实较小，为62.92 g。     

刈割次数对苜蓿相关表型性状与饲草产量的影响

试验选取4份苜蓿材料,设4次刈割处理,观察测试表型性状及干物质的变化动态,并用DPS7.05数据处理系统对各性状指标与饲草产量的关系进行计算分析,以探讨刈割次数对苜蓿表型性状及饲草产量的影响,为高效优质生产提供依据。结果表明,刈割频度显著影响苜蓿越冬率(P<0.05),苜蓿株高、茎粗、茎叶比、分枝数等指标均随刈割次数增加呈明显降低趋势,其中WL525苜蓿首次刈割与其他3次刈割时的株高、茎粗均呈现显著性差异(P<0.05),茎叶比差异性不显著(P>0.05);而苜蓿饲草产量则随刈割次数增多而增加,与刈割1次的情况相比,WL525苜蓿刈割4次后产量增量最多,达1885kg/hm₂;4次刈割后试验材料饲草总产量从高到底的次序依次为WL525>WL903>赛迪>惊喜。全部材料中与饲草产量关联度最大的指标为株高和茎粗,其中株高与惊喜苜蓿饲草产量的关联系数最大,达0.3751;茎粗与WL525苜蓿、WL903苜蓿饲草产量的关联系数最大,分别为0.2854、0.1944。     

Comparative proteomics analysis of maize (Zea mays) leaves infected by small brown planthopper (Laodelphax striatellus)

Maize rough dwarf disease (MRDD) is a viral disease caused by brown planthopper infestation, and leads to great yield loss, especially in China. Comparative proteomics was performed using maize inbred line Zheng 58 and LN 287. MRDD pathogen was detected as rice black-streaked dwarf virus (RBSDV) by quantitative real time PCR (qRT-PCR) in Shandong Province, China. The modified trichloroacetic acid (TCA)/acetone method was used for soluble protein extraction from leaves. Two-dimensional electrophoresis (2-DE) analysis was performed on 24-cm long, pH 4–7 linear immobilized pH gradient (IPG) strips, and gels were stained with silver and coomassie brilliant blue. We identified 944 proteins expressed in RBSDV infected maize leaves by proteomics approaches. Among these, 44 protein spots that revealed a 1.5-fold difference in intensity were identified by mass spectrometry between mock-inoculated and RBSDV infected samples. Among these, 17 and 26 spots were up-regulated, and 27 and 18 spots were down-regulated in the virus infected samples of Zheng 58 and LN 287, respectively. Differential protein spots were analyzed by mass spectrometry identification, which could be divided into six categories. Furthermore, the expression of stress-related proteins was detected and confirmed by qRT-PCR. This study lays the foundation for further investigations, enabling the enhancement of MRDD resistance in maize.