Chlamydia Trachomatis hijacks energy stores from the host and accumulates glycogen in the inclusion lumen through a dual pathway / Chlamydia Trachomatis détourne l'énergie stockée de l'hôte et accumule le glycogène dans le lumen de l'inclusion par un chemin double

Gehre, Lena

17 June 2015

Chlamydia trachomatis est une bactérie intracellulaire obligatoire pathogène pour l'homme, qui se développe dans un compartiment appelé inclusion. La membrane de l'inclusion constitue une protection contre les défenses de l'hôte, mais limite l'accès aux nutriments. Un élément essentiel pour C. trachomatis est le glucose. Son polymère, le glycogène, est abondant dans le lumen de l'inclusion. Ce travail a eu pour objectif de reconstituer le flux de glucose dans des cellules infectées et d'expliquer l'accumulation du glycogène. En résumé, notre travail démontre que l'accumulation de glycogène dans la lumière de l'inclusion est le résultat de deux processus, l'import de glycogène " brut " de l'hôte par invagination de la membrane de l'inclusion, et la synthèse de novo de glycogène dans le lumen de l'inclusion. Ce dernier implique l'import d'UDP-glucose par un transporteur de la cellule hôte qui est recruté dans la membrane de l'inclusion, et la sécrétion d'enzymes bactériennes dans le lumen de l'inclusion. Ces mécanismes permettent aux bactéries de stocker des molécules énergétique, inaccessibles à l'hôte. / The human pathogen Chlamydia trachomatis is an obligate intracellular bacterium, which develops in a parasitophorous compartment called inclusion. The inclusion membrane serves as a barrier to host defense mechanisms, but limits access to nutrients. One essential nutrient for C. trachomatis is glucose, and its polymer, glycogen, is highly abundant in the inclusion lumen. This work aimed to reconstitute the glucose flow in C. trachomatis infected cells and to understand the mechanisms for glycogen accumulation. In summary, our work demonstrates that glycogen storage in C. trachomatis inclusions is the result of two different strategies, bulk acquisition of host glycogen through invagination of the inclusion membrane, and de novo synthesis of glycogen within the inclusion lumen. The latter mechanism implicates the import of host UDP-glucose through a host transporter that is recruited to the inclusion membrane, and the secretion of bacterial glycogen enzymes into the inclusion lumen. These processes allow the bacteria to build an energy store within the inclusion lumen, out of reach for the host.

Chlamydia trachomatis

Glycogène

UDP-Glucose

Sécrétion type 3

Slc35d2

Parasite intracellulaire

Intracellular bacterium

Glycogen

571.6

Characterization of Hemicellulose Biosynthesis Genes in Avena

Fogarty, Melissa Coon

09 April 2020

Avena sativa L. (2n = 6x = 42, AACCDD genome composition) or common oat is the cereal grain possessing the highest levels of water-soluble seed (1-3,1-4)-β-D-glucan (β-glucan), a hemicellulose important to human health due to its ability to lower serum LDL cholesterol levels. Understanding the mechanisms of β-glucan accumulation in oat endosperm is, consequently, of great interest. We report a genome-wide association study (GWAS) to identify quantitative trait loci (QTLs) controlling β-glucan production in oat, identifying 58 significantly associated markers. Synteny with the barley (Hordeum vulgare L.) genome identified four major regions of interest, the CslF and CslH gene families along with UGPase and AGPase as candidate genes. Subgenome-specific expression of the A, C, and D homoeologs of major β-glucan synthase AsCslF6 revealed that AsCslF6_C is the least expressed in all tissue types and time points, with low-β-glucan varieties recording the highest proportion of AsCslF6_C expression. In order to further investigate the candidate genes identified in our GWAS study and gain a greater understanding of the other cell wall polysaccharides that comprise the total fiber content in oat we sought to characterize five additional genes. Accordingly, we cloned and sequenced the three homoeologs of AsUGP and AsAGPS1. AsAGPS1 is the small subunit 1 gene of the enzyme ADP-glucose pyrophosphorylase (AGPase), which is responsible for catalyzing the first committed step in the starch biosynthesis pathway through the production of ADP-glucose. AsUGP is the gene the codes for UDP-glucose pyrophosphorylase (UGPase) an enzyme responsible for the reversible production of UDP-glucose (UDPG). UDPG is used directly or indirectly as a precursor for the biosynthesis of cell wall polysaccharides. In high β-glucan mutant line ‘OT3044’ we observed increased expression of AsUGP with a corresponding reduction of AsAGPS1 expression. Similarly, we observed an inverse expression pattern in low-fiber mutant line ‘OT3018’, wherein AsUGP expression was decreased in favor of AsAGPS1 expression. Further, we also found evidence that these changes in both AsUGP and AsAGPS1 expression are due primarily to up- or down-regulation in the A-genome homoeoalleles. Additionally, we characterized genes in the CslC family (CslC4, CslC9) and CslA family (CslA7) responsible for xyloglucan and glucomannan synthesis, respectively. High-fiber line ‘HiFi’ showed the least amount of overall expression of these three genes, raising the possibility that the increased β-glucan is due to a reduction in other hemicelluloses. After analyzing homoeolog-specific expression in multiple genes we observed that the A genome consistently had the most highly expressed homoeoallele, hinting at a universal preference for expression of this subgenome. We present hypotheses regarding multiple points in carbohydrate metabolism having the potential to alter β-glucan content in oat.

β-glucan

genome wide association studies

Avena

CslF6

ADP-glucose pyrophosphorylase

UDP-glucose pyrophosphorylase

Life Sciences

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

Plant UDP-glucose Pyrophosphorylase : Function and Regulation

Meng, Meng

January 2008

UDP-glucose pyrophosphorylase (UGPase) is an important enzyme of carbohydrate metabolism in all living organisms. The main aim of this thesis was to investigate the function and regulation of plant UGP genes as well as the UGPase proteins. Both in vivo and in vitro approaches were used, including the use of transgenic plants deficient in UGPase activity, and using purified proteins and their mutants to elucidate the structure/ function properties of UGPase. In both Arabidopsis and aspen, there are two highly similar UGP genes being actively transcribed, but not to the same extent. For both species, the UGP genes could be classified into two categories: a “house-keeping” gene and a subsidiary gene, with the former functioning universally in all the tissues to support the normal growth, whereas the latter usually expressed at a lower level in most of the organs/tissues tested. Besides, the two UGP genes were also found being differentially regulated under abiotic stress conditions, e.g. low temperature. By investigating the Arabidopsis T-DNA insertion mutants, which respectively have one or both of the UGP genes knocked out, we noticed that as little as 10% of the remaining UGPase activity could still support normal growth and development under controlled conditions, with little or no changes in carbohydrate contents, including soluble sugars (e.g. sucrose), starch and cell wall polysaccharides. Those plants, however, had a significantly decreased fitness under field conditions, i.e. the plants most deficient in UGPase activity produced up to 50% less seeds than in wt. Therefore, we concluded that UGPase is not a rate-limiting enzyme in carbohydrate synthesis pathways, but still is essential in viability of Arabidopsis plants. In order to characterize two Arabidopsis UGPase isozymes, both proteins were heterologously overexpressed in prokaryotic cells and purified by affinity chromatography. The two isozymes showed little differences in physical and biochemical properties, including substrate specificity, Km values with substrates in both directions of the reaction, molecular masses, isoelectric point (pI), and equilibrium constant. On the other hand, possibilities of distinct post-translational regulatory mechanisms were indicated, based on amino acid (aa) motif analyses, and on 3D analyses of derived crystal structures of the two proteins. We used the heterologous bacterial system also to overexpress barley UGPase and several of its mutants, both single mutants and those with whole domains/ exons deleted. As a result, we have identified several aa residues/ protein domains that may be essential for structural integrity and catalytic/ substrate-binding properties of the protein. For instance, we found that the last exon of UGPase (8 aa at the end of C-terminus) was important for the protein ability to oligomerize and that Lys-260 and the second-to-last exon were essential for pyrophosphate (but not UDP-glucose) binding. The data emphasized the critical role of central part of the active site (so called NB-loop) in catalysis, but also pointed out to the role of N-terminus in catalysis and oligomerization, but not substrate binding, and that of C-terminus in both catalysis/substrate binding and oligomerization.

UDP-glucose pyrophosphorylase

carbohydrate metabolism

in vivo regulation

T-DNA knockout

heterologous expression

isozyme

mutagenesis

kinetic property

oligomerization

Plant physiology

Växtfysiologi

Mutagenesis of the sugar donor site of the Arabidopsis thaliana glycosyltransferase UGT72B1

Palmqvist, Emma

January 2010

The Arabidopsis thaliana glycosyltransferase UGT72B1 is one of many enzymes which catalyze the reaction oflinking a glucose moiety from UDP-glucose to an acceptor molecule, in this case a chloroaniline or a chlorophenol. This is part of a detoxification system of the plant cell, similar to that in humans where a glucuronosyltransferases are enabling drug metabolism. It would be of interest to investigate the activity of the human enzyme towards different pharmaceuticals and determine the effect the linkage of glucose has to properties of the compounds. However, the human enzymes are membrane proteins and thus difficult to purify and crystallize. Here, an attempt was made to instead change the substrate specificity of UGT72B1 from UDPglucose to UDP-glucuronic acid. Combination of the four point mutations G18S, P139R, W367S and AG387ED were introduced in UGT72B1. However, no UDP-glucuronic acid activity was obtained. Single mutants W367S and AG387ED retained similar activity as of the wildtype while P139R had highly reduced activity and G18S was not expressed at all. All other combinations of mutations resulted in even less activity. Four chimeric proteins were also constructed. They were combinations of the UGT72B1 and the human enzyme UGT2B4. These were all soluble proteins but no activity could be determined. / Glykosyltransferaset UGT72B1 från Arabidopsis thaliana är ett av många enzymer som katalyserar reaktionen där en glukosenhet från UDP-glukos länkas till en acceptormolekyl, i det här fallet en kloranilin eller en klorfenol. Det är en del av ett detoxifieringssytem i växtcellen, som liknar det i människan, där ett glukuronosyltransferas möjliggör nedbrytning av bl.a. läkemedel. Det vore intressant att kunna undersöka de humana enzymernas aktivitet mot olika läkemedel och även fastställa effekten glukoslänkningen har på dessa substansers egenskaper. De humana enzymerna är dock membranprotein och är därför svåra att rena fram och att kristallisera. Här har istället ett försök gjorts för att ändra substratspecificiteten hos UGT72B1 från UDP-glukos till UDP-glukuronsyra. Kombinationer av de fyra punktmutationerna G18S, P139R, W367S och AG387ED introducerades i UGT72B1. Ingen aktivitet med UDP-glukuronsyra erhölls dock. Enkelmutanterna W367S och AG387ED bibehöll liknande aktivitet som vildtypen, medan P139R hade starkt reducerad aktivitet och G18S uttrycktes inte alls. Alla andra kombinationer av mutationer resulterade i ännu lägre aktivitet. Fyra chimeriska proteiner konstruerades också. De skapades genom kombination av UGT72B1 och det humana enzymet UGT2B4. Dessa var alla lösliga proteiner men ingen av dem uppvisade någon aktivitet.

Biochemistry

Biokemi