The SET-domain protein superfamily: protein lysine methyltransferases

The SET-domain protein methyltransferase superfamily includes all but one of the proteins known to methylate histones on lysine. Histone methylation is important in the regulation of chromatin and gene expression.     

Vertebrate kinetochore protein architecture: protein copy number

To define the molecular architecture of the kinetochore in vertebrate cells, we measured the copy number of eight kinetochore proteins that link kinetochore microtubules (MTs [kMTs]) to centromeric DNA. We used a fluorescence ratio method and chicken DT40 cell lines in which endogenous loci encoding the analyzed proteins were deleted and complemented using integrated green fluorescent protein fusion transgenes. For a mean of 4.3 kMTs at metaphase, the protein copy number per kMT is between seven and nine for members of the MT-binding KNL-1/Mis12 complex/Ndc80 complex network. It was between six and nine for four members of the constitutive centromere-associated network: centromere protein C (CENP-C), CENP-H, CENP-I, and CENP-T. The similarity in copy number per kMT for all of these proteins suggests that each MT end is linked to DNA by six to nine fibrous unit attachment modules in vertebrate cells, a conclusion that indicates architectural conservation between multiple MT-binding vertebrate and single MT-binding budding yeast kinetochores.     

The SET-domain protein superfamily: protein lysine methyltransferases

The SET-domain protein methyltransferase superfamily includes all but one of the proteins known to methylate histones on lysine. Histone methylation is important in the regulation of chromatin and gene expression.     

Improved immunomatrix methods to detect protein:protein interactions

Immunoprecipitation (IP) and coimmunoprecipitation (co-IP) are key techniques for studying protein-protein interactions. These methods utilize immobilized Protein A or Protein G to isolate antibody-bound target antigens. The main disadvantage of traditional IP and co-IP is that the conditions used to elute the precipitated antigen also release the antibody thus contaminating the antigen and destroying the antibody support. To overcome these problems, we describe two methods to generate a reusable antibody support by cross-linking the antibody to immobilized Protein A or Protein G, or by coupling it directly to the resin (see Scheme 1). Antibody cross-linking can be done in 1 h while antibody coupling requires 4 h. IP or co-IP is accomplished by incubating the antibody resin with the protein sample. Washes and elutions are carried out in a spin column to reduce resin loss and decrease assay time. Target proteins are eluted with 0.1 M glycine (pH 2.8) and the resin-bound antibody is re-equilibrated in phosphate-buffered saline (PBS) for reuse. Our studies have demonstrated that the immobilization efficiency for the antibody coupling method was similar for several species of antibody. Furthermore, we illustrate that using both methods of antibody immobilization yield IP and co-IP results similar to traditional protocols but eliminate the antibody heavy and light chain contamination.     

LDL protein nitration: implication for LDL protein unfolding

Oxidatively- or enzymatically-modified low-density lipoprotein (LDL) is intimately involved in the initiation and progression of atherosclerosis. The in vivo modified LDL is electro-negative (LDL⁻) and consists of peroxidized lipid and unfolded apoB-100 protein. This study was aimed at establishing specific protein modifications and conformational changes in LDL⁻ assessed by liquid chromatography/tandem mass spectrometry (LC/MS/MS) and circular dichroism analyses, respectively. The functional significance of these chemical modifications and structural changes were validated with binding and uptake experiments to- and by bovine aortic endothelial cells (BAEC).The plasma LDL⁻ fraction showed increased nitrotyrosine and lipid peroxide content as well as a greater cysteine oxidation as compared with native- and total-LDL. LC/MS/MS analyses of LDL⁻ revealed specific modifications in the apoB-100 moiety, largely involving nitration of tyrosines in the α-helical structures and β₂ sheet as well as cysteine oxidation to cysteic acid in β₁ sheet. Circular dichroism analyses showed that the α-helical content of LDL⁻ was substantially lower (∼25%) than that of native LDL (∼90%); conversely, LDL⁻ showed greater content of β-sheet and random coil structure, in agreement with unfolding of the protein. These results were mimicked by treatment of LDL subfractions with peroxynitrite (ONOO⁻) or SIN-1: similar amino acid modifications as well as conformational changes (loss of α-helical structure and gain in β-sheet structure) were observed. Both LDL⁻ and ONOO⁻-treated LDL showed a statistically significant increase in binding and uptake to- and by BAEC compared to native LDL. We further found that most binding and uptake in control-LDL was through LDL-R with minimal oxLDL-R-dependent uptake. ONOO⁻-treated LDL was significantly bound and endocytosed by LOX-1, CD36, and SR-A with minimal contribution from LDL-R.It is suggested that lipid peroxidation and protein nitration may account for the mechanisms leading to apoB-100 protein unfolding and consequential increase in modified LDL binding and uptake to and by endothelial cells that is dependent on oxLDL scavenger receptors.     

Recombinant protein hydrazides: application to site-specific protein PEGylation

Here, we describe a novel method for the site-specific C-terminal PEGylation of recombinant proteins. This general approach exploits chemical cleavage of precursor intein-fusion proteins with hydrazine to directly produce recombinant protein hydrazides. This unique functionality within the protein sequence then facilitates site-specific C-terminal modification by hydrazone-forming ligation reactions. This approach was used to generate folded, site-specifically C-terminal PEGylated IFNalpha2b and IFNbeta1b, which retained excellent antiviral activity, demonstrating the utility of this technology in the PEGylation of therapeutic proteins. As this methodology is straightforward to perform, is compatible with disulfide bonds, and is exclusively selective for the protein C-terminus, it shows great potential as general technology for the site-specific engineering and labeling of recombinant proteins.     

Disulfide bonds: protein folding and subcellular protein trafficking

The study of disulfide-bond-containing proteins has advanced our understanding of the mechanism(s) by which the majority of secretory and membrane-bound proteins acquire their biologically functional folded forms. This covalent linkage has been exploited by a number of research laboratories to harness or trap intermediates populating the folding trajectories of biopolymers. The resulting body of gathered in vitro data demonstrates that, in general, there is a common event underscoring the maturation of disulfide-bond-containing proteins. This commonality is the existence of competition between a physical, conformational folding reaction and a chemical, thiol-disulfide exchange reaction during fold acquisition. The competition, in turn, impacts the fate of the polypeptide in being secreted or retrotranslocated. The role of a host of subcellular factors, including protein disulfide isomerase, that influences this critical spatiotemporal juncture of the fold-maturation process is discussed. Finally, the impact of this competition on the onset of neurodegenerative disorders is elaborated upon.     

Predicting protein function from protein/protein interaction data: a probabilistic approach

MOTIVATION:The development of experimental methods for genome scale analysis of molecular interaction networks has made possible new approaches to inferring protein function. This paper describes a method of assigning functions based on a probabilistic analysis of graph neighborhoods in a protein-protein interaction network. The method exploits the fact that graph neighbors are more likely to share functions than nodes which are not neighbors. A binomial model of local neighbor function labeling probability is combined with a Markov random field propagation algorithm to assign function probabilities for proteins in the network. RESULTS: We applied the method to a protein-protein interaction dataset for the yeast Saccharomyces cerevisiae using the Gene Ontology (GO) terms as function labels. The method reconstructed known GO term assignments with high precision, and produced putative GO assignments to 320 proteins that currently lack GO annotation, which represents about 10% of the unlabeled proteins in S. cerevisiae.     

Activities of the Sex-lethal protein in RNA binding and protein:protein interactions.

The Drosophila sex determination gene Sex-lethal (Sxl) controls its own expression, and the expression of downstream target genes such as transformer , by regulating pre-mRNA splicing and mRNA translation. Sxl codes an RNA-binding protein that consists of an N-terminus of approximately 100 amino acids, two 90 amino acid RRM domains, R1 and R2, and an 80 amino acid C-terminus. In the studies reported here we have examined the functional properties of the different Sxl protein domains in RNA binding and in protein:protein interactions. The two RRM domains are responsible for RNA binding. Specificity in the recognition of target RNAs requires both RRM domains, and proteins which consist of the single domains or duplicated domains have anomalous RNA recognition properties. Moreover, the length of the linker between domains can affect RNA recognition properties. Our results indicate that the two RRM domains mediate Sxl:Sxl protein interactions, and that these interactions probably occur both in cis and trans. We speculate that cis interactions between R1 and R2 play a role in RNA recognition by the Sxl protein, while trans interactions stabilize complex formation on target RNAs that contain two or more closely spaced binding sites. Finally, we show that the interaction of Sxl with the snRNP protein Snf is mediated by the R1 RRM domain.     

Globular protein stability: aspects of interest in protein turnover

The conformational stability of globular proteins is remarkably low. Under physiological conditions, the native globular conformation is only from 5 to 15 kcal/mole more stable than unfolded conformations. In addition, small changes in the structure of a protein such as removing one terminal residue or cleaving a single peptide bond frequently lead to a substantial decrease in the stability. Likewise, single substitutions in the amino acid sequence can increase or decrease the stability by several kilocalories per mole. The low conformational stability of globular proteins and the sensitivity to small changes in structure suggest a possible role for conformational stability in the intracellular degradation of proteins. Several lines of evidence from in vivo studies of protein degradation are consistent with this idea.     

Evolution of protein specificity: insights from ancestral protein reconstruction

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Converting the prion protein: what makes the protein infectious

The discovery of prion disease transmission in mammals, as well as a non-Mendelian type of inheritance in yeast, has led to the establishment of a new concept in biology, the prion hypothesis. The prion hypothesis postulates that an abnormal protein conformation propagates itself in an autocatalytic manner via recruitment of the normal isoform of the same protein as a substrate, and thereby acts either as a transmissible agent of disease (in mammals) or as a heritable determinant of phenotype (in yeast and fungus). Although reconstitution of fully infectious PrP(Sc)in vitro from synthetic components has not yet been achieved, numerous lines of evidence indicate that the prion protein is the major and essential component, if not the only one, of the prion infectious agent. This article summarizes our current knowledge about the chemical nature of the prion infectious agent, describes potential strategies and challenges related to the generation of prion infectivity de novo, proposes new hypotheses to explain the apparently low infectivity observed in the first synthetic mammalian prions, and describes plausible effects of chemical modifications on prion conversion.     

Geminivirus C3 protein: replication enhancement and protein interactions

Most dicot-infecting geminiviruses encode a replication enhancer protein (C3, AL3, or REn) that is required for optimal replication of their small, single-stranded DNA genomes. C3 interacts with C1, the essential viral replication protein that initiates rolling circle replication. C3 also homo-oligomerizes and interacts with at least two host-encoded proteins, proliferating cell nuclear antigen (PCNA) and the retinoblastoma-related protein (pRBR). It has been proposed that protein interactions contribute to C3 function. Using the C3 protein of Tomato yellow leaf curl virus, we examined the impact of mutations to amino acids that are conserved across the C3 protein family on replication enhancement and protein interactions. Surprisingly, many of the mutations did not affect replication enhancement activity of C3 in tobacco protoplasts. Other mutations either enhanced or were detrimental to C3 replication activity. Analysis of mutated proteins in yeast two-hybrid assays indicated that mutations that inactivate C3 replication enhancement activity also reduce or inactivate C3 oligomerization and interaction with C1 and PCNA. In contrast, mutated C3 proteins impaired for pRBR binding are fully functional in replication assays. Hydrophobic residues in the middle of the C3 protein were implicated in C3 interaction with itself, C1, and PCNA, while polar resides at both the N and C termini of the protein are important for C3-pRBR interaction. These experiments established the importance of C3-C3, C3-C1, and C3-PCNA interactions in geminivirus replication. While C3-pRBR interaction is not required for viral replication in cycling cells, it may play a role during infection of differentiated cells in intact plants.     

When protein folding is simplified to protein coiling: the continuum of solenoid protein structures

Solenoid proteins contain repeating structural units that form a continuous superhelix. This category of proteins conveys the least complicated relationship between a sequence and the corresponding three-dimensional structure. Although solenoid proteins are divided into different classes according to commonly used classification schemes, they share many structural and functional properties.     

AnaGram: protein function assignment

SUMMARY: AnaGram is a web service for protein function assignment based on identity detection of small significant fragments (protomotifs) that can act as modular pieces in peptide construction. The system is able to assign function by finding correlations between protomotifs and functional annotations contained in SWISS-PROT and Medline databases. In addition, function ontologies are used for hierarchical organization of the predicted functions. Extensive tests have been carried out to evaluate the accuracy and performance of the system. AVAILABILITY: http://jaguar.genetica.uma.es/anagram.htm     

神经颗粒素:一种脑特异性蛋白质

神经颗粒素(Neurogrann,Ng)是一种新发现的由78个氨基酸组成的脑特异性蛋白,主要分布于人类或动物的大脑皮层、海马和嗅球等脑区的神经突触后。作为Calpacitin蛋白家族中的一员,Ng是蛋白激酶C的天然作用底物及钙调蛋白(CaM)的储库。在生理状态下,Ng与CaM结合形成复合体,而在蛋白激酶C或氧化剂的作用下,Ng可被磷酸化、氧化及谷胱甘肽化等化学修饰,降低其与CaM的亲和力,从而参与对CaM及CaM-激活的蛋白酶,如CaM-依赖性NO合酶、CaM-依赖性蛋白激酶Ⅱ(CaMKⅡ)及CaM-依赖性腺苷酸环化酶的调节。同时,由于CaM-依赖性蛋白酶大多参与长时程增强(LTP)和长时程抑制(LTD)的诱导,并且Ng的基因表达和蛋白质合成与神经元的突触形成、分化同步,因此,Ng可能在学习、记忆、神经系统发育(可塑性)等生理性变化中具有重要作用。此外,一些研究表明,Ng还可能参与甲状腺机能减退、睡眠剥夺、衰老及脑低氧预适应等病理生理学变化所造成的神经系统功能的改变。     

The DING protein: an autocrine growth-stimulatory protein related to the human synovial stimulatory protein

A synovial stimulating protein (SSP) has previously been isolated from rheumatoid arthritis synovial fluid and from the culture fluid of rheumatoid arthritis synovial fibroblasts. We have previously isolated, from skin fibroblast cultures, a 40 kDa hirudin-binding protein, which had amino acid sequence homology with the SSP. We sought to clarify the relationship, if any, between the SSP and the hirudin-binding protein. We show that the hirudin-binding protein is immunologically cross-reactive with a protein identical with, or very similar to, the SSP. This hirudin-binding protein is produced by normal and rheumatoid arthritis fibroblasts in culture, and also by cervical carcinoma cells. Traces of an SSP-like protein, and of proteins intermediate in size between the SSP and the hirudin-binding protein, suggest that the hirudin-binding protein may be proteolytically derived from the SSP. An SSP-like protein of about 200 kDa is present in all synovial fluid samples, arthritic and normal, indicating that its presence is not a primary cause of rheumatoid arthritis. There is no evidence for the existence of smaller fragments of the SSP-like protein in synovial fluid. A cDNA sequence, coding for part of the 40 kDa protein, has been obtained. The derived amino acid sequence indicates that a domain, previously identified in the dishevelled gene from Drosophila melanogaster, is present in this protein. Peptides predicted from the cDNA sequence were used to raise antisera, which recognise both the 40 kDa protein and the SSP-like protein. One of the antibody preparations is a good inhibitor of fibroblast proliferation, which confirms the autocrine growth-stimulatory role originally proposed for these proteins.     

Proteomics: the protein revolution

Proteomics, the latest scientific buzzword and research field, represents a milestone in biological research, as proteins return to centre stage. But what has led to this protein renaissance and why has proteomics become a key research tool in the post-genomic era? The answers to these questions lie in the huge progress that has been made in the area of genomics.