Classification and comparative analysis of Curcuma longa L. expressed sequences tags (ESTs) encoding glycine-rich proteins (GRPs)

Glycine-rich proteins (GRPs) are a group of proteins characterized by their high content of glycine residues often occurring in repetitive blocs. The diverse expression pattern and sub cellular localization of various GRPs suggest their implication in different physiological processes. Several GRPs has been isolated and characterized from different monocots and dicots. However, little or no information is available about the structure and function of GRPs in asexually reproducing plants. In this study, in-silico analysis of expressed sequence tag database resulted in the isolation of fifty-one GRPs from Curcuma longa L., an asexually reproducible plant of great medicinal and economic significance. Phylogenetic analysis grouped the GRPs into four distinct classes based on conserved motifs and nature of glycine-rich repeats. Majority of the isolated GRPs exhibited high homology with known GRPs from other plants that are expressed in response to various stresses. The presence of high structural diversity and signal peptide in some GRPs suggest their diverse physiological role and tissue specific localization. The isolated sequences can be used as a framework for cloning, characterization and expressional analysis of GRPs in response to various biotic and abiotic stresses in Curcuma longa as well as other asexually reproducing plants.     

Conservation of structure and cold-regulation of RNA-binding proteins in cyanobacteria: probable convergent evolution with eukaryotic glycine-rich RNA-binding proteins

The rbp gene family of the cyanobacterium Anabaena variabilis strain M3 consists of eight members that encode small RNA-binding proteins containing a single RNA recognition motif (RRM). Similar genes are found in the genomes of Synechocystis sp. PCC6803, Helicobacter pylori and Treponema pallidum, but are absent from the other completely sequenced prokaryotic genomes. The expression of the rbp genes of Anabaena is induced by low temperature, with the exception of the rbpD gene. We found four stretches of conserved sequences in the 5'-untranslated region of the cyanobacterial rbp genes that are known to be induced by low temperature. The cold-regulated Rbp proteins contain a short C-terminal glycine-rich domain. In this respect, these proteins are similar to plant and mammalian glycine-rich RNA-binding proteins (GRPs), which also contain a single RRM domain with a C-terminal glycine-rich domain and are highly expressed at low temperature. Detailed phylogenetic analysis showed, however, that the cyanobacterial Rbp proteins and the eukaryotic GRPs do not belong to a single lineage, but that the glycine-rich domains are likely to have been added independently. The cold-regulation of both types of proteins is also likely to have evolved independently. Furthermore, the chloroplast RNA-binding proteins are not likely to have originated from the Rbp proteins of endosymbiont cyanobacterium, but are supposed to have diverged from the GRPs. These results suggest that the cyanobacterial Rbp proteins and the eukaryotic GRPs are similar in both structure and regulation, but that this apparent similarity has resulted from convergent evolution.     

Glycine-rich proteins encoded by a nodule-specific gene family are implicated in different stages of symbiotic nodule development in Medicago spp

Four genes encoding small proteins with significantly high glycine content have been identified from root nodules of Medicago sativa. All of these proteins as well as their Medicago truncatula homologues carried an amino terminal signal peptide and a glycine-rich carboxy terminal domain. All except nodGRP3 lacked the characteristic repeat structure described for cell wall and stress response-related glycine-rich proteins (GRP). Expression of these GRP genes was undetectable in flower, leaf, stem, and hypocotyl cells, whereas expression was highly induced during root nodule development, suggesting that GRP genes act as nodulins. Moreover, none of these nodule-expressed GRP genes were activated by hormones or stress treatments, which are inducers of many other GRPs. In Rhizobium-free spontaneous nodules and in nodules induced by a noninfective mutant strain of Sinorhizobium meliloti, all these genes were repressed, while they were induced in Fix- nodules, unaffected in bacterial infection, but halted in bacteroid differentiation. These results demonstrated that bacterial infection but not bacteroid differentiation is required for the induction of the nodule-specific GRP genes. Differences in kinetics and localization of gene activation as well as in the primary structure of proteins suggest nonredundant roles for these GRPs in nodule organogenesis.     

cDNA encoding a wheat (Triticum aestivum cv. Chinese Spring) glycine-rich RNA-binding protein

A wheat cDNA encoding a glycine-rich RNA-binding protein, whGRP-1, was isolated. WhGRP-1 contains two conserved domains, the RNA-binding motif (RNP motif) combined with a series of glycine-rich imperfect repeats, characteristic of a conserved family of plant RNA-binding proteins. Northern analysis revealed that whGRP-1 mRNA accumulates to high levels in roots and to lower levels in leaves of wheat seedlings. whGRP-1 mRNA accumulation is not enhanced by exogenous abscisic acid in seedlings and accumulates to very high levels during wheat embryo development, showing a pattern different from that of the ABA-inducible wheat Em gene.     

Protoxylem: the deposition of a network containing glycine-rich cell wall proteins starts in the cell corners in close association with the pectins of the middle lamella

Antibodies were used to localise polysaccharide and protein networks in the protoxylem of etiolated soybean (Glycine max L.) hypocotyls. The deposition of glycine-rich proteins (GRPs) starts in the cell corners between protoxylem elements and xylem parenchyma cells. Finally, the GRPs form a network between two mature protoxylem elements. The network also interconnects the ring- and spiral-shaped secondary wall thickenings, as well as the thickenings with the middle lamellae of living xylem parenchyma cells. In addition to the GRP network, a polysaccharide network composed mainly of pectins is involved in the attachment of the secondary wall thickenings to the middle lamellae of xylem parenchyma cells.     

Structural and functional diversity of cadherin superfamily: Are new members of cadherin superfamily involved in signal transduction pathway?

A large number of cadherins and cadherin-related proteins are expressed in different tissues of a variety of multicellular organisms. These proteins share one property: their extracellular domains consist of multiple repeats of a cadherin-specific motif. A recent structure study has shown that the cadherin repeats roughly corresponding to the folding unit of the extracellular domains. The members of the cadherin superfamily are roughly classified into two groups, classical type cadherins proteins and protocadherin type according to their structural properties. These proteins appear to be derived from a common ancestor that might have cadherin repeats similar to those of the current protocadherins, and to have common functional properties. Among various cadherins, E-cadherin was the first to be identified as a Ca²⁺-dependent homophilic adhesion protein. Recent knockout mice experiments have proven its biological role, but there are still several puzzling unsolved properties of the cell adhesion activity. Other members of cadherin superfamily show divergent properties and many lack some of the expected properties of cell adhesion protein. Since recent studies of various adhesion proteins reveal that they are involved in different signal transduction pathways, the idea that the new members of cadherin superfamily may participate in more general cell-cell interaction processes including signal transduction is an intriguing hypothesis. The cadherin superfamily is structurally divergent and possibly functionally divergent as well. © 1996 Wiley-Liss, Inc.     

Structural determinants crucial to the RNA chaperone activity of glycine-rich RNA-binding proteins 4 and 7 in Arabidopsis thaliana during the cold adaptation process

Although glycine-rich RNA-binding proteins (GRPs) have been determined to function as RNA chaperones during the cold adaptation process, the structural features relevant to this RNA chaperone activity remain largely unknown. To uncover which structural determinants are necessary for RNA chaperone activity of GRPs, the importance of the N-terminal RNA recognition motif (RRM) and the C-terminal glycine-rich domains of two Arabidopsis thaliana GRPs (AtGRP4 harbouring no RNA chaperone activity and AtGRP7 harbouring RNA chaperone activity) was assessed via domain swapping and mutation analyses. The results of domain swapping and deletion experiments showed that the domain sequences encompassing the N-terminal RRM of GRPs were found to be crucial to the ability to complement cold-sensitive Escherichia coli mutant cells under cold stress, RNA melting ability, and freezing tolerance ability in the grp7 loss-of-function Arabidopsis mutant. In particular, the N-terminal 24 amino acid extension of AtGRP4 impedes the RNA chaperone activity. Collectively, these results reveal that domain sequences and overall folding of GRPs governed by a specific modular arrangement of RRM and glycine-rich sequences are critical to the RNA chaperone activity of GRPs during the cold adaptation process in cells.     

Diverse roles of glycine-rich RNA-binding protein 7 in the response of camelina (<Emphasis Type="Italic">Camelina sativa</Emphasis>) to abiotic stress

Camelina sativa L. is an oilseed crop used as a potential low-cost biofuel resource. Despite the economic and agricultural benefits of this crop, studies demonstrating the physiological and genetic response of camelina to changing environmental conditions are limited. In this study, three stress-responsive glycine-rich RNA-binding proteins (GRPs) in camelina—named CsGRP7a, CsGRP7b, and CsGRP7c—were isolated, and their functional roles in stress responses were characterized. The three CsGRP7 genes had similar nucleotide and deduced amino acid sequences, and contained an N-terminal RNA-recognition motif and a C-terminal glycine-rich region. The CsGRP7 genes were ubiquitously expressed in all plant tissues, and CsGRP7 proteins were localized to both the cytoplasm and the nucleus. The expression of CsGRP7 genes was markedly upregulated by cold stress, whereas their expression was only slightly affected by salt or dehydration stress. Analysis of CsGRP7a-expressing transgenic Arabidopsis thaliana and camelina plants revealed that CsGRP7a plays a positive role in cold stress tolerance, but a negative role in salt or drought stress tolerance. All three CsGRP7s harbored RNA chaperone activity. Collectively, these data indicate that the stress-responsive CsGRP7s harbor RNA chaperone activity and play different roles in the plant response to abiotic stresses.     

Cold shock domain proteins and glycine-rich RNA-binding proteins from Arabidopsis thaliana can promote the cold adaptation process in Escherichia coli

Despite the fact that cold shock domain proteins (CSDPs) and glycine-rich RNA-binding proteins (GRPs) have been implicated to play a role during the cold adaptation process, their importance and function in eukaryotes, including plants, are largely unknown. To understand the functional role of plant CSDPs and GRPs in the cold response, two CSDPs (CSDP1 and CSDP2) and three GRPs (GRP2, GRP4 and GRP7) from Arabidopsis thaliana were investigated. Heterologous expression of CSDP1 or GRP7 complemented the cold sensitivity of BX04 mutant Escherichia coli that lack four cold shock proteins (CSPs) and is highly sensitive to cold stress, and resulted in better survival rate than control cells during incubation at low temperature. In contrast, CSDP2 and GRP4 had very little ability. Selective evolution of ligand by exponential enrichment (SELEX) revealed that GRP7 does not recognize specific RNAs but binds preferentially to G-rich RNA sequences. CSDP1 and GRP7 had DNA melting activity, and enhanced RNase activity. In contrast, CSDP2 and GRP4 had no DNA melting activity and did not enhance RNAase activity. Together, these results indicate that CSDPs and GRPs help E.coli grow and survive better during cold shock, and strongly imply that CSDP1 and GRP7 exhibit RNA chaperone activity during the cold adaptation process.     

RCC1-like repeat proteins: a pangenomic, structurally diverse new superfamily of beta-propeller domains

The beta-propeller fold is a phylogenetically widespread, common protein architecture able to support a range of different functions such as catalysis, ligand binding and transport, regulation and protein binding. Interestingly, it appears that the beta-propeller topology is also compatible with strikingly diverse sequences. Amongst this diversity, there are three large groups of proteins with related sequences and very important cellular and intercellular regulatory functions: WD, kelch, and YWTD proteins. A common characteristic between these protein families is that their sequences, while distinct, all contain internal repeats 40-45 residues long. Through a pangenomic analysis using internal repeat profiles derived from the structurally known propeller modules of the eukaryotic protein RCC1 and the related prokaryotic protein BLIP-II, we have defined a new superfamily of propeller repeats, the RCC1-like repeats (RLRs). These sequences turn out to be more phylogenetically widespread than other large groups of propeller proteins, occurring in both prokaryotic and eukaryotic genomes. Interestingly, our research showed that RLR domains with different numbers of repeats exist, ranging from 3 to 7, and possibly more. A novel, intriguing finding is the discovery of sequences with 3 repeats, as well as proteins with 10 modular units, though in the latter case it is not clear whether these are made of two 5-bladed domains or a single, novel 10-bladed propeller. In addition, the results indicate that circular permutation events may have taken place in the evolution of these proteins. It is now established that the group of RLR proteins is extremely numerous and is characterized by unique, remarkable features which place it in a position of special interest as an important superfamily of proteins in nature.     

The evolution of gametic compatibility and compatibility groups in the sea urchin Mesocentrotus franciscanus: An avenue for speciation in the sea

The generation of reproductive incompatibility between groups requires a rare genotype with low compatibility to increase in frequency. We tested the hypothesis that sexual conflict driven by the risk of polyspermy can generate compatibility groups in gamete recognition proteins (GRPs) in the sea urchin Mesocentrotus franciscanus. We examined variation in the sperm (bindin) and egg (EBR1) GRPs, how this variation influences fertilization success and how allele frequencies shift in these GRPs over time. The EBR1 gene is a large, 4595 amino acid protein made up of 27 thrombospondin type 1 domain (TSP) and 20 C1s/C1r, uEGF and bone morphogenic protein subdomain (CUB) repeats. Two TSP and two CUB repeats each demonstrate two common non‐synonymous haplotypes (alleles). Sperm bindin and one of these EBR1 repeats (TSP8) shift allele frequencies from one common to two common types over an approximate 200 year interval associated with the removal of predatory sea otters and rising sea urchin abundances; the egg receptor shifts first, followed by the sperm ligand. Laboratory crosses indicate that the historically common sperm and egg gamete recognition proteins have high compatibility as do the new common proteins, with mismatches having lower compatibility. This process of creating compatibility groups sets the stage for reproductive isolation and speciation.     

Root-specific expression of a Zea mays gene encoding a novel glycine-rich protein,zmGRP3

The isolation and characterization of a cDNA clone from Zea mays coding for a novel glycine-rich protein (GRP) is described. The corresponding 1.4 kb mRNA accumulates exclusively in roots (primary, lateral seminal and crown roots) of young maize seedlings, following developmentally specific patterns. In agreement with previously described GRPs from other plant species the derived protein sequence exhibits a hydrophobic domain at the N-terminal region followed by repeated glycine-rich motifs. Genomic Southern analysis indicates that the zmGRP3 gene is present in the maize genome as one or two copies or at a low copy number.     

Statistical characterization of the GxxxG glycine repeats in the flagellar biosynthesis protein FliH and its Type III secretion homologue YscL

Background  

FliH is a protein involved in the export of components of the bacterial flagellum and we herein describe the presence of glycine-rich repeats in FliH of the form AxxxG(xxxG) _m xxxA, where the value of m varies considerably in FliH proteins from different bacteria. While GxxxG and AxxxA patterns have previously been described, the long glycine repeat segments in FliH proteins have yet to be characterized. The Type III secretion system homologue to FliH (YscL, AscL, PscL, etc.) also contains a similar GxxxG repeat, and hence the presence of the repeat is evolutionarily conserved in these proteins, suggesting an important structural role or biological function.     

The mitochondrial transport protein superfamily

The ADP/ATP, phosphate, and oxoglutarate/malate carrier proteins found in the inner membranes of mitochondria, and the uncoupling protein from mitochondria in mammalian brown adipose tissue, belong to the same protein superfamily. Established members of this superfamily have polypeptide chains approximately 300 amino acids long that consist of three tandem related sequences of about 100 amino acids. The tandem repeats from the different proteins are interrelated, and probably have similar secondary structures. The common features of this superfamily are also present in nine proteins of unknown functions characterized by DNA sequencing in various species, most notably inCaenorhabditis elegans andSaccharomyces cerevisiae. The high level expression inEscherichia coli of the bovine oxoglutarate/malate carrier, and the reconstitution of active carrier from the expressed protein, offers encouragement that the identity of superfamily members of known sequence but unknown function may be uncovered by a similar route.     

Comparative localization of three classes of cell wall proteins.

The localization of the cell wall proline-rich proteins (PRPs), and the gene expression of the cell wall glycine-rich proteins (GRPs) and the hydroxyproline-rich glycoproteins (HRGPs) were examined in several dicot species. The PRPs are accumulated in the corner walls of the cortex where several cells are joined together and in the protoxylem cell walls of 3-day-old soybean root. In 1-month-old soybean plants, the PRPs are specifically deposited in xylem vessel elements of the young stem, and they are accumulated in both phloem fibers and xylem vessel elements and fibers of the older stem. Likewise, the PRPs are localized in xylem vessel elements and fibers in tomato, petunia, potato and tobacco stems. They are also found in outer and inner phloem fiber cell walls of tomato stem and in outer phloem fiber cell walls of petunia stem. The gene expression of the HRGPs and the GRPs is developmentally regulated in tomato, petunia and tobacco stems. HRGP mRNAs are abundant in outer and inner phloem regions, while GRP mRNAs are present mostly in primary xylem and in the cambium region. Immunocytochemical localization showed that the GRPs have a localization pattern similar to that of the PRPs in tomato, petunia and tobacco stems.     

WAKs: cell wall-associated kinases linking the cytoplasm to the extracellular matrix

There are only a few proteins identified at the cell surface that could directly regulate plant cell wall functions. The cell wall-associated kinases (WAKs) of angiosperms physically link the plasma membrane to the carbohydrate matrix and are unique in that they have the potential to directly signal cellular events through their cytoplasmic kinase domain. In Arabidopsis there are five WAKs and each has a cytoplasmic serine/threonine protein kinase domain, spans the plasma membrane, and extends a domain into the cell wall. The WAK extracellular domain is variable among the five isoforms, and collectively the family is expressed in most vegetative tissues. WAK1 and WAK2 are the most ubiquitously and abundantly expressed of the five tandemly arrayed genes, and their messages are present in vegetative meristems, junctions of organ types, and areas of cell expansion. They are also induced by pathogen infection and wounding. Recent experiments demonstrate that antisense WAK expression leads to a reduction in WAK protein levels and the loss of cell expansion. A large amount of WAK is covalently linked to pectin, and most WAK that is bound to pectin is also phosphorylated. In addition, one WAK isoform binds to a secreted glycine-rich protein (GRP). The data support a model where WAK is bound to GRP as a phosphorylated kinase, and also binds to pectin. How WAKs are involved in signaling from the pectin extracellular matrix in coordination with GRPs will be key to our understanding of the cell wall's role in cell growth.