断奶对仔猪肠道屏障的影响及营养调控

在集约化养殖中,3~4周龄早期断奶是仔猪生命周期中一个非常紧张的时期,此时仔猪胃肠道还未发育成熟。肠道屏障由上皮、免疫和肠神经系统组成,这些系统控制上皮屏障的完整性以及肠道功能,包括肠腔营养物质、水和电解质的运输。早期断奶导致肠道通透性增加,出现胃肠功能紊乱的情况,可能对猪只一生产生长期的影响。因此,仔猪断奶饲粮需要正确水平的营养素、营养源和高质量的添加剂,鼓励仔猪快速进食,减轻或消除断奶应激综合症,降低死亡率和发病率。养猪就是养"肠道",合理使用功能性氨基酸、植物化学物质和有机酸等添加剂,能够修复由于断奶应激综合症导致的肠道屏障功能障碍。     

<Emphasis Type="Italic">OsLAP6/OsPKS1</Emphasis>, an orthologue of <Emphasis Type="Italic">Arabidopsis PKSA/LAP6</Emphasis>, is critical for proper pollen exine formation

Background

Male fertility is crucial for rice yield, and the improvement of rice yield requires hybrid production that depends on male sterile lines. Although recent studies have revealed several important genes in male reproductive development, our understanding of the mechanisms of rice pollen development remains unclear.

Results

We identified a rice mutant oslap6 with complete male sterile phenotype caused by defects in pollen exine formation. By using the MutMap method, we found that a single nucleotide polymorphism (SNP) variation located in the second exon of OsLAP6/OsPKS1 was responsible for the mutant phenotype. OsLAP6/OsPKS1 is an orthologous gene of Arabidopsis PKSA/LAP6, which functions in sporopollenin metabolism. Several other loss-of-function mutants of OsLAP6/OsPKS1 generated by the CRISPR/Cas9 genomic editing tool also exhibited the same phenotype of male sterility. Our cellular analysis suggested that OsLAP6/OsPKS1 might regulate pollen exine formation by affecting bacula elongation. Expression examination indicated that OsLAP6/OsPKS1 is specifically expressed in tapetum, and its product is localized to the endoplasmic reticulum (ER). Protein sequence analysis indicated that OsLAP6/OsPKS1 is conserved in land plants.

Conclusions

OsLAP6/OsPKS1 is a critical molecular switch for rice male fertility by participating in a conserved sporopollenin precursor biosynthetic pathway in land plants. Manipulation of OsLAP6/OsPKS1 has potential for application in hybrid rice breeding.

     

‘红国王’葡萄组织培养快速繁殖

为建立‘红国王’葡萄组培快繁体系,本试验研究了生长素、接种材料类型、培养条件对组培苗继代增殖与生根的影响。结果表明,0.5 mg/L IAA适合‘红国王’的继代增殖,繁殖系数为5.49,在培养基中附加0.3 mg/L NAA,愈伤组织少且根系粗壮;适合‘红国王’组培苗生长的蔗糖浓度为25~30 g/L,在该浓度下植株长势健壮,生根条数多;带半叶单芽茎段为‘红国王’适宜接种材料类型;接种后第1天至第10天暗培养,可促进‘红国王’根系发育;放置于LED灯复合光红∶蓝∶白=3∶1∶1下,可获得长势强、根系强壮的组培苗;继代间隔为40 d时,繁殖速度较快。     

双斜盘多排式轴向柱塞马达转矩特性分析

为了实现多级转速和转矩的输出,轴向柱塞马达必须使用节流阀、减压阀等耗能元件来改变输入压力和流量,但同时降低了效率。新型双斜盘多排式轴向柱塞马达可以利用其结构的特殊性,实现输出转矩的多样性。本文基于双斜盘多排式轴向柱塞马达的结构特点及工作原理,推导了该马达在不同工作方式下的理论瞬时转矩和转矩不均匀系数,并通过Matlab分析了内外马达转矩系数比对转矩不均匀系数的影响,设计了马达的实验液压系统并搭建了实验平台,对马达进行了原理性实验,并进行了数据分析。实验结果表明,在额定压力和额定排量下,该马达能实现多种不同的转速与转矩输出,随着内外马达转矩系数比的增大,低速大转矩的转矩不均匀系数越小,高速低转矩不稳定系数越大,通过合理设计可以实现马达在不同工作状态下的稳定运行,验证了新型马达在结构原理上的可行性,为新型轴向柱塞马达的改进设计提供了实验依据。     

定西于家山黄土洞穴的分布特征与侵蚀临界研究

黄土洞穴与滑坡、沟蚀等侵蚀过程联系紧密并加剧了黄土高原的水土流失程度,但目前黄土洞穴发育的分布特征与侵蚀临界暂未明晰。利用无人机获得了研究区高分辨率影像与数字表面模型,基于影像标识了黄土洞穴并统计了其土地利用类型与洞穴直径,利用标识点在数字表面模型上提取了黄土洞穴的坡度、坡向、曲率和汇水面积等地形数据并分析了黄土洞穴的分布特征。结果表明,黄土洞穴直径大多4 m。黄土洞穴在耕地上发育较少,多发育于牧草地区域流水汇聚的凹形坡,且在阴坡更为发育。同时,黄土洞穴坡度正切值范围集中于0.4～1.0,汇水面积一般不超过3 000 m~2。依托统计的坡度正切值与汇水面积数据绘制了黄土洞穴的侵蚀临界图并对比了黄土洞穴与浅沟、切沟的侵蚀临界。黄土洞穴的侵蚀临界边界分别为SA~(0.150)=0.368与SA~(0.135)=7.580,分布较广且覆盖了浅沟与切沟的侵蚀临界。浅沟、切沟的演化与黄土洞穴的发育有关,黄土洞穴通过连通与坍塌促进了浅沟、切沟的发育、转换与扩展,并因此加剧了黄土高原的水土流失。研究量化了黄土洞穴发育的分布特征,建立了黄土洞穴与浅沟、切沟的联系并深化了对黄土洞穴侵蚀过程的认识。     

新疆日光温室前屋面的风载数值模拟分析

【目的】 对日光温室前屋面风载大小和变化趋势进行模拟,可辅助前屋面骨架结构优化设计和前屋面实际风载计算,为提前预测和防灾功能提供科学依据。【方法】 将日光温室墙体、保温被和骨架等结构简化,使用UG 软件对日光温室进行造型,将模型与空气进行布尔求差,得到整体模型,将整体模型导入到ANSYS ICEM中,进行网格划分,得到保温被4种工作状态薄膜风压。再通过Y向的9条曲线画出不同条件下风压变化对比曲线。【结果】 在无保温被和保温被全铺时,薄膜最南侧风压最高,约1.014×10⁵Pa,往北侧风压逐渐降低,脊高位置风压最小约1.010×10⁵Pa。由于最南侧风遇到薄膜阻碍,造成风压的升高,而北侧接近日光温室顶端,风速快,而风速快的位置风压小。在保温被全卷及半卷时,也是最南侧风压较最高,约1.014×10⁵Pa,往北有风压的降低,总体屋面风压变化比较小,约1.013×10⁵Pa。只是保温被半卷时,在保温被卷放位置会有风压的突变为1.012×10⁵Pa。【结论】 无保温被、保温被全铺、保温被全卷及保温被半卷4种情况南侧风压较大且相差不大,但越往北侧,保温被全卷或半卷会造成薄膜风压的升高,尤其是顶部的突然升高。保温被全铺是最佳防风方案。南侧风压高,南侧前屋面钢骨架拱形段的性能对日光温室结构稳定性和安全性至关重要,设计和建设时需要着重计算和核验。     

3株氟磺胺草醚降解真菌的分离与鉴定

为了解决大豆田除草剂氟磺胺草醚长期使用造成的残留问题,本研究利用富集培养法进行菌株筛选,利用高效液相色谱法测定其降解能力,通过形态和16S rDNA序列分析对其进行种属鉴定。结果表明,本研究从长期施用氟磺胺草醚的土壤中分离纯化出3株能以氟磺胺草醚为唯一碳源生长的真菌菌株FF1、FF2和FF3。它们在7天内对初始浓度600 mg/L氟磺胺草醚的降解率分别为21.03%、15.74%和11.88%,这3个菌株分别鉴定为Aspergillus jensenii（詹森曲霉）、Penicillium dipodomyicola（双足青霉）和Rhizopus oryzae（稻根霉菌）。这3个种属的获得为氟磺胺草醚污染土壤生物修复提供了新的菌种资源。     

Updating the elite rice variety Kongyu 131 by improving the <Emphasis Type="Italic">Gn1a</Emphasis> locus

Background

Kongyu 131 is an elite japonica rice variety of Heilongjiang Province, China. It has the characteristics of early maturity, superior quality, high yield, cold tolerance and wide adaptability. However, there is potential to improve the yield of Kongyu 131 because of the relatively few grains per panicle compared with other varieties. Hence, we rebuilt the genome of Kongyu 131 by replacing the GRAIN NUMBER1a (Gn1a) locus with a high-yielding allele from a big panicle indica rice variety, GKBR. High-resolution melting (HRM) analysis was used for single nucleotide polymorphism (SNP) genotyping.

Results

Quantitative trait locus (QTL) analysis of the BC₃F₂ population showed that the introgressed segment carrying the Gn1a allele of GKBR significantly increased the branch number and grain number per panicle. Using 5 SNP markers designed against the sequence within and around Gn1a, the introgressed chromosome segment was shortened to approximately 430 Kb to minimize the linkage drag by screening recombinants in the target region. Genomic components of the new Kongyu 131 were detected using 220 SNP markers evenly distributed across 12 chromosomes, suggesting that the recovery ratio of the recurrent parent genome (RRPG) was 99.89%. Compared with Kongyu 131, the yield per plant of the new Kongyu 131 increased by 8.3% and 11.9% at Changchun and Jiamusi, respectively.

Conclusions

To achieve the high yield potential of Kongyu 131, a minute chromosome fragment carrying the favorable Gn1a allele from the donor parent was introgressed into the genome of Kongyu 131, which resulted in a larger panicle and subsequent yield increase in the new Kongyu 131. These results indicate the feasibility of improving an undesirable trait of an elite variety by replacing only a small chromosome segment carrying a favorable allele.