Genomic analysis of biochemical function

Establishing the linkage between an individual biochemical activity and the gene(s) specifying that activity has been facilitated by advances in mass spectrometry and affinity purification methods. In addition, a genomic protein array has been produced in yeast by fusing each yeast open reading frame to glutathione-S-transferase, thus linking each protein with its cognate gene. Purification and biochemical assay of pools of glutathione-S-transferase-open-reading-frame proteins allows analysis of the entire proteome for biochemical activities, followed by simple deconvolution to identify the responsible open reading frame. An alternative method to analyze large sets of proteins is the use of protein microarrays in which over 10,000 individual proteins can be immobilized and assayed on a single slide.     

PIRLs: a novel class of plant intracellular leucine-rich repeat proteins

Leucine-rich repeat (LRR) proteins feature tandem leucine-rich motifs that form a protein-protein interaction domain. Plants contain diverse classes of LRR proteins, many of which take part in signal transduction. We have identified a novel family of nine Arabidopsis LRR proteins that, based on predicted intracellular location and LRR motif consensus sequence, are related to Ras-binding LRR proteins found in signaling complexes in animals and yeast. This new class has been named plant intracellular Ras group-related LRR proteins (PIRLs). We have characterized PIRL cDNAs, rigorously defined gene and protein annotations, investigated gene family evolution and surveyed mRNA expression. While LRR regions suggested a relationship to Ras group LRR proteins, outside of their LRR domains PIRLs differed from Ras group proteins, exhibiting N- and C-terminal regions containing low complexity stretches and clusters of charged amino acids. PIRL genes grouped into three subfamilies based on sequence relationships and gene structures. Related gene pairs and dispersed chromosomal locations suggested family expansion by ancestral genomic or segmental duplications. Expression surveys revealed that all PIRL mRNAs are actively transcribed, with three expressed differentially in leaves, roots or flowers. These results define PIRLs as a distinct, plant-specific class of intracellular LRR proteins that probably mediate protein interactions, possibly in the context of signal transduction. T-DNA knock-out mutants have been isolated as a starting point for systematic functional analysis of this intriguing family.     

Identification of structural motifs and amino acids within the structure of human heparan sulfate 3-O-sulfotransferase that mediate enzymatic function.

In an accompanying paper [J. R. Myette, Z. Shriver, J. Liu, G. Venkataraman, and R. Sasisekharan (2002) Biochem. Biophys. Res. Commun. 290, 1206-1213], we described the purification and biochemical characterization of a soluble, recombinantly expressed form of the human heparan sulfate 3-O-sulfotransferase (3-OST-1). Such an important first step enables detailed structure-function studies for this class of enzymes. Herein, we describe a complimentary, structure-based homology modeling approach for predicting 3-OST-1 structure. This approach employs a variety of structural analysis and molecular modeling tools used in conjunction with protein crystallographic studies of related enzymes. In this manner, we describe important motifs within the predicted three-dimensional structure of the enzyme and identify specific amino acids that are likely important for enzymatic function.     

A multipurpose fusion tag derived from an unstructured and hyperacidic region of the amyloid precursor protein

Expression and purification of aggregation‐prone and disulfide‐containing proteins in Escherichia coli remains as a major hurdle for structural and functional analyses of high‐value target proteins. Here, we present a novel gene‐fusion strategy that greatly simplifies purification and refolding procedure at very low cost using a unique hyperacidic module derived from the human amyloid precursor protein. Fusion with this polypeptide (dubbed FATT for Flag‐Acidic‐Target Tag) results in near‐complete soluble expression of variety of extracellular proteins, which can be directly refolded in the crude bacterial lysate and purified in one‐step by anion exchange chromatography. Application of this system enabled preparation of functionally active extracellular enzymes and antibody fragments without the need for condition optimization.     

Identification and characterization of an animal delta(12) fatty acid desaturase gene by heterologous expression in Saccharomyces cerevisiae

We have cloned a Caenorhabditis elegans cDNA encoding a Delta12 fatty acid desaturase and demonstrated its activity by heterologous expression in Saccharomyces cerevisiae. The predicted protein is highly homologous both to the cloned plant genes with similar function and to the published sequence of the C. elegans omega-3 fatty acid desaturase. In addition, it conforms to the structural constraints expected of a membrane-bound fatty acid desaturase including the canonical histidine-rich regions. This is the first report of a cloned animal Delta(12) desaturase gene. Expression of this cDNA in yeast resulted in the accumulation of 16:2 and 18:2 (linoleic) acids. The increase of membrane fluidity brought about by this change in unsaturation was measured. The production of polyunsaturated fatty acids in yeast cells and the concomitant increase in membrane fluidity was correlated with a modest increase in growth rate at low temperature and with increased resistance to ethanol and oxidative stress.     

Characteristics affecting expression and solubilization of yeast membrane proteins

Biochemical and structural analysis of membrane proteins often critically depends on the ability to overexpress and solubilize them. To identify properties of eukaryotic membrane proteins that may be predictive of successful overexpression, we analyzed expression levels of the genomic complement of over 1000 predicted membrane proteins in a recently completed Saccharomyces cerevisiae protein expression library. We detected statistically significant positive and negative correlations between high membrane protein expression and protein properties such as size, overall hydrophobicity, number of transmembrane helices, and amino acid composition of transmembrane segments. Although expression levels of membrane and soluble proteins exhibited similar negative correlations with overall hydrophobicity, high-level membrane protein expression was positively correlated with the hydrophobicity of predicted transmembrane segments. To further characterize yeast membrane proteins as potential targets for structure determination, we tested the solubility of 122 of the highest expressed yeast membrane proteins in six commonly used detergents. Almost all the proteins tested could be solubilized using a small number of detergents. Solubility in some detergents depended on protein size, number of transmembrane segments, and hydrophobicity of predicted transmembrane segments. These results suggest that bioinformatic approaches may be capable of identifying membrane proteins that are most amenable to overexpression and detergent solubilization for structural and biochemical analyses. Bioinformatic approaches could also be used in the redesign of proteins that are not intrinsically well-adapted to such studies.     

Improving expression and solubility of rice proteins produced as fusion proteins in Escherichia coli

For proteins of higher eukaryotes, such as plants, which have large genomes, recombinant protein expression and purification are often difficult. Expression levels tend to be low and the expressed proteins tend to misfold and aggregate. We tested seven different expression vectors in Escherichia coli for rapid subcloning of rice genes and for protein expression and solubility levels. Each expressed gene product has an N-terminal fusion protein and/or tag, and an engineered protease site upstream of the mature rice protein. Several different fusion proteins/tags and protease sites were tested. We found that the fusion proteins and the protease sites have significant and varying effects on expression and solubility levels. The expression vector with the most favorable characteristics is pDEST-trx. The vector, which is a modified version of the commercially available expression vector, pET-32a, contains an N-terminal thioredoxin fusion protein and a hexahistidine tag, and is adapted to the Gateway expression system. However, addition of an engineered protease site could drastically change the expression and solubility properties. We selected 135 genes corresponding to potentially interesting rice proteins, transferred the genes from cDNAs to expression vectors, and engineered in suitable protease sites N-terminal to the mature proteins. Of 135 genes, 131 (97.0%) could be expressed and 72 (53.3%) were soluble when the fusion proteins/tags were present. Thirty-eight mature-length rice proteins and domains (28.1%) are suitable for NMR solution structure studies and/or X-ray crystallography. Our expression systems are useful for the production of soluble plant proteins in E. coli to be used for structural genomics studies.     

Structure and function of proteins controlling strain-specific pathogen resistance in plants

Recently recognised structural and amino acid sequence similarities between plant disease resistance (R) proteins and animal proteins such as Apaf-1 and CED-4 are providing conceptual models for resistance protein function. Data from extensive DNA sequencing of resistance gene families are indicating that the leucine-rich repeat motif is an important determinant of gene-for-gene specificity and that intergenic DNA sequence exchange is a major contributor to R gene diversity.     

From genes to proteins: high-throughput expression and purification of the human proteome

The development of high-throughput methods for gene discovery has paved the way for the design of new strategies for genome-scale protein analysis. Lawrence Livermore National Laboratory and Onyx Pharmaceuticals, Inc., have produced an automatable system for the expression and purification of large numbers of proteins encoded by cDNA clones from the IMAGE (Integrated Molecular Analysis of Genomes and Their Expression) collection. This high-throughput protein expression system has been developed for the analysis of the human proteome, the protein equivalent of the human genome, comprising the translated products of all expressed genes. Functional and structural analysis of novel genes identified by EST (Expressed Sequence Tag) sequencing and the Human Genome Project will be greatly advanced by the application of this high-throughput expression system for protein production. A prototype was designed to demonstrate the feasibility of our approach. Using a PCR-based strategy, 72 unique IMAGE cDNA clones have been used to create an array of recombinant baculoviruses in a 96-well microtiter plate format. Forty-two percent of these cDNAs successfully produced soluble, recombinant protein. All of the steps in this process, from PCR to protein production, were performed in 96-well microtiter plates, and are thus amenable to automation. Each recombinant protein was engineered to incorporate an epitope tag at the amino terminal end to allow for immunoaffinity purification. Proteins expressed from this system are currently being analyzed for functional and biochemical properties.     

Toxin-dependent utilization of engineered ribosomal protein L3 limits trichothecene resistance in transgenic plants

The contamination of agricultural products with Fusarium mycotoxins is a problem of world-wide importance. Fusarium graminearum and related species, which are important pathogens of small grain cereals and maize, produce an economically important and structurally diverse class of toxins designated trichothecenes. Trichothecenes inhibit eukaryotic protein synthesis. Therefore, a proposed role for these fungal toxins in plant disease development is to block or delay the expression of defence-related proteins induced by the plant. Using yeast as a model system, we have identified several mutations in the gene encoding ribosomal protein L3 (Rpl3), which confer semi-dominant resistance to trichothecenes. Expression of an engineered tomato RPL3 (LeRPL3) cDNA, into which one of the amino acid changes identified in yeast was introduced, improved the ability of transgenic tobacco plants to adapt to the trichothecene deoxynivalenol (DON), but did not result in constitutive resistance. We show here that, in the presence of wild-type Rpl3 protein, the engineered Rpl3 protein is not utilized, unless yeast transformants or the transgenic plants are challenged with sublethal amounts of toxin. Our data from yeast two-hybrid experiments suggest that affinity for the ribosome assembly factor Rrb1p could be altered by the toxin resistance-conferring mutation. This toxin-dependent utilization of the resistance-conferring Rpl3 protein could seriously limit efforts to utilize the identified target alterations in transgenic crops to increase trichothecene tolerance and Fusarium resistance.     

An autoactive mutant of the M flax rust resistance protein has a preference for binding ATP, whereas wild-type M protein binds ADP

Resistance (R) proteins are key regulators of the plant innate immune system and are capable of pathogen detection and activation of the hypersensitive cell death immune response. To understand the molecular mechanism of R protein activation, we undertook a phenotypic and biochemical study of the flax nucleotide binding (NB)-ARC leucine-rich repeat protein, M. Using Agrobacterium-mediated transient expression in flax cotyledons, site-directed mutations of key residues within the P-loop, kinase 2, and MHD motifs within the NB-ARC domain of M were shown to affect R protein function. When purified using a yeast expression system and assayed for ATP and ADP, these mutated proteins exhibited marked differences in the quantity and identity of the bound nucleotide. ADP was bound to recombinant wild-type M protein, while the nonfunctional P-loop mutant did not have any nucleotides bound. In contrast, ATP was bound to an autoactive M protein mutated in the highly conserved MHD motif. These data provide direct evidence supporting a model of R protein function in which the "off" R protein binds ADP and activation of R protein defense signaling involves the exchange of ADP for ATP.     

The extracellular domain of immunodeficiency virus gp41 protein: expression in Escherichia coli, purification, and crystallization.

The env gene of SIV and HIV-1 encodes a single glycoprotein gp 160, which is processed to give a noncovalent complex of the soluble glycoprotein gp120 and the transmembrane glycoprotein gp41. The extracellular region (ectodomain), minus the N-terminal fusion peptide, of gp41 from HIV-1 (residues 27-154) and SIV (residues 27-149) have been expressed in Escherichia coli. These insoluble proteins were solubilized and subjected to a simple purification and folding scheme, which results in high yields of soluble protein. Purified proteins have a trimeric subunit composition and high alpha-helical content, consistent with the predicted coil-coil structure. SIV gp41 containing a double cysteine mutation was crystallized. The crystals are suitable for X-ray structure determination and, preliminary analysis, together with additional biochemical evidence, indicates that the gp41 trimer is arranged as a parallel bundle with threefold symmetry.     

A novel gene family in moss (Physcomitrella patens) shows sequence homology and a phylogenetic relationship with the TIR-NBS class of plant disease resistance genes

Plant disease resistance (R) genes encode proteins in which several motifs of the nucleotide-binding region (NBS) are highly conserved. Using degenerate primers designed according to the kinase 1 (P-loop) and hydrophobic (HD) motifs of the R gene NBS domains, homologous sequences were cloned from moss (Physcomitrella patens; phylum Bryophyta) representing an ancient nonvascular plant. A novel gene family (PpC) with at least eight homologous members was found. Expression of five members was detected. The level of expression was dependent on the developmental stage of moss, being higher in the gametophyte tissue than in the protonema tissue. The PpCs contained the conserved motifs characteristic of the NBS regions of R genes, and a kinase domain was found upstream from the NBS region. Phylogenetic analysis using the deduced NBS amino acid sequences of the PpCs and the plant genes available in databanks indicated that the PpCs show the closest relationship with the TIR-NBS class of R genes. No significant similarity to plant genes other than R genes was observed. These findings shed novel light on the evolutionary history of the R gene families, suggesting that the NBS region characteristic of the TIR-NBS class of R-like genes evolved prior to the evolutionary differentiation of vascular and nonvascular plants.     

Elongation factor 1 alpha from Saccharomyces cerevisiae. Rapid large-scale purification and molecular characterization

Cytoplasmic elongation factor 1 alpha (EF-1 alpha) was purified to homogeneity from the yeast Saccharomyces cerevisiae using a large-scale procedure. The three steps of purification used were batch adsorption on phosphocellulose, phosphocellulose chromatography and, as the last step, GDP-Sepharose or Biorex column chromatography. The protein is very basic (pI = 9.2) and has an apparent molecular mass of 49 kDa, as determined by polyacrylamide gel electrophoresis using denaturing conditions. It is one of the most abundant proteins in yeast (about 5% of total soluble protein), as shown by two-dimensional gel electrophoresis and by immunological titration. A strong immunological and structural homology was found between yeast EF-1 alpha and elongation factors from other sources. Common immunological features were found between yeast and wheat germ EF-1 alpha. Tryptic hydrolysis of yeast EF-1 alpha in the presence of 25% glycerol generated a large trypsin-resistant polypeptide (Mr = 43,000) which had the same NH2-terminal sequence as the proteolyzed product from rabbit reticulocyte, Artemia salina EF-1 alpha and Escherichia coli EF-Tu. Completed DNA sequence determination of one structural gene for yeast EF-1 alpha confirmed a remarkable conservation of several protein sequence domains in yeast and animal EF-1 alpha (Cottrelle, P., Thiele, D., Price, V., Memet, S., Micouin, J.Y., Marck, C., Buhler, J.M. Sentenac, A., and Fromageot, P. (1985) J. Biol. Chem. 260, 3090-3096).     

Spotted leaf11, a negative regulator of plant cell death and defense, encodes a U-box/armadillo repeat protein endowed with E3 ubiquitin ligase activity

The rice (Oryza sativa) spotted leaf11 (spl11) mutant was identified from an ethyl methanesulfonate-mutagenized indica cultivar IR68 population and was previously shown to display a spontaneous cell death phenotype and enhanced resistance to rice fungal and bacterial pathogens. Here, we have isolated Spl11 via a map-based cloning strategy. The isolation of the Spl11 gene was facilitated by the identification of three additional spl11 alleles from an IR64 mutant collection. The predicted SPL11 protein contains both a U-box domain and an armadillo (ARM) repeat domain, which were demonstrated in yeast and mammalian systems to be involved in ubiquitination and protein-protein interactions, respectively. Amino acid sequence comparison indicated that the similarity between SPL11 and other plant U-box-ARM proteins is mostly restricted to the U-box and ARM repeat regions. A single base substitution was detected in spl11, which results in a premature stop codon in the SPL11 protein. Expression analysis indicated that Spl11 is induced in both incompatible and compatible rice-blast interactions. In vitro ubiquitination assay indicated that the SPL11 protein possesses E3 ubiquitin ligase activity that is dependent on an intact U-box domain, suggesting a role of the ubiquitination system in the control of plant cell death and defense.     

寄主植物与病原菌免疫反应的分子遗传基础

近年来,大量的植物抗病基因和病原菌无毒基因被克隆,抗病基因和无毒基因的结构、功能及其互作关系的研究也取得重大进展。在植物中,由病原菌模式分子(pathogen-associated molecular patterns, PAMPs)引发的免疫反应(PAMP-triggered immunity, PTI)和由效应因子引发的免疫反应(effector-triggered immunity, ETI)是植物在长期进化过程中形成的两类抵抗病原物的机制。PTI反应主要通过细胞表面受体(patternrecognition receptors, PRRs)识别并结合PAMPs从而激活下游免疫反应,而在ETI反应中,则通过植物R基因(resistance gene,R)与病原菌无毒基因(avirulence gene, Avr)产物间的直接或间接相互作用来完成免疫反应。本文对植物PTI反应和ETI反应分别进行了概述,重点探讨了植物R基因与病原菌Avr基因之间的互作遗传机理,并对目前植物抗性分子遗传机制研究和抗病育种中的问题进行了探讨和展望。