采用胚挽救获得Ogura CMS甘蓝与甘蓝型油菜的种间杂种

为将甘蓝型油菜细胞质雄性不育系(Ogura CMS)的恢复基因转至甘蓝Ogura CMS材料上,以6份甘蓝Ogura CMS材料为母本,以含恢复基因的甘蓝型油菜为父本,人工杂交结合胚挽救培养,研究取材时期、培养基成分和杂交组合对胚珠成苗的影响,同时对胚挽救培养获得的植株是否为真实F1杂种进行鉴定。结果发现,胚珠培养以剥蕾授粉后16d取材时胚珠成苗数最多,成苗率为4.56%;培养基以MS+GA 0.1 mg·L~(-1)+NAA 0.1 mg·L~(-1)+0.5%水解酪蛋白(CH)+0.5%活性炭(AC)成苗效果最好,成苗率高达6.24%;M09CMS×RFO-46组合成苗数最多,成苗率为5.96%。67株胚挽救培养得到的植株经流式细胞仪、SSR分子标记和形态学鉴定,得出65株为真杂种,真杂种率高达97%。     

热风干燥过程中山药水分状态的变化研究

为了解山药的水分赋存状态的变化，以襄阳道地山药为材料，分别在60、70、80、90、100 ℃条件下进行热风干燥，采用低场核磁共振（LF-NMR）和差式量热扫描（DSC）技术，每隔15 min测定山药在热风干燥过程中的水分状态及迁移规律。结果表明，在60~90 ℃条件下，温度越高，干基含水率的降速越快。山药的T2弛豫图谱有3个较为明显的吸收峰，随干燥进程的延续，各峰面积均明显减少，其中自由水所在峰的面积降幅最大，表明干燥过程中自由水散失最多，而且自由水逐渐向半结合水和结合水迁移，冷冻峰和解冻峰也随之变小。但在100 ℃下干燥时，样品可能因表面板结导致干基含水率、低场核磁吸收峰升高，冷冻和解冻峰面积增加。因此，在实际干燥过程中，山药的热风干燥温度不宜高至100 ℃。     

两种弧菌对菲律宾蛤仔代谢途径影响的比较研究

采用基于核磁共振波谱技术的代谢组学技术,探索菲律宾蛤仔在受到鳗弧菌和灿烂弧菌感染的代谢物变化特征,构建菲律宾蛤仔对弧菌感染后的代谢网络调控图谱,并比较两种弧菌毒性效应的差异。试验结果表明,3种代谢物葡萄糖、谷氨酸、苏氨酸在两种弧菌感染时均发生了变化,表征鳗弧菌感染的代谢物为牛磺酸、精氨酸、酪氨酸、苯丙氨酸、赖氨酸、亮氨酸、异亮氨酸、缬氨酸;而表征灿烂弧菌污染的代谢物为甜菜碱、二甲基甘氨酸、胆碱、谷氨酸、亚牛磺酸。     

不同秧龄对沿江地区双季晚稻秧苗素质及产量的影响

以早熟高产品种上农粳2号和镇稻18为材料,采用常规毯苗机械栽插,分别设置20 d、24 d、28 d、32 d等4个秧龄处理,研究不同秧龄对沿江地区双季晚稻秧苗素质、生育进程、茎蘖动态及产量构成的影响。结果表明,随秧龄天数增加,参试品种的绿叶数、茎基宽和根系盘结力均逐渐升高;与20 d、24 d和28 d秧龄的处理相比,32 d秧龄处理的成熟期提前4~5 d,茎蘖高峰期提早15 d左右,结实率显著升高;与24 d秧龄处理相比,上农粳2号和镇稻18在32 d秧龄处理下的产量分别提高10.26%和20.82%。在秧苗强化化控和苗床管理的条件下,安徽沿江地区常规毯苗机插的栽插秧龄可延长至32 d。     

水稻育性调控相关基因RNAi载体的构建及其表型鉴定

利用RNAi干扰技术研究不同基因对花粉发育、卵细胞发育和合子胚发育的影响是一种重要的手段。本研究通过筛选水稻在生殖发育过程中的9个重要调控基因,构建基因的RNAi表达载体,分析转基因植株育性及相关性状表型,以期探明RNAi表达载体对靶标性状的干扰效应。其中,AT61~AT63、AT64~AT66、AT67~AT69表达载体分别靶标花粉育性、卵细胞发育以及合子胚发育的调控。结果表明,除RNAi表达载体AT64没有获得转基因植株外,其余8个RNAi表达载体均获得了转基因植株;对T0代转基因植株的花粉育性、结实率以及潮霉素筛选(40 mg/L)发芽率检测的统计结果显示,RNAi表达载体AT62(花粉发育调控)、AT65(卵细胞发育调控)和AT67(合子胚发育调控)的干扰效应较强。本研究结果将为创制新型水稻基因工程不育系提供策略和选择。     

Vitrification of mouse two-cell and blastocyst stage embryos in simplified closed system using either a hemi-straw or a hollow fiber device

Two-cell stage and blastocyst stage mouse embryos were equilibrated in a medium containing 7.5% ethylene glycol (EG) and 7.5% dimethyl sulfoxide (DMSO) for 8–15 min. Vitrification was performed in a medium containing 0.5 M sucrose and either 15% EG + 15% DMSO, 17.5% EG + 17.5% DMSO, or 20% EG + 20% DMSO for 30 s. They were then placed either on a hemi-straw (HS) or a hollow fiber vitrification (HFV) device and vitrified by cooled air inside a 0.5-ml straw. In two-cell embryos, a 100% survival rate was obtained from all groups except the 20% HS group (P > .05). All vitrified two-cell groups showed similar rates of blastocyst development to that of fresh control group (P > .05), except 17.5% and 20% HFV groups, which were significantly lower than the other groups (P < .05). In the blastocyst embryos, the HFV groups were divided into two subgroups (non-collapsed; HFV-NC and collapsed; HFV-C blastocyst). Re-expansion rate in 15% HFV-NC, 17.5% HFV-NC, and 15% HFV-C groups was reduced (P < .05), whereas the rest were similar to control. In conclusion, we established a simplified, reliable, and closed system for HFV vitrification applying hemi-straw, which does not require skilled practitioners.     

Male sterility in soybean: Occurrence,molecular basis and utilization

In plants, male sterility (MS) is a specific breeding target trait. With the advancements in agriculture, utilization of heterosis breeding in hybrid production through MS lines has become the main breeding tool of various cross‐pollinated and even self‐pollinated crops. Soybean is an essential source of oil and protein; however, the low yield is a major factor limiting its development. Soybean MS mainly comprises cytoplasmic‐nuclear MS and nuclear/genic MS (NMS/GMS), which can effectively utilize heterosis to improve soybean yield. This review outlines the recent research progress on the development of new genetically MS lines, exploring the underlying molecular mechanism of MS, identification and cloning of MS and fertility restoration genes, and the application of MS lines. We further discussed and prospected the future developmental scenario direction of the soybean MS, based on the previous studies of other crops sterility system. Moreover, this review also provides comprehensive information for better application of MS to soybean breeding programme.     

Embryo-mediated genome editing for accelerated genetic improvement of livestock

Selecting beneficial DNA variants is the main goal of animal breeding. However, this process is inherently inefficient because each animal only carries a fraction of all desirable variants. Genome editing technology with its ability to directly introduce beneficial sequence variants offers new opportunities to modernize animal breeding by overcoming this biological limitation and accelerating genetic gains. To realize rapid genetic gain, precise edits need to be introduced into genomically-selected embryos, which minimizes the genetic lag. However, embryo-mediated precision editing by homology-directed repair (HDR) mechanisms is currently an inefficient process that often produces mosaic embryos and greatly limits the numbers of available edited embryos. This review provides a summary of genome editing in bovine embryos and proposes an embryo-mediated accelerated breeding scheme that overcomes the present efficiency limitations of HDR editing in bovine embryos. It integrates embryo-based genomic selection with precise multi-editing and uses embryonic cloning with elite edited blastomeres or embryonic pluripotent stem cells to resolve mosaicism, enable multiplex editing and multiply rare elite genotypes. Such a breeding strategy would enable a more targeted, accelerated approach for livestock improvement that allows stacking of beneficial variants, even including novel traits from outside the breeding population, in the most recent elite genetic background, essentially within a single generation.