RSBP15 interacts with and stabilizes dRSPH3 during sperm axoneme assembly in Drosophila

Flagellum in sperm is composed of over 200 different proteins and is essential for sperm motility. In particular, defects in the assembly of the radial spoke in the flagellum result in male infertility due to loss of sperm motility. However, mechanisms regulating radial spoke assembly remain unclear in metazoans.Here, we identified a novel Drosophila protein radial spoke binding protein 15(RSBP15) which plays an important role in regulating radial spoke assembly. Loss of RSBP15 results in complete lack of mature sperms in seminal vesicles(SVs), asynchronous individualization complex(IC) and defective "9 + 2"structure in flagella. RSBP15 is colocalized with dRSPH3 in sperm flagella, and interacts with dRSPH3 through its DD_R_PKA superfamily domain which is important for the stabilization of dRSPH3. Moreover,loss of dRSPH3, as well as dRSPH1, dRSPH4 a and dRSPH9, showed similar phenotypes to rsbp15 KO mutant. Together, our results suggest that RSBP15 acts in stabilizing the radial spoke protein complex to anchor and strengthen the radial spoke structures in sperm flagella.     

SAA-Cas9: A tunable genome editing system with increased bio-safety and reduced off-target effects

The site-specific nature and ease of handling of clustered regularly interspaced palindromic repeat(CRISPR)/Cas9 has fulfilled the decades-long goal of genome engineering,and thus has pushed the biological sciences into a new era in which site-directed manipulation of DNA is no longer a short slab(Doudna and Charpentier,2014).The incomparable power of this system also enabled unprecedented new opportunities for practical applications in agriculture,ecosystem and human health(Liu,2017).However,with the extremely rapid development and application of CRISPR system,concerns about its bio-safety have been increasing(Caplan et al.,2015;Taning et al.,2017).While multiple studies have addressed this issue,alternative options for regulating Cas9 are of great interest.As has been proved by increasing evidences,another well?known concern is the off-target effects,which could not only confound research experiments or breeding,but also cause unwanted side effects in the forthcoming therapeutic uses(Fu et aL,2013;Taning et al.,2017;Zhang et al.,2018).     

PIK-75 promotes homology-directed DNA repair

Homo!ogy-directed repair(HDR)is one of two major DNA repair pathways to mend the double-strand breaks(DSBs)formed in the genome(Liang et al.,1998;Pardo et al.,2009).Although less efficient compared with another DNA repair pathway,nonhomologous end joining(NHEJ),HDR is a type of precise repair to restore DNA damage and sustain genomic stability(Pardo et al.,2009;Ceccaldi et al.,2016).By contrast,NHEJ usually introduces mutations into the repaired site,thus probably harming the genomic integrity(Lieber et al.,2003).The error-free property enables HDR to be harnessed to correct a faulty mutation for therapeutic purpose in cells or in the body(Wu et al.,2013).In add让ion,HDR possesses great potential in the generation of genome-edited animals with precise genetic modifications,such as point mutation,DNA replacement,and DNA insertion in a specific genomic site(Wang et al.,2013).However,the low repair frequency mediated by HDR significantly limits让s application for efficient gene correction or establishment of various genetically modified animal models.Currently,multiple site-specific endonucleases have emerged as highly efficient tools to create targeted DSBs and markedly promote subsequent DNA repair either via HDR or NHEJ(Gaj et al.,2013).Nonetheless,the HDR-mediated modifications following the cleavage of engineering nucleases are still inefficient,usually with an efficiency less than 20%in cultured mammalian cells and embryos(Mali et al..2013;Wang et al.,2013;Yang et al.,2013).     

Gut microbiota from end-stage renal disease patients disrupt gut barrier function by excessive production of phenol

<正>End stage renal disease (ESRD), an advanced stage of chronic kidney disease, has received increasing attention as a leading public health problem (Webster et al., 2017). Chronic kidney disease (CKD) and ESRD are invariably accompanied by chronic systemic inflammation which plays central roles in CKD progression (Cachofeiro et al., 2008) and the increased mortality due to cardiovascular disease (Landray et al., 2004). Accumulating evidence in humans and     

Oxymatrine Inhibits Bocavirus MVC Replication,Reduces Viral Gene Expression and Decreases Apoptosis Induced by Viral Infection

Oxymatrine(OMT), as the main active component of Sophoraflavescens, exhibits a variety of pharmacological properties,including anti-oxidative, anti-inflammatory, anti-tumor, and anti-viral activities, and currently is extensively employed to treat viral hepatitis; however, its effects on parvovirus infection have yet to be reported. In the present study, we investigated the effects of OMT on cell viability, virus DNA replication, viral gene expression, cell cycle, and apoptosis in Walter Reed canine cells/3873 D infected with minute virus of canines(MVC). OMT, at concentrations below 4 mmol/L(no cellular toxicity), was found to inhibit MVC DNA replication and reduce viral gene expression at both mRNA and protein levels, which was associated with the inhibition of cell cycle S-phase arrest in early-stage of MVC infection.Furthermore, OMT significantly increased cell viability, decreased MVC-infected cell apoptosis, and reduced the expression of activated caspase 3. Our results suggest that OMT has potential application in combating parvovirus infection.     

Aminopeptidase N Knockout Pigs Are Not Resistant to Porcine Epidemic Diarrhea Virus Infection

<正>Dear Editor,Porcine epidemic diarrhea virus(PEDV) is the etiologic agent of porcine epidemic diarrhea(PED), which is an acute, highly contagious, and devastating enteric viral disease in pigs(Lee 2015). PEDV is a coronavirus that mainly infects and replicates in villous enterocytes of the small intestine in pigs(Li et al. 2016). PEDV can infect     

火龙果茎基因组DNA提取方法改良

火龙果(Hylocereus undulatus)是近年发展起来的一种新兴热带水果, 其茎富含多糖、多酚及其它次生代谢物, 黏性极大, 很难从中提取高质量的DNA。特别是一年生以上的老茎, 目前尚未有较好的DNA提取方法。为了解决这一难题, 该研究对CTAB+Tris-HCl洗涤法进行了3种方式的改良。结果表明, “改进三”方法可不受取样时期和取样部位的限制, 从一年生以上火龙果茎中提取的DNA质量最好且不含黏性物质, 可用于酶切与分子标记等生化和分子生物学实验。该研究探索了一条较为理想的火龙果茎DNA提取方法, 值得推广应用。     

纳他霉素对芒果采后胶孢炭疽菌的抑菌效果及机理

以纳他霉素为抑菌剂, 实验测定了离体条件下不同浓度纳他霉素对胶孢炭疽菌(Colletotrichum gloeosporioides)的孢子萌发及菌丝生长的抑制效果, 以及活体损伤接种炭疽病菌后, 纳他霉素对芒果(Mangifera indica)果实炭疽病的防治效果。通过测定纳他霉素处理后胶孢炭疽菌的细胞膜相对渗透率、可溶性蛋白含量、细胞膜完整性、孢子内活性氧水平和线粒体分布情况, 初步探明其抑菌机理。结果表明, 3 mg∙L ^-1纳他霉素可显著抑制胶孢炭疽菌孢子萌发、芽管伸长和菌落生长, 80 mg∙L ^-1纳他霉素可有效抑制芒果贮存过程中果实炭疽病斑的扩展。纳他霉素处理后胶孢炭疽菌细胞膜相对渗透率和可溶性蛋白含量增加; 2 mg∙L ^-1纳他霉素处理8小时, 处理组胶孢炭疽菌孢子细胞膜损伤染色率为33.6%, 对照组染色率为13.9%; 处理组胞内活性氧产生染色率达46.9%, 比对照组高39.7%; 同时观察到纳他霉素使胞内线粒体分布不均且荧光信号微弱。以上结果表明, 纳他霉素可以破坏胶孢炭疽病菌细胞膜, 诱导活性氧大量积累, 并降低线粒体活性, 从而干扰菌体正常生理活性, 使其代谢活动受影响, 从而达到抑菌目的。     

基于光合系统参数建立马铃薯耐荫性综合评价体系

为构建便捷的马铃薯(Solanum tuberosum)耐荫性综合评价体系并发掘耐荫种质, 以35个马铃薯品种(系)为实验材料, 测定块茎膨大期遮荫下植株叶片叶绿素含量、光合能力和叶绿素荧光等光合参数及收获后块茎单株产量和淀粉含量等指标。根据耐荫系数, 利用主成分分析法、隶属函数法、聚类分析法和逐步回归分析法进行综合评价。通过主成分分析将马铃薯耐荫性相关的13个单项光合指标转换为6个综合指标, 代表了全部信息的87.51%。以此计算各种质的隶属函数值, 并以主成分的贡献率进行加权, 最终获得所用材料耐荫性的综合评价值(D值)。根据D值聚类分析结果将35个马铃薯分为4类, 其中Eshu10和Lishu6分别为耐荫性最强和最弱的品种。通过逐步回归分析建立了马铃薯耐荫性评价数学模型: D=0.060+0.106G_s+0.214qP+0.143NPQ。同时, 用该评价体系鉴定为耐荫性强的品种(系)在遮荫后其产量和/或淀粉含量等指标减幅均低于耐荫性弱的种质, 表明该评价体系可用于快速评价和预测马铃薯种质的耐荫性。