A repetitive proline-rich protein from the gymnosperm douglas fir is a hydroxyproline-rich glycoprotein

Intact cell elution of suspension cultures derived from Douglas fir, Pseudotsuga menziesii (Mirbel) Franco, yielded two extensin monomers, the first hydroxyproline-rich glycoproteins (HRGPs) to be isolated from a gymnosperm. These HRGPs resolved on Superose-6 gel filtration. The smaller monomer was compositionally similar to angiosperm extensins like tomato P1. The larger monomer had a simple composition reminiscent of repetitive proline-rich proteins (RPRPs) from soybean cell walls and contained proline, hydroxyproline, and sugar; hence designated a proline-hydroxyproline-rich glycoprotein (PHRGP). The simple composition of the PHRGP implied a periodic structure which was confirmed by the simple chymotryptic map and 45-residue partial sequence of the major proline-hydroxyproline-rich glycoprotein chymotryptide 5: Lys-Pro-Hyp-Val-Hyp-Val-Ile-Pro-Pro-Hyp-Val-Val-Lys-Pro-Hyp-Hyp-Val- Tyr-Lys-Pro-Hyp-Val-Hyp-Val-Ile-Pro-Pro-Hyp-Val-Val-Lys-Pro-Hyp-Hyp- Val-Tyr-Lys-Ile-Pro-Pro(Hyp)-Val-Ile-Lys-Pro. Proline-hydroxyproline-rich glycoprotein chymotryptide 5 contained an 18-residue tandem repeat devoid of tetra(hydroxy)-proline or serine; it also contained two instances of the five-residue motif Hyp-Hyp-Val-Tyr-Lys and five of the general Pro-Pro-X-X-Lys motif, thereby establishing its homology with typical angiosperm RPRPs and extensins from tomato, petunia, carrot, tobacco, sugar beet, and Phaseolus. Unlike the nonglycosylated soybean RPRP, the highly purified Douglas fir PHRGP was lightly glycosylated, confirmed by a quantitative hydroxyproline glycoside profile, indicating that extensins can range from highly glycosylated hydroxyproline to little or no glycosylated hydroxyproline. Comparison of extensin sequence data strongly indicates that a major determinant of hydroxyproline glycosylation specificity is hydroxyproline contiguity: extensins with tetrahydroxyproline blocks are very highly arabinosylated (>90% hydroxyproline glycosylated), tri- and dihydroxyproline are less so, and single hydroxyproline residues perhaps not at all. Despite high yields of extensins eluted from intact cells, the Douglas fir cell wall itself was hydroxyproline poor yet remarkably rich in protein (>20%), again emphasizing the existence of other structural cell wall proteins that are neither HRGPs nor glycine-rich proteins.     

Focus Issue on Plant Cell Walls: A Bioinformatics Approach to the Identification,Classification, and Analysis of Hydroxyproline-Rich Glycoproteins

Hydroxyproline-rich glycoproteins (HRGPs) are a superfamily of plant cell wall proteins that function in diverse aspects of plant growth and development. This superfamily consists of three members: hyperglycosylated arabinogalactan proteins (AGPs), moderately glycosylated extensins (EXTs), and lightly glycosylated proline-rich proteins (PRPs). Hybrid and chimeric versions of HRGP molecules also exist. In order to “mine” genomic databases for HRGPs and to facilitate and guide research in the field, the BIO OHIO software program was developed that identifies and classifies AGPs, EXTs, PRPs, hybrid HRGPs, and chimeric HRGPs from proteins predicted from DNA sequence data. This bioinformatics program is based on searching for biased amino acid compositions and for particular protein motifs associated with known HRGPs. HRGPs identified by the program are subsequently analyzed to elucidate the following: (1) repeating amino acid sequences, (2) signal peptide and glycosylphosphatidylinositol lipid anchor addition sequences, (3) similar HRGPs via Basic Local Alignment Search Tool, (4) expression patterns of their genes, (5) other HRGPs, glycosyl transferase, prolyl 4-hydroxylase, and peroxidase genes coexpressed with their genes, and (6) gene structure and whether genetic mutants exist in their genes. The program was used to identify and classify 166 HRGPs from Arabidopsis (Arabidopsis thaliana) as follows: 85 AGPs (including classical AGPs, lysine-rich AGPs, arabinogalactan peptides, fasciclin-like AGPs, plastocyanin AGPs, and other chimeric AGPs), 59 EXTs (including SP₅ EXTs, SP₅/SP₄ EXTs, SP₄ EXTs, SP₄/SP₃ EXTs, a SP₃ EXT, “short” EXTs, leucine-rich repeat-EXTs, proline-rich extensin-like receptor kinases, and other chimeric EXTs), 18 PRPs (including PRPs and chimeric PRPs), and AGP/EXT hybrid HRGPs.The genomics era has produced vast amounts of biological data that await examination. In order to “mine” such data effectively, a bioinformatics approach can be utilized to identify genes of interest, subject them to various in silico analyses, and extract relevant biological information on them from various public databases. Examination of such data produces novel insights with respect to the genes in question and can be used to facilitate and guide further research in the field. Such is the case here, where bioinformatics tools were developed to identify, classify, and analyze members of the Hyp-rich glycoprotein (HRGP) superfamily encoded by the Arabidopsis (Arabidopsis thaliana) genome.HRGPs are a superfamily of plant cell wall proteins that are subdivided into three families, arabinogalactan proteins (AGPs), extensins (EXTs), and Pro-rich proteins (PRPs), and extensively reviewed (Showalter, 1993; Kieliszewski and Lamport, 1994; Nothnagel, 1997; Cassab, 1998; José-Estanyol and Puigdomènech, 2000; Seifert and Roberts, 2007). However, it has become increasingly clear that the HRGP superfamily is perhaps better represented as a spectrum of molecules ranging from the highly glycosylated AGPs to the moderately glycosylated EXTs and finally to the lightly glycosylated PRPs. Moreover, hybrid HRGPs, composed of HRGP modules from different families, and chimeric HRGPs, composed of one or more HRGP modules within a non-HRGP protein, also can be considered part of the HRGP superfamily. Given that many HRGPs are composed of repetitive protein sequences, particularly the EXTs and PRPs, and many have low sequence similarity to one another, particularly the AGPs, BLAST searches typically identify only a few closely related family members and do not represent a particularly effective means to identify members of the HRGP superfamily in a comprehensive manner.Building upon the work of Schultz et al. (2002) that focused on the AGP family, a new bioinformatics software program, BIO OHIO, developed at Ohio University, makes it possible to search all 28,952 proteins encoded by the Arabidopsis genome and identify putative HRGP genes. Two distinct types of searches are possible with this program. First, the program can search for biased amino acid compositions in the genome-encoded protein sequences. For example, classical AGPs can be identified by their biased amino acid compositions of greater then 50% Pro (P), Ala (A), Ser (S), and Thr (T), as indicated by greater than 50% PAST. Similarly, arabinogalactan peptides (AG peptides) are identified by biased amino acid compositions of greater then 35% PAST, but the protein (i.e. peptide) must also be between 50 and 90 amino acids in length. Likewise, PRPs can be identified by a biased amino acid composition of greater then 45% PVKCYT. Second, the program can search for specific amino acid motifs that are commonly found in known HRGPs. For example, SP₄ pentapeptide and SP₃ tetrapeptide motifs are associated with EXTs, a fasciclin H1 motif is found in fasciclin-like AGPs (FLAs), and PPVX(K/T) (where X is any amino acid) and KKPCPP motifs are found in several known PRPs (Fowler et al., 1999). In addition to searching for HRGPs, the program can analyze proteins identified by a search. For example, the program checks for potential signal peptide sequences and glycosylphosphatidylinositol (GPI) plasma member anchor addition sequences, both of which are associated with HRGPs (Showalter, 1993, 2001; Youl et al., 1998; Sherrier et al., 1999; Svetek et al., 1999). Moreover, the program can identify repeated amino acid sequences within the sequence and has the ability to search for bias amino acid compositions within a sliding window of user-defined size, making it possible to identify HRGP domains within a protein sequence.Here, we report on the use of this bioinformatics program in identifying, classifying, and analyzing members of the HRGP superfamily (i.e. AGPs, EXTs, PRPs, hybrid HRGPs, and chimeric HRGPs) in the genetic model plant Arabidopsis. An overview of this bioinformatics approach is presented in Figure 1. In addition, public databases and programs were accessed and utilized to extract relevant biological information on these HRGPs in terms of their expression patterns, most similar sequences via BLAST analysis, available genetic mutants, and coexpressed HRGP, glycosyl transferase (GT), prolyl 4-hydroxylase (P4H), and peroxidase genes in Arabidopsis. This information provides new insight to the HRGP superfamily and can be used by researchers to facilitate and guide further research in the field. Moreover, the bioinformatics tools developed here can be readily applied to protein sequences from other species to analyze their HRGPs or, for that matter, any given protein family by altering the input parameters.Open in a separate windowFigure 1.Bioinformatics workflow diagram summarizing the identification, classification, and analysis of HRGPs (AGPs, EXTs, and PRPs) in Arabidopsis. Classical AGPs were defined as containing greater than 50% PAST coupled with the presence of AP, PA, SP, and TP repeats distributed throughout the protein, Lys-rich AGPs were a subgroup of classical AGPs that included a Lys-rich domain, and chimeric AGPs were defined as containing greater than 50% PAST coupled with the localized distribution of AP, PA, SP, and TP repeats. AG peptides were defined to be 50 to 90 amino acids in length and containing greater than 35% PAST coupled with the presence of AP, PA, SP, and TP repeats distributed throughout the peptide. FLAs were defined as having a fasciclin domain coupled with the localized distribution of AP, PA, SP, and TP repeats. Extensins were defined as containing two or more SP₃ or SP₄ repeats coupled with the distribution of such repeats throughout the protein; chimeric extensins were similarly identified but were distinguished from the extensins by the localized distribution of such repeats in the protein; and short extensins were defined to be less than 200 amino acids in length coupled with the extensin definition. PRPs were identified as containing greater than 45% PVKCYT or two or more KKPCPP or PVX(K/T) repeats coupled with the distribution of such repeats and/or PPV throughout the protein. Chimeric PRPs were similarly identified but were distinguished from PRPs by the localized distribution of such repeats in the protein. Hybrid HRGPs (i.e. AGP/EXT hybrids) were defined as containing two or more repeat units used to identify AGPs, extensins, or PRPs. The presence of a signal peptide was used to provide added support for the identification of an HRGP but was not used in an absolute fashion. Similarly, the presence of a GPI anchor addition sequence was used to provide added support for the identification of classical AGPs and AG peptides, which are known to contain such sequences. BLAST searches were also used to provide some support to our classification if the query sequence showed similarity to other members of an HRGP subfamily. Note that some AGPs, particularly chimeric AGPs, and PRPs were identified from an Arabidopsis database annotation search and that two chimeric extensins were identified from the primary literature as noted in the text.     

Structure of the Threonine-Rich Extensin from Zea mays

Chymotryptic digestion of a threonine-rich hydroxyproline-rich glycoprotein (THRGP) purified from the cell surface of a Zea mays cell suspension culture gave a peptide map dominated by the hexadecapeptide TC5: Thr-Hyp-Ser-Hyp-Lys-Pro-Hyp-Thr-Pro-Lys-Pro-Thr-Hyp-Hyp-Thr-Tyr, in which the repetitive motif Ser-Hyp-Lys-Pro-Hyp-Thr-Pro-Lys is homologous with the dominant decamer of P1-type dicot extensins: Ser-Hyp-Hyp-Hyp-Hyp-Thr-Hyp-Val-Tyr-Lys, modified by a Lys for Hyp substitution at residue 3, a Val-Tyr deletion at residues 8 and 9, and incomplete post-translational modification of proline residues. One of the minor peptides (TC1) contained the 8-residue sequence: Thr-Hyp-Ser-Hyp-Hyp-Hyp-Hyp-Tyr corresponding to the C-terminal tail (judging from the recently isolated maize cDNA clone MC56) which is homologous with the major repetitive motif of the `P3' class of dicot extensins. Direct peptide sequencing defined potential glycosylated regions on the THRGP corresponding to clone MC56 and showing that glycosylated and nonglycosylated domains alternate with high regularity. The THRGP is not in the polyproline-II conformation, judging from circular dichroic spectra, but nevertheless is an extended rod, from electron microscopic data. HF-solvolysis of cell walls from maize coleoptile, root, and root tip released deglycosylated THRGP detected on sodium dodecyl sulfate-polyacrylamide gel electrophoresis immunoblots with high titer rabbit polyclonal antibodies raised against the intact THRGP. In a quantitative enzyme-linked immunosorbent assay, these antibodies cross-reacted 20% with tomato P1 extensin, and 18% with anhydrous hydrogen fluoride-deglycosylated P1. These results, together with other previously published data, show that maize THRGP is homologous with the dicot P1 extensins and, as such, is the first extensin isolated from a graminaceous monocot.     

A gymnosperm extensin contains the serine-tetrahydroxyproline motif

The extensin family is a diverse group of hydroxyproline-rich glycoproteins located in the cell wall and characterized by repetitive peptide motifs glycosylated to various degrees. The origin of this diversity and its relationship to function led us earlier to compare extensins of the two major groups of angiosperms from which we concluded that the highly glycosylated Ser-Hyp₄ motif was characteristic of advanced herbaceous dicots, occurring rarely or not at all in a representative graminaceous monocot (Zea mays) and a chenopod (Beta vulgaris) representative of primitive dicots. Because these results could arise either from loss or acquisition of a characteristic feature, we chose a typical gymnosperm representing seed-bearing plants more primitive than the angiosperms. Thus, salt eluates of Douglas fir (Pseudotsuga menziesii) cell suspension cultures yielded two monomeric extensins differing in size and composition. The larger extensin reported earlier lacked the Ser-Hyp₄ motif, was rich in proline and hydroxyproline, and contained peptide motifs similar to the dicot repetitive proline-rich proteins. The smaller extensin monomer reported here (Superose-6 peak 2 [SP2]) was compositionally similar to typical dicot extensins such as tomato P1, mainly consisting of Hyp, Thr, Ser, Pro, Val, Tyr, Lys, His, abundant arabinose, and a small but significant galactose content. A chymotryptic peptide map (on Hamilton PRP-1) of anhydrous hydrogen fluoride-deglycosylated SP2 yielded eight peptides sequenced after further purification on a high-resolution fast-sizing column (polyhydroxyethyl aspartamide; Poly LC). Significantly, two of the eight peptides contained the Ser-Hyp₄ motif, consistent both with the SP2 amino acid composition as well as the presence of hydroxyproline tetraarabinoside as a small (4% of total Hyp) component of the hydroxyproline arabinoside profile; thus, hydroxyproline tetraarabinoside corroborates the presence of Ser-Hyp₄, in agreement with our earlier observation that Hyp contiguity and Hyp glycosylation are positively correlated. Interestingly, other peptide sequences indicate that SP2 contains motifs such as Ser-Hyp₃-Thr-Hyp-Tyr, Ser-Hyp₄-Lys, and (Ala-Hyp)_n repeats that are related to and typify dicot extensins P1, P3, and arabinogalactan proteins, respectively. Overall, these peptide sequences confirm our previous prediction that Ser-Hyp₄ is indeed an ancient motif and also strongly support our suggestion that the extensins comprise an extraordinarily diverse, but nevertheless phylogenetically related, family of cell wall hydroxyproline-rich glycoproteins.     

A Histidine-Rich Extensin from Zea mays Is an Arabinogalactan Protein

Earlier we isolated a threonine-rich extensin from maize (Zea mays). Here, we report that maize cell suspension cultures yield a new extensin rich in histidine (HHRGP) that also has characteristics of arabinogalactan proteins (AGPs). Thus, chymotryptic peptide maps of anhydrous hydrogen fluoride (HF)-deglycosylated HHRGP showed repetitive motifs related to both extensins and AGPs as follows. HHRGP contains Ala-Hyp₃ and Ala-Hyp₄ repeats that may be related to the classical dicot Ser-Hyp₄ extensin motif by the single T → G (Ser → Ala) base change. Furthermore, HHRGP also contains the repetitive motif Ala-Hyp-Hyp-Hyp-His-Phe-Pro-Ser-Hyp-Hyp related to the Ser-Hyp₄-Ser-Hyp-Ser-Hyp₄ motif of P3-type dicot extensin. However, HHRGP also has AGP characteristics, notably an elevated alanine content, near sequence identity with the known Lolium AGP peptide Ser-Hyp-Hyp-Ala-Pro-Ala-Pro, the putative presence of glucuronoarabinogalactan, and precipitation by Yariv antigen, but β-elimination of arabinogalactan indicates its O-linkage to serine rather than the characteristic O-hydroxyproline link of other AGPs. Although HHRGP might be a “chimera” of two different proteins, i.e. an extensin and an AGP, this is unlikely because one can account for the apparent chimera by the codon relationships of the five common hydroxyproline-rich glycoprotein amino acid residues, Ser, Pro, Thr, Ala (TCx, CCx, ACx, GCx) and histidine (CAT or CAC), which facilitate interconversion of major motifs by single point mutations. Thus, we propose that the extensin family of wall proteins consists of a highly diversified phylogenetic series ranging from basic minimally glycosylated repetitive pro-rich proteins to the highly glycosylated acidic AGPs. To relate this diversity of form and function at the molecular level, we identified putative functional domains hypothetically involved in properties such as reptation, recognition, adhesion, intermolecular cross-linkage, and self-assembly. Not previously noted, peptide palindromes feature prominently in HHRGP: Hyp-Hyp-Ala-Ala-Asn-Ala-Ala-Hyp-Hyp and Hyp-Hyp-Hyp-His-His-His-Hyp-Hyp-Hyp; in P3: Hyp₄-Ser-Hyp-Ser-Hyp₄, and in other extensins. Such palindromes would enhance glycoprotein stereoregularity, thereby possibly promoting quasicrystalline interactions between wall components.     

Immunohistochemical analysis of cell wall hydroxyproline-rich glycoproteins in the roots of resistant and susceptible wax gourd cultivars in response to Fusarium oxysporum f. sp. Benincasae infection and fusaric acid treatment

Hydroxyproline-rich glycoproteins (HRGPs) play a defensive role in host–pathogen interactions. However, specific roles of individual HRGPs in plant defense against pathogen are poorly understood. Changes in extracellular distribution and abundance of individual cell wall HRGPs were investigated on root sections of two wax gourd (Benincasa hispida Cogn.) cultivars (Fusarium wilt resistant and susceptible, respectively), which were analyzed by immunolabelling with 20 monoclonal antibodies recognizing different epitopes of extensins and arabinogalactan proteins (AGPs) after being inoculated with Fusarium oxysporum f. sp. Benincasae or treated with fusaric acid (FA). These analyses revealed the following: (1) The levels of JIM11 and JIM20 interacting extensins were higher in the resistant cultivar. Either treatment caused a dramatic decrease in signal in both cultivars, but some new signal appeared in the rhizodermis. (2) The AGPs or rhamnogalacturonan containing CCRCM7-epitope were enhanced in the resistant cultivar, but not in the susceptible one by either treatment. (3) Either treatment caused a slight increase in the levels of the AGPs recognized by LM2 and JIM16, but there were no differences between two cultivars. (4) The MAC204 signal nearly disappeared after FA treatment, but this was not the case with pathogen attack. (5) The LM14 signal slightly decreased after both treatments in both cultivars, but a less decrease was observed with the resistant cultivar. These results indicate that the CCRCM7 epitope likely contributed to the resistance of wax gourd to this pathogen, and JIM11 and JIM20 interacting extensins as well as LM2, LM14, MAC204 and JIM16 interacting AGPs were involved in the host–pathogen interaction.     

Hydroxyproline‐rich Glycoproteins and Plant Defence

The distinguished plant cell wall component referred to as hydroxyproline‐rich glycoproteins (HRGPs) exists in two forms: soluble in the symplast and insoluble in the apoplast. Insolubilization of HRGPs in cell walls through oxidative cross‐linking which is elicited by stress represents a characteristic feature exhibited by two classes of HRGPs, namely, extensins and proline/HRGPs. Cross‐linking of these HRGPs is an important process to strengthen the cell walls that contributes to plant defence reactions. In this review, the available information on these proteins is analysed with respect to their roles in host‐pathosystems and the various techniques applied for their characterization. Future prospects on strengthening of cell walls through gene regulation and transgenic approaches are also addressed.     

Purification and Partial Characterization of a Hydroxyproline-Rich Glycoprotein in a Graminaceous Monocot, Zea mays

Graminaceous monocots generally contain low levels of hydroxyproline-rich Glycoproteins (HRGPs). As HRGPs are often at the cell surface, we used the intact cell elution technique (100 millimolar AlCl₃) to isolate soluble surface proteins from Zea mays cell suspension cultures. Further fractionation of the trichloroacetic acid-soluble eluate on the cation exchangers phospho-cellulose and BioRex-70 gave several retarded, hence presumably basic fractions, which also contained hydroxyproline (Hyp). One of these fractions yielded a pure HRGP after a final purification step involving Superose-6 gel filtration. As this HRGP was unusually rich in threonine, (25 mole%) we designated it as a threonine-hydroxyproline-rich glycoprotein (THRGP); it contained about 27% carbohydrate occurring exclusively as arabinosylated Hyp, predominantly as the monosaccharide (15%), and trisaccharide (25%) with 48% Hyp nonglycosylated—a characteristically graminaceous monocot profile. Amino acid analysis confirmed the basic character, and gave a low alanine content. Reaction with Yariv artificial antigen was negative. These characteristics show that the THRGP is not an arabinogalactan protein. On the other hand, antibodies raised against tomato extensin P1 cross-reacted significantly with the THRGP; this cross-reactivity and the above analytical data provide the best evidence to date for the presence of extensin in a graminaceous monocot.     

Plant cell wall glycoproteins and their genes

At least two main groups of glycoproteins can be distinguished in plant cell walls: extensins which are insoluble cell wall proteins; and soluble arabinogalactan proteins (AGPs) which have a high carbohydrate content such that protein content constitutes in some cases only 5 % of the glycoprotein weight. These two groups of proteins together with other cell wall proteins more or less glycosylated, such as proline-rich proteins (PRPs), hybrid PRP (HyPRPs) and expansins, are reviewed and compared with similar proteins present in other cell compartments. Different patterns of N- or O-glycosylation are analysed. In some cases, these cell wall proteins or proteins related to them present patterns of glycosylation that act as epitopes recognizable by IgE in allergic responses.     

Comparative study on the cell wall structure of protein-producing Bacillus brevis

Abstract Among eight strains of protein-producing Bacillus brevis , three morphological groups have been identified according to the structure of the cell walls.

• (I)

  Cell wall consisting of a peptidoglycanlayer
• (II)

  Two-layered cell wall consisting of a peptidoglycan-layer and an S-layer
• (III)

  Three-layered cell wall consisting of a peptidoglycan-layer and two S-layers

Group I and group II cell walls have not been described yet for protein-producing bacteria. The S-layers observed in this study all had hexagonal symmetry and lattice constants of approximately 18 nm. The immunological relation between the S-layer proteins of the newly isolated B. brevis strains and those of B. brevis 47 has been examined using antisera against both S-layer-proteins of B. brevis 47. S-layers from protein-producing B. brevis strains, which were adjacent to the peptidoglycan-layer, were similar to each other, whether they were the outermost cell wall layer (group II) or not (group III). However, no similarity was found between these layers and the outermost S-layer of B. brevis 47 (group III).     

Molecular characterization of a zygote wall protein: an extensin-like molecule in Chlamydomonas reinhardtii.

The green alga Chlamydomonas reinhardtii elaborates two biochemically and morphologically distinct cell walls during its life cycle: one surrounds the vegetative and gametic cell and the other encompasses the zygote. Hydroxyproline-rich glycoproteins (HRGPs) constitute a major component of both walls. We describe the isolation and characterization of a zygote-specific gene encoding a wall HRGP. The derived amino acid sequence of this algal HRGP is similar to those of higher plant extensins, rich in proline and serine residues and possessing repeating amino acid motifs, notably X(Pro)3 and (Ser-Pro)n. Antiserum against this zygote wall protein detected common epitopes in several other zygote polypeptides, at least one of which is also encoded by a zygote-specific gene. We conclude that there is one set of HRGP wall genes expressed only in zygotes and another set that is specific to vegetative and gametic cells.     

Isodityrosine cross-linking mediates insolubilization of cell walls in Chlamydomonas.

Enzymatic removal of the cell wall induces vegetative Chlamydomonas reinhardtii cells to transcribe wall genes and synthesize new hydroxyproline-rich glycoproteins (HRGPs) related to the extensins found in higher plant cell walls. A cDNA expression library made from such induced cells was screened with antibodies to an oligopeptide containing the (SP)x repetitive domains found in Chlamydomonas wall proteins. One of the selected cDNAs encodes an (SP)x-rich polypeptide that also displays a repeated YGG motif. Ascorbate, a peroxidase inhibitor, and tyrosine derivatives were shown to inhibit insolubilization of both the vegetative and zygotic cell walls of Chlamydomonas, suggesting that oxidative cross-linking of tyrosines is occurring. Moreover, insolubilization of both walls was concomitant with a burst in H2O2 production and in extracellular peroxidase activity. Finally, both isodityrosine and dityrosine were found in hydrolysates of the insolubilized vegetative wall layer. We propose that the formation of tyrosine cross-links is essential to Chlamydomonas HRGP insolubilization.     

Bioinformatic Identification and Analysis of Extensins in the Plant Kingdom

Extensins (EXTs) are a family of plant cell wall hydroxyproline-rich glycoproteins (HRGPs) that are implicated to play important roles in plant growth, development, and defense. Structurally, EXTs are characterized by the repeated occurrence of serine (Ser) followed by three to five prolines (Pro) residues, which are hydroxylated as hydroxyproline (Hyp) and glycosylated. Some EXTs have Tyrosine (Tyr)-X-Tyr (where X can be any amino acid) motifs that are responsible for intramolecular or intermolecular cross-linkings. EXTs can be divided into several classes: classical EXTs, short EXTs, leucine-rich repeat extensins (LRXs), proline-rich extensin-like receptor kinases (PERKs), formin-homolog EXTs (FH EXTs), chimeric EXTs, and long chimeric EXTs. To guide future research on the EXTs and understand evolutionary history of EXTs in the plant kingdom, a bioinformatics study was conducted to identify and classify EXTs from 16 fully sequenced plant genomes, including Ostreococcus lucimarinus, Chlamydomonas reinhardtii, Volvox carteri, Klebsormidium flaccidum, Physcomitrella patens, Selaginella moellendorffii, Pinus taeda, Picea abies, Brachypodium distachyon, Zea mays, Oryza sativa, Glycine max, Medicago truncatula, Brassica rapa, Solanum lycopersicum, and Solanum tuberosum, to supplement data previously obtained from Arabidopsis thaliana and Populus trichocarpa. A total of 758 EXTs were newly identified, including 87 classical EXTs, 97 short EXTs, 61 LRXs, 75 PERKs, 54 FH EXTs, 38 long chimeric EXTs, and 346 other chimeric EXTs. Several notable findings were made: (1) classical EXTs were likely derived after the terrestrialization of plants; (2) LRXs, PERKs, and FHs were derived earlier than classical EXTs; (3) monocots have few classical EXTs; (4) Eudicots have the greatest number of classical EXTs and Tyr-X-Tyr cross-linking motifs are predominantly in classical EXTs; (5) green algae have no classical EXTs but have a number of long chimeric EXTs that are absent in embryophytes. Furthermore, phylogenetic analysis was conducted of LRXs, PERKs and FH EXTs, which shed light on the evolution of three EXT classes.     

UDP-Glucose level as a limiting factor for IAA-induced cell elongation in Avena coleoptile segments

The effects of galactose on IAA-induced elongation and endogenous level of UDP-glucose (UDPG) in oat ( Avena sativa L. cv. Victory) coleoptile segments were examined under various growth conditions to see if there was a correlation between the level of UDPG and auxin-induced growth. The following results were obtained:

• (1)

  Galactose (10 m M ) inhibited the auxin-induced cell elongation of oat coleoptile segments after a lag of ca 2 h. Determinations of cell wall polysaccharides and UDP-sugars indicated that galactose, when inhibiting the cell wall polysaccharide synthesis, decreased the level of UDPG but caused an increase in the levels of Gal-1-P and UDP-Gal.
• (2)

  When coleoptile segments treated with IAA and galactose were transferred to galactose-free IAA-solution, the segment elongation was restored and the amounts of cell wall polysaccharides increased. During this period, the amount of UDPG increased and the levels of Gal-1-P and UDP-Gal slightly decreased or leveled off. The UDP-pentoses changed similarly as UDPG did.
• (3)

  Addition of sucrose (30 m M ) enhanced IAA-induced cell elongation and removed growth inhibition by 1 m M galactose. Sucrose increased the amounts of the cell wall polysaccharides and the level of UDPG in the presence or absence of IAA and also counteracted the decrease in UDPG caused by galactose.

These results indicate that the level of UDPG is an important limiting factor for cell wall biosynthesis and, thus, for auxin-induced elongation.     

Associations between corticolous microarthropod communities and epiphytic cover on bark

The discontinuous bark cover formed by epiphytic lichens and algae provides a mosaic of microhabitats for the fauna. Multivariate analyses applied to 1800 samples collected in Belgian Lorraine (southern Belgium) during each of the four seasons has made it possible to distinguish five major classes of arthropod microcommunities. Two of them are confined to special habitats or places at certain seasons, viz.

• –

  a Pseudochermes fraxini (Homoptera) community found on Fraxinus during the summer, and "trophically" different from others;
• –

  a Vertagopus arborea (Collembola) community observed in foliose lichens in St. Mard mainly in winter.

The three other classes are directly related to the epiphytic cover, viz.

• –

  a Dometorina plantivaga (Oribatida) community found in crustose epiphytes;
• –

  an Eueremaeus oblongus/Trichoribates trimaculatus (Oribatida) community sheltered by foliose lichens;
• –

  an Entomobrya nivalis (Collembola)/Cerobasis guestfalicus (Psocoptera) community observed in fruticose lichens.

The ecological meaning of those microcommunities (mosaic and stratification patterns, seasonal variation, succession) is discussed. The results support the hypothesis that corticolous microcoenoses are associated with the epiphyte type and that their composition is greatly affected by the vegetation stratification pattern on bark.     

Endemism in Tasmanian cool temperate rainforest: alternative hypotheses

Endemism in Tasmanian cool temperate rainforest: alternative hypotheseS. Evidence is presented which suggests that hypotheses presented by Kirkpatrick & Brown relating to endemic species in Tasmania are either invalid or of limited importance for woody rainforest species.
In their place three hypotheses are presented to account for the presence of endemic species in Tasmanian cool temperate rainforest on the basis of the fossil record and the distribution of species which are closely related to the endemics. The first two hypotheses relate to the presence of the endemic species in the general Tasmanian region. They are:

• 1. 

  Some species evolved in southeastern Australia during the Tertiary in response to the changing climate. Some of the ancestral species still occur in temperate rainforest at lower latitudes in Australia.
• 2. 

  Some species have remained essentially unchanged in Tasmania during the Tertiary and Quaternary climatic changes.

The third hypothesis relates to the restriction of these cool temperate rainforest species to Tasmania:

• 1. 

  Post-glacial climatic changes (especially a decrease in rainfall) and the human influence (especially land clearing and fire) may have combined to eliminate some cool temperate rainforest species from mainland Australia.

     

Volvocine cell walls and their constituent glycoproteins: An evolutionary perspective

Summary Similarities in the composition of the extracellular matrix suggest that only some species of the unicellularChlamydomonas are closely related to the colonial and multicellular flagellated members of the family Volvocaceae. The cell walls from all of the algae in this volvocine group contain a crystalline layer. This lattice structure can be used as a phylogenetic marker to divideChlamydomonas species into distinct classes, only one of which includes the volvocacean algae. Similarly, not all species ofChlamydomonas are sensitive to each other's cell wall lytic enzymes, implying divergence of the enzyme's inner wall substrate. Interspecific reconstitution of the crystalline layer is possible betweenC. reinhardtii and the multicellularVolvox carteri, but not betweenC. reinhardtii andC. eugametos. The hydroxyproline-rich glycoproteins (HRGPs) which make up the crystalline layer in genera which have a similar crystal structure exhibit many homologies. Interestingly, the evolutionarily distant cell walls ofC. reinhardtii andC. eugametos also contain some HRGPs displaying a few morphological and amino acid sequence homologies. The morphological similarities between the flagellar agglutinins (HRGPs responsible for sexual recognition and adhesion during the mating reaction) and the cell wall HRGPs leads to the proposal of a superfamily from which novel HRGPs (designed for self-assembly/recognition) can constantly evolve. Just as variations in the wall HRGPs can lead to unique wall structures, new agglutinins facilitate sexual isolation of new species. Thus, the HRGPs could emerge as valuable phylogenetic markers.Abbreviations GLE gametic lytic enzyme - GP glycoprotein - HRGP hydroxyproline-rich glycoprotein - SDS PAGE sodium dodecyl sulfate polyacrylamide gel electrophoresis - VLE vegetative lytic enzyme - VSP vegetative serine/proline-rich - WP wall protein - ZSP zygotic serine/proline-rich     

Di-isodityrosine is the intermolecular cross-link of isodityrosine-rich extensin analogs cross-linked in vitro

Extensins are cell wall hydroxyproline-rich glycoproteins that form covalent networks putatively involving tyrosyl and lysyl residues in cross-links catalyzed by one or more extensin peroxidases. The precise cross-links remain to be chemically identified both as network components in muro and as enzymic products generated in vitro with native extensin monomers as substrates. However, some extensin monomers contain variations within their putative cross-linking motifs that complicate cross-link identification. Other simpler extensins are recalcitrant to isolation including the ubiquitous P3-type extensin whose major repetitive motif, Hyp)(4)-Ser-Hyp-Ser-(Hyp)(4)-Tyr-Tyr-Tyr-Lys, is of particular interest, not least because its Tyr-Tyr-Tyr intramolecular isodityrosine cross-link motifs are also putative candidates for further intermolecular cross-linking to form di-isodityrosine. Therefore, we designed a set of extensin analogs encoding tandem repeats of the P3 motif, including Tyr --> Phe and Lys --> Leu variations. Expression of these P3 analogs in Nicotiana tabacum cells yielded glycoproteins with virtually all Pro residues hydroxylated and subsequently arabinosylated and with likely galactosylated Ser residues. This was consistent with earlier analyses of P3 glycopeptides isolated from cell wall digests and the predictions of the Hyp contiguity hypothesis. The tyrosine-rich P3 analogs also contained isodityrosine, formed in vivo. Significantly, these isodityrosine-containing analogs were further cross-linked in vitro by an extensin peroxidase to form the tetra-tyrosine intermolecular cross-link amino acid di-isodityrosine. This is the first identification of an inter-molecular cross-link amino acid in an extensin module and corroborates earlier suggestions that di-isodityrosine represents one mechanism for cross-linking extensins in muro.     

Arabinogalactan proteins in root and pollen-tube cells: distribution and functional aspects

BACKGROUND: Arabinogalactan proteins (AGPs) are complex proteoglycans of the cell wall found in the entire plant kingdom and in almost all plant organs. AGPs encompass a large group of heavily glycosylated cell-wall proteins which share common features, including the presence of glycan chains especially enriched in arabinose and galactose and a protein backbone particularly rich in hydroxyproline residues. However, AGPs also exhibit strong heterogeneities among their members in various plant species. AGP ubiquity in plants suggests these proteoglycans are fundamental players for plant survival and development. SCOPE: In this review, we first present an overview of current knowledge and specific features of AGPs. A section devoted to major tools used to study AGPs is also presented. We then discuss the distribution of AGPs as well as various aspects of their functional properties in root tissues and pollen tubes. This review also suggests novel directions of research on the role of AGPs in the biology of roots and pollen tubes.     

Changes in Cell Wall Properties Coincide with Overexpression of Extensin Fusion Proteins in Suspension Cultured Tobacco Cells

Extensins are one subfamily of the cell wall hydroxyproline-rich glycoproteins, containing characteristic SerHyp₄ glycosylation motifs and intermolecular cross-linking motifs such as the TyrXaaTyr sequence. Extensins are believed to form a cross-linked network in the plant cell wall through the tyrosine-derivatives isodityrosine, pulcherosine, and di-isodityrosine. Overexpression of three synthetic genes encoding different elastin-arabinogalactan protein-extensin hybrids in tobacco suspension cultured cells yielded novel cross-linking glycoproteins that shared features of the extensins, arabinogalactan proteins and elastin. The cell wall properties of the three transgenic cell lines were all changed, but in different ways. One transgenic cell line showed decreased cellulose crystallinity and increased wall xyloglucan content; the second transgenic cell line contained dramatically increased hydration capacity and notably increased cell wall biomass, increased di-isodityrosine, and increased protein content; the third transgenic cell line displayed wall phenotypes similar to wild type cells, except changed xyloglucan epitope extractability. These data indicate that overexpression of modified extensins may be a route to engineer plants for bioenergy and biomaterial production.