The complex structures of arabinogalactan-proteins and the journey towards understanding function

Arabinogalactan-proteins (AGPs) are a family of complex proteoglycans found in all higher plants. Although the precise function(s) of any single AGP is unknown, they are implicated in diverse developmental roles such as differentiation, cell-cell recognition, embryogenesis and programmed cell death. DNA sequencing projects have made possible the identification of the genes encoding a large number of putative AGP protein backbones. In contrast, our understanding of how AGPs undergo extensive post-translational modification is poor and it is important to understand these processes since they are likely to be critical for AGP function. Genes believed to be responsible for post-translational modification of an AGP protein backbone, include prolyl hydroxylases, glycosyl transferases, proteases and glycosylphosphatidylinositol-anchor synthesising enzymes. Here we examine models for proteoglycan function in animals and yeast to highlight possible strategies for determining the function(s) of individual AGPs in plants.     

Molecular cloning of cDNAs encoding the protein backbones of arabinogalactan-proteins from the filtrate of suspension-cultured cells of Pyrus communis and Nicotiana alata

This paper reports the isolation of cDNAs encoding the protein backbone of two arabinogalactan-proteins (AGPs), one from pear cell suspension cultures (AGP Pc 2) and the other from suspension cultures of Nicotiana alata (AGP Na 2). The proteins encoded by these cDNAs are quite different from the 'classical' AGP backbones described previously for AGPs isolated from pear suspension cultures and extracts of N. alata styles. The cDNA for AGP Pc 2 encodes a 294 amino acid protein, of which a relatively short stretch (35 amino acids) is Hyp/Pro rich; this stretch is flanked by sequences which are dominated by Asn residues. Asn residues are not a feature of the 'classical' AGP backbones in which Hyp/Pro, Ser, Ala and Thr account for most of the amino acids. The cDNA for AGP Na 2 encodes a 437 amino acid protein, which contains two distinct domains: one rich in Hyp/Pro, Ser, Ala, Thr and the other rich in Asn, Tyr and Ser. The composition and sequence of the Pro-rich domain resembles that of the 'classical' AGP backbone. The Asn-rich domains of the two cDNAs described have no sequence similarity; in both cases they are predicted to be processed to give a mature backbone with a composition similar to that of the 'classical' AGPs. The study shows that different AGPs can differ in the amino acid sequence in the protein backbone, as well as the composition and sequence of the arabinogalactan side-chains. It also shows that differential expression of genes encoding AGP protein backbones, as well as differential glycosylation, can contribute to the tissue specificity of AGPs.     

Using genomic resources to guide research directions. The arabinogalactan protein gene family as a test case

Arabinogalactan proteins (AGPs) are extracellular hydroxyproline-rich proteoglycans implicated in plant growth and development. The protein backbones of AGPs are rich in proline/hydroxyproline, serine, alanine, and threonine. Most family members have less than 40% similarity; therefore, finding family members using Basic Local Alignment Search Tool searches is difficult. As part of our systematic analysis of AGP function in Arabidopsis, we wanted to make sure that we had identified most of the members of the gene family. We used the biased amino acid composition of AGPs to identify AGPs and arabinogalactan (AG) peptides in the Arabidopsis genome. Different criteria were used to identify the fasciclin-like AGPs. In total, we have identified 13 classical AGPs, 10 AG-peptides, three basic AGPs that include a short lysine-rich region, and 21 fasciclin-like AGPs. To streamline the analysis of genomic resources to assist in the planning of targeted experimental approaches, we have adopted a flow chart to maximize the information that can be obtained about each gene. One of the key steps is the reformatting of the Arabidopsis Functional Genomics Consortium microarray data. This customized software program makes it possible to view the ratio data for all Arabidopsis Functional Genomics Consortium experiments and as many genes as desired in a single spreadsheet. The results for reciprocal experiments are grouped to simplify analysis and candidate AGPs involved in development or biotic and abiotic stress responses are readily identified. The microarray data support the suggestion that different AGPs have different functions.     

Arabinogalactan-proteins: a class of extracellular matrix proteoglycans involved in plant growth and development

Arabinogalactanproteins (AGPs) are proteoglycans of the extracellular matrix o f most plants. Since the late 1980s, AGPs have attracted widespread attention from plant biologists following reports of their involvement in plant development. In particular, the use of monoclonal antibodies to carbohydrate epitopes of AGPs has demonstrated stage- and tissue-specificity and has led to suggestions that they are involved in tissue morphogenesis. The recent cloning of the genes for several AGP protein backbones allows us to consider new strategies to address their function. Here, we summarize our knowledge of AGPs and consider parallels with animal proteoglycans as a possible framework for future work.     

Isolation and identification of glycosylphosphatidylinositol-anchored arabinogalactan proteins and novel beta-glucosyl Yariv-reactive proteins from seeds of rice (Oryza sativa)

Arabinogalactan proteins (AGPs) are highly glycosylated extracellular glycoproteins playing important roles in plant growth and development. We have previously reported the possibility that AGPs are involved in the induction of alpha-amylase by gibberellin (GA) in barley aleurone layers by using the beta-glucosyl Yariv reagent (beta-GlcY), which has been presumed to specifically bind AGPs. In this present study, we isolated beta-GlcY-reactive proteins from rice bran rich in aleurone cells. The N-terminal sequences of classical AGP and AG peptides were determined from hydrophilic fractions obtained by reversed phase HPLC. Interestingly, a novel non-specific lipid transfer protein-like protein (OsLTPL1) and a novel early nodulin-like protein (OsENODL1) were also identified in the more hydrophobic fractions from HPLC as beta-GlcY-reactive proteins. Expression analysis of the genes coding for these proteins was performed. While classical AGP, AG peptides and OsLTPL1 were expressed in various parts of rice, OsENODL1 showed temporally and spatially specific expression in the aleurone layers. This new beta-GlcY-reactive protein is a promising candidate for the extracellular signaling factors of GA action in cereal seeds. Furthermore, the possibility that proteins with the AG glycomodule might react with beta-GlcY may broaden the definition of AGPs.     

Arabinogalactan proteins are required for apical cell extension in the moss Physcomitrella patens

Cell biological, structural, and genetic approaches have demonstrated the presence of arabinogalactan proteins (AGPs) in the moss Physcomitrella patens and provided evidence for their function in cell expansion and specifically in the extension of apical tip-growing cells. Inhibitor studies indicated that apical cell expansion in P. patens is blocked by synthetic AGP binding beta-glucosyl Yariv reagent (betaGlcYR). The anti-(1-->5)-alpha-L-arabinan monoclonal antibody LM6 binds to some AGPs in P. patens, to all plasma membranes, and to the cell wall surface at the most apical region of growing protonemal filaments. Moreover, LM6 labeling of cell walls at the tips of apical cells of P. patens was abolished in the presence of betaGlcYR, suggesting that the localized movement of AGPs from the plasma membrane to the cell wall is a component of the mechanism of tip growth. Biochemical and bioinformatic analyses were used to identify seven P. patens ESTs encoding putative AGP core proteins from homology with Arabidopsis thaliana, Brassica napus, and Oryza sativa sequences and from peptide fragments isolated from betaGlcYR-precipitated AGPs. Gene knockout by homologous recombination of one of these genes, P. patens AGP1, encoding a classical AGP core protein, resulted in reduced cell lengths in protonemal filaments, indicating a role for AGP1 in apical cell expansion in P. patens.     

Post-translational modifications of arabinogalactan-peptides of Arabidopsis thaliana. Endoplasmic reticulum and glycosylphosphatidylinositol-anchor signal cleavage sites and hydroxylation of proline

We have developed a method for separating the deglycosylated protein/peptide backbones of the small arabinogalactan (AG)-peptides from the larger classical arabinogalactan-proteins (AGPs). AGPs are an important class of plant proteoglycans implicated in plant growth and development. Separation of AG-peptides enabled us to identify eight of 12 AG-peptides from Arabidopsis thaliana predicted from genomic sequences. Of the remaining four, two have low abundance based on expressed sequence tag databases and the other two are only present in pollen (At3g20865) or flowers (At3g57690) and therefore would not be detected in our analysis. Characterization of AG-peptides was performed using matrix-assisted laser desorption ionization-time of flight mass spectrometry and tandem mass spectrometry protein sequencing. These data provide (i) experimental evidence that AG-peptides are processed in vivo for the addition of a glycosylphosphatidylinositol (GPI) anchor, (ii) cleavage site information for both the endoplasmic reticulum secretion signal and the GPI-anchor signal for eight of the 12 AG-peptides, and (iii) experimental evidence that the Gly-Pro motif is hydroxylated in vivo. Furthermore, we show that AtAGP16 is GPI-anchored despite its unusually long hydrophobic C-terminal GPI-signal sequence. Prior to this work, the GPI-anchor cleavage site for only two plant proteins, NaAGP1 from Nicotiana alata and PcAGP1 from Pyrus communis, had been determined experimentally. Characterization of the post-translational modifications of AG-peptides contributes toward obtaining the complete primary structure of this class of biologically important plant proteoglycans and provides a greater understanding of post-translational modifications of plant proteins.     

Purification and cloning of an arabinogalactan-protein from xylem of loblolly pine

 An arabinogalactan-protein (AGP) was purified from differentiating xylem of loblolly pine (Pinus taeda L.) and the N-terminal sequence used to identify a cDNA clone. The protein, PtaAGP3, was not coded for by any previously identified AGP-like genes. Moreover, PtaAGP3 was abundantly and preferentially expressed in differentiating xylem. The encoded protein contains four domains, a signal peptide, a cleaved hydrophilic region, a region rich in serine, alanine, and proline/hydroxyproline, and a hydrophobic C-terminus. It is postulated to contain a GPI (glycosylphosphatidylinositol) anchor site. If the protein is cleaved at the putative GPI anchor site, as has been observed in other classical AGPs, all but the Ser-Ala-Pro/Hyp-rich domain may be missing from the mature protein. Xylem-specific AGPs are hypothesized to be involved in xylem development. Received: 29 July 1999 / Accepted: 19 August 1999     

Properties of family 79 beta-glucuronidases that hydrolyze beta-glucuronosyl and 4-O-methyl-beta-glucuronosyl residues of arabinogalactan-protein

The carbohydrate moieties of arabinogalactan-proteins (AGPs), which are mainly composed of Gal, L-Ara, GlcA, and 4-Me-GlcA residues, are essential for the physiological functions of these proteoglycans in higher plants. For this study, we have identified two genes encoding family 79 beta-glucuronidases, designated AnGlcAase and NcGlcAase, in Aspergillus niger and Neurospora crassa, respectively, based on the amino acid sequence of a native beta-glucuronidase purified from a commercial pectolytic enzyme preparation from A. niger. Although the deduced protein sequences of AnGlcAase and NcGlcAase were highly similar, the recombinant enzymes expressed in Pichia pastoris exhibited distinct substrate specificity toward 4-Me-GlcA residues of AGPs: recombinant AnGlcAase (rAnGlcAase) substantially liberated both GlcA and 4-Me-GlcA residues from radish AGPs, whereas recombinant NcGlcAase (rNcGlcAase) activity on the 4-Me-GlcA residues of AGPs was very low. Maximum activity of rAnGlcAase hydrolyzing PNP beta-GlcA occurred at pH 3.0-4.0, whereas the maximum rNcGlcAase activity was at pH 6.0. The apparent Km values of rAnGlcAase were 30.4 microM for PNP beta-GlcA and 422 microM for beta-GlcA-(1-->6)-Gal, and those of rNcGlcAase were 38.3 microM and 378 microM, respectively. Similar to the native enzyme, rAnGlcAase was able to catalyze the transglycosylation of GlcA residues from PNP beta-GlcA to various monosaccharide acceptors such as Glc, Gal, and Xyl. We propose that both AnGlcAase and NcGlcAase are instances of a novel type of beta-glucuronidase with the capacity to hydrolyze beta-GlcA and 4-Me-beta-GlcA residues of AGPs, although they differ significantly in their preferences.     

The lysine-rich arabinogalactan-protein subfamily in Arabidopsis: gene expression, glycoprotein purification and biochemical characterization

AtAGP17, AtAGP18 and AtAGP19 are homologous genes encoding three putative glycosylphosphatidylinositol (GPI)-anchored classical arabinogalactan-proteins (AGPs) in Arabidopsis. They are distinguished from other AGPs by a short, C-terminal lysine-rich region. Organ-specific expression of these genes was revealed by Northern blot analysis. AtAGP17 was strongly expressed in leaves and stems, and weakly expressed in flowers and roots; AtAGP18 was strongly expressed in flowers, and moderately expressed in roots, stems and young leaves; and AtAGP19 was strongly expressed in stems, moderately expressed in flowers and roots, and weakly expressed in young leaves. One of these genes, AtAGP17, was expressed and purified as a green fluorescent protein (GFP) fusion protein in transgenic tobacco cells using hydrophobic interaction chromatography, size exclusion chromatography and reverse phase high-performance liquid chromatography. The fusion (glyco)protein produced a characteristic AGP 'smear' with a molecular mass of 80-150 kDa when detected by Western blot analysis. Glycosyl composition and linkage analyses of purified GFP-AtAGP17 showed that carbohydrate accounted for approximately 86% of the molecule, with arabinose and galactose as major, and rhamnose and glucuronic acid as minor glycosyl residues and with 1,3,6-galactose, 1,4-glucuronic acid, 1,3-galactose and terminal arabinose as major linkages. GFP-AtAGP17 was also precipitated by beta-Yariv reagent, further confirming that AtAGP17 is a bona fide AGP. Confocal fluorescence microscopy of plasmolysed, transformed cells indicated that AtAGP17 is localized on the plasma membrane and in Hechtian strands. Hydroxyproline (Hyp) glycoside profiles of GFP-AtAGP17 in conjunction with the deduced protein sequence also served to corroborate the Hyp contiguity hypothesis, which predicts contiguous Hyp residues as attachment sites for arabinosides and clustered, non-contiguous Hyp residues as attachment sites for arabinogalactan polysaccharides.     

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.     

Isolation of the protein backbone of an arabinogalactan-protein from the styles of Nicotiana alata and characterization of a corresponding cDNA.

Arabinogalactan-proteins (AGPs) from the styles of Nicotiana alata were isolated by ion exchange and gel filtration chromatography. After deglycosylation by anhydrous hydrogen fluoride, the protein backbones were fractionated by reversed-phase HPLC. One of the protein backbones, containing mainly hydroxyproline, alanine, and serine residues (53% of total residues), was digested with proteases, and the peptides were isolated and sequenced. This sequence information allowed the cloning of a 712-bp cDNA, AGPNa1. AGPNa1 encodes a 132-amino acid protein with three domains: an N-terminal secretion signal sequence, which is cleaved from the mature protein; a central sequence, which contains most of the hydroxyproline/proline residues; and a C-terminal hydrophobic region. AGPNa1 is expressed in many tissues of N. alata and related species. The arrangement of domains and amino acid composition of the AGP encoded by AGPNa1 are similar to that of an AGP from pear cell suspension culture filtrate, although the only sequence identity is at the N termini of the mature proteins.     

DNA sequence and analysis of the bet genes encoding the osmoregulatory choline—glycine betaine pathway of Escherichia coli

The sequence was determined of 6493 nucleotides encompassing the bet genes of Escherichia coli which encode the osmoregulatory choline-glycine betaine pathway. Four open reading frames were identified: betA encoding choline dehydrogenase, a flavoprotein of 61.9kDa; betB encoding betaine aldehyde dehydrogenase (52.8kDa); betT encoding a proton-motive-force-driven, high-affinity transport system for choline (75.8kDa); and betl, capable of encoding a protein of 21.8kDa, implicated as a repressor involved in choline regulation of the bet genes. Identification of the genes was supported by subcloning, physical mapping of lambda placMu53 insertions, amino acid sequence similarity, or N-terminal amino acid sequencing. The bet genes are tightly spaced, with betT located upstream of, and transcribed divergently to, the tandemly linked betIBA genes.     

Prospecting for novel biocatalysts in a soil metagenome

The metagenomes of complex microbial communities are rich sources of novel biocatalysts. We exploited the metagenome of a mixed microbial population for isolation of more than 15 different genes encoding novel biocatalysts by using a combined cultivation and direct cloning strategy. A 16S rRNA sequence analysis revealed the presence of hitherto uncultured microbes closely related to the genera Pseudomonas, Agrobacterium, Xanthomonas, Microbulbifer, and Janthinobacterium. Total genomic DNA from this bacterial community was used to construct cosmid DNA libraries, which were functionally searched for novel enzymes of biotechnological value. Our searches in combination with cosmid sequencing resulted in identification of four clones encoding 12 putative agarase genes, most of which were organized in clusters consisting of two or three genes. Interestingly, nine of these agarase genes probably originated from gene duplications. Furthermore, we identified by DNA sequencing several other biocatalyst-encoding genes, including genes encoding a putative stereoselective amidase (amiA), two cellulases (gnuB and uvs080), an alpha-amylase (amyA), a 1,4-alpha-glucan branching enzyme (amyB), and two pectate lyases (pelA and uvs119). Also, a conserved cluster of two lipase genes was identified, which was linked to genes encoding a type I secretion system. The novel gene aguB was overexpressed in Escherichia coli, and the enzyme activities were determined. Finally, we describe more than 162 kb of DNA sequence that provides a strong platform for further characterization of this microbial consortium.