Altered growth and cell walls in a fucose-deficient mutant of Arabidopsis.

A biochemical screening procedure was developed to identify mutants of Arabidopsis thaliana in which the polysaccharide composition of the cell wall was altered. Over 5000 ethyl methanesulfonate-mutagenized plants were analyzed by this method, leading to the identification of 38 mutant lines. One complementation group of mutants was completely deficient in l-fucose, a constituent of pectic and hemicellulosic polysaccharides. These mutant plants were dwarfed in growth habit, and their cell walls were considerably more fragile than normal.

Substitution of L-fucose by L-galactose in cell walls of Arabidopsis mur1.

An Arabidopsis thaliana mutant (mur1) has less than 2 percent of the normal amounts of L-fucose in the primary cell walls of aerial portions of the plant. The survival of mur1 plants challenged the hypothesis that fucose is a required component of biologically active oligosaccharides derived from cell wall xyloglucan. However, the replacement of L-fucose (that is, 6-deoxy-L-galactose) by L-galactose does not detectably alter the biological activity of the oligosaccharides derived from xyloglucan. Thus, essential structural and conformational features of xyloglucan and xyloglucan-derived oligosaccharides are retained when L-galactose replaces L-fucose.

The Archaebacterium Thermococcus celer Represents, a Novel Genus within the Thermophilic Branch of the Archaebacteria.

Thermococcus celer, isolated from a solfataric marine water hole on a beach of Vulcano, Italy, is a spheric organism of about 1 µm diameter, during multiplication often constricted to diploforms. The organism utilizes peptides and protein, which are oxidized to CO(2) by sulfur respiration. Alternatively, though less efficiently, it can exist by an unknown type of fermentation. The optimal growth temperature is 88 °C, the optimal pH 5.8, the optimal NaCl concentration 3.8 g/l. Under these conditions with yeast extract (2 g/l) as carbon source and in the presence of finely distributed sulfur (10 g/1), the generation time is about 50 min. The envelope consists of subunits in two dimensional hexagonal dense packing. The absence of murein, the presence of polyisopranyl alcohols in the membrane, the component pattern and the rifampicin resistance of the DNA dependent RNA polymerase and the insensitivity of the organism towards the antibiotics streptomycin and vancomycin prove the archaebacterial nature of Thermococcus celer. The component pattern of the DNA dependent RNA polymerase conforms with the type pattern of RNA polymerases from thermoacidophilic archaebacteria. The absence of an immunochemical cross-reaction of the enzyme from Thermococcus with those from Thermoproteus, Desulfurococcus, Sulfolobus and Thermoplasma and the extent of cross-hybridization of the 16S rRNA with DNAs of other thermoacidophiles place it into the thermoacidophilic branch of the archaebacteria as a novel isolated genus.

Identification and characterization of a defective SSV1 genome integrated into a tRNA gene in the archaebacterium Sulfolobus sp. B12.

Within the chromosome of the archaebacterium Sulfolobus sp. B12, a 7.4 kb region was identified which displayed extensive sequence similarities to the 15.5 kb genetic element SSV1 carried by the same strain both as a circular form and as a site-specifically integrated copy. DNA sequence analysis indicated that this 7.4 kb region (designated SSV1intB) represented an SSV1-like element distinguishable from the full-length integrated copy (designated SSV1intA) by extensive deletions and point mutations. The physical organization of DNA sequences of SSV1intB indicated that this element was integrated at the same attP site as previously identified for SSV1intA. A comparison of the DNA sequences at the left attachment sites of SSV1intA and SSV1intB revealed that they both represented very similar putative arginine tRNA genes followed by a 10 bp inverted repeat sequence. S1 nuclease mapping experiments indicated that these tRNA genes are transcribed.

Molecular genetics of nucleotide sugar interconversion pathways in plants.

Nucleotide sugar interconversion pathways represent a series of enzymatic reactions by which plants synthesize activated monosaccharides for the incorporation into cell wall material. Although biochemical aspects of these metabolic pathways are reasonably well understood, the identification and characterization of genes encoding nucleotide sugar interconversion enzymes is still in its infancy. Arabidopsis mutants defective in the activation and interconversion of specific monosaccharides have recently become available, and several genes in these pathways have been cloned and characterized. The sequence determination of the entire Arabidopsis genome offers a unique opportunity to identify candidate genes encoding nucleotide sugar interconversion enzymes via sequence comparisons to bacterial homologues. An evaluation of the Arabidopsis databases suggests that the majority of these enzymes are encoded by small gene families, and that most of these coding regions are transcribed. Although most of the putative proteins are predicted to be soluble, others contain N-terminal extensions encompassing a transmembrane domain. This suggests that some nucleotide sugar interconversion enzymes are targeted to an endomembrane system, such as the Golgi apparatus, where they may co-localize with glycosyltransferases in cell wall synthesis. The functions of the predicted coding regions can most likely be established via reverse genetic approaches and the expression of proteins in heterologous systems. The genetic characterization of nucleotide sugar interconversion enzymes has the potential to understand the regulation of these complex metabolic pathways and to permit the modification of cell wall material by changing the availability of monosaccharide precursors.

The mur4 mutant of arabidopsis is partially defective in the de novo synthesis of uridine diphospho L-arabinose.

To obtain information on the synthesis and function of arabinosylated glycans, the mur4 mutant of Arabidopsis was characterized. This mutation leads to a 50% reduction in the monosaccharide L-arabinose in most organs and affects arabinose-containing pectic cell wall polysaccharides and arabinogalactan proteins. Feeding L-arabinose to mur4 plants restores the cell wall composition to wild-type levels, suggesting a partial defect in the de novo synthesis of UDP-L-arabinose, the activated sugar used by arabinosyltransferases. The defect was traced to the conversion of UDP-D-xylose to UDP-L-arabinose in the microsome fraction of leaf material, indicating that mur4 plants are defective in a membrane-bound UDP-D-xylose 4-epimerase.

A bifunctional epimerase-reductase acts downstream of the MUR1 gene product and completes the de novo synthesis of GDP-L-fucose in Arabidopsis.

L-Fucose is a monosaccharide found as a component of glycoproteins and cell wall polysaccharides in higher plants. The MUR1 gene of Arabidopsis thaliana encodes a GDP-D-mannose 4,6-dehydratase catalyzing the first step in the de novo synthesis of GDP-L-fucose from GDP-D-mannose (Bonin et al. 1997, Proc. Natl Acad. Sci. USA, 94, 2085-2090). Plant genes encoding the subsequent steps in L-fucose synthesis (3,5-epimerization and 4-reduction) have not been described previously. Based on sequence similarities to a bacterial gene involved in capsule synthesis we have cloned a gene from Arabidopsis, now designated GER1, which encodes a bifunctional 3, 5-epimerase-4-reductase in L-fucose synthesis. The combined action of the MUR1 and GER1 gene products converts GDP-D-mannose to GDP-L-fucose in vitro demonstrating that this entire nucleotide-sugar interconversion pathway could be reconstituted using plant genes expressed in Escherichia coli. In vitro assays indicated that the GER1 protein does not act as a GDP-D-mannose 3, 5-epimerase, an enzymatic activity involved in the de novo synthesis of GDP-L-galactose and L-ascorbic acid. Similarly, L-ascorbate levels in GER1 antisense plants were unchanged indicating that GDP-D-mannose 3,5-epimerase is encoded by a separate gene.

Elements of an archaeal promoter defined by mutational analysis.

The sequence requirements for specific and efficient transcription from the 16S/23S rRNA promoter of Sulfolobus shibatae were analysed by point mutations and by cassette mutations using an in vitro transcription system. The examination of the box A-containing distal promoter element (DPE) showed the great importance of the TA sequence in the center of box A for transcription efficiency and the influence of the sequence upstream of box A on determining the distance between the DPE and the start site. In most positions of box A, replacement of the wild type bases by adenines or thymines are less detrimental than replacements by cytosines or guanines. The effectiveness of the proximal promoter element (PPE) was not merely determined by its high A + T content but appeared to be directly related to its nucleotide sequence. At the start site a pyrimidine/purine (py/pu) sequence was necessary for unambiguous initiation as shown by analysis of mutants where the wild type start base was replaced. The sequence of box A optimal for promoter function in vitro is identical to the consensus of 84 mapped archaeal promoter sequences.

Transfer RNA genes frequently serve as integration sites for prokaryotic genetic elements.

The DNA sequences were determined at the boundaries of the integrated copy of the archaebacterial genetic element SSV1. A 44 bp sequence present as a single copy on the 15.5 kb circular SSV1 DNA flanked the integrated copy as a direct DNA sequence repeat, suggesting that SSV1 integration occurred by recombination between this 44 bp SSV1 sequence and an identical sequence on the bacterial chromosome. At the left attachment site, a region encompassing the 44 bp attachment core sequence and the 31 nucleotides upstream of it displayed all characteristics expected for an arginine tRNA gene. An analysis of published attachment site sequences of other systems revealed that tRNA genes also constitute the bacterial attachment site in the case of three temperate phages and two transmissible plasmids in eubacteria, indicating a widespread occurrence of tRNA genes as integration target sites. This finding may be important for the understanding of mechanisms and evolution of site-specific recombination.

Analysis of transcription in the archaebacterium Sulfolobus indicates that archaebacterial promoters are homologous to eukaryotic pol II promoters.

The 5'-termini were precisely mapped for five constitutive and one UV-inducible transcript from the Sulfolobus virus-like particle SSV1. The comparison of the DNA sequences around these transcriptional initiation sites revealed the presence of two conserved sequence elements: a trinucleotide sequence close to the initiation site itself and an AT-rich hexanucleotide sequence centered about 26 nucleotides upstream of it. Similar DNA sequences were found upstream of the transcriptional start sites for the ribosomal RNA genes in Sulfolobus and upstream of transcriptional start sites in other archaebacteria, allowing the derivation of a general consensus sequence for archaebacterial promoters. This consensus sequence is unlike that found in eubacteria but it resembles promoters recognized by eukaryotic RNA polymerase II.

Transcription termination in the archaebacterium Sulfolobus: signal structures and linkage to transcription initiation.

The precise map positions were determined for the 3'-termini of five transcripts of the Sulfolobus virus-like particle SSV1. In all cases analyzed, these 3'-termini mapped immediately downstream of a sequence TTTTTYT which was part of a pyrimidine-rich region of 16-19 nucleotides length. No correlation was evident between the position of the 3'-termini and possible secondary structures within the RNA. In two cases, the 3'-termini of SSV1 transcripts mapped in the immediate vicinity of transcriptional initiation sites suggesting that transcription termination can be linked to the re-initiation of RNA synthesis.

Gene expression in archaebacteria: physical mapping of constitutive and UV-inducible transcripts from the Sulfolobus virus-like particle SSV1.

The transcription of the genome of the UV-inducible Sulfolobus virus-like particle SSV1 was studied. Eight different transcripts could be distinguished by Northern analysis that were present in uninduced cells and the coordinately increased in amount after UV induction of SSV1. Using single-stranded DNA probes from different parts of the genome, the approximate map positions of these RNAs and the directions of transcription were determined. In two cases, terminator read-through resulted in the formation of more than one RNA species from a single 5' end and therefore the eight different RNAs corresponded to only five different transcriptional starts. Two RNAs sharing a common 5' end encode SSV1 structural proteins. The 5' end of these transcripts was determined by S1 nuclease analysis. About 20 nucleotides upstream of the transcriptional start of these RNAs, there is an AT-rich region resembling putative promoter sequences which have been found at a similar distance 5' to the genes encoding stable RNAs in Thermoproteus. In addition to the eight constitutive transcripts, a UV-inducible RNA of 0.3 kb was mapped on the SSV1 genome. In contrast to all other RNAs, it was not detectable in uninduced cells and it is expressed shortly before the amplification and packaging of the SSV1 genome commences.

Mutational analysis of an archaebacterial promoter: essential role of a TATA box for transcription efficiency and start-site selection in vitro.

By using a recently developed in vitro transcription assay, the 16S/23S rRNA-encoding DNA promoter from the archaebacterium Sulfolobus sp. B12 was dissected by deletion and linker substitution mutagenesis. The analysis of 5' and 3' deletion mutants defined a core promoter region between positions -38 and -2 containing all information for efficient and specific transcription. Further characterization of this region by linker substitution mutagenesis indicated two sequence elements important for promoter function--one located between positions -38 and -25 (distal promoter element) and the other one located between positions -11 and -2 (proximal promoter element). The distal promoter element encompassed the TATA-like "box A" element located approximately 26 nucleotides upstream of the majority of transcription start sites in archaebacteria (Archaeobacteria). All mutations within this box A motif virtually abolished promoter function. Complete inactivation of the proximal promoter element was dependent on extensive mutagenesis; this element is not conserved between archaebacterial promoters except for a high A + T content in stable RNA gene promoters from Sulfolobus. Mutants containing insertions or deletions between the distal and proximal promoter elements were only slightly affected in their transcription efficiency but displayed a shift in their major initiation site, retaining an essentially fixed distance between the distal promoter element and the transcription start site. Thus, efficient transcription and start-site selection were dependent on a conserved TATA-like sequence centered approximately 26 nucleotides upstream of the initiation site, a situation unlike that of eubacterial promoters but resembling the core structure of most eukaryotic RNA polymerase II (and some RNA polymerase III) promoters. This finding suggests a common evolutionary origin of these promoters consistent with the known similarities between archaebacterial and eukaryotic RNA polymerases.

In vitro transcription of two rRNA genes of the archaebacterium Sulfolobus sp. B12 indicates a factor requirement for specific initiation.

We describe a cell-free transcription system for the archaebacterium Sulfolobus sp. B12 that specifically initiates transcription at the 5S rRNA-encoding DNA and the 16S/23S rRNA-encoding DNA promoters of the same species. With this crude extract system, specific initiation was absolutely dependent on the box A motif, a highly conserved promoter element in archaebacteria located approximately 25 base pairs upstream of transcription initiation sites. In vitro transcription of the rRNA genes by purified RNA polymerase, however, resulted in semi-specific, box A-independent initiation, indicating that factor(s) in the crude extract were necessary for the highly specific box A-dependent transcription. Fractionation of the cell-free extract by sucrose-gradient centrifugation resulted in the identification of a low molecular weight fraction complementing purified RNA polymerase to an extract-like specificity.

One of two tandem Arabidopsis genes homologous to monosaccharide transporters is senescence-associated.

A gene designated SFP1, which is similar to major facilitator superfamily monosaccharide transporters, is induced during leaf senescence. Genomic sequence analysis identified a second highly similar and closely linked gene, SFP2, suggesting that SFP1 and SFP2 may have arisen through a recent duplication event. However, RNA gel-blot analyses and histochemical localization of a reporter gene activity in transgenic plants show that SFP1 and SFP2 are differentially regulated and that only SFP1 is induced during leaf senescence. The increase in SFP1 gene expression during leaf senescence is paralleled by an accumulation of monosaccharides. Possible roles for SFP1 in sugar transport during leaf senescence are discussed.

Mutants of Arabidopsis thaliana with altered cell wall polysaccharide composition.

To analyze the synthesis, structure and function of the plant cell wall by a genetic approach, 5200 chemically mutagenized Arabidopsis plants were screened for changes in the monosaccharide composition of hydrolyzed cell wall material by gas chromatography of alditol acetates This screening procedure identified 23 mutant lines representing 11 different loci designated mur1 to mur11. The mur lines fall into essentially three groups: (1) complete absence of a monosaccharide, (2) significant reduction in the amount of a single monosaccharide, and (3) complex alterations in the relative amounts of several monosaccharides. All mutants in the first category represent alleles of the mur1 locus, and are deficient in the de novo synthesis of fucose. Mutants with reductions in a single monosaccharide have been identified for fucose (mur2, mur3), arabinose (mur4, mur5, mur6, mur7), and rhamnose (mur8). Mutants with complex changes in monosaccharide composition are represented by the mur9, mur10 and mur11 loci. Most of the mutant lines did not show obvious morphological or physiological alterations; however, lines mur1, mur9 and mur10 co-segregated with reduced vigor or dwarfism of the plants. These results demonstrate the feasibility of identifying plants with altered cell wall compositions via a biochemical screening procedure. The availability of these mutants provides novel opportunities to study the functions of cell wall polysaccharides, gain insight into the biosynthesis of cell wall material, and clone cell wall-related genes.

SAV 1, a temperate u.v.-inducible DNA virus-like particle from the archaebacterium Sulfolobus acidocaldarius isolate B12.

Sulfolobus acidocaldarius, strain B12, which harbours a double-stranded DNA species both as a plasmid and in a linear form, which is integrated at a specific site of the chromosome, produces virus-like particles upon u.v. irradiation. These particles contain the same circular DNA and a number of coat proteins and are probably surrounded by a lipid membrane. They are lemon shaped, 100 x 60 nm in size and carry tail structures at one pole. The host cell recovers and remains lysogenic after virus production. Though a large fraction of liberated particles is found attached to structures derived from the cells, neither adsorption nor infection of a number of Sulfolobus isolates has so far been observed.

Comparative evaluation of gene expression in archaebacteria.

Gene organization, gene structure, especially regarding transcription and translation signals, and the structure of essential components of the gene expression machinery of archaebacteria are compared with those of eubacteria and eukaryotes. Many features of the genetic machinery of archaebacteria are shared either with eubacteria or with eukaryotes. For example, the translation signals including ribosome-binding sites are the same as in eubacteria, but the consensus sequence of archaebacterial promoters closely resembles that of the eukaryotic polymerase II promoters. Archaebacterial genes can be organized in transcription units resembling those of eubacteria. But the sequences of several protein components of the genetic machinery have strikingly more homology with those of their eukaryotic than with those of their eubacterial correspondents. The sequences of the large components of DNA-dependent RNA polymerases of archaebacteria closely resemble those of the eukaryotic RNA polymerases II and, somewhat less, III. In a dendrogram calculated from percentage homology data, the eukaryotic RNA polymerase I component A shares a branching point with the eubacterial component. The implications of these findings for the origin and the evolution of the eukaryotic ancestry are discussed.

Fumaric acid: an overlooked form of fixed carbon in Arabidopsis and other plant species.

Photoassimilates are used by plants for production of energy, as carbon skeletons and in transport of fixed carbon between different plant organs. Many studies have been devoted to characterizing the factors that regulate photoassimilate concentrations in different plant species. Most studies examining photoassimilate concentrations in C3 plants have focused on analyzing starch and soluble sugars. However, work presented here demonstrates that a number of C3 plants, including the popular model organism Arabidopsis thaliana (L.) Heynh., and agriculturally important plants, such as soybean, Glycine max (L.) Merr., contain significant quantities of fumaric acid. In fact, fumaric acid can accumulate to levels of several milligrams per gram fresh weight in Arabidopsis leaves, often exceeding those of starch and soluble sugars. Fumaric acid is a component of the tricarboxylic acid cycle and, like starch and soluble sugars, can be metabolized to yield energy and carbon skeletons for production of other compounds. Fumaric acid concentrations increase with plant age and light intensity in Arabidopsis leaves. Moreover, Arabidopsis phloem exudates contain significant quantities of fumaric acid, raising the possibility that fumaric acid may function in carbon transport.

The MUR1 gene of Arabidopsis thaliana encodes an isoform of GDP-D-mannose-4,6-dehydratase, catalyzing the first step in the de novo synthesis of GDP-L-fucose.

GDP-L-fucose is the activated nucleotide sugar form of L-fucose, which is a constituent of many structural polysaccharides and glycoproteins in various organisms. The de novo synthesis of GDP-L-fucose from GDP-D-mannose encompasses three catalytic steps, a 4,6-dehydration, a 3,5-epimerization, and a 4-reduction. The mur1 mutant of Arabidopsis is deficient in L-fucose in the shoot and is rescued by growth in the presence of exogenously supplied L-fucose. Biochemical assays of the de novo pathway for the synthesis of GDP-L-fucose indicated that mur1 was blocked in the first nucleotide sugar interconversion step, a GDP-D-mannose-4,6-dehydratase. An expressed sequence tag was identified that showed significant sequence similarity to proposed bacterial GDP-D-mannose-4,6-dehydratases and was tightly linked to the mur1 locus. A full-length clone was isolated from a cDNA library, and its coding region was expressed in Escherichia coli. The recombinant protein exhibited GDP-D-mannose-4,6-dehydratase activity in vitro and was able to complement mur1 extracts in vitro to complete the pathway for the synthesis of GDP-L-fucose. All seven mur1 alleles investigated showed single point mutations in the coding region for the 4,6-dehydratase, confirming that it represents the MUR1 gene.