SNase R在胍变性过程中构象与活力变化的比较

以紫外差光谱、荧光光谱为监测手段对金黄色葡萄球菌核酸酶类似物(SNase R)在胍溶液中构象与活力变化进行了比较.SNase R在Llmol L0.8mol L和0.5mol L胍溶液变性时变性过程均为两个一级反应,但是酶在上述胍浓度下失活的速度远快于构象变化的速度:酶在同一胍浓度下活力丧失的程度也远快于构象变化的程度.上述结果表明:SNase R的活性部位可能位于柔性较大的区域.     

金黄色葡萄球菌核酸酶基因的片段缺失与定点突变

金黄色葡萄球菌核酸酶R(SNase R)是金黄色葡萄球菌核酸酶(SNase A)的一种类似物,具有与SNaseA相同的酶活性,与SNase A唯一不同之处是在N端多出6个氨基酸残基。为了得到完整的SNase基因并使其在E.Coli中表达,我们利用单链U模板—单引物突变法,将为6个额外氨基酸残基编码的18个氨基酸残基删除,其突变率可达90％。进而,完整的SNase A基因被重组入表达载体pBV221。细菌表达产物的PAGE分析结果指出,SNase A在E.coli中得到高效表达。与此同时,我们利用两个不同的引物在单链U模板上同时介导两种不同类型的突变(片段缺失、碱基取代)其突变率可达83％以上,这为进行多种类型的高效突变提供一个有用的方法。本文也对影响突变率的某些实验因素进行了讨论。     

金黄色葡萄球菌核酸酶C末端去9肽对酶蛋白溶液构象的影响

通过多维异核核磁共振方法,结合运用荧光和圆二色等光谱方法,比较研究了V8菌株金黄色葡萄球菌核酸酶（含149个氨基酸残基）,酶蛋白1－140片段（SNase140)以及在TMP（thymidine 5′-monophosphate)和Ca^2 存在下的SNase140的溶液构象状态。探讨了酶蛋白C末端去9肽后对酶蛋白构象和活力的影响。研究指出,远离酶蛋白活性部位残基间相互作用的变化,将通过酶蛋白两个亚结构域之间所形成的氢键,影响酶蛋白活性部位的空间构象,从而影响酶蛋白的活力。     

在金黄色葡萄球菌核酸酶测活体系中Ca~(2+)与底物DNA的结合

将携带金黄色葡萄球菌核酸酶(SNase)基因的质粒pFOG405转化到大肠杆菌SE6004中,获得分泌表达的SNase,在该酶的测活体系中,观察到激活剂Ca~(2+)与底物DNA微弱结合,引起底物DNA的UV光谱在260nm附近明显下降。在Ca~(2+)浓度为10mM时,底物DNA紫外区CD光谱在270—280nm和210—230nm处〔θ〕值减少,〔θ〕值为零的点从260nm移至257nm。这一结果表明,Ca~(2+)与底物DNA在缺少SNase的情况下仍能结合,引起DNA分子构象变化。     

在金黄色葡萄球菌核酸酶测活体系中Ca~(2+)与底物DNA的结合

将携带金黄色葡萄球菌核酸酶(SNase)基因的质粒pFOG405转化到大肠杆菌SE6004中,获得分泌表达的SNase,在该酶的测活体系中,观察到激活剂Ca~(2+)与底物DNA微弱结合,引起底物DNA的UV光谱在260nm附近明显下降。在Ca~(2+)浓度为10mM时,底物DNA紫外区CD光谱在270—280nm和210—230nm处〔θ〕值减少,〔θ〕值为零的点从260nm移至257nm。这一结果表明,Ca~(2+)与底物DNA在缺少SNase的情况下仍能结合,引起DNA分子构象变化。     

生物物理学报第九卷1993年总目录

分子生物物理 期 页 盐酸己烷基双狐对肌酸激酶的活力及构象的影响 李学刚 邹承鲁11茶刺蛾颗粒体病毒病毒粒子的表面增强喇曼散射(SERS)光谱研究 刘新民 黄天菩 鲍培谛 伍铁桥 杨志荣 刘仕贵 16 淀粉麦芽寡糖酶的连续测活 赫荣乔 赵康源110 在银溶胶中甘氨酸和甘氨酸二肽的表面增强拉曼散射 孙永泰 杨景文 张极震 朱克莉 梁 沂116 AZI—Asp人胰岛素突变体〕4埃分辨率品体结构研究 金 雷 黄伟军 曾宗浩 王大成L.La。g4laer J.Mark。se。120 SNaseR与SNase酶学性质的比较研究 张广发 静国忠 126 括楼核糖核酸酶的性质研究 赵 罩 华 陵 …     

鹅观草属三个种的染色体组分析与同工酶分析

本文通过对鹅观草属的三个种:鹅观草(Roegneria kamoji Ohwi)、纤毛鹅观草(R. ciliaris (Trin.) Nevski)和竖立鹅观草(R. japonensis (Honda)Keng)的染色体组分析和二种同工酶电泳酶谱的分析,研究了这三个种的系统关系。两个种均含有两个相同的染色体组。R. kamoji和R. ciliari、R. japonensis的杂种F_1减数分裂均不正常,不能结实;而R. ciliaris和R. japonensis的正反交杂种F_1减数分裂规则,结实正常,两个种之间无生殖隔离。R. kamoji的酯酶和酸性磷酸酯酶同工酶谱与R. ciliaris和R. japonensis有明显区别,而后二种的上述酶谱无明显差异。上述结果均一致地支持了将R. ciliaris和R. japonensis合并为一种的观点,将R. japonensis处理为R. ciliaris的变种。     

灰色链霉菌胰蛋白酶在变铅青链霉菌中的异源表达及酶学性质分析

胰蛋白酶作为一种重要的丝氨酸蛋白酶被广泛应用于食品、医药和皮革等工业领域.本文成功实现了灰色链霉菌来源的胰蛋白编码基因在变铅青链霉菌中的高效活性表达,并对其酶学性质进行分析比较.以灰色链霉菌ATCC10137基因组为模板,获得胰蛋白酶编码基因sprT并克隆至表达质粒pIJ86,成功构建了重组链霉菌工程菌TK24/pIJ86-sprT.以R2YE和SELF为发酵培养基,最高酶活分别达9.21 U/mL和8.61 U/mL.酶学性质分析表明,和牛胰蛋白酶(BT)相比,重组链霉菌胰蛋白酶(rSGT)的耐酸能力强,具有较广的pH;且rSGT对酰胺键具有更高的特异性;此外,Zn2+和有机溶剂分别对rSGT的酯酶活力和酰胺酶活力具有促进作用;本研究结果为rSGT的性质改造以及工业应用提供了依据.     

甲壳素酶Chisb的定向进化及生物转化合成几丁寡糖

甲壳素酶具有广泛的工业应用前景,如可将虾壳、蟹壳和其他甲壳废物降解成以几丁寡糖为主的高附加值产品,但野生型甲壳素酶催化效率低,大大限制了几丁寡糖的生产。笔者在前期研究中表达了一个具有较高效催化效率的甲壳素酶Chisb,并对其酶学性质进行了初步研究。为进一步提高甲壳素酶Chisb的催化效率,以R13NprB-C-SP-H为亲本,采用易错PCR(Error-pronePCR)技术构建随机突变体文库,对甲壳素酶Chisb进行定向进化。经过96孔板初筛和摇瓶复筛,获得了两个催化效率进一步提高的突变体C43D和E336R。对突变体的酶学性质进行分析, C43D和E336R的最适催化温度为55℃, C43D的最适pH为5.0,E336R的最适pH为9.0;其催化效率相比对照分别提高了1.35倍和1.57倍;而E336R和C43D催化产几丁寡糖的含量分别为2.53 g/L和2.06 g/L,相比对照(0.89 g/L)分别提高了2.84倍和2.31倍;底物转化率分别为84.3%和68.7%,相比对照(29.7%)分别提高了54.6%和39%。研究表明,通过易错PCR引入随机突变的方法能够有效提高甲壳素酶Chisb的催化效率。上述研究获得的催化效率提高的正向突变体及其酶学性质分析对生物转化合成几丁寡糖具有重要研究意义和应用价值。     

纤毛鹅观草与本田鹅观草的生物系统学研究

本文通过对鹅观草属的两个种:本田鹅观草(Roegneria hondai Kitagawa)和纤毛鹅观草(R.ciliaris(Trin)Nevski)及其种间杂种的形态变异、染色体配对行为和同工酶电泳酶谱的分析,研究了这两个种间的亲缘关系,杂种F_1减数分裂染色体配对数很高,F_1自然条件下具有低的结实率。R.ciliaris根部和幼叶的酯酶、过氧化物酯同工酶谱与R.hondai的酶谱间存在差异。上述结果表明,R.ciliaris和R.hondai亲缘关系很近,享有两个共同的基本染色体组,可拟定R.hondai的染色体组为S~hy~h。R.ciliaris同R.hondai间的亲缘关系较R.ciliaris同R.pendulina和R.pendulina同R.hondai间更近。     

Conformational adjustments of SNase R and its N-terminal fragments probed by monoclonal antibodies

Two monoclonal antibodies specific for staphylococcal nuclease R (SNase R) (McAb2C9 and McAb1B8) were prepared and used to probe protein folding during peptide elongation, by measuring antibody binding to seven N-terminal fragments (SNR141, SNR135, SNR121, SNR110, SNR102, SNR79 and SNR52) of SNase R. Comparative studies of the conformations of the N-terminal fragments have shown that all seven fragments of SNase R have a certain amount of residual structure, indicating that folding may occur during elongation of the nascent peptide chain. We show that the binding abilities of the intact enzyme and its seven fragments to the monoclonal antibodies are not simply proportional to the length of the peptide chain, suggesting that there may be continuous conformational adjustment in the nascent peptide chain as new C-terminal amino acids are added. A folding intermediate close in structure to the native state but with structural features in common with SNR121 is highly populated in 0.6 M GuHCl, and is also formed transiently during folding.     

Correlation Times and Adiabatic Barriers for Methyl Rotation in SNase

The relation of rotational correlation times to adiabatic rotational barriers for alanine methyl groups in staphylococcal nuclease (SNase) is investigated. The hypothesis that methyl rotational barriers may be useful probes of local packing in proteins is supported by an analysis of ten X-ray crystal structures of SNase mutants. The barrier heights are consistent across a set of ten structures of a native SNase and mutants containing single-point mutations or single or double insertions, most in a ternary SNase complex. The barriers for different methyls have a range of 7.5 kcal/mol, which at 300 K would correspond to a five-order-of-magnitude range in correlation time. It is demonstrated that adiabatic rotational barriers can fluctuate significantly during an MD simulation of hydrated SNase, but that a Boltzmann weighted average is predictive of rotational correlation times determined from correlation functions. Even if a given methyl is on average quite sterically hindered, infrequently sampled low-barrier conformations may dominate the Boltzmann distribution. This result is consistent with the observed uniformity of NMR correlation times for (13)C-labeled methyls. The methyl barriers in simulation fluctuate on multiple time scales, which can make the precise relationship between methyl rotational correlation time and methyl rotation barriers complicated. The implications of these issues for the interpretation of correlation times determined from NMR and simulation are discussed.     

Deletion of the omega-loop in the active site of staphylococcal nuclease. 1. Effect on catalysis and stability

The high-resolution X-ray structure of wild-type staphylococcal nuclease (E43 SNase) suggests that Glu 43 acts a general basic catalyst to assist the attack of water on a phosphodiester substrate [Loll, P., & Lattman, E. E. (1989) Proteins: Struct., Funct., Genet. 5, 183]. Glu 43 is located at the base of the solvent-exposed and conformationally mobile omega-loop in the active site of E43 SNase having the sequence Glu43-Thr44-Lys45-His46-Pro47-Lys48- Lys49-Gly50-Val51-Glu52, where the gamma-carboxylate of Glu 52 is hydrogen bonded to the amide hydrogen of Glu 43. With a metabolic selection for SNase activity produced in an Escherichia coli host, we detected an unexpected deletion of residues 44-49 of the omega-loop of E43 SNase in cassette mutagenesis experiments designed to randomize codons 44 and 45 in the omega-loop and increase the activity of the previously described E43D mutation (D43 SNase). A high-resolution X-ray structure of D43 SNase has revealed that the E43D substitution significantly changes the structure of the omega-loop, reduces the interaction of the essential Ca2+ ion with its active-site ligands, and diminishes the network of hydrogen-bonded water molecules in the active site [Loll, P., & Lattman, E. E. (1990) Biochemistry 29, 6866]. This deletion of six amino acids from the omega-loop generates a protein (E43 delta SNase) having a partially solvent-exposed, surface beta-turn with the sequence Glu43-Gly50-Val51-Glu52; the structure of this beta-turn is addressed in the following article [Baldisseri et al. (1991) Biochemistry (following paper in this issue)].(ABSTRACT TRUNCATED AT 250 WORDS)     

Deletion of the omega-loop in the active site of staphylococcal nuclease. 2. Effects on protein structure and dynamics

It has been shown (Poole et al., 1991) that deletion of residues 44-49 from the sequence of staphylococcal nuclease (E43 SNase) results in an enzyme (E43 delta SNase) that is significantly more active than D43 SNase, an enzyme that differs from the wild-type enzyme by deletion of a single methylene group. In addition, both E43 delta SNase and D43 delta SNase are significantly more stable than their respective parent enzymes. Herein we use high-resolution 2D and 3D NMR spectroscopy to characterize the solution conformations of the four enzymes in order to better understand their differences in stability and activity. The backbone assignments of E43 SNase were extended to the three mutant proteins (uniformly 15N-enriched) by using 2D HSQC, 3D HOHAHA-HMQC, and 3D NOESY-HMQC spectra. The NOE patterns observed for E43 and D43 SNase in solution are consistent with the crystal structures of these proteins. The NOESY data further show that the intact and deleted proteins have essentially the same structures except that (a) the disordered omega-loops in the intact proteins are replaced by tight type II' turns, formed by residues 43-50-51-52, in the deleted proteins and (b) the orientation of the D43 side chain in crystalline D43 SNase differs from that found for D43 delta SNase in solution. Except for regions neighboring the omega-loops, the intact and deleted proteins show nearly identical amide 15N and 1H chemical shifts. In contrast, there are widespread, small and similar, chemical shift differences (a) between E43 SNase and D43 SNase and (b) between E43 delta SNase and D43 delta SNase.(ABSTRACT TRUNCATED AT 250 WORDS)     

P100, a transcriptional coactivator,is a human homologue of staphylococcal nuclease.

Staphylococcus aureus nuclease (SNase) homologues, previously thought to be restricted to bacteria and archaea, are demonstrated by sequence analysis to be present also in eukaryotes. The human cellular coactivator p100 is shown to contain four repeats, each of which is a SNase homologue. Surprisingly, these repeats are unlikely to possess SNase-like activities as each lacks equivalent SNase catalytic residues, yet they may mediate p100''s single-stranded DNA-binding function. Products of Corydalis sempervirens and Saccharomyces cerevisiae open reading frames are predicted to adopt the same fold and possess similar functions as SNase. Five additional hypothetical proteins of bacterial origin are also predicted to be active SNase-like nucleases, including one that appears to be C-terminally truncated in a manner analogous to an engineered active SNase variant. Conservation of Asp-19 and Asp-83 among these homologues suggests a re-evaluation of the roles of these residues in Ca(2+)-binding and/or catalysis.     

A molecular dynamics simulation of SNase and its hydration shell at high temperature and high pressure

Temperature- and pressure-induced unfolding of staphylococcal nuclease (SNase) was studied by Royer, Winter et al. using a variety of experimental techniques (SAXS, FT-IR and fluorescence spectroscopy, DSC, PPC, densimetry). For a more detailed understanding of the underlying mechanistic processes of the different unfolding scenarios, we have carried out a series of molecular dynamics (MD) computer simulations on SNase. We investigated the initial changes of the structure of the protein upon application of pressure (up to 5 kbar) and discuss volumetric and structural differences between the native and pressure pre-denatured state. Additionally, we have obtained the compressibility of the protein and hydration water and compare these data with experimental results. As water plays a crucial role in determining the structure, dynamics and function of proteins, we undertook a detailed analysis of the structure of the interfacial water and the protein-solvent H-bond network as well. Moreover, we report here also MD results on the temperature-induced unfolding of SNase. The time evolution of the protein volume and solvent accessible surface area during thermal unfolding have been investigated, and we present a detailed discussion of the temperature-induced unfolding pathway of SNase in terms of secondary and tertiary structural changes.     

Kinetic and conformational effects of lysine substitutions for arginines 35 and 87 in the active site of staphylococcal nuclease

The high-resolution X-ray crystal structure of staphylococcal nuclease (SNase) suggests that the guanidinium groups of Arg 35 and Arg 87 participate as electrophilic catalysts in the attack of water on the substrate phosphodiester. Both arginine residues have been replaced with "conservative" lysine residues so that both the importance of these residues in catalysis and the effect of changes in electrostatic interactions on active site conformation can be assessed. The catalytic efficiencies of R35K and R87K are decreased by factors of 10(4) and 10(5) relative to wild-type SNase, with R87K showing a very significant reduction in its affinity for both DNA substrate and the competitive inhibitor thymidine 3',5'-bisphosphate (pdTp). The thermal denaturation behavior of both mutant enzymes differs from that of wild type both in the absence and in the presence of the active site ligands Ca2+ and pdTp. Both the 1H NMR chemical shifts and interresidue nuclear Overhauser effects (NOEs) of residues previously assigned to be in the hydrophobic core of SNase are altered in R35K and R87K. These observations, similar to those recently reported by our laboratories for substitutions for Glu 43 [Hibler, D. W., Stolowich, N. J., Reynolds, M. A., Gerlt, J. A., Wilde, J. A., & Bolton, P. H. (1987) Biochemistry 26, 6278; Wilde, J. A., Bolton, P. H., Dell'Acqua, M., Hibler, D. W., Pourmotabbed, T., & Gerlt, J. A. (1988) Biochemistry 27, 4127], suggest that lysine substitutions are not conservative in SNase and disrupt the conformation of the active site.(ABSTRACT TRUNCATED AT 250 WORDS)