Structural disorder in proteins

The refinement of X-ray structural data gives the mean square displacements, x ², at each position in the protein molecule. In order to get information on the significance of such values different refinement methods have been compared. The metmyoglobin structure was determined at 300 K and x ²-values were obtained with the restrained refinement procedure in reciprocal space of Konnert and Hendrickson. A comparison with the results of Frauenfelder et al. was used for an error estimation. The inclusion of surface bound water increases the accuracy of the results but does not change the general picture. For erythrocruorin (CTT3) a refinement was performed in reciprocal space and compared with a refinement in real space performed earlier. The x ²-values obtained from both procedures are similar although the reciprocal space refinement gives results which are physically more reasonable.A comparison of the disorder in myoglobin and erythrocruorin showed that the structural similarity results in a similarity in the disorder. Contacts of molecules in the crystal do not dominate the disorder although they locally influence x ²-values. CTT3 shows large disorder in the heme region in contrast to myoglobin. The differences in the rigidity of the F-helix can be correlated with the oxygen affinities supporting models for O₂ binding developed by Frauenfelder et al.     

Structural domains in RNAi

Structural and biochemical studies have begun to elucidate the pathway of RNA silencing that leads to the formation of the RISC complex. The outstanding feature of this pathway is the precise recognition and processing of double-stranded RNA. We present a review of recent structures that illustrate the molecular mechanisms contributing to these two related functions, highlighting models of Drosha, Dicer, and RISC function.     

Structural polymorphism in DNA

We have used the enzyme micrococcal nuclease and the methylating reagent dimethyl sulfate to examine the structural properties of eukaryotic DNAs. Our studies demonstrate extensive structural polymorphism in the DNA double helix. Moreover, we find that the distribution of helical variants is in some instances correlated with the functional organization of the DNA. These observations raise the possibility that eukaryotic DNAs may be organized into discrete functional units having characteristic structural properties. In addition, we find that boundaries between different functional units are typically marked by DNA segments having unusual conformational properties. Such structural perturbations could serve as signals in the utilization of genetic information in eukaryotes, and may be important in a variety of different protein-DNA interactions.     

Structural neuroimaging in autism

Structural neuroimaging studies done by means of magnetic resonance imaging (MRI) have provided important insights into the neurobiological basis for autism. The aim of this article is to review the current state of knowledge regarding structural brain abnormalities in autism. Results of MRI studies dealing with total brain volume, the volume of the cerebellum, caudate nucleus, thalamus, amygdala, hippocampus and the area of the corpus callosum are summarized. Existing research suggests that autistic individuals have larger total brain, cerebellar and caudate nucleus volumes; however, the area of the corpus callosum is reduced. Results of studies involving the amygdala and hippocampus volume in autistic subjects remain inconsistent and no changes have been detected in thalamic volume.     

Structural disorder in eukaryotes

Based on early bioinformatic studies on a handful of species, the frequency of structural disorder of proteins is generally thought to be much higher in eukaryotes than in prokaryotes. To refine this view, we present here a comparative prediction study and analysis of 194 fully described eukaryotic proteomes and 87 reference prokaryotes for structural disorder. We found that structural disorder does distinguish eukaryotes from prokaryotes, but its frequency spans a very wide range in the two superkingdoms that largely overlap. The number of disordered binding regions and different Pfam domain types also contribute to distinguish eukaryotes from prokaryotes. Unexpectedly, the highest levels--and highest variability--of predicted disorder is found in protists, i.e. single-celled eukaryotes, often surpassing more complex eukaryote organisms, plants and animals. This trend contrasts with that of the number of domain types, which increases rather monotonously toward more complex organisms. The level of structural disorder appears to be strongly correlated with lifestyle, because some obligate intracellular parasites and endosymbionts have the lowest levels, whereas host-changing parasites have the highest level of predicted disorder. We conclude that protists have been the evolutionary hot-bed of experimentation with structural disorder, in a period when structural disorder was actively invented and the major functional classes of disordered proteins established.     

结构生物学研究在中国

1970年代初期,中国科学工作者测定了亚洲地区第一个蛋白质晶体结构——猪胰岛素三方二锌晶体结构,成为中国结构生物学历史发展的起点.进入新世纪,该学科领域已进入国际前沿,展现出快速发展态势,正在迎来发展新时期.本篇评述包含"历史发展","现代化实验设施建设"和"深入生命世界,走进国际前沿——近年代表性研究成果集萃"三个主题节段,以较全视野反映结构生物学研究在中国的发展历程.     

Structural organization of saponins in Caryophyllaceae

Phytochemistry Reviews - Saponins in Caryophyllaceae were subjected to many structural elucidations for several decades leading to big datasets of molecules essentially based on four aglycones:...     

后基因组时代中的结构生物学

20 0 0年 6月 2 6日 ,美英两国首脑会同公私两大人基因组测序集团 ,在华盛顿白宫东厅正式向世人宣告 :人基因组的工作草图 (ｗｏｒｋｉｎｇｄｒａｆｔ)已经绘制完成 .以此为标志 ,在人类跨进 2 1世纪历史新纪元之际 ,生命科学也正在迎来一个崭新的时代 ,即后基因组时代 (ｐｏｓｔ ｇｅｎｏｍｅｅｒａ) .这是生命科学历史发展中一次新的飞跃 .2 0世纪生物学的最基本成就是揭示生命机体的世代遗传主要是以基因为载体的核酸负责 ,有机体的当代生命活动主要决定于蛋白质的结构与功能 ,从而将整个生物学推进到以核酸和蛋白质为中心的分子生物学时…     

Structural proteomics in drug discovery

High-throughput, automated or semiautomated methodologies implemented by companies and structural genomics initiatives have accelerated the process of acquiring structural information for proteins via x-ray crystallography. This has enabled the application of structure-based drug design technologies to a variety of new structures that have potential pharmacologic relevance. Although there remain major challenges to applying these approaches more broadly to all classes of drug discovery targets, clearly the continued development and implementation of these structure-based drug design methodologies by the scientific community at large will help to address and provide solutions to these hurdles. The result will be a growing number of protein structures of important pharmacologic targets that will help to streamline the process of identification and optimization of lead compounds for drug development. These lead agonist and antagonist pharmacophores should, in turn, help to alleviate one of the current critical bottlenecks in the drug discovery process; that is, defining the functional relevance of potential novel targets to disease modification. The prospect of generating an increasing number of potential drug candidates will serve to highlight perhaps the most significant future bottleneck for drug development, the cost and complexity of the drug approval process.     

Structural variation in PWWP domains

The PWWP domain is a ubiquitous eukaryotic protein module characterised by a region of sequence similarity of approximately 80 amino acids containing a highly conserved PWWP motif. It is frequently found in proteins associated with chromatin. We have determined the structure of a PWWP domain from the S. pombe protein SPBC215.07c using NMR spectroscopy. The structure is composed of a five stranded beta barrel followed by two alpha helices. Comparison to the recently reported structure of a homologous domain from the mammalian DNA methyltransferase Dnmt3b reveals substantial differences both in the C-terminal helical region and in the PWWP motif.     

Structural Genomics in Pharmaceutical Design

Journal of Structural and Functional Genomics -     

Structural differences in reciprocal translocations

Summary Interchange segment sizes and the sizes of chromosome imbalance arising from the different modes of meiotic segregation were measured in a selected sample of 20 reciprocal translocations (Rcp). The Rcp were selected by two modes of ascertainment: (I) neonates with an unbalanced form of the translocation, and (II) couples with recurrent spontaneous abortions without evidence of full-term translocation aneuploid offspring.The measurements (% of haploid autosomal length: %HAL) were plotted as the observed or potential chromosomal imbalance with monosomy (abscissa) and trisomy (ordinate). It was found that (a) the interchange segments were larger in the spontaneous abortion Rcp, (b) that all of the imbalances observed in full-term neonates plotted close to the origin and to the left of the line joining 4% trisomy to 2% monosomy, and (c) the imbalances observed in the neonates in each individual Rcp were of the smallest size possible arising by any segregation mode.It was concluded that a major factor in the survival to term of aneuploid conceptuses is the size (proportion of genome) of the chromosome abnormality, irrespective of the origin of the chromosome regions. These results are discussed in relation to their use as a model to evaluate the risk of abnormal offspring in the progeny of translocation heterozygotes (the Chromosome Imbalance Size-Viability Model).     

Structural transition in peptide nanotubes

Phase transitions in organic and inorganic materials are well-studied classical phenomena, where a change in the crystal space group symmetry induces a wide variation of physical properties, permitted by the crystalline symmetry in each phase. Here we observe a conformational induced transition in bioinspired peptide nanotubes (PNTs). We found that the PNTs change their original molecular assembly from a linear peptide conformation to a cyclic one, followed by a change of the nanocrystalline structure from a noncentrosymmetric hexagonal space group to a centrosymmetric orthorhombic space group. The observed transition is irreversible and induces a profound variation in the PNTs properties, from the microscopic to the macroscopic level. In this context, we follow the unique changes in the molecular, morphological, piezoelectric, second harmonic generation, and wettability properties of the PNTs.