Proteinaceous inhibitors of endo-beta-glucanases

Both plants and filamentous phytopathogens secrete proteins that inhibit endo-beta-glucanases. The first endo-beta-glucanase inhibitor proteins to be discovered are XEGIP, a tomato protein that inhibits fungal xyloglucan-specific endo-beta-1,4-glucanases, and GIP1, an oomycete protein that inhibits endo-beta-1,3-glucanases produced by the plant host. These inhibitor proteins act by forming high-affinity complexes with their endoglucanase ligands. A family of XEGIP-like proteins has been identified. At least one member of this family (extracellular dermal glycoprotein, EDGP) has been shown to have endoglucanase-inhibitor activity, while other members have sequence similarity to a xylanase inhibitor from wheat (TAXI-1). The oomycete inhibitor GIP1 is a catalytically inactive serine protease homolog (SPH) whose structure is unrelated to XEGIP. Both types of inhibitor proteins are likely to affect the interactions of plants with filamentous phytopathogens, and a basic model describing their roles in pathogenesis is proposed.     

Multiple Copies of Genes Encoding XEGIPs are Harbored in an 85-kB Region of the Potato Genome

Proteinaceous inhibitors of plant cell wall degrading enzymes can provide a first level of defense from invasive phytopathogens. One recently discovered inhibitor is the xyloglucans-specific endoglucanase inhibitor protein (XEGIP) originally found in tomato. This inhibitor protein has since been found in many solanaceous plants as well as other dicots. As xyloglucans play a major role in maintaining cell wall structure in dicots, protection of xyloglucan is critical. Thus far, only a single potato XEGIP had been identified (AY321357), even though a major pathogen of potato, Phytophthora infestans, has multiple copies of xyloglucan-specific endoglucanase. We now report that potato has nine additional copies of XEGIP, clustered together on a small region of chromosome one. They are located adjacent to the previously described potato XEGIP and represent one of the highest degrees of gene duplication relative to any other potato inhibitor. Synteny with tomato indicates this duplication may have occurred before speciation of Solanum.     

Crystal structure of basic 7S globulin, a xyloglucan-specific endo-β-1,4-glucanase inhibitor protein-like protein from soybean lacking inhibitory activity against endo-β-glucanase

β-Linked glucans such as cellulose and xyloglucan are important components of the cell walls of most dicotyledonous plants. These β-linked glucans are constantly exposed to degradation by various endo-β-glucanases from pathogenic bacteria and fungi. To protect the cell wall from degradation by such enzymes, plants secrete proteinaceous endo-β-glucanases inhibitors, such as xyloglucan-specific endo-β-1,4-glucanase inhibitor protein (XEGIP) in tomato. XEGIPs typically inhibit xyloglucanase, a member of the glycoside hydrolase (GH)12 family. XEGIPs are also found in legumes, including soybean and lupin. To date, tomato XEGIP has been well studied, whereas XEGIPs from legumes are less well understood. Here, we determined the crystal structure of basic 7S globulin (Bg7S), a XEGIP from soybean, which represents the first three-dimensional structure of XEGIP. Bg7S formed a tetramer with pseudo-222 symmetry. Analytical centrifugation and size exclusion chromatography experiments revealed that the assembly of Bg7S in solution depended on pH. The structure of Bg7S was similar to that of a xylanase inhibitor protein from wheat (Tritinum aestivum xylanase inhibitor) that inhibits GH11 xylanase. Surprisingly, Bg7S lacked inhibitory activity against not only GH11 but also GH12 enzymes. In addition, we found that XEGIPs from azukibean, yardlongbean and mungbean also had no impact on the activity of either GH12 or GH11 enzymes, indicating that legume XEGIPs generally do not inhibit these enzymes. We reveal the structural basis of why legume XEGIPs lack this inhibitory activity. This study will provide significant clues for understanding the physiological role of Bg7S.     

Identification of a single-copy gene encoding a Type I chlorophyll a/b-binding polypeptide of photosystem I in Arabidopsis thaliana

We have isolated and sequenced cDNA and genomic clones from Arabidopsis thaliana which specify a 241 residue protein with 84% sequence identity to a photosystem I Type I chlorophyll a/b -binding (CAB) protein from tomato. The open reading frame is interrupted by three introns which are found at equivalent positions as the corresponding introns in the tomato gene. Comparison to the amino acid sequence of other CAB proteins confirms that all CAB proteins share two regions of very high similarity. However, near the N-terminus and between the conserved regions this light-harvesting complex I (LHCI) protein, as other LHCI proteins from other plant species, has sequence motifs which appear to be PSI-specific. Restriction analysis of genomic DNA shows that the Arabidopsis protein is encoded by a single-copy gene.     

Structural and phylogenetic analysis of Pto-type disease resistance gene candidates in banana

The tomato Pto gene encodes a serine/threonine kinase (STK) whose molecular characterization has provided valuable insights into the disease resistance mechanism of tomato and it is considered as a promising candidate for engineering broad-spectrum pathogen resistance in this crop. In this study, a pair of degenerate primers based on conserved subdomains of plant STKs similar to the tomato Pto protein was used to amplify similar sequences in banana. A fragment of approximately 550 bp was amplified, cloned and sequenced. The sequence analysis of several clones revealed 13 distinct sequences highly similar to STKs. Based on their significant similarity with the tomato Pto protein (BLASTX E value <3e-53), seven of them were classified as Pto resistance gene candidates (Pto-RGCs). Multiple sequence alignment of the banana Pto-RGC products revealed that these sequences contain several conserved subdomains present in most STKs and also several conserved residues that are crucial for Pto function. Moreover, the phylogenetic analysis showed that the banana Pto-RGCs were clustered with Pto suggesting a common evolutionary origin with this R gene. The Pto-RGCs isolated in this study represent a valuable sequence resource that could assist in the development of disease resistance in banana.     

Structure and expression of an inhibitor of fungal polygalacturonases from tomato

A polygalacturonase inhibitor protein (PGIP) was characterized from tomato fruit. Differential glycosylation of a single polypeptide accounted for heterogeneity in concanavalin A binding and in molecular mass. Tomato PGIP had a native molecular mass of 35 to 41 kDa, a native isoelectric point of 9.0, and a chemically deglycosylated molecular mass of 34 kDa, suggesting shared structural similarities with pear fruit PGIP. When purified PGIPs from pear and tomato were compared, tomato PGIP was approximately twenty-fold less effective an inhibitor of polygalacturonase activity isolated from cultures of Botrytis cinerea. Based on partial amino acid sequence, polymerase chain reaction products and genomic clones were isolated and used to demonstrate the presence of PGIP mRNA in both immature and ripening fruit as well as cell suspension cultures. Nucleotide sequence analysis indicates that the gene, uninterrupted by introns, encodes a predicted 36.5 kDa polypeptide containing amino acid sequences determined from the purified protein and sharing 68% and 50% amino acid sequence identity with pear and bean PGIPs, respectively. Analysis of the PGIP sequences also revealed that they belong to a class of proteins which contain leucine-rich tandem repeats. Because these sequence domains have been associated with protein-protein interactions, it is possible that they contribute to the interaction between PGIP and fungal polygalacturonases.     

Molecular characterization of a gene encoding a cysteine-rich protein preferentially expressed in anthers of Lycopersicon esculentum

The tomato (Lycopersicon esculentum Mill.) cDNA clone TomA5B was isolated by differential screening of a cDNA library prepared from anthers at late meiosis to tetrad formation. The 5B gene is present in a single copy in the tomato genome. Expression is developmentally regulated and tissue specific. RNA accumulation was detected from premeiosis through tetrad release in the tapetal cell layer of the anther with low levels of RNA detected in petals and early stages of pistil development. The protein deduced from the DNA sequence analysis is predicted to have a molecular mass of 11.1 kDa and a secretory signal sequence, suggesting it is a secreted protein. The deduced 5B protein has a pattern of cysteine residues that is similar to other proteins that have stamen-specific expression and to a superfamily of seed proteins. The 5B protein is unique in that there is no amino acid sequence similarity to other proteins beyond the similar cysteine motif.     

巴西橡胶Pto类抗病同源序列的克隆与系统发育重建

番茄Pto基因是一类可以编码丝氨酸/苏氨酸激酶(STK)序列的广谱抗性候选基因,其序列克隆与鉴定为深入了解番茄的抗病机制奠定了基础.在该研究中,一对依据Pto基因的保守序列设计的简并引物被用来扩增巴西橡胶中Pto基因抗病同源序列,扩增得到了一个约550 bp的基因片段,其随后被克隆并测序.序列分析发现,其中的7个抗病同源序列与Pto基因高度同源(BLASTX E value <3e-53),所以其被认为是Pto基因抗病同源序列(Pto-RGCs).通过巴西橡胶的Pto-RGCs多序列比对表明,这些序列包含了多个STKs保守的次级结构域.此外,系统发育分析也表明,巴西橡胶的Pto-RGCs属于Pto基因同源的R基因.该研究结果中Pto-RGCs可为巴西橡胶抗病的发展提供一个有效的基因资源.     

In vitro processing of tomato proteinase inhibitor I by barley microsomal membranes: a system for analysis of cotranslational processing of plant endomembrane proteins

A plant-derived in vitro system for the study of cotranslational processing of plant endomembrane proteins has been developed and used to investigate cotranslational proteolytic processing of tomato proteinase inhibitor I. Translation of the inhibitor I precursor in wheat germ lysate supplemented with barley aleurone microsomal membranes resulted in cotranslational import of the protein into microsomal vesicles and cleavage of the signal sequence. NH₂-terminal sequence analysis of the translocated inhibitor I processing intermediate showed that the signal sequence was cleaved between Ala₂₃ and Arg₂₄ of the precursor protein. Parallel experiments using dog pancreas microsomal membranes indicated an identical site of cleavage, suggesting that the substrate determinants for signal sequence processing are conserved across kingdoms. The plant-derived processing system used for this study may be valuable for analysis of cotranslational processing of other plant preproteins and for characterizing the components of the cotranslational import machinery in plants.     

Structural basis for inhibition of xyloglucan-specific endo-β-1,4-glucanase (XEG) by XEG-protein inhibitor

Microorganisms such as plant pathogens secrete glycoside hydrolases (GHs) to digest the polysaccharide chains of plant cell walls. The degradation of cell walls by these enzymes is a crucial step for nutrition and invasion. To protect the cell wall from these enzymes, plants secrete glycoside hydrolase inhibitor proteins (GHIPs). Xyloglucan-specific endo-β-1,4-glucanase (XEG), a member of GH family 12 (GH12), could be a great threat to many plants because xyloglucan is a major component of the cell wall in most plants. Understanding the inhibition mechanism of XEG by GHIP is therefore of great importance in the field of plant defense, but to date the mechanism and specificity of GHIPs remain unclear. We have determined the crystal structure of XEG in complex with extracellular dermal glycoprotein (EDGP), a carrot GHIP that inhibits XEG. The structure reveals that the conserved arginines of EDGP intrude into the active site of XEG and interact with the catalytic glutamates of the enzyme. We have also determined the crystal structure of the XEG-xyloglucan complex. These structures show that EDGP closely mimics the XEG-xyloglucan interaction. Although EDGP shares structural similarity to a wheat GHIP (Triticum aestivum xylanase inhibitor-IA (TAXI-IA)) that inhibits GH11 family xylanases, the arrangement of GH and GHIP in the XEG-EDGP complex is distinct from that in the xylanase-TAXI-IA complex. Our findings imply that plants have evolved structures of GHIPs to inhibit different GH family members that attack their cell walls.     

Cloning, in silico characterization and interaction of cysteine protease and cystatin for establishing their role in early blight disease in tomato

Cysteine protease (CP) and Cysteine protease inhibitor (CPI) or cystatin constitute a critical point in programmed cell death (PCD), a basic biological phenomenon which takes place in the plants, when they are exposed to varying biotic and abiotic stresses. In the present study we isolated and cloned cDNAs encoding cysteine protease and cystatin from early blight infected tomato plants. Using computational biology tools the sequence-structure-function relationships for the tomato cystatin and cysteine protease were elucidated. Interaction between the cystatin and cysteine protease of host and pathogen is higher as compared to interaction shown by cystatin and cysteine protease within the host. The interaction energy of (a)tomato cystatin—tomato cysteine protease, (b)tomato cystatin—fungal cysteine protease and (c)tomato cysteine protease—fungal cystatin are ?319.33 Kcal/mol, ?504.71 Kcal/mol and ?373.731 Kcal/mol respectively. Comparative protein sequence analysis with different plant cystatins and cysteine protease were also done with the sequences of cystatin and cysteine protease isolated from tomato. Structures for all the cystatin and cysteine protease were modeled along with their interactions with fungal cystatin and cysteine protease in order to explore the structural variability and its manifestation at the functional level. This helped to relate the already known functions of these proteins with their sequences as well as the predicted structures. This also served to better understand the CP-CPI interaction operational in developing this protein family and its implication in plant defense during fungal pathogenesis in tomato plants.     

Characterization and comparative sequence analysis of the DNA mismatch repair MSH2 and MSH7 genes from tomato

DNA mismatch repair proteins play an essential role in maintaining genomic integrity during replication and genetic recombination. We successfully isolated a full length MSH2 and partial MSH7 cDNAs from tomato, based on sequence similarity between MutS and plant MSH homologues. Semi-quantitative RT-PCR reveals higher levels of mRNA expression of both genes in young leaves and floral buds. Genetic mapping placed MSH2 and MSH7 on chromosomes 6 and 7, respectively, and indicates that these genes exist as single copies in the tomato genome. Analysis of protein sequences and phylogeny of the plant MSH gene family show that these proteins are evolutionarily conserved, and follow the classical model of asymmetric protein evolution. Genetic manipulation of the expression of these MSH genes in tomato will provide a potentially useful tool for modifying genetic recombination and hybrid fertility between wide crosses.     

A tomato xylem sap protein represents a new family of small cysteine-rich proteins with structural similarity to lipid transfer proteins

The coding sequence of a major xylem sap protein of tomato was identified with the aid of mass spectrometry. The protein, XSP10, represents a novel family of extracellular plant proteins with structural similarity to plant lipid transfer proteins. The XSP10 gene is constitutively expressed in roots and lower stems. The decline of XSP10 protein levels in tomato infected with a fungal vascular pathogen may reflect breakdown or modification by the pathogen.     

Cloning and characterization of two xyloglucanases from Paenibacillus sp. strain KM21

Two xyloglucan-specific endo-beta-1,4-glucanases (xyloglucanases [XEGs]), XEG5 and XEG74, with molecular masses of 40 kDa and 105 kDa, respectively, were isolated from the gram-positive bacterium Paenibacillus sp. strain KM21, which degrades tamarind seed xyloglucan. The genes encoding these XEGs were cloned and sequenced. Based on their amino acid sequences, the catalytic domains of XEG5 and XEG74 were classified in the glycoside hydrolase families 5 and 74, respectively. XEG5 is the first xyloglucanase belonging to glycoside hydrolase family 5. XEG5 lacks a carbohydrate-binding module, while XEG74 has an X2 module and a family 3 type carbohydrate-binding module at its C terminus. The two XEGs were expressed in Escherichia coli, and recombinant forms of the enzymes were purified and characterized. Both XEGs had endoglucanase active only toward xyloglucan and not toward Avicel, carboxymethylcellulose, barley beta-1,3/1,4-glucan, or xylan. XEG5 is a typical endo-type enzyme that randomly cleaves the xyloglucan main chain, while XEG74 has dual endo- and exo-mode activities or processive endo-mode activity. XEG5 digested the xyloglucan oligosaccharide XXXGXXXG to produce XXXG, whereas XEG74 digestion of XXXGXXXG resulted in XXX, XXXG, and GXXXG, suggesting that this enzyme cleaves the glycosidic bond of unbranched Glc residues. Analyses using various oligosaccharide structures revealed that unique structures of xyloglucan oligosaccharides can be prepared with XEG74.     

Interaction of Nectarin 4 with a fungal protein triggers a microbial surveillance and defense mechanism in nectar

Understanding the biochemical mechanisms by which plants respond to microbial infection is a fundamental goal of plant science. Extracellular dermal glycoproteins (EDGPs) are widely expressed in plant tissues and have been implicated in plant defense responses. Although EDGPs are known to interact with fungal proteins, the downstream effects of these interactions are poorly understood. To gain insight into these phenomena, we used tobacco floral nectar as a model system to identify a mechanism by which the EDGP known as Nectarin IV (NEC4) functions as pathogen surveillance molecule. Our data demonstrates that the interaction of NEC4 with a fungal endoglucanase (XEG) promotes the catalytic activity of Nectarin V (NEC5), which catalyzes the conversion of glucose and molecular oxygen to gluconic acid and H(2)O(2). Significantly enhanced NEC5 activity was observed when XEG was added to nectar or nectarin solutions that contain NEC4. This response was also observed when the purified NEC4:XEG complex was added to NEC4-depleted nectarin solutions, which did not respond to XEG alone. These results indicate that formation of the NEC4:XEG complex is a key step leading to induction of NEC5 activity in floral nectar, resulting in an increase in concentrations of reactive oxygen species (ROS), which are known to inhibit microbial growth directly and activate signal transduction pathways that induce innate immunity responses in the plant.     

A novel function for the cathepsin D inhibitor in tomato

Proteinaceous aspartic proteinase inhibitors are rare in nature and are described in only a few plant species. One of them corresponds to a family of cathepsin D inhibitors (CDIs) described in potato (Solanum tuberosum), involving up to 15 isoforms with a high sequence similarity. In this work, we describe a tomato (Solanum lycopersicum) wound-inducible protein called jasmonic-induced protein 21 (JIP21). Sequence analysis of its cDNA predicted a putative function as a CDI. The JIP21 gene, whose protein has been demonstrated to be glycosylated, is constitutively expressed in flowers, stem, and fruit, and is inducible to high levels by wounding and methyl jasmonate in leaves of tomato plants. The genomic sequence of JIP21 shows that the gene is intronless and reveals the presence of both a methyl jasmonate box (TGACT) and a G-box (CACGT) in the promoter. In contrast to the presumed role of JIP21 based on sequence analysis, a detailed biochemical characterization of the purified protein uncovers a different function as a strong chymotrypsin inhibitor, which questions the previously predicted inhibitory activity against aspartic proteinases. Moreover, Egyptian cotton worm (Spodoptera littoralis) larvae fed on transgenic tomato plants overexpressing JIP21 present an increase in mortality and a delay in growth when compared with larvae fed on wild-type plants. These larvae belong to the Lepidoptera family whose main digestive enzymes have been described as being Ser proteases. All these results support the notion that tomato JIP21 should be considered as a chymotrypsin inhibitor belonging to the Ser proteinase inhibitors rather than a CDI. Therefore, we propose to name this protein tomato chymotrypsin inhibitor 21 (TCI21).     

Amino acid sequence of an extracellular, phosphate-starvation-induced ribonuclease from cultured tomato (Lycopersicon esculentum) cells

The primary structure of an extracellular ribonuclease (RNase LE) from Pi-depleted media of cultured cells of Lycopersicon esculentum L. cv. Lukullus has been determined. This was carried out by analysis of peptides isolated after enzymatic and chemical cleavage of the reduced and S-ethylpyridylated protein. RNase LE consists of 205 amino acid residues and has a molecular mass of 22,666 Da and an isoelectric point of 4.24. The enzyme contains 10 half-cystines. There are no potential N-glycosylation sites in the sequence. The sequence of RNase LE is homologous with those of self-incompatibility proteins of several higher plant species and with those of a number of fungal RNases. The sequence similarity with the family of self-incompatibility proteins is greater than with the fungal RNases, suggesting that the self-incompatibility proteins arose from ancestral RNase by gene duplication after the divergence of higher plants and fungi. Two pentapeptide sequences, i.e. HGLWP and KHGTC (or KHGSC), are present at identical positions in all the aligned proteins, suggesting that they contribute to the active site.