Automated assembly of protein blocks for database searching.

A system is described for finding and assembling the most highly conserved regions of related proteins for database searching. First, an automated version of Smith's algorithm for finding motifs is used for sensitive detection of multiple local alignments. Next, the local alignments are converted to blocks and the best set of non-overlapping blocks is determined. When the automated system was applied successively to all 437 groups of related proteins in the PROSITE catalog, 1764 blocks resulted; these could be used for very sensitive searches of sequence databases. Each block was calibrated by searching the SWISS-PROT database to obtain a measure of the chance distribution of matches, and the calibrated blocks were concatenated into a database that could itself be searched. Examples are provided in which distant relationships are detected either using a set of blocks to search a sequence database or using sequences to search the database of blocks. The practical use of the blocks database is demonstrated by detecting previously unknown relationships between oxidoreductases and by evaluating a proposed relationship between HIV Vif protein and thiol proteases.     

Subunit assembly of plant lectins

Lectins are a structurally diverse group of carbohydrate recognizing proteins that are involved in various biological processes and exhibit substantial structural diversity. Interestingly, in spite of having varied carbohydrate-binding specificities, they show modest variation in their secondary and tertiary structure. However, very similar tertiary folds give rise to a range of quaternary structures by simply varying the mutual orientations of the subunits involved. The variety in the quaternary structure generates multivalency in sugar specificities among lectins along with the requisite surface topology to allow for unobstructed recognition events.     

Regen: program for designing gene assembly

One of the main problems in constructing synthetic genes is the incorrect hybridisation between the oligonucleotides. The problem is resolved if the sequence uniquely defines the position of the oligonucleotide in the assembled gene. This can be accomplished through the wise partition of dsDNA sequence in the fragments. We describe a program for use in designing such gene assembly. For a given DNA sequence and the approximate location of oligonucleotide boundary it generates all sets of protruding ends that share the smallest homology.     

Biologically inspired strategy for programmed assembly of viral building blocks with controlled dimensions

Facile fabrication of building blocks with precisely controlled dimensions is imperative in the development of functional devices and materials. We demonstrate the assembly of nanoscale viral building blocks of controlled lengths using a biologically motivated strategy. To achieve this we exploit the simple self-assembly mechanism of Tobacco mosaic virus (TMV), whose length is solely governed by the length of its genomic mRNA. We synthesize viral mRNA of desired lengths using simple molecular biology techniques, and in vitro assemble the mRNA with viral coat proteins to yield viral building blocks of controlled lengths. The results indicate that the assembly of the viral building blocks is consistent and reproducible, and can be readily extended to assemble building blocks with genetically modified coat proteins (TMV1cys). Additionally, we confirm the potential utility of the TMV1cys viral building blocks with controlled dimensions via covalent and quantitative conjugation of fluorescent markers. We envision that our biologically inspired assembly strategy to design and construct viral building blocks of controlled dimensions could be employed to fabricate well-controlled nanoarchitectures and hybrid nanomaterials for a wide variety of applications including nanoelectronics and nanocatalysis.     

植物群落构建的生态过滤机制研究进展

生物多样性的形成和维持机制,即群落构建机制,一直以来都是群落生态学研究的核心问题。植物群落构建的确定性过程主要是生态过滤机制(包括环境过滤和生物过滤,其中生物过滤包括种间竞争和种内功能性状变异)作用的结果。学者们构建了大量的理论、方法、模型来解释和验证生态过滤机制对群落构建的影响,并取得了显著的成果。然而,关于生态过滤机制在不同尺度的作用、生态过滤机制的各要素分解和量化等方面的研究仍有诸多疑问。重点综述了环境过滤、种间竞争和种内功能性状变异的最新研究进展,并指出了现有研究的不足之处。在未来的研究中,应注重生态过滤机制的各要素分解和量化,加强研究手段的综合运用,关注时空动态变化对植物群落构建的影响,重视对不同植物群落构建机制的共性和个性特征的认识,同时强调与其他生态过程、群落构建机制的整合。通过这些尝试,有助于人们更好的理解植物群落构建过程中的生态过滤机制的作用。     

Domains as functional building blocks of plant proteins

Emerging evidence in eukaryotic systems suggests that many proteins of diverse cellular processes are made up of protein domains that are well defined in both sequence and structure. This article updates the identification of many ‘classic’ eukaryotic protein domains in various plant cellular processes, with particular emphasis on the non-catalytic categories. We discuss the importance of domains to plant-protein functions and cellular networking, and the emergence of plant-specific domains.     

Building blocks for automated elucidation of metabolites: Machine learning methods for NMR prediction

Background  

Current efforts in Metabolomics, such as the Human Metabolome Project, collect structures of biological metabolites as well as data for their characterisation, such as spectra for identification of substances and measurements of their concentration. Still, only a fraction of existing metabolites and their spectral fingerprints are known. Computer-Assisted Structure Elucidation (CASE) of biological metabolites will be an important tool to leverage this lack of knowledge. Indispensable for CASE are modules to predict spectra for hypothetical structures. This paper evaluates different statistical and machine learning methods to perform predictions of proton NMR spectra based on data from our open database NMRShiftDB.     

Sulfonamide resistance gene for plant transformation

The sulfonamide resistance gene from plasmid R46 encodes for a mutated dihydropteroate synthase insensitive to inhibition by sulfonamides. Its coding sequence was fused to the pea ribulose bisphosphate carboxylase/oxygenase transit peptide sequence. Incubation of isolated chloroplasts with the fusion protein synthesised in vitro, showed that the bacterial enzyme was transported to the chloroplast stroma and processed into a mature form. Expression of the gene fusion in transgenic plants resulted in a high level of resistance to sulfonamides. Direct selection of transformed shoots on leaf explants was efficient using sulfonamides as sole selective agents. Transformed shoots rooted normally on sulfonamides at concentrations toxic for untransformed ones. Sulfonamide resistance was transmitted to the progeny of transformed plants as a single Mendelian dominant character. These results demonstrate that this chimeric gene can be used as an efficient and versatile selectable marker for plant transformation.     

Sanguinarine blocks cytokinesis in bacteria by inhibiting FtsZ assembly and bundling

Bacterial diseases are among the leading causes of human death. The development of antibiotic resistance greatly contributes to the high mortality rate, and thus, the discovery of antibacterial drugs with novel mechanisms of action is needed. In this study, we found that sanguinarine, a benzophenanthridine alkaloid, strongly induced filamentation in both Gram-positive and Gram-negative bacteria and prevented bacterial cell division by inhibiting cytokinesis. Sanguinarine did not perturb the membrane structure in Escherichia coli. However, it perturbed the cytokinetic Z-ring formation in E. coli. In addition, sanguinarine strongly reduced the frequency of the occurrence of Z rings/micrometer of Bacillus subtilis length but did not alter the number of nucleoids/micrometer of cell length. The results suggested that sanguinarine inhibited cytokinesis in B. subtilis by inhibiting Z-ring formation without affecting nucleoid segregation. Sanguinarine inhibited the assembly of purified FtsZ and reduced the bundling of FtsZ protofilaments in vitro. Further, the interaction of sanguinarine to FtsZ was investigated using size-exclusion chromatography, an extrinsic fluorescent probe 1-anilinonaphthalene-8-sulfonic acid, and tryptophan fluorescence of mutated FtsZ (Y371W). Sanguinarine was found to bind to FtsZ with a dissociation constant of 18-30 microM. The results together show that sanguinarine inhibits bacterial division by perturbing FtsZ assembly dynamics in the Z ring and provide evidence in support of the hypothesis that the assembly and bundling of FtsZ play a critical role in bacterial cytokinesis. The results suggest that sanguinarine may be used as a lead compound to develop FtsZ-targeted antibacterial agents.     

Leishmania donovani lipophosphoglycan blocks NADPH oxidase assembly at the phagosome membrane

Phagocytosis of Leishmania donovani promastigotes is characterized by an inhibition of phagolysosome biogenesis mediated by the surface glycolipid lipophosphoglycan (LPG). However, the consequences of this inhibition on macrophage function remain to be determined. In this study, we investigated the impact of LPG-mediated phagosome remodelling on the assembly and function of the NADPH oxidase complex. Phagocytosis of both wild-type and LPG-defective L. donovani promastigotes triggered the release of similar levels of superoxide. However, wild-type promastigotes, but not LPG-defective mutants, inhibited generation of superoxide at the phagosome. Confocal microscopy imaging revealed that the membrane component gp91(phox) and the Rho-family GTPase Rac1 were present on phagosomes containing either wild-type or LPG-defective promastigotes. In contrast, the NADPH oxidase cytosolic components p47(phox) and p67(phox) were excluded from phagosomes in a LPG-dependent fashion. This inhibition is not the consequence of a general defect in the initiation of the NADPH oxidase activation process because both wild-type and LPG-defective promastigotes induced p47(phox) phosphorylation and the formation of complexes containing p47(phox) and p67(phox). Thus, by remodelling their intracellular habitat, L. donovani promastigotes prevent the assembly of a functional phagosomal NADPH oxidase complex, thereby evading an important host innate defence mechanism.     

In silico protein design by combinatorial assembly of protein building blocks

Utilizing concepts of protein building blocks, we propose a de novo computational algorithm that is similar to combinatorial shuffling experiments. Our goal is to engineer new naturally occurring folds with low homology to existing proteins. A selected protein is first partitioned into its building blocks based on their compactness, degree of isolation from the rest of the structure, and hydrophobicity. Next, the protein building blocks are substituted by fragments taken from other proteins with overall low sequence identity, but with a similar hydrophobic/hydrophilic pattern and a high structural similarity. These criteria ensure that the designed protein has a similar fold, low sequence identity, and a good hydrophobic core compared with its native counterpart. Here, we have selected two proteins for engineering, protein G B1 domain and ubiquitin. The two engineered proteins share approximately 20% and approximately 25% amino acid sequence identities with their native counterparts, respectively. The stabilities of the engineered proteins are tested by explicit water molecular dynamics simulations. The algorithm implements a strategy of designing a protein using relatively stable fragments, with a high population time. Here, we have selected the fragments by searching for local minima along the polypeptide chain using the protein building block model. Such an approach provides a new method for engineering new proteins with similar folds and low homology.     

Tankyrase-1 assembly to large protein complexes blocks its telomeric function

Tankyrase-1 poly(ADP-ribosyl)ates the telomere-binding protein TRF1. This post-translational modification dissociates TRF1 from telomeres, enhancing telomerase-mediated telomere elongation. Tankyrase-1 multimerizes via its sterile alpha motif domain, but its functional implication remains elusive. Here, we found that excessive amounts of tankyrase-1 form punctate nuclear foci. This focus formation depends on both homophilic multimerization and heterophilic protein-protein interaction. These foci are functionally dormant because they do not efficiently release TRF1 from telomeres. Consistently, hyper-overexpression of tankyrase-1 attenuates its ability to elongate telomeres. These observations suggest that tankyrase-1 assembly to large protein complexes masks its telomeric function.

Structured summary

MINT-7987689, MINT-7987677: Tankyrase-1 (uniprotkb:O95271) and TRF1 (uniprotkb:P54274) colocalize (MI:0403) by fluorescence microscopy (MI:0416)MINT-7987977: Tankyrase-1 (uniprotkb:O95271) physically interacts (MI:0915) with TRF1 (uniprotkb:P54274) by anti tag coimmunoprecipitation (MI:0007)MINT-7987998: Tankyrase-1 (uniprotkb:O95271) physically interacts (MI:0915) with Tankyrase-1 (uniprotkb:O95271) by anti tag coimmunoprecipitation (MI:0007).     

Building blocks, hinge-bending motions and protein topology.

Here we show that the locations of molecular hinges in protein structures fall between building block elements. Building blocks are fragments of the protein chain which constitute local minima. These elements fold first. In the next step they associate through a combinatorial assembly process. While chain-linked building blocks may be expected to trial-associate first, if unstable, alternate more stable associations will take place. Hence, we would expect that molecular hinges will be at such inter-building block locations, or at the less stable, unassigned regions. On the other hand, hinge-bending motions are well known to be critical for protein function. Hence, protein folding and protein function are evolutionarily related. Further, the pathways through which proteins attain their three dimensional folds are determined by protein topology. However, at the same time the locations of the hinges, and hinge-bending motions are also an outcome of protein topology. Thus, protein folding and function appear coupled, and relate to protein topology. Here we provide some results illustrating such a relationship.     

Colchicine-resistant assembly of tubulin in plant mitosis

Summary Tubulin distribution in c-mitoses (induced by 1 mM colchicine) has been studied by indirect immunofluorescence with monoclonal antibodies inAllium cepa L. meristems proliferating under steady state kinetics. Two hours after colchicine treatment was initiated tubulin is detected in approximately 25% of the cells as arrowheads on the kinetochores, as if these structures stabilize microtubules against disassembly. Total disassembly of microtubules occurs in 70% of the c-mitoses six hours after the initiation of the colchicine treatment, when restitution nuclei also start appearing. After 2 to 14 hours of colchicine treatment, tubulin is detected in about 30% of the c-mitoses, both in small kinetochores-like dots and in a strand which apparently connects sister kinetochores. Other larger microtubule-like structures, up to 20 m long, apparently unassociated with kinetochores, are assembled in the presence of cholchicine in c-mitoses after 10 hours. Such structures disappear when chromosomes decondense and the nuclear envelope reforms in the restitution nucleus; they do not seem to be related to interphase cortical microtubules which reappear in control telophase.     

植物群落构建机制研究进展

群落构建研究对于解释物种共存和物种多样性的维持是至关重要的,因此一直是生态学研究的中心论题。尽管近年来关于生态位和中性理论的验证研究已经取得了显著的成果,但对于局域群落构建机制的认识仍存在很大争议。随着统计和理论上的进步使得用功能性状和群落谱系结构解释群落构建机制变为可能,主要是通过验证共存物种的性状和谱系距离分布模式来实现。然而,谱系和功能性状不能相互替代,多种生物和非生物因子同时控制着群落构建,基于中性理论的扩散限制、基于生态位的环境过滤和竞争排斥等多个过程可能同时影响着群落的构建。所以,综合考虑多种方法和影响因素探讨植物群落的构建机制,对于预测和解释植被对干扰的响应,理解生物多样性维持机制有重要意义。试图在简要回顾群落构建理论及研究方法发展的基础上,梳理其最新研究进展,并探讨整合功能性状及群落谱系结构的研究方法,解释群落构建和物种多样性维持机制的可能途径。在结合功能性状和谱系结构研究群落构建时,除了考虑空间尺度、环境因子、植被类型外,还应该关注时间尺度、选择性状的种类和数量、性状的种内变异、以及人为干扰等因素对群落构建的影响。     

Hormones as go-betweens in plant microbiome assembly

The interaction of plants with complex microbial communities is the result of co-evolution over millions of years and contributed to plant transition and adaptation to land. The ability of plants to be an essential part of complex and highly dynamic ecosystems is dependent on their interaction with diverse microbial communities. Plant microbiota can support, and even enable, the diverse functions of plants and are crucial in sustaining plant fitness under often rapidly changing environments. The composition and diversity of microbiota differs between plant and soil compartments. It indicates that microbial communities in these compartments are not static but are adjusted by the environment as well as inter-microbial and plant–microbe communication. Hormones take a crucial role in contributing to the assembly of plant microbiomes, and plants and microbes often employ the same hormones with completely different intentions. Here, the function of hormones as go-betweens between plants and microbes to influence the shape of plant microbial communities is discussed. The versatility of plant and microbe-derived hormones essentially contributes to the creation of habitats that are the origin of diversity and, thus, multifunctionality of plants, their microbiota and ultimately ecosystems.