At UBP3 and At UBP4 are two closely related Arabidopsis thaliana ubiquitin-specific proteases present in the nucleus

The ubiquitin-specific proteases (UBPs) are a class of enzymes vital to the ubiquitin pathway. These enzymes cleave ubiquitin at its C-terminus from two types of substrates containing (i) ubiquitin in an α-amino linkage, as found in the primary ubiquitin translation products, polyubiquitin and ubiquitin-ribosomal fusion proteins, or (ii) ubiquitin in an ?-amino linkage, as found in multiubiquitin chains either unattached or conjugated to cellular proteins. We have isolated cDNAs for two Arabidopsis thaliana genes, AtUBP3 and AtUBP4, which encode UBPs that are 93% identical. These two cDNAs represent the only two members of this subgroup and encode the smallest UBPs described to date in any organism. Using in vivo assays in Escherichia coli that allow the coexpression of a UBP with a putative substrate, we have shown that AtUBP3 and AtUBP4 can specifically deubiquitinate the artificial substrate Ub-X-β-gal but cannot act upon the natural α-amino-linked ubiquitin fusions Arabidopsis Ub-CEP52 and Arabidopsis polyubiquitin. Affinity-purified antibody prepared against AtUBP3 expressed in E. coli recognizes both AtUBP3 and AtUBP4. AtUBP3 and/or AtUBP4 are present in all Arabidopsis organs examined and at multiple developmental stages. Subcellular localization studies show that AtUBP3 and/or AtUBP4 are present in nuclear extracts. Possible physiological roles for these UBPs are discussed.     

The ubiquitin-specific protease UBP14 is essential for early embryo development in Arabidopsis thaliana

The ubiquitin/26S proteasome pathway is a major route for selectively degrading cytoplasmic and nuclear proteins in eukaryotes. In this pathway, chains of ubiquitins become attached to short-lived proteins, signalling recognition and breakdown of the modified protein by the 26S proteasome. During or following target degradation, the attached multi-ubiquitin chains are released and subsequently disassembled by ubiquitin-specific proteases (UBPs) to regenerate free ubiquitin monomers for re-use. Here, we describe Arabidopsis thaliana UBP14 that may participate in this recycling process. Its amino acid sequence is most similar to yeast UBP14 and its orthologues, human IsoT1-3 and Dictyostelium UbpA, and it can functionally replace yeast UBP14 in a ubp14Delta mutant. Like its orthologues, AtUBP14 can disassemble multi-ubiquitin chains linked internally via epsilon-amino isopeptide bonds using Lys48 and can process some, but not all, translational fusions of ubiquitin linked via alpha-amino peptide bonds. However, unlike its yeast and Dictyostelium orthologues, AtUBP14 is essential in Arabidopsis. T-DNA insertion mutations in the single gene that encodes AtUBP14 cause an embryonic lethal phenotype, with the homozygous embryos arresting at the globular stage. The arrested seeds have substantially increased levels of multi-ubiquitin chains, indicative of a defect in ubiquitin recycling. Taken together, the data demonstrate an essential role for the ubiquitin/26S proteasome pathway in general and for AtUBP14 in particular during early plant development.     

Ubiquitin-specific proteases from Arabidopsis thaliana: cloning of AtUBP5 and analysis of substrate specificity of AtUBP3, AtUBP4, and AtUBP5 using Escherichia coli in vivo and in vitro assays

A cDNA for a new ubiquitin-specific protease (UBP), AtUBP5, was identified from Arabidopsis thaliana flower mRNA using an oligonucleotide made against the conserved UBP cysteine (Cys) box. The 924-amino-acid AtUBP5 contains the regions characteristic of all UBPs and has 35% identity and 53% similarity overall to a mammalian UBP (Unp), resulting from additional significant similarity outside these regions. AtUBP5 has 48% identity and 58% similarity overall to two uncharacterized Arabidopsis genomic sequences but is distinct outside the UBP conserved regions from two other previously published Arabidopsis UBPs, AtUBP3 and -4. Using in vivo Escherichia coli assays, which allow co-expression of GSTAtUBPs and substrates, we show that all three UBPs were active. AtUBP5 was active without 311 amino acids N-terminal to the active site cysteine, or without 233 nonconserved amino acids between the Cys and His boxes, or without both, indicating the core region was sufficient. In in vivo and in vitro assays, GSTAtUBP3, -4, and -5 exhibited preference for specific Ub-Ub linkages, suggesting accessibility and/or conformation is important and demonstrating that these enzymes cleave post-translationally. A chimeric UBP consisting of the AtUBP5 Cys box with AtUBP3 amino acids was active and exhibited AtUBP3 specificity, indicating that the modular nature of UBPs and specificity for cleavage sites is not determined by the Cys box.     

The ubiquitin-specific protease subfamily UBP3/UBP4 is essential for pollen development and transmission in Arabidopsis

Deubiquitinating enzymes are essential to the ubiquitin (Ub)/26S proteasome system where they release Ub monomers from the primary translation products of poly-Ub and Ub extension genes, recycle Ubs from polyubiquitinated proteins, and reverse the effects of ubiquitination by releasing bound Ubs from individual targets. The Ub-specific proteases (UBPs) are one large family of deubiquitinating enzymes that bear signature cysteine and histidine motifs. Here, we genetically characterize a UBP subfamily in Arabidopsis (Arabidopsis thaliana) encoded by paralogous UBP3 and UBP4 genes. Whereas homozygous ubp3 and ubp4 single mutants do not display obvious phenotypic abnormalities, double-homozygous mutant individuals could not be created due to a defect in pollen development and/or transmission. This pollen defect was rescued with a transgene encoding wild-type UBP3 or UBP4, but not with a transgene encoding an active-site mutant of UBP3, indicating that deubiquitination activity of UBP3/UBP4 is required. Nuclear DNA staining revealed that ubp3 ubp4 pollen often fail to undergo mitosis II, which generates the two sperm cells needed for double fertilization. Substantial changes in vacuolar morphology were also evident in mutant grains at the time of pollen dehiscence, suggesting defects in vacuole and endomembrane organization. Even though some ubp3 ubp4 pollen could germinate in vitro, they failed to fertilize wild-type ovules even in the absence of competing wild-type pollen. These studies provide additional evidence that the Ub/26S proteasome system is important for male gametogenesis in plants and suggest that deubiquitination of one or more targets by UBP3/UBP4 is critical for the development of functional pollen.     

拟南芥砷诱导基因At4g13180的表达模式研究

拟南芥(Arabidopsis thaliana)砷诱导基因At4g13180编码蛋白是短链脱氢酶(Short-Chain Dehydrogenase/Reductase Superfamily,SDR)家族的成员之一,其过表达可以增强植物对过氧化氢的耐受性。该实验通过半定量RT-PCR,构建ProAt4g13180:GUS、At4g13180-EGFP和At4g13180-OE表达载体,获得At4g13180基因过表达转基因株系,并研究了At4g13180基因的表达模式及其编码蛋白的亚细胞定位。结果显示,At4g13180基因在根尖、叶脉、萼片和花丝等组织都强烈表达,该基因编码蛋白主要定位于胞质和核中。该研究结果为深入探究拟南芥砷诱导基因At4g13180的功能奠定了一定的基础。     

UBIQUITIN-SPECIFIC PROTEASES function in plant development and stress responses

Key message

UBIQUITIN-SPECIFIC PROTEASES play important roles in plant development and stress responses.

Abstract

Protein ubiquitination and deubiquitination are reversible processes, which can modulate the stability, activity as well as subcellular localization of the substrate proteins. UBIQUITIN-SPECIFIC PROTEASE (UBP) protein family participates in protein deubiquitination. Members of UBP family are involved in a variety of physiological processes in plants, as evidenced by their functional characterization in model plant Arabidopsis and other plants. UBPs are conserved in plants and distinct UBPs function in different regulatory processes, although functional redundancies exist between some members. Here we briefly reviewed recent advances in understanding the biological functions of UBP protein family in Arabidopsis, particularly the molecular mechanisms by which UBPs regulate plant development and stress responses. We believe that elucidation of UBPs function and regulation in Arabidopsis will provide new insights about protein deubiquitination and might shed light on the understanding of the mechanistic roles of UBPs in general, which will definitely contribute to crop improvement in agriculture.

     

The Arabidopsis mitochondrial membrane‐bound ubiquitin protease UBP27 contributes to mitochondrial morphogenesis

Mitochondria are essential organelles with dynamic morphology and function. Post‐translational modifications (PTMs), which include protein ubiquitination, are critically involved in animal and yeast mitochondrial dynamics. How PTMs contribute to plant mitochondrial dynamics is just beginning to be elucidated, and mitochondrial enzymes involved in ubiquitination have not been reported from plants. In this study, we identified an Arabidopsis mitochondrial localized ubiquitin protease, UBP27, through a screen that combined bioinformatics and fluorescent fusion protein targeting analysis. We characterized UBP27 with respect to its membrane topology and enzymatic activities, and analysed the mitochondrial morphological changes in UBP27T‐DNA insertion mutants and overexpression lines. We have shown that UBP27 is embedded in the mitochondrial outer membrane with an N_in–C_out orientation and possesses ubiquitin protease activities in vitro. UBP27 demonstrates similar sub‐cellular localization, domain structure, membrane topology and enzymatic activities with two mitochondrial deubiquitinases, yeast ScUBP16 and human HsUSP30, which indicated that these proteins are functional orthologues in eukaryotes. Although loss‐of‐function mutants of UBP27 do not show obvious phenotypes in plant growth and mitochondrial morphology, UBP27 overexpression can change mitochondrial morphology from rod to spherical shape and reduce the mitochondrial association of dynamin‐related protein 3 (DRP3) proteins, large GTPases that serve as the main mitochondrial fission factors. Thus, our study has uncovered a plant ubiquitin protease that plays a role in mitochondrial morphogenesis possibly through modulation of the function of organelle division proteins.     

Ubiquitin-specific proteases of Saccharomyces cerevisiae. Cloning of UBP2 and UBP3, and functional analysis of the UBP gene family.

In eukaryotes, both natural and engineered ubiquitin (Ub) fusions to itself or other proteins are cleaved by processing proteases after the last (Gly76) residue of ubiquitin. YUH1 and UBP1, the genes for two ubiquitin-specific proteases of the yeast Saccharomyces cerevisiae, have been cloned previously and shown to encode nonhomologous proteins. Using an Escherichia coli-based genetic screen, we have isolated two other yeast genes for ubiquitin-specific proteases, named UBP2 and UBP3. Ubp2 (1,264 residues), Ubp3 (912 residues), and the previously cloned Ubp1 (809 residues) are largely dissimilar except for two short regions containing Cys and His which encompass their putative active sites. Neither of these proteases has sequence similarities to Yuh1. Both Ubp2 and the previously identified Ubp1 cleave in vitro at the C terminus of the ubiquitin moiety in natural and engineered fusions irrespective of their size, poly-Ub being the exception. However, both Ubp1 and Ubp2 are also capable of cleaving poly-Ub when coexpressed with it in E. coli, suggesting that such cleavage is largely cotranslational. Although inactive in E. coli extracts, Ubp3 was active with all of the tested ubiquitin fusions except poly-Ub when coexpressed with them in E. coli. Null yuh1 ubp1 ubp2 ubp3 quadruple mutants are viable and retain the ability to deubiquitinate ubiquitin fusions, indicating the presence of at least one more ubiquitin-specific processing protease in S. cerevisiae.     

The ubiquitin binding domain ZnF UBP recognizes the C-terminal diglycine motif of unanchored ubiquitin

Ubiquitin binding proteins regulate the stability, function, and/or localization of ubiquitinated proteins. Here we report the crystal structures of the zinc-finger ubiquitin binding domain (ZnF UBP) from the deubiquitinating enzyme isopeptidase T (IsoT, or USP5) alone and in complex with ubiquitin. Unlike other ubiquitin binding domains, this domain contains a deep binding pocket where the C-terminal diglycine motif of ubiquitin is inserted, thus explaining the specificity of IsoT for an unmodified C terminus on the proximal subunit of polyubiquitin. Mutations in the domain demonstrate that it is required for optimal catalytic activation of IsoT. This domain is present in several other protein families, and the ZnF UBP domain from an E3 ligase also requires the C terminus of ubiquitin for binding. These data suggest that binding the ubiquitin C terminus may be necessary for the function of other proteins.     

A Quantitative Proteomics Study of Early Heat‐Regulated Proteins by Two‐Dimensional Difference Gel Electrophoresis Identified OsUBP21 as a Negative Regulator of Heat Stress Responses in Rice

To understand the early heat shock (HS)‐regulated cellular responses that influence the tolerance of rice plant to high environmental temperatures, two‐dimensional difference gel electrophoresis (2D‐DIGE) is performed to explore the early HS‐regulated proteome. Multiple proteins that show abundance changes after 1 and 5 min of HS treatment are identified. Of the early HS‐regulated proteins identified, the abundance of a ubiquitin‐specific protease, OsUBP21, and its Arabidopsis homolog, AtUBP13, is found to be upregulated by 5 min of HS treatment. Further, knocking the expression of OsUBP21 or AtUBP13 down or out increases the tolerance of rice and Arabidopsis plants to HS stress, suggesting that the function of these ubiquitin‐specific proteases in regulating plant HS responses is conserved between monocots and dicots. 2D‐DIGE showed a group of proteins are differentially regulated in wild‐type and ubp21 mutant after 30 min of HS treatment. Among these proteins, 11 are found to interact directly with OsUBP21; thus, they may be targets of OsUBP21. Future analyses of the roles of these OsUBP21‐interacting proteins in plant HS responses will help reveal the protein ubiquitination/deubiquitination‐regulated cellular responses induced by HS in rice.     

PHH1 , a novel gene from Arabidopsis thaliana that encodes a protein similar to plant blue-light photoreceptors and microbial photolyases

 A cDNA from Arabidopsis thaliana similar to microbial photolyase genes, and designated AT-PHH1, was isolated using a photolyase-like cDNA from Sinapsis alba (SA-PHR1) as a probe. Multiple isolations yielded only PHH1 cDNAs, and a few blue-light-receptor CRY1 (HY4) cDNAs (also similar to microbial photolyase genes), suggesting the absence of any other highly similar Arabidopsis genes. The AT-PHH1 and SA-PHR1 cDNA sequences predict 89% identity at the protein level, except for an AT-PHH1 C-terminal extension (111 amino acids), also not seen in microbial photolyases. AT-PHH1 and CRY1 show less similarity (54% protein identity), including respective C-terminal extensions that are themselves mostly dissimilar. Analysis of fifteen AT-PHH1 genomic isolates reveals a single gene, with three introns in the coding sequence and one in the 5′-untranslated leader. Full-length AT-PHH1, and both AT-PHH1 and AT-PHH1ΔC-513 (truncated to be approximately the size of microbial photolyase genes) cDNAs, were overexpressed, respectively, in yeast and Escherichia coli mutants hypersensitive to ultraviolet light. The absence of significant effects on resistance suggests either that any putative AT-PHH1 DNA repair activity requires cofactors/chromophores not present in yeast or E. coli, or that AT-PHH1 encodes a blue-light/ultraviolet-A receptor rather than a DNA repair protein. Received: 27 March 1996/Accepted: 30 July 1996     

Identification of a second pyridoxine (pyridoxamine) 5′-phosphate oxidase in <Emphasis Type="Italic">Arabidopsis thaliana</Emphasis>

Pyridoxine (pyridoxamine) 5′-phosphate oxidase (PPOX) is involved in the biosynthetic pathway of vitamin B₆, converting pyridoxine 5′-phosphate (PNP) or pyridoxamine 5′-phosphate (PMP) into pyridoxal 5′-phosphate (PLP). PLP is a well-known cofactor of numerous enzymes including transamination and decarboxylation reactions. We have previously identified a PPOX (AtPPOX-1) protein encoded by At5g49970 in Arabidopsis thaliana. Here, we report a second PPOX in Arabidopsis, which was named as AtPPOX-2 encoded by At2g46580. The RT-PCR amplified cDNA of AtPPOX-2 was cloned into an Escherichia coli expression vector and a yeast shuttle vector. Both PPOX enzyme assay and complementation of the oxidative stress sensitivity phenotype of a yeast PDX3 deletion mutant demonstrated that At2g46580 encodes a PPOX protein (AtPPOX-2). The catalytic efficiency of AtPPOX-1 is approximately 300-fold higher than that of AtPPOX-2 for PNP. Based on bioinformatic analysis, AtPPOX-2 has a putative mitochondrial transit peptide at the N-terminus. The truncated AtPPOX-2 without 18 amino acids at the N-terminal end lost PPOX activity, suggesting that the N-terminal 18 amino acids are necessary for the enzyme activity of AtPPOX-2. Phylogenetic analysis of AtPPOX-2 homologs from all domains of life suggests that AtPPOX-2 homologs in plants are the product of lateral gene transfer from the cyanobacterial endosymbionts from which plastids are derived.     

Expression analysis of a high-affinity nitrate transporter isolated from Arabidopsis thaliana by differential display

We used the differential display technique on total RNAs from roots of Arabidopsis thaliana (L.) Heynh. plants which had or had not been induced for 2 h by nitrate. One isolated cDNA clone, designated Nrt2:1At, was found to code for a putative high-affinity nitrate transporter. Two genomic sequences homologous to Nrt2:1At were found to be localized on the same fragment of chromosome 1 in the Arabidopsis genome. Expression analyses of both low- and high-affinity nitrate transporter genes, respectively Nrt1:1At (previously named Chl1) and Nrt2:1At, were carried out on plants grown under different nitrogen regimes. In this paper, we show that both genes are induced by very low levels of nitrate (50 μM KNO₃). However, stronger induction was observed with Nrt2:1At than with Nrt1:1At. Moreover, these two genes, although both over-expressed in a nitrate-reductase-deficient mutant, were differently regulated when N-sufficient wild-type or mutant plants were transferred to an N-free medium. Indeed, the steady-state amounts of Nrt1:1At mRNA declined whereas the amount of Nrt2:1At mRNA increased, probably reflecting the de-repression of the high-affinity transport system during N-starvation. Received: 4 May 1998 / Accepted: 26 August 1998     

Production of <Emphasis Type="Italic">N</Emphasis><Superscript><Emphasis Type="Italic">α</Emphasis></Superscript>-acetylated thymosin α1 in <Emphasis Type="Italic">Escherichia coli</Emphasis>

Background  

Thymosin α1 (Tα1), a 28-amino acid N ^α -acetylated peptide, has a powerful general immunostimulating activity. Although biosynthesis is an attractive means of large-scale manufacture, to date, Tα1 can only be chemosynthesized because of two obstacles to its biosynthesis: the difficulties in expressing small peptides and obtaining N ^α -acetylation. In this study, we describe a novel production process for N ^α -acetylated Tα1 in Escherichia coli.     

拟南芥At1g10300基因调节叶形和开花时间

核仁G蛋白1(Nucleolar G protein 1,NOG1)是一种高度保守的核仁GTP酶,在真核生物中广泛存在,参与60 S核糖体亚基前体的组装。在线虫中敲减NOG1的表达造成生长缓慢、虫体变小和寿命延长的表型,而过量表达NOG1则使线虫的寿命缩短。拟南芥的At1g10300基因注释为NOG1-2,但是其生物学功能还有待研究。该研究对其功能进行了初步研究,首先检测了该基因在拟南芥各个器官的表达情况。结果表明:该基因在7 d龄幼苗、茎生叶和花中均有表达,其中在花中表达量最高。获得了At1g10300基因的T-DNA插入突变体,发现在长日照条件下,At1g10300突变体植株的莲座紧凑,莲座叶片长宽比降低,但叶面积和植株高度与野生型相比无显著差异,表明其叶形发生改变;突变体植株的抽薹时间晚于野生型。荧光定量RT-PCR结果表明,突变体植株中开花促进因子FT、CO和GI的表达水平下调,而开花抑制因子FLC的表达水平上调。以上结果揭示At1g10300基因的突变影响了FT、CO、GI及FLC基因的表达,使植株出现晚花表型。     

Expression and purification of ubiquitin-specific protease (UBP1) ofSaccharomyces cerevisiae in recombinantEscherichia coli

Truncated form of UBP1, an ubiquitin-specific protease ofSaccharomyces cerevisiae, was overexpressed inEscherichia coli. The hexahistidine residue (His₆) was fused to the N-terminus of truncated UBP1 and the corresponding recombinant protein was purified with high yield by immobilized metal affinity chromatography. The truncated form of UBP1 protein was functional to cleave ubiquitinated human growth hormone as substrate. Effects of pH and temperature were investigated in order to optimize deubiquitinating reactions for the truncated UBP1. Optimum temperature and pH for the cleavage reaction were 40°C and pH 8.0, respectively.     

The SOS screen in Arabidopsis: A search for functions involved in DNA metabolism

The SOS screen, as originally described by Perkins et al. (1999) [7], was setup with the aim of identifying Arabidopsis functions that might potentially be involved in the DNA metabolism. Such functions, when expressed in bacteria, are prone to disturb replication and thus trigger the SOS response. Consistently, expression of AtRAD51 and AtDMC1 induced the SOS response in bacteria, even affecting E. coli viability. 100 SOS-inducing cDNAs were isolated from a cDNA library constructed from an Arabidopsis cell suspension that was found to highly express meiotic genes. A large proportion of these SOS⁺ candidates are clearly related to the DNA metabolism, others could be involved in the RNA metabolism, while the remaining cDNAs encode either totally unknown proteins or proteins that were considered as irrelevant. Seven SOS⁺ candidate genes are induced following gamma irradiation. The in planta function of several of the SOS-inducing clones was investigated using T-DNA insertional mutants or RNA interference. Only one SOS⁺ candidate, among those examined, exhibited a defined phenotype: silenced plants for DUT1 were sensitive to 5-fluoro-uracil (5FU), as is the case of the leaky dut-1 mutant in E. coli that are affected in dUTPase activity. dUTPase is essential to prevent uracil incorporation in the course of DNA replication.     

Ubiquitins (polyubiquitin and ubiquitin extension protein) in marine sponges: cDNA sequence and phylogenetic analysis

The complete nucleotide sequences of two Suberites domuncula cDNAs and one Sycon raphanus cDNA, all encoding ubiquitin, have been determined. One cDNA from S. domuncula codes for polyubiquitin with four tandemly repeated monomeric units and the second cDNA encodes ubiquitin fused to a ribosomal protein of 78 amino acids (aa). S. domuncula possesses at least one additional polyubiquitin gene, from which the last two monomers were also sequenced. All analysed genes from S. domuncula encode identical ubiquitin proteins, with only one aa difference (Ala 19) to the human/higher animals ubiquitin (Pro 19). Ubiquitin in S. domuncula is identical with the ubiquitin found in another Demospongia, Geodia cydonium. The cDNA from S. raphanus encodes polyubiquitin with seven tandemly repeated units. All these gene monomers code for the same ubiquitin, which differs from the human/higher animals ubiquitin only at position 24 (Asp in Sycon, Glu in others). However, ubiquitin from S. raphanus (Calcarea) shows two aa differences (positions 19 and 24), when compared with the ubiquitin sequences from the two Demospongiae. In a phylogenetic tree constructed by multiple sequence alignment of all sponge ubiquitin gene monomers so far identified, all monomers from the same species cluster together, with the clear exception of the monomer from S. domuncula ribosomal protein fusion gene. This monomer branches off first from the tree and forms a separate line; this gives evidence for a very ancient split of ubiquitin-ribosomal-protein fusion genes from polyubiquitin encoding genes and their long separate coexistence in eukaryotes. The ubiquitin extension protein from S. domuncula is 78 aa long, displays all characteristics of 76–81 aa long ribosomal fusion proteins and shows 78% identity in the first 73 aa with the human S27a protein. However, its C-terminal sequence: 69-GLTYVYKKSD-78 is more similar to the plant consensus (69-GLTYVYQ/NK-76), than to the higher animal consensus (69-CLTYCFNK-76). This protein isolated from a sponge, belonging to the phylogenetically oldest multicellular animals, the Porifera, branches off first from the phylogenetic tree of metazoan ubiquitin extension proteins of the small ribosomal subunits.     

Structure of the O-antigen and characterization of the O-antigen gene cluster of Escherichia coli O108 containing 5,7-diacetamido-3,5,7,9-tetradeoxy-l-glycero-d-galacto-non-2-ulosonic (8-epilegionaminic) acid

On mild acid degradation of the lipopolysaccharide of Escherichia coli O108, the O-polysaccharide was isolated and studied by sugar analysis and one- and two-dimensional ¹H- and ¹³C-NMR spectroscopy. The polysaccharide was found to contain an unusual higher sugar, 5,7-diacetamido-3,5,7,9-tetradeoxy-l-glycero-d-galacto-non-2-ulosonic acid (di-N-acetyl-8-epilegionaminic acid, 8eLeg5Ac7Ac). The following structure of the tetrasaccharide repeating unit of the polysac-charide was established: →4)-α-8eLegp5Ac7Ac-(2→6)-α-D-Galp-(1→3)-α-L-FucpNAc-(1→3)-α-D-GlcpNAc-(1→. Functions of the E. coli O108 antigen biosynthetic genes, including seven putative genes for synthesis of 8eLeg5Ac7Ac, were assigned by sequencing the O-antigen gene cluster along with comparison with gene databases and known biosynthetic pathways for related nonulosonic acids.