mRNA环结构对蛋白质折叠速率的影响

前期的相关研究发现mRNA二级结构中存在对蛋白质折叠速率的重要影响因素.而mRNA二级结构中普遍存在着各种复杂的环结构,这些环结构是否对蛋白质折叠速率也有重要的影响呢?不同的环结构对蛋白质折叠速率的影响是否相同呢?基于此想法,建立了一个包含mRNA内部环、发夹环、膨胀环和多分支环等环结构信息和相应蛋白质折叠速率的数据库.对于数据库中的每一个蛋白质,计算了mRNA二级结构中各种环结构碱基含量、配对碱基含量及单链碱基含量等参量,分析了各参量与相应蛋白质折叠速率的相关性.结果显示,各种环结构碱基含量与蛋白质折叠速率均呈极显著或显著正相关.说明mRNA环结构对蛋白质折叠速率有重要的影响.进一步,把蛋白质按照不同折叠类型或不同二级结构类型分组后,对每一组蛋白质重复上述的分析工作.结果表明,对不同类蛋白质,mRNA的各种环结构对其相应蛋白质折叠速率的影响存在着显著差异.上述研究将为进一步开展有关mRNA和蛋白质折叠速率的研究奠定理论基础.     

Mutagenesis of histidine 26 demonstrates the importance of loop-loop and loop-protein interactions for the function of iso-1-cytochrome c.

In yeast iso-1-cytochrome c, the side chain of histidine 26 (His26) attaches omega loop A to the main body of the protein by forming a hydrogen bond to the backbone atom carbonyl of glutamic acid 44. The His26 side chain also forms a stabilizing intra-loop interaction through a hydrogen bond to the backbone amide of asparagine 31. To investigate the importance of loop-protein attachment and intra-loop interactions to the structure and function of this protein, a series of site-directed and random-directed mutations were produced at His26. Yeast strains expressing these variant proteins were analyzed for their ability to grow on non-fermentable carbon sources and for their intracellular production of cytochrome c. While the data show that mutations at His26 lead to slightly decreased intracellular amounts of cytochrome c, the level of cytochrome c function is decreased more. The data suggest that cytochrome c reductase binding is affected more than cytochrome c oxidase or lactate dehydrogenase binding. We propose that mutations at this residue increase loop mobility, which, in turn, decreases the protein's ability to bind redox partners.     

Protein loop modeling by using fragment assembly and analytical loop closure

Protein loops are often involved in important biological functions such as molecular recognition, signal transduction, or enzymatic action. The three dimensional structures of loops can provide essential information for understanding molecular mechanisms behind protein functions. In this article, we develop a novel method for protein loop modeling, where the loop conformations are generated by fragment assembly and analytical loop closure. The fragment assembly method reduces the conformational space drastically, and the analytical loop closure method finds the geometrically consistent loop conformations efficiently. We also derive an analytic formula for the gradient of any analytical function of dihedral angles in the space of closed loops. The gradient can be used to optimize various restraints derived from experiments or databases, for example restraints for preferential interactions between specific residues or for preferred backbone angles. We demonstrate that the current loop modeling method outperforms previous methods that employ residue‐based torsion angle maps or different loop closure strategies when tested on two sets of loop targets of lengths ranging from 4 to 12. Proteins 2010. © 2010 Wiley‐Liss, Inc.     

家兔的开环及闭环视动震颤（OKN）研究

研究了家兔闭环及开环状态的ＯＫＮ反应。闭环时,ＯＫＮ眼动速度与刺激速度成正比,增益接近１。当固定受刺激眼形成开环状态时,ＯＫＮ眼动速度远大于刺激速度,增益可达１０２左右,说明ＯＫＮ系统是由运动跟踪的负反馈机制控制的;刺激范围缩小则眼动反应减弱,表明ＯＫＮ系统对运动信息具有空间总和作用;以视野中不同高度的局部刺激时,发现视网膜中央视带比周边部对ＯＫＮ刺激的敏感性高;单光点刺激视带中央可诱发出清楚的ＯＫＮ反应,这为临床上应用ＯＫＮ客观测定视网膜功能和运动感知提供了可能性。     

Structural and dynamical correlations in PfHGXPRT oligomers: A molecular dynamics simulation study

PfHGXPRT is a key enzyme involved in purine nucleotide salvage pathway of the malarial parasite, Plasmodium falciparum. Atomistic molecular dynamics simulations have been performed on two types of PfHGXPRT dimers (D1 and D3) and its tetramer in their apo and ligand-bound states. A significant event in the catalytic cycle is the dynamics of a gate that provides access for the ligand molecules to the reaction center. The gate is formed by loops II and IV, the former being the most flexible. Large amplitude conformational changes have been observed in active site loop II. Upon complete occupancy of the active site, loop II gets stabilized due to specific interactions between its residues and the ligand molecules. Remote loop, X, is seen to be less fluxional in the D3 dimer than in D1 which is rationalized as due to the greater number of inter-subunit contacts in the former. The presence of ligand molecules in subunits of the tetramer further reduces the flexibility of loop X epitomizing a communication between this region and the active sites in the tetramer. These observations are in accordance with the outcomes of several experimental investigations. Participation of loop X in the oligomerization process has also been discerned. Between the two types of dimers in solution, D1 tetramerizes readily and thus would not be present as free dimers. We conjecture an equilibrium to exist between D3 and the tetramer in solution; upon binding of the ligand molecules to the D3 dimer, this equilibrium shifts toward the tetramer.     

Accurate and efficient loop selections by the DFIRE-based all-atom statistical potential

The conformations of loops are determined by the water-mediated interactions between amino acid residues. Energy functions that describe the interactions can be derived either from physical principles (physical-based energy function) or statistical analysis of known protein structures (knowledge-based statistical potentials). It is commonly believed that statistical potentials are appropriate for coarse-grained representation of proteins but are not as accurate as physical-based potentials when atomic resolution is required. Several recent applications of physical-based energy functions to loop selections appear to support this view. In this article, we apply a recently developed DFIRE-based statistical potential to three different loop decoy sets (RAPPER, Jacobson, and Forrest-Woolf sets). Together with a rotamer library for side-chain optimization, the performance of DFIRE-based potential in the RAPPER decoy set (385 loop targets) is comparable to that of AMBER/GBSA for short loops (two to eight residues). The DFIRE is more accurate for longer loops (9 to 12 residues). Similar trend is observed when comparing DFIRE with another physical-based OPLS/SGB-NP energy function in the large Jacobson decoy set (788 loop targets). In the Forrest-Woolf decoy set for the loops of membrane proteins, the DFIRE potential performs substantially better than the combination of the CHARMM force field with several solvation models. The results suggest that a single-term DFIRE-statistical energy function can provide an accurate loop prediction at a fraction of computing cost required for more complicate physical-based energy functions. A Web server for academic users is established for loop selection at the softwares/services section of the Web site http://theory.med.buffalo.edu/.     

经直接与间接通路的视动震颤(OKN)眼动反应

采用鼻向及颞光栅图形刺激猫的半侧视网膜,以探讨鼻侧半神网膜至视束核的视动震颤直接通路及颞侧半视网膜经皮层至ＮＯＴ的间接通路对ＯＫＮ眼动反应的神经控制特性。实验结果显示：高速度刺激的闭环ＯＫＮ反应及开环ＯＫＮ反应均对鼻向运动刺激有明显的方向选择性;半侧视网膜刺激时,鼻侧半视网膜的鼻向ＯＫＮ增益明显高于颞侧半视网膜的鼻向增益,说明猫的ＫＯＮ眼动反应以跟踪鼻向运动为主,并且这种对鼻向运动刺激选择性主要来     

microRNA调控网络与肿瘤

microRNA(miRNA)是一类长度约为22nt的小分子非编码RNA,对基因表达进行转录后调控。基因调控网络由各种回路,如前馈和反馈回路组成。它通过将外界刺激整合成合适的输出信号,控制细胞从增殖到死亡几乎所有的生命活动。已知基因调控网络的失调与肿瘤的发生发展密切相关。新近的实验证据表明,miRNA广泛参与基因调控网络中的反馈和前馈回路。该文主要介绍miRNA在基因表达调控网络中的作用及其与肿瘤发生发展的关系。     

Characterization of a pilot plant airlift tower loop bioreactor. I: evaluation of the phase properties with model media

Investigations were carried out in a 9 m high, 4 m(3) volume, pilot plant airlift tower loop bioreactor with a draft tube. The reactor was characterized by measuring residence time distributions of the gas phase using pseudostochastic tracer signals and a mass spectrometer and by evaluating the mixing in the liquid phase with single-pulse tracer inputs. The local gas holdup and the bubble size (piercing length) were measured with two-channel electrical conductivity probes. The mean residence times and the intensities of the axial mixing in the riser and downcomer and the circulation times of the phases as well as the fraction of the recirculated gas phase were evaluated. The gas holdup in the riser is nearly uniform along the reactor. In the downcomer, it diminishes from top to bottom. The liquid phase dispersion coefficients, D(L), are smaller than those measured in the corresponding bubble columns. In the pilot plant with tap water the following relationship was found: D(Lr) = cw(SG) (n); with c = 203.4; n = 0.5;D(Lr)(cm(2) s(-1);) and W(SG)(cm s(-1)) where D(Lr) is the longitudinal dispersion coefficient in the riser and W(SG) is the superficial gas velocity. The gas phase dispersion coefficients in the riser of the pilot plant, D(Gr), are also enlarged with increasing superficial gas velocity, W(SG), however, no simple relationship exists. Parameter D(Gr) is the highest in the presence of antifoam agents, intermediate in tap water, and the smallest in ethanol solution.     

A Novel 8-nm Protein Cage Formed by Vibrio cholerae Acylphosphatase

Here we show the formation of an ~ 8-nm cage formed by the self-assembly of acylphosphatase from Vibrio cholerae O395 (Vc-AcP). The 12-subunit cage structure forms spontaneously and is stabilized through binding of sulfate ions at its exterior face and interfacial regions. Crystal structure and studies in solutions illuminate the basis for the formation of the cage, while a single (Cys20 → Arg) mutation (Vc-AcP-C20R) transforms Vc-AcP to a potent enzyme but disrupts the assembly into a trimer.     

Turnover and accessibility of a reentrant loop of the Na+-glutamate transporter GltS are modulated by the central cytoplasmic loop

Abstract

GltS of Escherichia coli is a secondary transporter that catalyzes Na⁺-glutamate symport. The structural model of GltS shows two homologous domains with inverted membrane topology that are connected by a central loop that resides in the cytoplasm. Each domain contains a reentrant loop structure. Accessibility of the Cys residues in two GltS mutants in which Pro351 and Asn356 in the reentrant loop in the C-terminal domain were replaced by Cys is demonstrated to be sensitive to the catalytic state supporting a role for the reentrant loops in catalysis. Saturating concentrations of the substrate L-glutamate protected both mutants against inactivation by thiol reagents, while the presence of the co-ion Na⁺ stimulated the inactivation of both mutants. Insertion of the 10 kDa biotin acceptor domain (BAD) of oxaloacetate decarboxylase of Klebsiella pneumoniae in the central cytoplasmic loop blocked the access pathway from the periplasmic side of the membrane to the cysteine residues in mutants P351C and N356C in the reentrant loop. Kinetically, insertion of BAD increased the maximal rate of uptake 2.7-fold while leaving the apparent affinity constants for L-glutamate and Na⁺ unaltered. The data suggests that insertion of BAD in the central loop results in conformational changes at the translocation site that lower the activation energy of the translocation step without affecting the access pathway from the periplasmic side for substrate and co-ions. It is concluded that changes in the central loop that connects the two domains may have a regulatory function on the activity of the transporter.     

Use of Implantable Loop Recorders to Unravel the Cause of Unexplained Syncope

Syncope is a symptom of many underlying disease states, which range from the relatively benign to the life threatening. There are numerous investigations done for patients with recurrent unexplained syncope which may have very low yield when it comes to making a definitive diagnosis. Recently, the implantable loop recorder (ILR) for continuous monitoring of the cardiac rhythm has been launched in India. This review will briefly discuss these current availabel strategies and focus on the usefulness of an ILR in the definitive diagnosis and treatment of patients with a recurrent unexplained syncope.     

Connectivity between surface and interior in catalytic subunits of acetylcholinesterases inferred from their X-ray structures

Catalytic activity and function of acetylcholinesterase (AChE; EC 3.1.1.7) have been recognized and studied for over a century and its quaternary and primary structures for about half a century, and its tertiary structure has been known for about 33 years. Clear understanding of relationships between the structure and the function is still pending for this enzyme. Hundreds of crystallographic, static snapshots of AChEs from different sources reveal largely one general backbone conformation with narrow entry into the active center gorge, tightly fit to accept one acetylcholine (ACh) molecule, in contrast to its high catalytic turnover. This short review of available X-ray structures of AChEs from electric ray Torpedo californica, mouse and human, finds some limited, yet consistent deviations in conformations of selected secondary structure elements of AChE relevant for its function. The observed conformational diversity of the acyl pocket loop of AChE, unlike the large Ω-loop, appears consistent with structurally dynamic INS data and solution-based SAXS experiments to explain its dominant role in controlling the size of the active center gorge opening, as well as connectivity between the immediate surroundings of the buried active Ser, and catalytically relevant sites on the AChE surface.

     

Dynamic mechanism for the serpin loop insertion as revealed by quantitative kinetics

The serpin conformational change by insertion of the reactive center loop into beta-sheet A plays a central role in multiple physiological consequences such as serine proteinase inhibition, latency and serpinopathic polymerization. To study the dynamic mechanism for the loop insertion, a novel kinetic method was established utilizing the ovalbumin mutant R339T/A352R; the loop insertion progressed after the cleavage of P1-P1' (Arg352-Ser353) by trypsin was quenched at pH 8 and 0.5 degrees C, and different conformers were quantified by separation using ion-exchange HPLC. The apparent first-order rate constant k(app) determined for various R339T/A352R derivatives differing in conformational stability was greatly increased by lowering the pH. The pH-dependence of k(app) indicated that the protonation of side-chain(s) with a pK(a) value of around 4.6 is a pre-requisite for the loop insertion. The theoretical rate constant k for the protonated form calculated from k(app) was highly variable, depending on the ovalbumin derivative; structural modifications that give increased mobility to helix F and the sheet-A half (s3A/s2A/s1A) resulted in a striking increase in the loop insertion rate constant k. The k values were determined at different temperatures for all the ovalbumin derivatives, and DeltaH(double dagger) and DeltaS(double dagger) values for the loop insertion reaction were determined according to the transition theory. The formation of the transition state was highly endothermic with minor entropy gain, requiring a DeltaG(double dagger) larger than 18 kcal/mol, which can offset the hydrogen-bond cleavages between s3A and s5A. These results are consistent with the transition state with an opened sheet A and altered orientation of helix F.     

DNA loop anchorage region colocalizes with the replication origin located downstream to the human gene encoding lamin B2

The recently developed procedure of topoisomerase II-mediated DNA loop excision has been used to analyze the topological organization of a human genome fragment containing the gene encoding lamin B2 and the ppv1 gene. A 3.5 kb long DNA loop anchorage/topoisomerase II cleavage region was found within the area under study. This region includes the end of the lamin B2 coding unit and an intergenic region where an origin of DNA replication was previously found. These observations further corroborate the hypothesis that DNA replication origins are located at or close to DNA loop anchorage regions. J. Cell. Biochem. 69:13–18, 1998. © 1998 Wiley-Liss, Inc.     

An investigation of cysteine mutants on the cytoplasmic loop X/XI in the melibiose transporter of Escherichia coli by using thiol reagents: implication of structural conservation of charged residues

The melibiose transporter (Mel B) of Escherichia coli is a cation-coupled (H(+), Li(+), and Na(+)) membrane protein (MW 50 kDa) consisting of 12 transmembrane helices that are connected by periplasmic and cytoplasmic loops, with both the C- and N-ends located on the cytoplasmic side of the membrane. Previous investigations on the largest cytoplasmic loop X/XI indicated that it is a functional re-entrant loop. In this communication, the cysteine mutants on loop X/XI were studied with charged thiol reagents MTSES, MTSET, and IAA for both the inhibition patterns and charge replacement/function rescue of inactive mutants in which the original charged residues were replaced by neutral cysteines. Strong inhibitions were observed in T373C and V376C by both MTSES and MTSET, consistent with previous results of PCMBS inhibition. The thiol reagents failed to recover the activities of inactive mutants D351C, D354C, and R363C and to inhibit active mutants E357C, K359C, and E365C to any significant extent, suggesting a structural conservation at D351, D354, and R363 and tolerance of structural variations at E357, K359, and E365. The results are consistent with previous observation of structural conservation of functionally charged residues in the transmembrane domains and extend to a loop the contention that in the melibiose transporter functionally important charged residues are structurally conserved.     

Serpins and other covalent protease inhibitors

Serpins are irreversible covalent 'suicide' protease inhibitors. In the past two years, important advances in the structural biology of serpins have been forthcoming with the crystal structures of a covalent complex between trypsin and alpha1-antitrypsin, and of a Michaelis encounter complex between trypsin S195A and serpin 1B from Manduca sexta. These structures have helped elucidate many aspects of the mechanism of action of serpins. Also, the crystal structure of the cysteine protease caspase-8 in complex with the inhibitor p35 has revealed a new family of suicide protease inhibitors.