Search

Your search keyword '"Gardner, Jeffrey G."' showing total 144 results
Start Over Author "Gardner, Jeffrey G."
144 results on '"Gardner, Jeffrey G."'

23. In Bacillus subtilis, the sirtuin protein deacetylase, encoded by the srtN gene (formerly yhdZ), and functions encoded by the acuABC genes control the activity of acetyl coenzyme a synthetase

Author

Gardner, Jeffrey G. and Escalante-Semerena, Jorge C.

Subjects
Bacillus subtilis -- Genetic aspects, Bacillus subtilis -- Physiological aspects, Acetyl coenzyme A synthetase -- Research, Genetic translation -- Physiological aspects, Biological sciences
Abstract

This report provides in vivo evidence for the posttranslational control of the acetyl coenzyme A (Ac-CoA) synthetase (AcsA) enzyme of Bacillus subtilis by the acuA and acuC gene products. In addition, both in vivo and in vitro data presented support the conclusion that the yhdZ gene of B. subtilis encodes a [NAD.sup.+]-dependent protein deacetylase homologous to the yeast Sir2 protein (also known as sirtuin). On the basis of this new information, a change in gene nomenclature, from yhdZ to srtN (for sirtuin), is proposed to reflect the activity associated with the YdhZ protein. In vivo control of B. subtilis AcsA function required the combined activities of AcuC and SrtN. Inactivation of acuC or srtN resulted in slower growth and cell yield under low-acetate conditions than those of the wild-type strain, and the acuC srtN strain grew under low-acetate conditions as poorly as the acsA strain. Our interpretation of the latter result was that both deacetylases (AcuC and SrtN) are needed to maintain AcsA as active (i.e., deacetylated) so the cell can grow with low concentrations of acetate. Growth of an acuA acuC srtN strain on acetate was improved over that of the [acuA.sup.+] acuC srtN strain, indicating that the AcuA acetyltransferase enzyme modifies (i.e., inactivates) AcsA in vivo, a result consistent with previously reported in vitro evidence that AcsA is a substrate of AcuA.

Published
2009

26. Control of acetyl-coenzyme a synthetase (AcsA) activity by acetylation/deacetylation without NA[D.sup.+] involvement in Bacillus subtilis

Author

Gardner, Jeffrey G., Grundy, Frank J., Henkin, Tina M., and Escalante-Semerena, Jorge C.

Subjects
Bacillus subtilis -- Genetic aspects, Protein biosynthesis -- Analysis, Biological sciences
Abstract

Posttranslational modification is an efficient mechanism for controlling the activity of structural proteins, gene expression regulators, and enzymes in response to rapidly changing physiological conditions. Here we report in vitro and in vivo evidence that the acuABC operon of the gram-positive soil bacterium Bacillus subtilis encodes a protein acetyltransferase (AcuA) and a protein deacetylase (AcuC), which may control the activity of acetyl-coenzyme A (CoA) synthetase (AMP-forming, AcsA) in this bacterium. Results from in vitro experiments using purified proteins show that AcsA is a substrate for the acetyl-CoA-dependent AcuA acetyltransferase. Mass spectrometry analysis of a tryptic digest of acetylated AcsA (Acs[A.sup.Ac]) identified residue Lys549 as the sole modification site in the protein. Unlike sirtuins, the AcuC protein did not require NA[D.sup.+] as cosubstrate to deacetylate Acs[A.sup.Ac]. The function of the putative AcuB protein remains unknown.

Published
2006

32. Transcriptomic analyses of bacterial growth on fungal necromass reveal different microbial community niches during degradation.

Author

Novak, Jessica K., Kennedy, Peter G., and Gardner, Jeffrey G.

Subjects
*SERRATIA marcescens, *BIOCHEMICAL substrates, *MICROBIAL growth, *NUTRIENT cycles, *BIOMASS, *SOIL microbiology, *BACTERIAL diversity
Abstract

Bacteria are major drivers of organic matter decomposition and play crucial roles in global nutrient cycling. Although the degradation of dead fungal biomass (necromass) is increasingly recognized as an important contributor to soil carbon (C) and nitrogen (N) cycling, the genes and metabolic pathways involved in necromass degradation are less characterized. In particular, how bacteria degrade necromass containing different quantities of melanin, which largely control rates of necromass decomposition in situ, is largely unknown. To address this gap, we conducted a multitimepoint transcriptomic analysis using three Gram-negative, bacterial species grown on low or high melanin necromass of Hyaloscypha bicolor. The bacterial species, Cellvibrio japonicus, Chitinophaga pinensis, and Serratia marcescens, belong to genera known to degrade necromass in situ. We found that while bacterial growth was consistently higher on low than high melanin necromass, the CAZyme-encoding gene expression response of the three species was similar between the two necromass types. Interestingly, this trend was not shared for genes encoding nitrogen utilization, which varied in C. pinensis and S. marcescens during growth on high vs low melanin necromass. Additionally, this study tested the metabolic capabilities of these bacterial species to grow on a diversity of C and N sources and found that the three bacteria have substantially different utilization patterns. Collectively, our data suggest that as necromass changes chemically over the course of degradation, certain bacterial species are favored based on their different ial metabolic capacities. IMPORTANCE Fungal necromass is a major component of the carbon (C) in soils as well as an important source of nitrogen (N) for plant and microbial growth. Bacteria associated with necromass represent a distinct subset of the soil microbiome and characterizing their functional capacities is the critical next step toward understanding how they influence necromass turnover. This is particularly important for necromass varying in melanin content, which has been observed to control the rate of necromass decomposition across a variety of ecosystems. Here we assessed the gene expression of three necromass-degrading bacteria grown on low or high melanin necromass and characterized their metabolic capacities to grow on different C and N substrates. These transcriptomic and metabolic studies provide the first steps toward assessing the physiological relevance of up-regulated CAZyme-encoding genes in necromass decomposition and provide foundational data for generating a predictive model of the molecular mechanisms underpinning necromass decomposition by soil bacteria. [ABSTRACT FROM AUTHOR]

Published
2024
Full Text
View/download PDF

33. Requirement of the type II secretion system for utilization of cellulosic substrates by Cellvibrio japonicus

Author

Gardner, Jeffrey G. and Keating, David H.

Subjects
Biomass energy -- Research, Cellulose -- Chemical properties, Gene mutations -- Analysis, Gram-negative bacteria -- Genetic aspects, Gram-negative bacteria -- Physiological aspects, Biological sciences
Abstract

The ability of Cellvibrio japonicus, a sequenced Gram-negative cellulolytic bacterium, to degrade bioenergy-related feedstocks is examined. A method is developed for constructing directed gene disruptions in Cellvibrio japonicus and has shown that efficient cellular secretion and growth on biomass are prevented by disruption of the type II secretion system.

Published
2010

37. The complex physiology of <italic>Cellvibrio japonicus</italic> xylan degradation relies on a single cytoplasmic β‐xylosidase for xylo‐oligosaccharide utilization.

Author

Blake, Andrew D., Beri, Nina R., Guttman, Hadassa S., Cheng, Raymond, and Gardner, Jeffrey G.

Subjects
LIGNOCELLULOSE biodegradation, CARBON cycle, ENTEROTYPES, RENEWABLE energy sources, XYLANS, OLIGOSACCHARIDES
Abstract

Summary: Lignocellulose degradation by microbes plays a central role in global carbon cycling, human gut metabolism and renewable energy technologies. While considerable effort has been put into understanding the biochemical aspects of lignocellulose degradation, much less work has been done to understand how these enzymes work in an in vivo context. Here, we report a systems level study of xylan degradation in the saprophytic bacterium Cellvibrio japonicus. Transcriptome analysis indicated seven genes that encode carbohydrate active enzymes were up‐regulated during growth with xylan containing media. In‐frame deletion analysis of these genes found that only gly43F is critical for utilization of xylo‐oligosaccharides, xylan, and arabinoxylan. Heterologous expression of gly43F was sufficient for the utilization of xylo‐oligosaccharides in Escherichia coli. Additional analysis found that the xyn11A, xyn11B, abf43L, abf43K, and abf51A gene products were critical for utilization of arabinoxylan. Furthermore, a predicted transporter (CJA_1315) was required for effective utilization of xylan substrates, and we propose this unannotated gene be called xntA (xylan transporter A). Our major findings are (i) C. japonicus employs both secreted and surface associated enzymes for xylan degradation, which differs from the strategy used for cellulose degradation, and (ii) a single cytoplasmic β‐xylosidase is essential for the utilization of xylo‐oligosaccharides. [ABSTRACT FROM AUTHOR]

Published
2018
Full Text
View/download PDF

43. Genetic and enzymatic characterization of Amy13E from Cellvibrio japonicus reclassifies it as a cyclodextrinase also capable of α-diglucoside degradation.

Author

Mascelli, Giulia M., Garcia, Cecelia A., and Gardner, Jeffrey G.

Subjects
*BACTERIAL enzymes, *ESCHERICHIA coli, *MALTOSE, *STARCH metabolism, *ENZYME biotechnology, *CYCLODEXTRINS, *OLIGOSACCHARIDES
Abstract

Cyclodextrinases are carbohydrate-active enzymes involved in the linearization of circular amylose oligosaccharides. Primarily thought to function as part of starch metabolism, there have been previous reports of bacterial cyclodextrinases also having additional enzymatic activities on linear malto-oligosaccharides. This substrate class also includes environmentally rare α-diglucosides such as kojibiose (α-1,2), nigerose (α-1,3), and isomaltose (α-1,6), all of which have valuable properties as prebiotics or low-glycemic index sweeteners. Previous genome sequencing of three Cellvibrio japonicus strains adapted to utilize these α-diglucosides identified multiple, but uncharacterized, mutations in each strain. One of the mutations identified was in the amy13E gene, which was annotated to encode a neopullulanase. In this report, we functionally characterized this gene and determined that it in fact encodes a cyclodextrinase with additional activities on α-diglucosides. Deletion analysis of amy13E found that this gene was essential for kojibiose and isomaltose metabolism in C. japonicus. Interestingly, a Δamy13E mutant was not deficient for cyclodextrin or pullulan utilization in C. japonicus; however, heterologous expression of the gene in E. coli was sufficient for cyclodextrin-dependent growth. Biochemical analyses found that CjAmy13E cleaved multiple substrates but preferred cyclodextrins and maltose, but had no activity on pullulan. Our characterization of the CjAmy13E cyclodextrinase is useful for re fining functional enzyme predictions in related bacteria and for engineering enzymes for biotechnology or biomedical applications. [ABSTRACT FROM AUTHOR]

Published
2024
Full Text
View/download PDF

47. A complex gene locus enables xyloglucan utilization in the model saprophyte C ellvibrio japonicus.

Author

Larsbrink, Johan, Thompson, Andrew J., Lundqvist, Magnus, Gardner, Jeffrey G., Davies, Gideon J., and Brumer, Harry

Subjects
XYLOGLUCANS, SAPROPHYTES, PLANT biomass, PLANT cell walls, INDUSTRIAL enzymology
Abstract

The degradation of plant biomass by saprophytes is an ecologically important part of the global carbon cycle, which has also inspired a vast diversity of industrial enzyme applications. The xyloglucans ( XyGs) constitute a family of ubiquitous and abundant plant cell wall polysaccharides, yet the enzymology of XyG saccharification is poorly studied. Here, we present the identification and molecular characterization of a complex genetic locus that is required for xyloglucan utilization by the model saprophyte C ellvibrio japonicus. In harness, transcriptomics, reverse genetics, enzyme kinetics, and structural biology indicate that the encoded cohort of an α-xylosidase, a β-galactosidase, and an α- l-fucosidase is specifically adapted for efficient, concerted saccharification of dicot (fucogalacto)xyloglucan oligosaccharides following import into the periplasm via an associated TonB-dependent receptor. The data support a biological model of xyloglucan degradation by C . japonicus with striking similarities - and notable differences - to the complex polysaccharide utilization loci of the Bacteroidetes. [ABSTRACT FROM AUTHOR]

Published
2014
Full Text
View/download PDF

48. In vitro and in vivo characterization of three Cellvibrio japonicus glycoside hydrolase family 5 members reveals potent xyloglucan backbone-cleaving functions

Author

Attia, Mohamed A., Nelson, Cassandra E., Offen, Wendy A., Jain, Namrata, Davies, Gideon J., Gardner, Jeffrey G., and Brumer, Harry

Subjects
2. Zero hunger, Saprophyte, Glycoside hydrolase, Cellvibrio japonicus, Xyloglucan, Saccharification, 3. Good health
Abstract

Background Xyloglucan (XyG) is a ubiquitous and fundamental polysaccharide of plant cell walls. Due to its structural complexity, XyG requires a combination of backbone-cleaving and sidechain-debranching enzymes for complete deconstruction into its component monosaccharides. The soil saprophyte Cellvibrio japonicus has emerged as a genetically tractable model system to study biomass saccharification, in part due to its innate capacity to utilize a wide range of plant polysaccharides for growth. Whereas the downstream debranching enzymes of the xyloglucan utilization system of C. japonicus have been functionally characterized, the requisite backbone-cleaving endo-xyloglucanases were unresolved. Results Combined bioinformatic and transcriptomic analyses implicated three glycoside hydrolase family 5 subfamily 4 (GH5_4) members, with distinct modular organization, as potential keystone endo-xyloglucanases in C. japonicus. Detailed biochemical and enzymatic characterization of the GH5_4 modules of all three recombinant proteins confirmed particularly high specificities for the XyG polysaccharide versus a panel of other cell wall glycans, including mixed-linkage beta-glucan and cellulose. Moreover, product analysis demonstrated that all three enzymes generated XyG oligosaccharides required for subsequent saccharification by known exo-glycosidases. Crystallographic analysis of GH5D, which was the only GH5_4 member specifically and highly upregulated during growth on XyG, in free, product-complex, and active-site affinity-labelled forms revealed the molecular basis for the exquisite XyG specificity among these GH5_4 enzymes. Strikingly, exhaustive reverse-genetic analysis of all three GH5_4 members and a previously biochemically characterized GH74 member failed to reveal a growth defect, thereby indicating functional compensation in vivo, both among members of this cohort and by other, yet unidentified, xyloglucanases in C. japonicus. Our systems-based analysis indicates distinct substrate-sensing (GH74, GH5E, GH5F) and attack-mounting (GH5D) functions for the endo-xyloglucanases characterized here. Conclusions Through a multi-faceted, molecular systems-based approach, this study provides a new insight into the saccharification pathway of xyloglucan utilization system of C. japonicus. The detailed structural–functional characterization of three distinct GH5_4 endo-xyloglucanases will inform future bioinformatic predictions across species, and provides new CAZymes with defined specificity that may be harnessed in industrial and other biotechnological applications., https://www.ncbi.nlm.nih.gov/pmc/articles/PMC5816542/

49. In vitro and in vivo characterization of three Cellvibrio japonicus glycoside hydrolase family 5 members reveals potent xyloglucan backbone-cleaving functions

Author

Attia, Mohamed A, Nelson, Cassandra E, Offen, Wendy A, Jain, Namrata, Davies, Gideon J, Gardner, Jeffrey G, and Brumer, Harry

Subjects
2. Zero hunger, 3. Good health
Abstract

Background: Xyloglucan (XyG) is a ubiquitous and fundamental polysaccharide of plant cell walls. Due to its structural complexity, XyG requires a combination of backbone-cleaving and sidechain-debranching enzymes for complete deconstruction into its component monosaccharides. The soil saprophyte Cellvibrio japonicus has emerged as a genetically tractable model system to study biomass saccharification, in part due to its innate capacity to utilize a wide range of plant polysaccharides for growth. Whereas the downstream debranching enzymes of the xyloglucan utilization system of C. japonicus have been functionally characterized, the requisite backbone-cleaving endo-xyloglucanases were unresolved. Results: Combined bioinformatic and transcriptomic analyses implicated three glycoside hydrolase family 5 subfamily 4 (GH5_4) members, with distinct modular organization, as potential keystone endo-xyloglucanases in C. japonicus. Detailed biochemical and enzymatic characterization of the GH5_4 modules of all three recombinant proteins confirmed particularly high specificities for the XyG polysaccharide versus a panel of other cell wall glycans, including mixed-linkage beta-glucan and cellulose. Moreover, product analysis demonstrated that all three enzymes generated XyG oligosaccharides required for subsequent saccharification by known exo-glycosidases. Crystallographic analysis of GH5D, which was the only GH5_4 member specifically and highly upregulated during growth on XyG, in free, product-complex, and active-site affinity-labelled forms revealed the molecular basis for the exquisite XyG specificity among these GH5_4 enzymes. Strikingly, exhaustive reverse-genetic analysis of all three GH5_4 members and a previously biochemically characterized GH74 member failed to reveal a growth defect, thereby indicating functional compensation in vivo, both among members of this cohort and by other, yet unidentified, xyloglucanases in C. japonicus. Our systems-based analysis indicates distinct substrate-sensing (GH74, GH5E, GH5F) and attack-mounting (GH5D) functions for the endo-xyloglucanases characterized here. Conclusions: Through a multi-faceted, molecular systems-based approach, this study provides a new insight into the saccharification pathway of xyloglucan utilization system of C. japonicus. The detailed structural–functional characterization of three distinct GH5_4 endo-xyloglucanases will inform future bioinformatic predictions across species, and provides new CAZymes with defined specificity that may be harnessed in industrial and other biotechnological applications.

50. Trehalose degradation in Cellvibrio japonicus exhibits no functional redundancy and is solely dependent on the Tre37A enzyme.

Author

Garcia, Cecelia A., Narrett, Jackson A., and Gardner, Jeffrey G.

Subjects
*TREHALOSE, *MOIETIES (Chemistry), *DISACCHARIDES, *METABOLIC models, *ENZYMES, *CARBOHYDRATES
Abstract

The α-diglucoside trehalose has historically been known as a component of bacterial stress response, though more recently has been studied for its relevance in human gut health and biotechnology development. The utilization of trehalose as a nutrient source by bacteria relies on carbohydrate active enzymes, specifically those of the glycoside hydrolase family 37, to degrade the disaccharide into substituent glucose moieties for entry into metabolism. Environmental bacteria using oligosaccharides for nutrients often possess multiple carbohydrate active enzymes predicted to have the same biochemical activity, and therefore are thought to be functionally redundant. In this study, we characterized trehalose degradation by the biotechnologically important saprophytic bacterium Cellvibrio japonicus. This bacterium possesses two predicted α-α-trehalase genes, tre37A and tre37B, and our investigation using mutational analysis found that only the former is essential for trehalose utilization by C. japonicus. Heterologous expression experiments found that only the expression of the C. japonicus tre37A gene in an E. coli treA mutant strain allowed for full utilization of trehalose. Biochemical characterization of C. japonicus GH37 activity determined that the tre37A gene product is solely responsible for cleaving trehalose, and is an acidic α-α-trehalase. Bioinformatic and mutational analysis indicate that Tre37A directly cleaves trehalose to glucose in the periplasm, as C. japonicus does not possess a phosphotransferase system. This study facilitates the development of a comprehensive metabolic model for α-linked disaccharides in C. japonicus, and more broadly expands our understanding of the strategies that saprophytic bacteria employ to capture diverse carbohydrates from the environment. [ABSTRACT FROM AUTHOR]

Published
2020
Full Text
View/download PDF

Catalog

Books, media, physical & digital resources
See catalog results