黄花大苞姜花药发育qRT-PCR内参基因筛选

qRT-PCR技术具有定量准确、灵敏度高、重复性好等特点,被广泛用于基因表达分析。内参基因的稳定性对于准确分析实验结果非常重要。该研究以黄花大苞姜(Caulokaempferia coenobialis)花粉母细胞时期(PMC)、四分体时期(TET)、成熟花粉时期(MP)的花药组织为材料,基于3个阶段花药转录组表达谱数据以及常用传统内参基因,筛选出Glyceraldehyde 3-phosphate dehydrogenase(GAPDH)、Malate dehydrogenase(MDH)、α-tubulin3(TUA3)、β-tubulin7(TUB7)和Actin6(ACT6)作为候选内参基因,进行qRT-PCR分析;并运用BestKeeper、geNorm和Normfinder软件综合分析5个候选内参基因在黄花大苞姜花药发育过程中的表达稳定性。结果表明:MDH和TUB7的表达最稳定,ACT6的稳定性最差;分别以MDH和TUB7作为内参,分析GBE1在黄花大苞姜花药发育中的表达模式,并与该基因在花药转录组中的表达模式做相关系数分析,3种表达模式结果一致,进一步验证了MDH和TUB7的表达稳定性。这说明MDH和TUB7适合作为qRTPCR分析黄花大苞姜花药发育过程中相关基因表达模式的内参基因。该研究结果为黄花大苞姜花药发育分子机制相关研究奠定了基础,也为姜科花药发育相关内参基因的选择提供了参考。     

红掌佛焰苞基因qRT-PCR分析中内参基因的筛选

为筛选红掌(Anthurium andraeanumLinden)中稳定表达、可用于佛焰苞中实时荧光定量PCR分析(qRT-PCR)的内参基因,对5个组成型表达基因EF1-a、UBQ7、ACTB、GADPH、His3进行表达稳定性分析,并利用所筛选的内参基因研究红掌的二氢黄酮醇还原酶基因(dfr)的表达水平。结果表明,5种内参基因在不同品种间的表达稳定性不同。据内参基因标准化因子的配对差异分析(Vn/n+1),判定内参基因的最适数目为2,ACTB和UBQ7在红掌不同品种及佛焰苞发育不同阶段中表达均稳定,是理想的内参基因。dfr在不同品种的佛焰苞及佛焰苞发育过程中均有表达,且dfr表达水平的变化趋势一致,因此,所选内参基因是合适的。     

基于联合测序分析技术挖掘红苞凤梨lncRNA信息

为了揭示lncRNA在红苞凤梨嵌合叶片形成和生长发育过程中的调控作用机制,该文以金边红苞凤梨为材料,采用Hiseq2500测序和SMRT三代全长转录组测序联合测序分析技术,分析挖掘红苞凤梨lncRNA信息。结果表明:(1)鉴定得到6 018条lncRNA,包含3 298个基因间lncRNA,870个反义lncRNA,717个内含子lncRNA和1 109个正义lncRNA,数据量较二代测序有了极大的提高。(2)结构分析表明,红苞凤梨lncRNA的总体表达丰度低于mRNA;序列长度在400~1 200 nt区间比例高于mRNA,而在1 600 nt区间,lncRNA分布的比例显著小于mRNA; lncRNA中的外显子数量总体少于mRNA,开放阅读框长度总体上也短于mRNA。(3)差异表达分析表明,在全绿、全白叶片发育过程中鉴定到1 710个差异表达lncRNA。(4)靶基因预测结果表明,5 441个lncRNA通过cis作用方式预测到靶基因,1 544个lncRNA通过trans方式预测到靶基因。(5)靶基因的功能注释和富集分析显示,差异表达lncRNA的靶基因主要作为酶蛋白参与调节叶片代谢活动和信号转导等方面,与叶片的颜色形成、光合作用和生长发育密切相关。该文鉴定出的lncRNA信息以及对其结构和功能的分析,为红苞凤梨以及凤梨科其他植物的lncRNA表观遗传调控机理研究提供了数据基础,筛选出的差异表达lncRNA在金边红苞凤梨叶片嵌合性状的形成和生长发育中具有重要的调控作用。     

Bt毒素诱导下小菜蛾实时定量PCR 内参基因的筛选

【目的】筛选出Bt毒素诱导后的小菜蛾Plutella xylostella (L.)的实时定量PCR最适内参基因。【方法】选取核糖体18S rRNA (18S rRNA)、 肌动蛋白（ACTB）、 延伸因子（EF1）、3-磷酸甘油醛脱氢酶（GAPDH）、 核糖体蛋白L32 (RPL32)、 核糖体蛋白S13 （RPS13）、 核糖体蛋白S20 （RPS20）和β-微管蛋白(TUB)基因作为候选内参基因, 以geNorm、 Normfinder和BestKeeper软件分析这8个基因在Bt毒素诱导后的小菜蛾不同品系中肠组织中的表达稳定性。并应用筛选出来的内参基因分析小菜蛾氨肽酶2（aminopeptidase N2, APN2）基因的表达水平。【结果】geNorm软件以RPS13和EF1为最稳定内参基因, NormFinder和BestKeeper软件均以RPS13和RPL32为最稳定基因。使用3种不同内参基因分析Bt毒素诱导后的小菜蛾Bt抗性和敏感品系中ANP2表达水平时, 新的内参基因EF1和传统内参基因RPL32表现了良好的稳定性, 二者作为标准化因子, ANP2表达量结果基本一致, 而使用18S rRNA作为内参基因, 却导致部分表达量分析结果有所误差。【结论】筛选出PRS13,RPL32和EF1可以作为小菜蛾某些试验条件下的内参基因, 对小菜蛾基因表达研究奠定了一定基础, 也对其他昆虫内参基因的筛选具有参考价值。     

翘嘴鳜per1 mRNA表达量分析中采用的内参基因稳定性比较

为筛选生物钟核心基因per1表达定量中的相对稳定性最好的内参基因,本研究取翘嘴鳜成鱼心脏、肝脏、肾脏、脑、红肌、白肌、肠、眼和脾等九个组织为研究对象,选取GAPDH、18S rRNA、β-actin、rps29、RPL13a、B2M和EF1a为内参基因,采用实时荧光定量PCR(qRT-PCR)对per1基因mRNA表达水平进行检测分析。研究结果表明18S rRNA和GAPDH的平均稳定值M最低,相对表达量最稳定。以18S rRNA和GAPDH为内参基因时分析发现per1基因表达量在肝脏中最高。本研究为在鱼类per1 mRNA表达检测过程中选用稳定的内参基因提供了实验和理论参考。     

光裸星虫(Sipunculus nudus)不同发育时期卵细胞内参基因的筛选

内参基因的选择对功能基因表达量的归一化处理尤为重要。为了筛选出光裸星虫不同发育时期卵子的最适内参基因,利用qRT-PCR测定了甘油醛-3-磷酸脱氢酶(GAPDH)、肽基脯氨酰顺反异构酶A(PPIA)、60S核糖体蛋白L10(60S-L10)、铁蛋白(Ferritin)、β-肌动蛋白(β-actin)、泛素C(UBC)、真核生物翻译起始因子(eIF)、NADH脱氢酶(NDH)、28S核糖体RNA(28S)、TATA盒结合蛋白(TBP)、18S核糖体RNA(18S)和琥珀酸脱氢酶A亚基(SDHA)共12个候选内参基因的表达水平,并通过4个程序(geNorm,NormFinder,BestKeeper以及RefFinder)综合分析了各基因的表达稳定性。结果显示:(1)12个候选内参基因均能获得特异性扩增产物,但表达情况各异;(2)对候选内参基因进行综合打分,得到候选内参基因稳定性排名为18S>GAPDH>28S>β-actin>UBC>e IF>NDH|TBP>PPIA|Ferritin>60S-L10>SDHA。18S和GAPDH稳定性较好,可作为不同发育时期卵细胞基因表达研究的单内参基因,或最优组合内参基因。     

五龄飞蝗不同发育时间实时定量PCR内参基因的筛选

【目的】筛选5龄飞蝗不同发育时间的最适内参基因,为相关研究提供基础数据。【方法】本文选取β-肌动蛋白(β-actin)、延长因子(EF-1α)、3-磷酸甘油醛脱氢酶(GAPDH)、核糖体蛋白49(RP49)、α-微管蛋白(α-Tubulin)和18S核糖体RNA(18S rRNA)基因作为候选内参基因,运用实时定量PCR(qPCR)方法研究各基因在5龄飞蝗不同发育时间的相对表达量,用geNorm与Normfmder软件分析这6个基因表达稳定性。【结果】geNorm分析结果显示6个内参基因表达稳定度M值顺序为:β-actin(0.3720)>RP49(0.3750)>α-Tubulin(0.4030)>18S rRNA(0.4270)>EF-1α(0.4970)>GAPDH(0.6040)。M值越小表示基因表达稳定度越高,同时geNorm软件以标准化因子配对差异值(Pairwise variations)0.15默认为取舍值,由于V2/3=0.098<0.15,所以最适内参基因数目为2个。运用NormFinder软件也得出相似的结果。【结论】β-actin与RP49为5龄飞蝗不同发育时间的最适内参基因。     

不同温度胁迫下瓜实蝇RT-qPCR内参基因筛选

特定条件下稳定表达内参基因的筛选是利用实时荧光定量PCR研究基因表达的关键基础。本研究以不同温度胁迫后后的瓜实蝇Bactrocera cucurbitae 2龄幼虫、雌虫和雄虫为试验材料,对其9个候选内参基因表达进行了RT-qPCR分析,并利用ge Norm、Norm Finder、Best Keeper和Ref Finder 4款软件分析各候选内参基因在3种虫态中的表达稳定性。结果表明,18S rRNA基因Ct值(≤5)较小,不适合作为内参基因使用,其它8个内参基因在瓜实蝇2龄幼虫中的稳定性排序为Rp L32 RPS13 TBPβ-tubulin TUBE Actin2 G6PDH Actin3。雌虫表达稳定性由高到低为:RPS13 Rp L32β-tubulin TBP TUBE Actin2 Actin3 G6PDH。雄虫表达稳定性为Rp L32 RPS13β-tubulin TBP TUBE Actin2 G6PDH Actin3。ge Norm软件分析各个虫态内参基因最佳组合均为2个。RPS13和Rp L32组合可作为瓜实蝇不同虫态下温度胁迫后的内参基因。     

无患子RT-qPCR内参基因的筛选与验证

无患子根、茎、叶、花和果皮均含有生物活性物质三萜皂苷,为了解三萜皂苷生物合成途径中相关基因的表达水平,需要筛选稳定表达的内参基因。以无患子根、茎、叶、芽、雄花、雌花和不同发育时期的果皮为材料,根据无患子转录组数据,选择Sm18S,SmACT,SmTBCC,SmEF-1α,SmRPL1,SmRPS26,SmUBC12,SmUBP等8个基因作为候选内参基因。通过实时荧光定量PCR(RT-qPCR)检测这些候选内参基因的表达量,并利用geNorm、NormFider和BestKeeper三个软件及RefFinder在线分析工具评价候选内参基因的稳定性。结果表明,8个候选内参基因的表达量在所有样本间的变化幅度存在差异;geNorm、NormFinder和BestKeeper 3个软件筛选出的最佳内参基因略有不同;综合分析结果表明SmACT、SmRPL1和SmUBP表达较为稳定,SmEF-1α稳定性最差;以SmACT、SmACT+SmRPL1组合和SmACT+SmRPL1+SmUBP组合为内参对三萜皂苷生物合成途径中的8个候选基因进行校准所得的表达量基本上保持一致,且相对表达量结果与转录组数据基...     

Genome Analysis inNeurospora crassa;Cloning of Four Lociarginine-1(arg-1),methionine-6(met-6),unknown-7(un-7), andribosome production-1(rip-1) and Associated Chromosome Walking

We have cloned fourNeurospora crassagenes by complementation analysis. Cloned genes include thearginine-1(arg-1),methionine-6(met-6),unknown-7(un-7), andribosome production-1(rip-1) loci. Chromosome walks were initiated in ordered cosmid libraries from the cloned loci. A total of about 700 kb of theNeurosporagenome is covered in these walks.     

Fluorescent labeling of (Na + K)-ATPase by 5-iodoacetamidofluorescein

5-Iodoacetamidofluorescein (5-IAF) covalently labels dog kidney (Na⁺ + K⁺)-ATPase with approximately 2 moles incorporated per mole of enzyme. ATPase and K⁺-phosphatase activities are fully retained after reaction, and the kinetic parameters for Na⁺, K⁺, Mg²⁺, ATP and p-nitrophenyl phosphate are likewise not significantly affected. The fluorescence of the bound 5-IAF is increased by ATP, Na⁺, and Mg²⁺, and decreased by K⁺. These fluorescence changes likely reflect ligand-induced stabilization of the E₁ or E₂ states of the enzyme.     

甘菊ClHSP70与ClHSP90基因的克隆及表达分析

该研究以甘菊(Chrysanthemum lavandulifolium)为实验材料,通过RT-PCR方法从甘菊转录组数据中分离出热激蛋白合成相关基因,命名为ClHSP70和ClHSP90。序列分析表明,ClHSP70基因ORF全长为2 559bp,编码852个氨基酸,蛋白功能区预测表明含有典型的HSP70蛋白NBD和SBD保守结构域;ClHSP90基因ORF全长为2 094bp,编码697个氨基酸,含有HATPase结构域和HSP90保守结构域。生物信息学分析表明,甘菊ClHSP70与大豆(Glycine max)和烟草(Nicotiana tomentosiformis)HSP70蛋白有较高的一致性,ClHSP90基因编码的氨基酸序列与紫茎泽兰(Ageratina adenophora)HSP90高度相似;实时荧光定量表达分析表明,在42℃处理不同时间,甘菊叶片中ClHSP70和ClHSP90基因表达均在0.5h时显著增加,1h达到最大值,2h后缓慢下降;不同组织表达分析表明,甘菊在42℃处理1h后,ClHSP70在成熟叶中的表达量显著高于嫩叶和根等其他组织;ClHSP90在成熟茎中的表达量最高。研究说明,ClHSP70和ClHSP90基因具有热激蛋白特征,参与了甘菊热胁迫应答过程,该研究结果为以后深入研究其基因功能奠定了基础。     

Annular and non-annular binding sites on the (Ca + Mg)-ATPase

Quenching of the fluorescence of the (Ca²⁺ + Mg²⁺)-ATPase purified from muscle sarcoplasmic reticulum can be used to measure relative binding constants of hydrophobic compounds to the phospholipid-protein interface. We show that the binding constant for cholesterol is considerably less than that for phosphatidylcholine, so that cholesterol is effectively excluded from the phospholipid annulus around the ATPase. However, dibromocholestan-3β-ol causes quenching of the fluorescence of the ATPase, and so has access to other, non-annular sites. We suggest that these non-annular sites could be at protein/protein interfaces in ATPase oligomers. Oleic acid can bind at the phospholipid/protein interface, although its binding constant is less than that for a phosphatidylcholine, and it can also bind at the postulated non-annular sites. The effects of these compounds on the activity of the ATPase depend on the structure of the phospholipid present in the systems.     

基因CfATG6和CfATG14参与调控果生刺盘孢细胞自噬和致病力

【目的】炭疽病是油茶的主要病害,由刺盘孢属的多种真菌引起,其中果生刺盘孢分布范围最广、分离率最高,是油茶炭疽病的主要致病菌。研究自噬相关蛋白CfAtg6和CfAtg14的生物学功能,为进一步揭示果生刺盘孢通过细胞自噬调控致病的分子机制,并为油茶炭疽病的防治提供理论基础。【方法】根据同源重组原理,通过聚乙二醇(polyethylene glycol, PEG)介导的方法,在果生刺盘孢中敲除基因CfATG6和CfATG14,并进一步获得回补菌株ΔCfatg6-C和ΔCfatg14-C。【结果】酵母双杂交试验结果显示,果生刺盘孢蛋白CfAtg6和CfAtg14可能存在互作关系。生物学表型测定结果表明,相较于野生型和回补菌株,突变体ΔCfatg6和ΔCfatg14均表现出营养生长速率显著减慢,附着胞形成率分别只有野生型的5%和18%;突变体ΔCfatg6和ΔCfatg14致病力均极显著减弱,造成的油茶叶片病斑面积少于野生型和回补菌株的1/3;CfATG6和CfATG14基因缺失突变体均丧失转运和降解CfAtg8蛋白的能力,并对细胞壁胁迫更敏感。突变体ΔCfatg6的分生孢子产量显著降低,仅为野生型的20%左右;氧化胁迫试验结果表明,相较于野生型和回补菌株,过氧化氢对突变体的生长抑制率升高10%左右。内质网压力胁迫试验表明,ΔCfatg14对二硫苏糖醇抑制率升高5%以上。【结论】自噬相关基因CfATG6和CfATG14参与调控了果生刺盘孢生长发育、细胞自噬和致病力。     

利用DNA片段测序方法探究枳属和富民枳的分类地位

富民枳(Poncirus polyandra)属于芸香科(Rutaceae)枳属(Poncirus Raf.).自发表以来,分类地位一直备受争议,其中在Flora of China中认为富民枳为柑橘杂交种(Poncirus polyandra),把枳属归并于柑橘属(Citrus).该研究选取枳属的富民枳、枳(Ponci...     

TFS1: A suppressor of cdc25 mutations in Saccharomyces cerevisiae

Summary The TFS1 gene of Saccharomyces cerevisiae is a dosage-dependent suppressor of cdc25 mutations. Overexpression of TFS1 does not alleviate defects of temperature-sensitive adenylyl cyclase (cdc35) or ras2 disruption mutations. The ability of TFS1 to suppress cdc25 is allele specific: the temperature-sensitive cdc25-1 mutation is suppressed efficiently but the cdc25-5 mutation and two disruption mutations are only partially suppressed. TFS1 maps to a previously undefined locus on chromosome XII between RDN1 and CDC42. The DNA sequence of TFS1 contains a single long open reading frame encoding a 219 amino acid polypeptide that is similar in sequence to two mammalian brain proteins. Insertion and deletion mutations in TFS1 are haploviable, indicating that TFS1 is not essential for growth.     

Dominant mutant alleles of yeast protein kinase geneCDC15 suppress thelte1 defect in termination of M phase and genetically interact withCDC14

LTE1 encodes a homolog of GDP-GTP exchange factors for the Ras superfamily and is required at low temperatures for cell cycle progression at the stage of the termination of M phase inSaccharomyces cerevisiae. We isolated extragenic suppressors which suppress the cold sensitivity oflte1 cells and confer a temperature-sensitive phenotype on cells. Cells mutant for the suppressor alone were arrested at telophase at non-permissive temperatures and the terminal phenotype was almost identical to that oflte1 cells at non-permissive temperatures. Genetic analysis revealed that the suppressor is allelic toCDC15, which encodes a protein kinase. Thecdc15 mutations thus isolated were recessive with regard to the temperature-sensitive phenotype and were dominant with respect to suppression oflte1. We isolatedCDC14 as a low-copy-number suppressor ofcdc15-rlt1.CDC14 encodes a phosphotyrosine phosphatase (PTPase) and is essential for termination of M phase. An extra copy ofCDC14 suppressed the temperature sensitivity ofcdc15-rlt1 cells, but not that ofcdc15-1 cells. In addition, some residues that are essential for the Cdc14 PTPase activity were found to be non-essential for the suppression. These results strongly indicate that Cdc14 possesses dual functions; PTPase activity is needed for one function but not for the other. We postulate that the cooperative action of Cdc14 and Cdc15 plays an essential role in the termination of M phase.     

AtBS14a and AtBS14b, two Bet1/Sft1-like SNAREs from Arabidopsis thaliana that complement mutations in the yeast SFT1 gene

SNAREs are membrane-associated proteins that play a central role in vesicle targeting and intra-cellular membrane fusion reactions in eukaryotic cells. Here we describe the identification of AtBS14a and AtBS14b, putative SNAREs from Arabidopsis thaliana that share 60% amino acid sequence identity. Both AtBS14a and BS14b are dosage suppressors of the temperature-sensitive growth defect in sft1-1 cells and over-expression of either AtBS14a or AtBS14b can support the growth of sft1Δ cells but not bet1Δ cells. These data together with structure–function and biochemical studies presented herein suggest that AtBS14a and AtBS14b share properties that are consistent with them being members of the Bet1/Sft1 SNARE protein family.     

Novel alleles ofcdc13 andcdc2 isolated as suppressors of mitotic catastrophe inSchizosaccharomyces pombe

Cell cycle control in the fission yeastSchizosaccharomyces pombe involves interplay amongst a number of regulatory molecules, including thecdc2, cdc13, cdc25, weel, andmik1 gene products. Cdc2, Cdc13, and Cdc25 act as positive regulators of cell cycle progression at the G2/M boundary, while Wee1 and Mik1 play a negative regulatory role. Here, we have screened for suppressors of the lethal premature entry into mitosis, termed mitotic catastrophe, which results from simultaneous loss of function of both Wee1 and Mik1. Through such a screen, we hoped to identify additional components of the cell cycle regulatory network, and/or G2/M-specific substrates of Cdc2. Although we did not identify such molecules, we isolated a number of alleles of bothcdc2 andcdc13, including a novel wee allele ofcdc2, cdc2-5w. Here, we characterizecdc2-5w and two alleles ofcdc13, which have implications for the understanding of details of the interactions amongst Cdc2, Cdc13, and Wee1.