Studies on the Role of UDP-Glucose Dehydrogenase in Polysaccharide Biosynthesis

Roman, Elisabet

January 2004

<p>Polysaccharides are found in all forms of life and serve diverse purposes. They are enzymatically synthesised from activated monosaccharide precursors, nucleotide sugars. One such nucleotide sugar is UDP-glucuronic acid, which is formed from UDP-glucose by the UDP-glucose dehydrogenase (UGDH) enzyme. UGDH has been proposed to have a regulatory role in the biosynthesis of polysaccharides. The aim of the studies presented in this thesis was to investigate the role of UGDH in the polysaccharide biosynthesis in three different systems: human cell culture, bacterial cultures<i> </i>and growing<i> </i>plants<i>. </i>The effects of UGDH-overexpression on polysaccharide biosyntheses and, when achievable, on UDP-sugar levels, were investigated.</p><p>A mammalian UGDH was cloned from a kidney cDNA library. Transient expression of the cloned enzyme in mammalian cells led to an increased UGDH-activity. Northern blotting analyses revealed a single transcript of 2.6 kb in adult mouse tissues whereas human tissues expressed a predominant transcript of 3.2 kb and a minor transcript of 2.6 kb.</p><p>Overexpression of the bovine UGDH in mammalian cells induced increased synthesis of the glycosaminoglycans; heparan sulphate, chondroitin sulphate and hyaluronan, without changing their relative proportions. The effects on glycosaminoglycan synthesis caused by an increased demand of UDP-glucuronic acid were studied by overexpression of hyaluronan synthase (Has3), which requires UDP-glucuronic acid as substrate. Overexpression of Has3 and coexpression of Has3 and UGDH resulted in highly augmented production of hyaluronan without noticeably affecting heparan sulfate and chondroitin sulfate synthesis.</p><p>Expression of the bacterial UGDH in <i>E. coli</i> resulted in increased formation of UDP-glucuronic acid, but, unexpectedly, also to synthesis of fewer K5 polysaccharide chains. </p><p>Overexpression of UGD1, one of four <i>A. thaliana</i> UGDH genes, in <i>A. thaliana,</i> resulted in dwarfism. Analysis of the cell wall polysaccharides showed alteration in saccharide composition. Paradoxically, the UDP-sugars derived from UDP-glucuronic acid decreased in amount.</p>

Biochemistry

UDP-glucose dehydrogenase

polysaccharide biosynthesis

glycosaminoglycan

A. thaliana

E. coli K5

Biokemi

Biochemistry

Biokemi

The expression and regulation of hyaluronan synthases and their role in glycosaminoglycan synthesis

Brinck, Jonas

January 2000

<p>The glycosaminoglycan hyaluronan is an essential component of the extracellular matrix in all higher organisms, affecting cellular processes such as migration, proliferation and differentiation. Hyaluronan is synthesized by a plasma membrane bound hyaluronan synthase (HAS) which exists in three genetic isoforms. This thesis focuses on the understanding of the hyaluronan biosynthesis by studies on the expression and regulation of the HAS proteins.</p><p>In order to characterize the structural and functional properties of the HAS isoforms we developed a method to solubilize HAS protein(s) while retaining enzymatic activity. The partially purified HAS protein is, most likely, not asscociated covalently with other components. Cells transfected with cDNAs for HAS1, HAS2 and HAS3 were studied and all three HAS isozymes were able to synthesize high molecular weight hyaluronan chains in intact cells. The regulation of the hyaluronan chain length involves cell specific elements as well as external stimulatory factors. HAS3 transfected cells with high hyaluronan production exhibit reduced migration capacity and reduced amounts of a cell surface hyaluronan receptor molecule (CD44) compared to wild-type cells.</p><p>The three HAS isoforms were studied and shown to be differentially expressed and regulated in response to external stimuli. Platelet derived growth factor (PDGF-BB) and transforming growth factor (TGF-<i>β</i>1) are important regulators of HAS at both the transcriptional and translational level. The HAS2 isoform is the isoform most susceptible to external regulation.</p><p>The role of the UDP-glucose dehydrogenase in mammalian glycosaminoglycan biosynthesis was assessed. The enzyme is essential for hyaluronan, heparan sulfate and chondroitin sulfate biosynthesis, but does not exert a rate-limiting effect.</p>

Biochemistry

hyaluronan

glycosaminoglycans

CD44

growth factors

UDP-glucose dehydrogenase

Biokemi

Biochemistry

Biokemi

The expression and regulation of hyaluronan synthases and their role in glycosaminoglycan synthesis

Brinck, Jonas

January 2000

The glycosaminoglycan hyaluronan is an essential component of the extracellular matrix in all higher organisms, affecting cellular processes such as migration, proliferation and differentiation. Hyaluronan is synthesized by a plasma membrane bound hyaluronan synthase (HAS) which exists in three genetic isoforms. This thesis focuses on the understanding of the hyaluronan biosynthesis by studies on the expression and regulation of the HAS proteins. In order to characterize the structural and functional properties of the HAS isoforms we developed a method to solubilize HAS protein(s) while retaining enzymatic activity. The partially purified HAS protein is, most likely, not asscociated covalently with other components. Cells transfected with cDNAs for HAS1, HAS2 and HAS3 were studied and all three HAS isozymes were able to synthesize high molecular weight hyaluronan chains in intact cells. The regulation of the hyaluronan chain length involves cell specific elements as well as external stimulatory factors. HAS3 transfected cells with high hyaluronan production exhibit reduced migration capacity and reduced amounts of a cell surface hyaluronan receptor molecule (CD44) compared to wild-type cells. The three HAS isoforms were studied and shown to be differentially expressed and regulated in response to external stimuli. Platelet derived growth factor (PDGF-BB) and transforming growth factor (TGF-β1) are important regulators of HAS at both the transcriptional and translational level. The HAS2 isoform is the isoform most susceptible to external regulation. The role of the UDP-glucose dehydrogenase in mammalian glycosaminoglycan biosynthesis was assessed. The enzyme is essential for hyaluronan, heparan sulfate and chondroitin sulfate biosynthesis, but does not exert a rate-limiting effect.

Biochemistry

hyaluronan

glycosaminoglycans

CD44

growth factors

UDP-glucose dehydrogenase

Biokemi

Biochemistry

Biokemi

Studies on the Role of UDP-Glucose Dehydrogenase in Polysaccharide Biosynthesis

Roman, Elisabet

January 2004

Polysaccharides are found in all forms of life and serve diverse purposes. They are enzymatically synthesised from activated monosaccharide precursors, nucleotide sugars. One such nucleotide sugar is UDP-glucuronic acid, which is formed from UDP-glucose by the UDP-glucose dehydrogenase (UGDH) enzyme. UGDH has been proposed to have a regulatory role in the biosynthesis of polysaccharides. The aim of the studies presented in this thesis was to investigate the role of UGDH in the polysaccharide biosynthesis in three different systems: human cell culture, bacterial cultures and growing plants. The effects of UGDH-overexpression on polysaccharide biosyntheses and, when achievable, on UDP-sugar levels, were investigated. A mammalian UGDH was cloned from a kidney cDNA library. Transient expression of the cloned enzyme in mammalian cells led to an increased UGDH-activity. Northern blotting analyses revealed a single transcript of 2.6 kb in adult mouse tissues whereas human tissues expressed a predominant transcript of 3.2 kb and a minor transcript of 2.6 kb. Overexpression of the bovine UGDH in mammalian cells induced increased synthesis of the glycosaminoglycans; heparan sulphate, chondroitin sulphate and hyaluronan, without changing their relative proportions. The effects on glycosaminoglycan synthesis caused by an increased demand of UDP-glucuronic acid were studied by overexpression of hyaluronan synthase (Has3), which requires UDP-glucuronic acid as substrate. Overexpression of Has3 and coexpression of Has3 and UGDH resulted in highly augmented production of hyaluronan without noticeably affecting heparan sulfate and chondroitin sulfate synthesis. Expression of the bacterial UGDH in E. coli resulted in increased formation of UDP-glucuronic acid, but, unexpectedly, also to synthesis of fewer K5 polysaccharide chains. Overexpression of UGD1, one of four A. thaliana UGDH genes, in A. thaliana, resulted in dwarfism. Analysis of the cell wall polysaccharides showed alteration in saccharide composition. Paradoxically, the UDP-sugars derived from UDP-glucuronic acid decreased in amount.

Biochemistry

UDP-glucose dehydrogenase

polysaccharide biosynthesis

glycosaminoglycan

A. thaliana

E. coli K5

Biokemi

Biochemistry

Biokemi

Isolation and evaluation of the sugarcane UDP-glucose dehydrogenase gene and promoter

Van der Merwe, Jennie

12 1900

Thesis (PhD (Genetics. Plant Biotechnology))--University of Stellenbosch, 2006. / The young internodes of sugarcane are ideal targets for altering metabolism, through genetic manipulation, to potentially control known fungal diseases such as Smut or to increase sucrose yields in these regions that are currently being discarded. At present, no regulatory sequences that specifically drive transgene expression in young developing sugarcane tissues are available. The objective of this study was therefore to isolate and evaluate such a sequence. The promoter targeted for isolation in this study regulates the expression of UDP-glucose dehydrogenase (EC 1.1.1.22), an enzyme which catalyses the oxidation of UDP-glucose to UDP-glucuronic acid, a precursor for structural polysaccharides which are incorporated into the developing cell wall. A strong correlation between the expression of UDP-glucose dehydrogenase and a demand for structural polysaccharides in developing tissues could therefore be expected. The first part of this study addressed the general practicality of promoter isolation from sugarcane, a complex polyploid. A gene encoding UDP-glucose dehydrogenase was isolated from a sugarcane genomic library. The gene contains an open reading frame (ORF) of 1443 bp, encoding 480 amino acids and one large intron (973 bp), located in the 5’-UTR. The derived amino acid sequence showed 88 – 98% identity with UDP-glucose dehydrogenase from other plant species, and contained highly conserved amino acid motifs required for cofactor binding and catalytic activity. Southern blot analysis indicates a low copy number for UDP-glucose dehydrogenase in sugarcane. The possible expression of multiple gene copies or alleles of this gene was investigated through comparison of sequences amplified from cDNA prepared from different tissues. Although five Single Nucleotide Polymorphisms (SNP) and one small-scale insertion/deletion (INDEL) were identified in the aligned sequences, hundred percent identity of the derived amino acid sequences suggested the expression of different alleles of the same gene rather than expression of multiple copies. The finding that multiple alleles are expressed to provide the required level of a specific enzyme, rather than the increased expression of one dominant allele, is encouraging for sugarcane gene and promoter isolation. In the second part of the study the suitability of UDP-glucose dehydrogenase as a target for the isolation of a developmentally regulated promoter was investigated. The contribution of UDP glucose dehydrogenase to pentan synthesis, as well as the expression pattern and subcellular localisation of the enzyme in mature sugarcane plants was studied at the tissue and cellular level. Radiolabelling with positionally labelled glucose was used to investigate the relative contributions of glycolysis, the oxidative pentose phosphate pathway and pentan synthesis to glucose catabolism. Significantly (P=0.05) more radiolabel was released as CO2 from [6-14C]- glucose than [1-14C]-glucose in younger internodes 3, 4 and 5, demonstrating a significant contribution of UDP-glucose dehydrogenase to glucose oxidation in the younger internodes. In addition, there was significantly (P=0.05) more radiolabel in the cell wall (fiber) component when the tissue was labelled with [1-14C]-glucose rather than [6-14C]-glucose. This also demonstrates a selective decarboxylation of glucose in position 6 prior to incorporation into the cell wall and is consistent with a major role for UDP-glucose dehydrogenase in cell wall synthesis in the younger internodes. Expression analysis showed high levels of expression of both the UDP-glucose dehydrogenase transcript and protein in the leafroll, roots and young internodes. In situ hybridisation showed that the UDP-glucose dehydrogenase transcript is present in virtually all cell types in the sugarcane internode, while immunolocalisation showed that the abundance of the protein declined in all cell types as maturity increased. Results obtained confirmed that this enzyme plays an important role in the provision of hemicellulose precursors in most developing tissues of the sugarcane plant, indicating that UDP-glucose dehydrogenase was indeed a suitable target for promoter isolation. Lastly, the promoter region and first intron, located in the 5’-untranslated region (UTR) of this gene, were isolated and subsequently fused to the GUS reporter gene for transient expression analysis and plant transformation. Transient expression analysis showed that the presence of the intron was essential for strong GUS expression. Analysis of stably transformed transgenic sugarcane plants, evaluated in a green house trial, showed that the isolated promoter is able to drive GUS expression in a tissue specific manner under these conditions.

Sugarcane

Promoters

UDP-Glucose dehydrogenase

Isolation

Dissertations -- Plant biotechnology

Theses -- Plant biotechnology

Sugarcane -- Genetic engineering

Glucuronosyltransferase.

Dehydrogenases

Plant genetic transformation

Gene regulation of UDP-glucose synthesis and metabolism in plants

Johansson, Henrik

January 2003

<p>Photosynthesis captures light from the sun and converts it into carbohydrates, which are utilised by almost all living organisms. The conversion between the different forms of carbohydrates is the basis to form almost all biological molecules.</p><p>The main intention of this thesis has been to study the role of UDP-glucose in carbohydrate synthesis and metabolism, and in particular the genes that encode UDP-glucose pyrophosphorylase (UGPase) and UDP-glucose dehydrogenase (UGDH) in plants and their regulation. UGPase converts glucose-1-phosphate to UDP-glucose, which can be utilised for sucrose synthesis, or cell wall polysaccharides among others. UGDH converts UDP-glucose to UDP-glucuronate, which is a precursor for hemicellulose and pectin. As model species I have been working with both Arabidopsis thaliana and poplar.</p><p>Sequences for two full-length EST clones of Ugp were obtained from both Arabidopsis and poplar, the cDNAs in Arabidopsis correlate with two genes in the Arabidopsis genomic database.</p><p>The derived protein sequences are 90-93% identical within each plants species and 80-83% identical between the two species.</p><p>Studies on Ugp showed that the expression is up-regulated by Pi-deficiency, sucrose-feeding and by light exposure in Arabidopsis. Studies with Arabidopsis plants with mutations in sugar/ starch- and Pi-content suggested that the Ugp expression is modulated by an interaction of signals derived from Pi-deficiency, sugar content and light/ dark conditions, where the signals act independently or inhibiting each other, depending on conditions. Okadaic acid, a known inhibitor of certain classes of protein phosphatases, prevented the up-regulation of Ugp by Pi-deficiency and sucrose-feeding. In poplar, sucrose also up-regulated the expression of Ugp. When poplar and Arabidopsis were exposed to cold, an increase of Ugp transcript content was detected as well as an increase in UGPase protein and activity. In poplar, Ugp was found to be expressed in all tissues that were examined (differentiating xylem, phloem, apical leaves and young and mature leaves).</p><p>By using antisense strategy, Arabidopsis plants that had a decrease in UGPase activity of up to 30% were obtained. In the antisense plants, the soluble carbohydrate content was reduced in the leaves by at least 50%; in addition the starch content decreased. Despite the changes in carbohydrate content, the growth rate of the antisense plants was not changed compared to wild type plants under normal growth conditions. However, in the antisense lines the UGPase activity and protein content in sliliques and roots increased, perhaps reflecting compensatory up-regulation of second Ugp gene. This correlates with a slightly larger molecular mass of UGPase protein in roots and siliques when compared to that in leaves. Maximal photosynthesis rates were similar for both wild type and antisense plants, but the latter had up to 40% lower dark respiration and slightly lower quantum yield than wild type plants.</p><p>Two Ugdh cDNAs from poplar and one from Arabidopsis were sequenced. The highest Ugdh expression was found in xylem and younger leaves. Expression data from sugar and osmoticum feeding experiment in poplar suggested that the Ugdh expression is regulated via an osmoticumdependent pathway.</p>

Molecular biology

antisense

Arabidopsis thaliana

carbohydrate

hybrid aspen

photosynthesis

poplar

sugar

UDP-glucose

UDP-glucose pyrophosphorylase

UDP-glucose dehydrogenase

Molekylärbiologi

Molecular biology

Molekylärbiologi

Gene regulation of UDP-glucose synthesis and metabolism in plants

Johansson, Henrik

January 2003

Photosynthesis captures light from the sun and converts it into carbohydrates, which are utilised by almost all living organisms. The conversion between the different forms of carbohydrates is the basis to form almost all biological molecules. The main intention of this thesis has been to study the role of UDP-glucose in carbohydrate synthesis and metabolism, and in particular the genes that encode UDP-glucose pyrophosphorylase (UGPase) and UDP-glucose dehydrogenase (UGDH) in plants and their regulation. UGPase converts glucose-1-phosphate to UDP-glucose, which can be utilised for sucrose synthesis, or cell wall polysaccharides among others. UGDH converts UDP-glucose to UDP-glucuronate, which is a precursor for hemicellulose and pectin. As model species I have been working with both Arabidopsis thaliana and poplar. Sequences for two full-length EST clones of Ugp were obtained from both Arabidopsis and poplar, the cDNAs in Arabidopsis correlate with two genes in the Arabidopsis genomic database. The derived protein sequences are 90-93% identical within each plants species and 80-83% identical between the two species. Studies on Ugp showed that the expression is up-regulated by Pi-deficiency, sucrose-feeding and by light exposure in Arabidopsis. Studies with Arabidopsis plants with mutations in sugar/ starch- and Pi-content suggested that the Ugp expression is modulated by an interaction of signals derived from Pi-deficiency, sugar content and light/ dark conditions, where the signals act independently or inhibiting each other, depending on conditions. Okadaic acid, a known inhibitor of certain classes of protein phosphatases, prevented the up-regulation of Ugp by Pi-deficiency and sucrose-feeding. In poplar, sucrose also up-regulated the expression of Ugp. When poplar and Arabidopsis were exposed to cold, an increase of Ugp transcript content was detected as well as an increase in UGPase protein and activity. In poplar, Ugp was found to be expressed in all tissues that were examined (differentiating xylem, phloem, apical leaves and young and mature leaves). By using antisense strategy, Arabidopsis plants that had a decrease in UGPase activity of up to 30% were obtained. In the antisense plants, the soluble carbohydrate content was reduced in the leaves by at least 50%; in addition the starch content decreased. Despite the changes in carbohydrate content, the growth rate of the antisense plants was not changed compared to wild type plants under normal growth conditions. However, in the antisense lines the UGPase activity and protein content in sliliques and roots increased, perhaps reflecting compensatory up-regulation of second Ugp gene. This correlates with a slightly larger molecular mass of UGPase protein in roots and siliques when compared to that in leaves. Maximal photosynthesis rates were similar for both wild type and antisense plants, but the latter had up to 40% lower dark respiration and slightly lower quantum yield than wild type plants. Two Ugdh cDNAs from poplar and one from Arabidopsis were sequenced. The highest Ugdh expression was found in xylem and younger leaves. Expression data from sugar and osmoticum feeding experiment in poplar suggested that the Ugdh expression is regulated via an osmoticumdependent pathway.

Molecular biology

antisense

Arabidopsis thaliana

carbohydrate

hybrid aspen

photosynthesis

poplar

sugar

UDP-glucose

UDP-glucose pyrophosphorylase

UDP-glucose dehydrogenase

Molekylärbiologi

Molecular biology

Molekylärbiologi