一种优化的MALDI-TOF质谱分析多肽C端序列方法

利用基质辅助激光解吸飞行时间 (MALDI TOF)质谱技术 ,测定羧肽酶Y消化蛋白质和多肽 .所产生的缩短肽片段的质量 ,在一张谱图上得到各个不同酶解时间所形成的肽质量梯度 .根据谱图中相邻两肽峰的质量差得到切去氨基酸的信息 ,从而读出C端氨基酸序列 .在pmol水平下对人促肾上腺皮质激素片段 (ACTH 1 3 9) ,人血管紧张肽片段 (angiotensin Ⅰ ,angiotensin Ⅱ )的C端序列进行了测定 .讨论了在不同浓度 ,不同时间 ,不同温度下酶解所得到的序列测定结果 .在优化条件下 ,人ACTH片段得到了C端 2 0个氨基酸残基顺序 ,为目前C端序列分析所得到的最长序列     

鱼腥藻苯丙氨酸脱氨酶的基因克隆、表达及最适反应pH改造

【目的】表达鱼腥藻苯丙氨酸脱氨酶(AvPAL),并经分子改造降低其最适反应pH。【方法】PCR克隆AvPAL编码基因,并在大肠杆菌中表达,用Ni2+亲和层析柱和凝胶柱纯化重组蛋白。利用GETAREA软件筛选与催化残基距离较近的暴露于酶分子表面的氨基酸位点,将其突变为带电性质不同的氨基酸,并对突变体进行酶学性质研究。【结果】在大肠杆菌中成功表达了AvPAL,纯化后得到电泳纯的重组酶。突变体E75Q和E75R的最适反应pH从8.5分别偏移到7.5和7.0。E75Q在pH 7.5时的比酶活较原酶提高了25%,在pH 6.5–9.5之间酶的稳定性良好,其最适反应温度为50 °C,在此温度下保温1 h酶活无显著变化。在最适反应条件下,E75Q的kcat/Km值较原酶提高了26.6%。【结论】改变AvPAL酶分子中起路易斯碱作用的关键氨基酸残基(质子受体)附近与之有相互作用的氨基酸的带电性质,降低了AvPAL的最适反应pH,提升了其在医疗领域的应用前景。     

氨基酸在蛋白质空间结构中的深度倾向性因子

用统计和几何方法给出了氨基酸在蛋白质空间结构中的深度计算,并利用PDB数据库得到了不同氨基酸在蛋白质中的深度倾向性因子,并得到了这些倾向性因子与氨基酸的物理、化学综合特性的相关性质.     

分枝犁头霉α-半乳糖苷酶的氨基酸组成及化学修饰

α-半乳糖苷酶进行氨基酸组分分析,结果为含有较多的酸性及巯水性氨基酸,较少的组氨酸、酪氨酸及半胱氨酸。 用几种蛋白质侧链修饰试剂对α-半乳糖苷酶进行化学修饰。在一定条件下,当巯基及酪氨酸残基分别被NEM、IAA及NAI修饰后,酶活力不受影响,说明这些基团与活力无关。当羟基、组氨酸及色氨酸残基分别被EDC、DEP、NBS及HNBB修饰后,酶活力大幅度下降,说明这些基团或者参与了酯催化作用或者位于酯活性位区附近。     

烟草NtASAT1基因的原核表达、纯化及功能验证

目的：烟草酰基糖酰基转移酶(Nicotiana tabacum acylsugar acyltransferase, NtASAT1)可催化短支链脂肪酸与蔗糖形成蔗糖单酯。利用大肠杆菌原核表达系统分析NtASAT1的表达,并对其进行纯化及功能验证。方法：首先利用生物信息学软件对烟草NtASAT1的理化性质、二级结构及同源性进行分析;之后从烟草腺毛的cDNA中克隆NtASAT1基因,并构建表达载体,研究其在BL21(DE3)中的表达情况;最后利用镍柱对NtASAT1进行纯化,将纯化后得到的目标蛋白进行酶反应,通过液相色谱-质谱法(liquid chromatography-mass spectrometry, LC-MS)检测产物并验证其功能活性。结果：C端截短93个氨基酸之后的NtASAT1能够在BL21(DE3)中表达。表达后的蛋白质大部分以不可溶状态存在于细胞中,不同的诱导剂浓度、诱导时间及诱导温度对于蛋白质可溶性表达影响不明显。利用镍柱对其纯化得到目标蛋白,加入底物进行酶反应,通过LC-MS检测到产物蔗糖单酯的存在。结论：通过克隆及纯化得到重组蛋白trNtASAT1,加入底物进行...     

非解朊栖热菌HG102耐热β-糖苷酶的结构与功能研究

非解朊栖热菌HG10 2耐热 β-糖苷酶为 (β/α)₈桶状结构 ,是具有水解功能和转糖苷功能的单体酶。该酶可以作为一个很好的模型来研究糖苷酶的反应机制、底物特异性和耐热的分子基础。根据对该酶的晶体结构解析和同家族酶的结构比较 ,推测Glu164和Glu338分别是质子供体和亲核基团两个活性位点 ;在α-螺旋N端第一位的脯氨酸和蛋白质外周的精氨酸是耐热机制的关键位点和关键氨基酸残基。为确定这些氨基酸残基的功能 ,通过基因定点突变的方法分别把Glu164、Glu338、Pro316、Pro356、Pro344和Arg325置换成Gln、Ala、Gly、Ala、Phe和Leu ,同时还对Pro316和Pro356进行了双置换。突变酶经过纯化得到电泳纯 ,用CD光谱进行了野生酶和突变酶的结构比较。通过突变酶的酶功能和酶学性质分析 ,结果表明Glu164和Glu338分别是质子供体和亲核基团 ,亲核基团的突变酶TnglyE338A可以合成混合型糖苷键寡糖类似物 ;在α-螺旋N端第一位的Pro316和Pro356以及在蛋白质外周形成离子键的Arg325均是对耐热性有贡献的关键氨基酸残基。     

牛血清白蛋白胰蛋白酶酶解产物的色谱-质谱联用分析及其三种数据库搜寻鉴定方法的比较

利用反相高效液相色谱 (RP HPLC)和电喷雾串联质谱 (ESI MS MS)联用技术直接对模式蛋白分子 (牛血清白蛋白 ,BSA)的胰蛋白酶酶解产物进行分离和测定 .获得的一系列BSA酶解片段的一级 (MS)和二级 (MS MS)质谱数据经分析软件处理后 ,分别在不同处理和不同参数条件下 ,用 3种不同的方法通过网上蛋白质数据库进行蛋白质搜寻鉴定 .结果显示 ,3种搜寻法都能正确地鉴定该蛋白质 ,其中以利用MS数据的肽质量指纹谱搜寻法 (PMF法 )较为快捷方便 ,但鉴定结果易受数据处理和数据库搜寻鉴定时参数设置等因素的影响 ;利用未解析MS MS数据 (rawMS MSdata)的搜寻法可在较宽的搜寻参数变化范围内获得明确的鉴定结果 ;而借助从头测序 (denovosequencing)结果的序列搜寻法 (sequencequery)则显示出更高的专一性 ,利用较少酶解片段数据就能得到稳定和明确的鉴定结果 ,搜寻参数变化的影响很小 .就酶解条件、数据处理和搜寻参数设置对蛋白质鉴定结果的影响展开详细的讨论 ,为蛋白质组学研究中的数据处理和库搜寻鉴定积累了可借鉴的资料     

卫星电视教学辅导

蛋白质是细胞内含量最丰富,具有极其重要功能的生物大分子。本章着重介绍蛋白质及其基本组成单位氨基酸的分解与合成代谢。生物体内具有各种蛋白酶,可以把蛋白质降解为氨基酸。以人和动物消化道中的蛋白酶为例,按其作用方式不同可以分为肽链外切酶,肽链内切酶及二肽酶。在这些酶的综合作用下,蛋白质水解成氨基酸,进入细胞内代谢。各种氨基酸虽侧链基团各不相同,但都具有氨基和羧基,因而具有共同的分解代谢途径——脱氨基作用与脱羧基作用。本章仅介绍氨基酸的共同的分解代     

外源水杨酸对铝胁迫下菊芋根系分泌物的影响

为探究铝胁迫对菊芋根系分泌物的影响以及外源水杨酸(SA)的缓解作用,该文以耐铝型南京菊芋和铝敏感型资阳菊芋为试验材料,采用土培法,设置铝浓度500 μmol·L^-1,分析了不同浓度(10、100、1 000 μmol·L^-1)SA对铝胁迫下菊芋根系分泌物中有机酸、氨基酸以及根尖相关代谢酶活的影响。结果表明:(1)单铝胁迫会导致菊芋根系分泌物中柠檬酸、草酸、苹果酸浓度升高,且南京菊芋升高幅度大于资阳菊芋; 柠檬酸合酶和苹果酸脱氢酶在单铝胁迫下活性增强; 脯氨酸含量显著提升,总氨基酸浓度均显著减少。(2)外源SA加入后,南京菊芋根系分泌的柠檬酸、草酸、苹果酸浓度均得到不同程度提高,但经高浓度(1 000 μmol·L^-1)SA处理后资阳菊芋根系分泌草酸显著降低,且在各浓度SA处理下苹果酸浓度均无明显变化; 柠檬酸合酶活性出现不同程度的增强,但对南京菊芋根尖中苹果酸脱氢酶活性影响不大,且高浓度(1 000 μmol·L^-1)SA处理后显著降低了资阳菊芋根尖中苹果酸脱氢酶活性; 脯氨酸含量显著下降,从总氨基酸浓度变化来看,南京菊芋在高浓度(1 000 μmol·L^-1)SA、资阳菊芋在低浓度(10 μmol·L^-1)SA处理下得到最大缓解效果。因此,菊芋通过分泌有机酸应对铝毒侵害,外源SA可促进菊芋根系有机酸代谢速率,分泌更多的有机酸来缓解铝胁迫,这种缓解效果在耐铝性相对较强的南京菊芋中表现更好。     

酿酒酵母W5核酸内切酶基因HO的克隆及生物信息学分析

目的:以酿酒酵母W5为出发菌株,对其核酸内切酶基因HO进行克隆及生物信息学分析。方法:首先运用Primer 5.0软件,设计一对扩增HO基因序列的引物,并以酿酒酵母W5全基因组为模板进行PCR扩增,获得酿酒酵母W5核酸内切酶HO基因片段,利用生物信息学技术对该序列进行验证及分析。结果:测序显示HO基因长度为1760bp,无碱基缺失,且该基因序列具有完整的开放读框。该基因编码的HO蛋白包含586个氨基酸残基,强酸性和强碱性氨基酸残基数量有明显差异;HO蛋白等电点为9.56,存在激酶位点,疏水性最大值为1.722,亚细胞定位预测其位于细胞核内,属于碱性胞内蛋白质,并构建了其空间结构模型。结论:对酿酒酵母W5核酸内切酶HO基因序列进行了克隆及生物信息学分析,所得数据可为酿酒酵母遗传背景研究提供一定的理论支持。     

Statistical analysis of protein structures suggests that buried ionizable residues in proteins are hydrogen bonded or form salt bridges

It is well known that nonpolar residues are largely buried in the interior of proteins, whereas polar and ionizable residues tend to be more localized on the protein surface where they are solvent exposed. Such a distribution of residues between surface and interior is well understood from a thermodynamic point: nonpolar side chains are excluded from the contact with the solvent water, whereas polar and ionizable groups have favorable interactions with the water and thus are preferred at the protein surface. However, there is an increasing amount of information suggesting that polar and ionizable residues do occur in the protein core, including at positions that have no known functional importance. This is inconsistent with the observations that dehydration of polar and in particular ionizable groups is very energetically unfavorable. To resolve this, we performed a detailed analysis of the distribution of fractional burial of polar and ionizable residues using a large set of ?2600 nonhomologous protein structures. We show that when ionizable residues are fully buried, the vast majority of them form hydrogen bonds and/or salt bridges with other polar/ionizable groups. This observation resolves an apparent contradiction: the energetic penalty of dehydration of polar/ionizable groups is paid off by favorable energy of hydrogen bonding and/or salt bridge formation in the protein interior. Our conclusion agrees well with the previous findings based on the continuum models for electrostatic interactions in proteins. Proteins 2011; © 2011 Wiley‐Liss, Inc.     

Environment and exposure to solvent of protein atoms. Lysozyme and insulin

A computer program is described for calculating the environment and the exposure to solvent of atoms of a protein. The computation is based on the atomic co-ordinates of the protein and on assumptions like those of Lee &; Richards (1971). Results for lysozyme and insulin are presented. Changes in exposure to solvent and in the nature of contacts that develop through folding, association reactions and crystallization are described numerically. The computations suggest several generalizations. (a) Lattice contacts within the protein crystal are characterized by a significantly smaller involvement of non-polar side chains and a proportionately greater involvement of ionizable side chains than is found for protein folding or for protein association reactions important for biological function, (b) In helical regions the carbonyl oxygen of the first residue in the helix has high probability of being shielded from solvent, (c) Glycine is among the residues having exposure least affected by folding; this accords with the expectation that it lies at bends of the peptide chain on the surface of the molecule.     

Dynamic arrangement of ion pairs and individual contributions to the thermal stability of the cofactor-binding domain of glutamate dehydrogenase from Thermotoga maritima

The dynamics of a hyperthermophilic protein fragment in a water environment, as studied by performing molecular dynamics (MD) simulations at various temperatures, is compared to the dynamical behavior of a homologous mesophilic protein simulated under identical conditions. The effects on the stability of the spatial arrangement and mobility of the charged residues in solution were quantified by calculating free energy changes upon salt bridge formation in these proteins. Electrostatic free energy terms derived from a thermodynamic cycle were obtained by solving the linearized Poisson-Boltzmann equation for a series of protein conformations generated by MD simulations and placed subsequently in a continuum solvent medium. Our results show that the ion pairs are electrostatically stabilizing in most of the cases, but their individual contributions vary significantly. The greater contribution of the charged residues to the stability of the hyperthermophilic protein as compared with the mesophilic counterpart was evidenced only by the calculations that included conformations sampled at 343 and 373 K. The "dynamic" structure of the hyperthermophilic protein fragment simulated at elevated temperatures reveals an optimum placement of the ionizable residues within the protein structure as well as the role of their cooperative interactions in promoting thermal stability. The thermodynamic properties such as electrostatic free energy differences, configurational entropies, and specific heat capacities calculated in the dynamic context of the protein structure provided new insight into the mechanism of protein thermostabilization.     

Primary structure of an aliphatic nitrile-degrading enzyme, aliphatic nitrilase, from Rhodococcus rhodochrous K22 and expression of its gene and identification of its active site residue.

Peptides obtained by cleavage of a Rhodococcus rhodochrous K22 nitrilase, which acts on aliphatic nitriles such as acrylonitrile, crotonitrile, and glutaronitrile, have been sequenced. The data allowed the design of oligonucleotide probes which were used to clone a nitrilase encoding gene. Plasmid pNK21, in which 2.05-kb sequence covering the region encoding the nitrilase was was placed under the control of the lac promoter, directed overproduction of enzymatically active nitrilase in response to addition of isopropyl beta-D-thiogalactopyranoside in Escherichia coli. Sodium dodecyl sulfate-polyacrylamide gel electrophoresis of the cell extract showed that the amount of nitrilase was about 40% of the total soluble proteins, leading to the establishment of a simple purification of the nitrilase. The nucleotide sequence of the nitrilase gene predicts a protein composed of 383 amino acids (M(r) = 42,275), including only one cysteine. The amino acid sequence homology between the Rhodococcus nitrilase and the Klebsiella ozaenae bromoxynil nitrilase [Stalker et al. (1988) J. Biol. Chem. 263, 6310-6314] was 38.3%, and a unique cysteinyl residue (Cys-170) in the former nitrilase was conserved at the corresponding position in the latter nitrilase. Cys-170 of the Rhodococcus nitrilase was replaced by Ala or Ser by site-directed mutagenesis. Both mutations resulted in the complete loss of nitrilase activity, clearly indicating that this cysteinyl residue is essential for the catalytic activity.     

Simplified methods for pKa and acid pH-dependent stability estimation in proteins: removing dielectric and counterion boundaries

Much computational research aimed at understanding ionizable group interactions in proteins has focused on numerical solutions of the Poisson-Boltzmann (PB) equation, incorporating protein exclusion zones for solvent and counterions in a continuum model. Poor agreement with measured pKas and pH-dependent stabilities for a (protein, solvent) relative dielectric boundary of (4,80) has lead to the adoption of an intermediate (20,80) boundary. It is now shown that a simple Debye-Huckel (DH) calculation, removing both the low dielectric and counterion exclusion regions associated with protein, is equally effective in general pKa calculations. However, a broad-based discrepancy to measured pH-dependent stabilities is maintained in the absence of ionizable group interactions in the unfolded state. A simple model is introduced for these interactions, with a significantly improved match to experiment that suggests a potential utility in predicting and analyzing the acid pH-dependence of protein stability. The methods are applied to the relative pH-dependent stabilities of the pore-forming domains of colicins A and N. The results relate generally to the well-known preponderance of surface ionizable groups with solvent-mediated interactions. Although numerical PB solutions do not currently have a significant advantage for overall pKa estimations, development based on consideration of microscopic solvation energetics in tandem with the continuum model could combine the large deltapKas of a subset of ionizable groups with the overall robustness of the DH model.     

pH replica-exchange method based on discrete protonation states

We propose a new algorithm for obtaining proton titration curves of ionizable residues. The algorithm is a pH replica-exchange method (PHREM), which is based on the constant pH algorithm of Mongan et al. (J Comput Chem 2004;25:2038-2048). In the original replica-exchange method, simulations of different replicas are performed at different temperatures, and the temperatures are exchanged between the replicas. In our PHREM, simulations of different replicas are performed at different pH values, and the pHs are exchanged between the replicas. The PHREM was applied to a blocked amino acid and to two protein systems (snake cardiotoxin and turkey ovomucoid third domain), in conjunction with a generalized Born implicit solvent. The performance and accuracy of this algorithm and the original constant pH method (PHMD) were compared. For a single set of simulations at different pHs, the use of PHREM yields more accurate Hill coefficients of titratable residues. By performing multiple sets of constant pH simulations started with different initial states, the accuracy of predicted pK(a) values and Hill coefficients obtained with PHREM and PHMD methods becomes comparable. However, the PHREM algorithm exhibits better samplings of the protonation states of titratable residues and less scatter of the titration points and thus better precision of measured pK(a) values and Hill coefficients. In addition, PHREM exhibits faster convergence of individual simulations than the original constant pH algorithm.     

Implicit solvent models for flexible protein-protein docking by molecular dynamics simulation

The suitability of three implicit solvent models for flexible protein-protein docking by procedures using molecular dynamics simulation is investigated. The three models are (i) the generalized Born (GB) model implemented in the program AMBER6.0; (ii) a distance-dependent dielectric (DDD) model; and (iii) a surface area-dependent model that we have parameterized and call the NPSA model. This is a distance-dependent dielectric model modified by neutralizing the ionizable side-chains and adding a surface area-dependent solvation term. These solvent models were first tested in molecular dynamics simulations at 300 K of the native structures of barnase, barstar, segment B1 of protein G, and three WW domains. These protein structures display a range of secondary structure contents and stabilities. Then, to investigate the performance of the implicit solvent models in protein docking, molecular dynamics simulations of barnase/barstar complexation, as well as PIN1 WW domain/peptide complexation, were conducted, starting from separated unbound structures. The simulations show that the NPSA model has significant advantages over the DDD and GB models in maintaining the native structures of the proteins and providing more accurate docked complexes.     

Unfolding by temperature and guanidine hydrochloride of chicken pancreatic polypeptide

Thermal unfolding of chicken pancreatic polypeptide at two different concentrations was studied at various pH values. The thermal stability was higher at higher protein concentrations. The transition temperatures at two different protein concentrations changed with pH in parallel and decreased by about 30 degrees C on lowering pH from 5 to 2. The results on the thermal unfolding were analyzed by assuming that the dimerization constant is independent of pH, that the thermal unfolding occurs only after the pancreatic polypeptide dimers dissociated into the monomers, and that one ionizable group participates in the acid unfolding of the monomer. The free energy change for the unfolding of the pancreatic polypeptide monomer was estimated to be 1.4 kcal/mol. The unfolding of pancreatic polypeptide by guanidine hydrochloride at pH 6.0 and 25 degrees C was also studied. The stability to guanidine hydrochloride was higher at higher protein concentrations.     

The cyanide hydratase enzyme of Fusarium lateritium also has nitrilase activity

The filamentous fungus Fusarium lateritium produces cyanide hydratase when grown in the presence of cyanide. The cyanide hydratase protein produced at a high level in Escherichia coli shows a low but significant nitrilase activity with acetonitrile, propionitrile and benzonitrile. The nitrilase activity is sufficient for growth of the recombinant strain on acetonitrile, propionitrile or benzonitrile as the sole source of nitrogen. The recombinant enzyme shows highest nitrilase activity with benzonitrile. Site-directed mutagenesis of the F. lateritium cyanide hydratase gene indicates that mutations leading to a loss of cyanide hydratase activity also lead to a loss of nitrilase activity. This suggests that the active site for cyanide hydratase and nitrilase activity in the protein is the same. This is the first evidence of cyanide hydratase having nitrilase activity.