Your search keyword '"D. Wade Abbott"' showing total 124 results

1. In vitro and ex vivo metabolism of chemically diverse fructans by bovine rumen Bifidobacterium and Lactobacillus species

Author

Marissa L. King, Xiaohui Xing, Greta Reintjes, Leeann Klassen, Kristin E. Low, Trevor W. Alexander, Matthew Waldner, Trushar R. Patel, and D. Wade Abbott

Subjects

Fructan, Linkage analysis, Bifidobacterium, Lactobacillus, Prebiotics, Rumen, Veterinary medicine, SF600-1100, Microbiology, QR1-502

Abstract

Abstract Background Inulin and inulin-derived fructooligosaccharides (FOS) are well-known prebiotics for use in companion animals and livestock. The mechanisms by which FOS contribute to health has not been fully established. Further, the fine chemistry of fructan structures from diverse sources, such as graminan-type fructans found in cereal crops, has not been fully elucidated. New methods to study fructan structure and microbial responses to these complex carbohydrates will be key for evaluating the prebiotic potency of cereal fructans found in cattle feeds. As the rumen microbiome composition is closely associated with their metabolic traits, such as feed utilization and waste production, prebiotics and probiotics represent promising additives to shift the microbial community toward a more productive state. Results Within this study, inulin, levan, and graminan-type fructans from winter wheat, spring wheat, and barley were used to assess the capacity of rumen-derived Bifidobacterium boum, Bifidobacterium merycicum, and Lactobacillus vitulinus to metabolize diverse fructans. Graminan-type fructans were purified and structurally characterized from the stems and kernels of each plant. All three bacterial species grew on FOS, inulin, and cereal crop fructans in pure cultures. L. vitulinus was the only species that could metabolize levan, albeit its growth was delayed. Fluorescently labelled polysaccharides (FLAPS) were used to demonstrate interactions with Gram-positive bacteria and confirm fructan metabolism at the single-cell level; these results were in agreement with the individual growth profiles of each species. The prebiotic potential of inulin was further investigated within naïve rumen microbial communities, where increased relative abundance of Bifidobacterium and Lactobacillus species occurred in a dose-dependent and temporal-related manner. This was supported by in situ analysis of rumen microbiota from cattle fed inulin. FLAPS probe derived from inulin and fluorescent in situ hybridization using taxon-specific probes confirmed that inulin interacts with Bifidobacteria and Lactobacilli at the single-cell level. Conclusion This research revealed that rumen-derived Bifidobacteria and Lactobacilli vary in their metabolism of structurally diverse fructans, and that inulin has limited prebiotic potential in the rumen. This knowledge establishes new methods for evaluating the prebiotic potential of fructans from diverse plant sources as prebiotic candidates for use in ruminants and other animals.

Published

2024

2. Characterization of Unfractionated Polysaccharides in Brown Seaweed by Methylation-GC-MS-Based Linkage Analysis

Author

Barinder Bajwa, Xiaohui Xing, Spencer C. Serin, Maria Hayes, Stephanie A. Terry, Robert J. Gruninger, and D. Wade Abbott

Subjects

methylation analysis, carboxyl reduction, whole food fiber, cell wall, alginate, cellulose, Biology (General), QH301-705.5

Abstract

This study introduces a novel approach to analyze glycosidic linkages in unfractionated polysaccharides from alcohol-insoluble residues (AIRs) of five brown seaweed species. GC-MS analysis of partially methylated alditol acetates (PMAAs) enables monitoring and comparison of structural variations across different species, harvest years, and tissues with and without blanching treatments. The method detects a wide array of fucose linkages, highlighting the structural diversity in glycosidic linkages and sulfation position in fucose-containing sulfated polysaccharides. Additionally, this technique enhances cellulose quantitation, overcoming the limitations of traditional monosaccharide composition analysis that typically underestimates cellulose abundance due to incomplete hydrolysis of crystalline cellulose. The introduction of a weak methanolysis-sodium borodeuteride reduction pretreatment allows for the detection and quantitation of uronic acid linkages in alginates.

Published

2024

3. Development of a spore-based mucosal vaccine against the bovine respiratory pathogen Mannheimia haemolytica

Author

Muhammed Salah Uddin, Jose Ortiz Guluarte, D. Wade Abbott, G. Douglas Inglis, Le Luo Guan, and Trevor W. Alexander

Subjects

Medicine, Science

Abstract

Abstract Bovine respiratory disease (BRD) is a significant health issue in the North American feedlot industry, causing substantial financial losses due to morbidity and mortality. A lack of effective vaccines against BRD pathogens has resulted in antibiotics primarily being used for BRD prevention. The aim of this study was to develop a mucosal vaccine against the BRD pathogen, Mannheimia haemolytica, using Bacillus subtilis spores as an adjuvant. A chimeric protein (MhCP) containing a tandem repeat of neutralizing epitopes from M. haemolytica leukotoxin A (NLKT) and outer membrane protein PlpE was expressed to produce antigen for adsorption to B. subtilis spores. Adsorption was optimized by comparing varying amounts of antigen and spores, as well as different buffer pH and reaction temperatures. Using the optimal adsorption parameters, spore-bound antigen (Spore-MhCP) was prepared and administered to mice via two mucosal routes (intranasal and intragastric), while intramuscular administration of free MhCP and unvaccinated mice were used as positive and negative control treatments, respectively. Intramuscular administration of MhCP elicited the strongest serum IgG response. However, intranasal immunization of Spore-MhCP generated the best secretory IgA-specific response against both PlpE and NLKT in all samples evaluated (bronchoalveolar lavage, saliva, and feces). Since proliferation of M. haemolytica in the respiratory tract is a prerequisite to lung infection, this spore-based vaccine may offer protection in cattle by limiting colonization and subsequent infection, and Spore-MhCP warrants further evaluation in cattle as a mucosal vaccine against M. haemolytica.

Published

2023

4. The Gram-positive bacterium Romboutsia ilealis harbors a polysaccharide synthase that can produce (1,3;1,4)-β-d-glucans

Author

Shu-Chieh Chang, Mu-Rong Kao, Rebecka Karmakar Saldivar, Sara M. Díaz-Moreno, Xiaohui Xing, Valentina Furlanetto, Johannes Yayo, Christina Divne, Francisco Vilaplana, D. Wade Abbott, and Yves S. Y. Hsieh

Subjects

Science

Abstract

Abstract (1,3;1,4)-β-d-Glucans are widely distributed in the cell walls of grasses (family Poaceae) and closely related families, as well as some other vascular plants. Additionally, they have been found in other organisms, including fungi, lichens, brown algae, charophycean green algae, and the bacterium Sinorhizobium meliloti. Only three members of the Cellulose Synthase-Like (CSL) genes in the families CSLF, CSLH, and CSLJ are implicated in (1,3;1,4)-β-d-glucan biosynthesis in grasses. Little is known about the enzymes responsible for synthesizing (1,3;1,4)-β-d-glucans outside the grasses. In the present study, we report the presence of (1,3;1,4)-β-d-glucans in the exopolysaccharides of the Gram-positive bacterium Romboutsia ilealis CRIBT. We also report that RiGT2 is the candidate gene of R. ilealis that encodes (1,3;1,4)-β-d-glucan synthase. RiGT2 has conserved glycosyltransferase family 2 (GT2) motifs, including D, D, D, QXXRW, and a C-terminal PilZ domain that resembles the C-terminal domain of bacteria cellulose synthase, BcsA. Using a direct gain-of-function approach, we insert RiGT2 into Saccharomyces cerevisiae, and (1,3;1,4)-β-d-glucans are produced with structures similar to those of the (1,3;1,4)-β-d-glucans of the lichen Cetraria islandica. Phylogenetic analysis reveals that putative (1,3;1,4)-β-d-glucan synthase candidate genes in several other bacterial species support the finding of (1,3;1,4)-β-d-glucans in these species.

Published

2023

5. Methylation-GC-MS/FID-Based Glycosidic Linkage Analysis of Unfractionated Polysaccharides in Red Seaweeds

Author

Barinder Bajwa, Xiaohui Xing, Stephanie A. Terry, Robert J. Gruninger, and D. Wade Abbott

Subjects

methylation analysis, reductive hydrolysis, whole food fiber, whole cell wall, anhydro sugar, agarose, Biology (General), QH301-705.5

Abstract

Glycosidic linkage analysis was conducted on the unfractionated polysaccharides in alcohol-insoluble residues (AIRs) prepared from six red seaweeds (Gracilariopsis sp., Prionitis sp., Mastocarpus papillatus, Callophyllis sp., Mazzaella splendens, and Palmaria palmata) using GC-MS/FID analysis of partially methylated alditol acetates (PMAAs). The cell walls of P. palmata primarily contained mixed-linkage xylans and small amounts of sulfated galactans and cellulose. In contrast, the unfractionated polysaccharides of the other five species were rich in galactans displaying diverse 3,6-anhydro-galactose and galactose linkages with varied sulfation patterns. Different levels of cellulose were also observed. This glycosidic linkage method offers advantages for cellulose analysis over traditional monosaccharide analysis that is known for underrepresenting glucose in crystalline cellulose. Relative linkage compositions calculated from GC-MS and GC-FID measurements showed that anhydro sugar linkages generated more responses in the latter detection method. This improved linkage workflow presents a useful tool for studying polysaccharide structural variations across red seaweed species. Furthermore, for the first time, relative linkage compositions from GC-MS and GC-FID measurements, along with normalized FID and total ion current (TIC) chromatograms without peak assignments, were analyzed using principal component analysis (PCA) as a proof-of-concept demonstration of the technique’s potential to differentiate various red seaweed species.

Published

2024

6. The pangenome of the wheat pathogen Pyrenophora tritici-repentis reveals novel transposons associated with necrotrophic effectors ToxA and ToxB

Author

Ryan Gourlie, Megan McDonald, Mohamed Hafez, Rodrigo Ortega-Polo, Kristin E. Low, D. Wade Abbott, Stephen E. Strelkov, Fouad Daayf, and Reem Aboukhaddour

Subjects

Tan spot, Fungal wheat pathogen, Pangenome, ToxA, ToxB, Transposons, Biology (General), QH301-705.5

Abstract

Abstract Background In fungal plant pathogens, genome rearrangements followed by selection pressure for adaptive traits have facilitated the co-evolutionary arms race between hosts and their pathogens. Pyrenophora tritici-repentis (Ptr) has emerged recently as a foliar pathogen of wheat worldwide and its populations consist of isolates that vary in their ability to produce combinations of different necrotrophic effectors. These effectors play vital roles in disease development. Here, we sequenced the genomes of a global collection (40 isolates) of Ptr to gain insights into its gene content and genome rearrangements. Results A comparative genome analysis revealed an open pangenome, with an abundance of accessory genes (~ 57%) reflecting Ptr’s adaptability. A clear distinction between pathogenic and non-pathogenic genomes was observed in size, gene content, and phylogenetic relatedness. Chromosomal rearrangements and structural organization, specifically around effector coding genes, were detailed using long-read assemblies (PacBio RS II) generated in this work in addition to previously assembled genomes. We also discovered the involvement of large mobile elements associated with Ptr’s effectors: ToxA, the gene encoding for the necrosis effector, was found as a single copy within a 143-kb ‘Starship’ transposon (dubbed ‘Horizon’) with a clearly defined target site and target site duplications. ‘Horizon’ was located on different chromosomes in different isolates, indicating mobility, and the previously described ToxhAT transposon (responsible for horizontal transfer of ToxA) was nested within this newly identified Starship. Additionally, ToxB, the gene encoding the chlorosis effector, was clustered as three copies on a 294-kb element, which is likely a different putative ‘Starship’ (dubbed ‘Icarus’) in a ToxB-producing isolate. ToxB and its putative transposon were missing from the ToxB non-coding reference isolate, but the homolog toxb and ‘Icarus’ were both present in a different non-coding isolate. This suggests that ToxB may have been mobile at some point during the evolution of the Ptr genome which is contradictory to the current assumption of ToxB vertical inheritance. Finally, the genome architecture of Ptr was defined as ‘one-compartment’ based on calculated gene distances and evolutionary rates. Conclusions These findings together reflect on the highly plastic nature of the Ptr genome which has likely helped to drive its worldwide adaptation and has illuminated the involvement of giant transposons in facilitating the evolution of virulence in Ptr.

Published

2022

7. Evaluation of the red seaweed Mazzaella japonica as a feed additive for beef cattle

Author

Stephanie A. Terry, Trevor Coates, Robert Gruninger, D. Wade Abbott, and Karen A. Beauchemin

Subjects

digestibility, greenhouse gas, macroalgae, nitrogen metabolism, rumen fermentation, Veterinary medicine, SF600-1100

Abstract

Supplementing ruminant diets with macroalgae is gaining interest globally because bromoform-containing seaweeds (e.g., Asparagopsis spp.) have been shown to be highly effective enteric methane (CH4) inhibitors. Some alternative seaweeds decrease in vitro CH4 production, but few have been evaluated in animals. This study examined the effects of including the red seaweed Mazzaella japonica in the diet of beef cattle on dry matter intake (DMI), rumen fermentation, digestibility, nitrogen (N) utilization, and enteric CH4 production. Six ruminally cannulated, mature beef heifers (824 ± 47.1 kg) were used in a double 3 × 3 Latin square with 35-d periods. The basal diet consisted of 52% barley silage, 44% barley straw, and 4% vitamin and mineral supplement [dry matter (DM) basis]. The treatments were (DM basis): 0% (control), 1%, and 2% M. japonica. The DMI increased quadratically (P = 0.025) with the inclusion of M. japonica, such that the DMI of heifers consuming 1% was greater (P

Published

2023

8. Comparative analysis of macroalgae supplementation on the rumen microbial community: Asparagopsis taxiformis inhibits major ruminal methanogenic, fibrolytic, and volatile fatty acid-producing microbes in vitro

Author

Eóin O’Hara, Stephanie A. Terry, Paul Moote, Karen A. Beauchemin, Tim A. McAllister, D. Wade Abbott, and Robert J. Gruninger

Subjects

methane, rumen, Asparagopsis, seaweed, livestock, greenhouse gas, Microbiology, QR1-502

Abstract

Seaweeds have received a great deal of attention recently for their potential as methane-suppressing feed additives in ruminants. To date, Asparagopsis taxiformis has proven a potent enteric methane inhibitor, but it is a priority to identify local seaweed varieties that hold similar properties. It is essential that any methane inhibitor does not compromise the function of the rumen microbiome. In this study, we conducted an in vitro experiment using the RUSITEC system to evaluate the impact of three red seaweeds, A. taxiformis, Palmaria mollis, and Mazzaella japonica, on rumen prokaryotic communities. 16S rRNA sequencing showed that A. taxiformis had a profound effect on the microbiome, particularly on methanogens. Weighted Unifrac distances showed significant separation of A. taxiformis samples from the control and other seaweeds (p 0.05). A. taxiformis reduced the abundance of all major archaeal species (p

Published

2023

9. Fluorescence activated cell sorting and fermentation analysis to study rumen microbiome responses to administered live microbials and yeast cell wall derived prebiotics

Author

Leeann Klassen, Greta Reintjes, Meiying Li, Long Jin, Carolyn Amundsen, Xiaohui Xing, Lharbi Dridi, Bastien Castagner, Trevor W. Alexander, and D. Wade Abbott

Subjects

rumen, microbiome, Bacteroides, mannan, yeast cell wall, fermentation, Microbiology, QR1-502

Abstract

Rapid dietary changes, such as switching from high-forage to high-grain diets, can modify the rumen microbiome and initiate gastrointestinal distress, such as bloating. In such cases, feed additives, including prebiotics and live microbials, can be used to mitigate these negative consequences. Bio-Mos® is a carbohydrate-based prebiotic derived from yeast cells that is reported to increase livestock performance. Here, the responses of rumen bacterial cells to Bio-Mos® were quantified, sorted by flow cytometry using fluorescently-labeled yeast mannan, and taxonomically characterized using fluorescence in situ hybridization and 16S rRNA sequencing. Further, to evaluate the effects of bovine-adapted Bacteroides thetaiotaomicron administration as a live microbial with and without Bio-Mos® supplementation, we analyzed microbial fermentation products, changes to carbohydrate profiles, and shifts in microbial composition of an in vitro rumen community. Bio-Mos® was shown to be an effective prebiotic that significantly altered microbial diversity, composition, and fermentation; while addition of B. thetaiotaomicron had no effect on community composition and resulted in fewer significant changes to microbial fermentation. When combined with Bio-Mos®, there were notable, although not significant, changes to major bacterial taxa, along with increased significant changes in fermentation end products. These data suggest a synergistic effect is elicited by combining Bio-Mos® and B. thetaiotaomicron. This protocol provides a new in vitro methodology that could be extended to evaluate prebiotics and probiotics in more complex artificial rumen systems and live animals.

Published

2023

10. Mechanistic insights into the digestion of complex dietary fibre by the rumen microbiota using combinatorial high-resolution glycomics and transcriptomic analyses

Author

Ajay Badhan, Kristin E. Low, Darryl R. Jones, Xiaohui Xing, Mohammad Raza Marami Milani, Rodrigo Ortega Polo, Leeann Klassen, Sivasankari Venketachalam, Michael G. Hahn, D. Wade Abbott, and Tim A. McAllister

Subjects

Glycoside hydrolase, CAZymes, Rumen microbiome, Glycome profiling, Linkage analysis, Transcriptome, Biotechnology, TP248.13-248.65

Abstract

There is a knowledge gap regarding the factors that impede the ruminal digestion of plant cell walls or if rumen microbiota possess the functional activities to overcome these constraints. Innovative experimental methods were adopted to provide a high-resolution understanding of plant cell wall chemistries, identify higher-order structures that resist microbial digestion, and determine how they interact with the functional activities of the rumen microbiota. We characterized the total tract indigestible residue (TTIR) from cattle fed a low-quality straw diet using two comparative glycomic approaches: ELISA-based glycome profiling and total cell wall glycosidic linkage analysis. We successfully detected numerous and diverse cell wall glycan epitopes in barley straw (BS) and TTIR and determined their relative abundance pre- and post-total tract digestion. Of these, xyloglucans and heteroxylans were of higher abundance in TTIR. To determine if the rumen microbiota can further saccharify the residual plant polysaccharides within TTIR, rumen microbiota from cattle fed a diet containing BS were incubated with BS and TTIR ex vivo in batch cultures. Transcripts coding for carbohydrate-active enzymes (CAZymes) were identified and characterized for their contribution to cell wall digestion based on glycomic analyses, comparative gene expression profiles, and associated CAZyme families. High-resolution phylogenetic fingerprinting of these sequences encoded CAZymes with activities predicted to cleave the primary linkages within heteroxylan and arabinan. This experimental platform provides unprecedented precision in the understanding of forage structure and digestibility, which can be extended to other feed-host systems and inform next-generation solutions to improve the performance of ruminants fed low-quality forages.

Published

2022

11. Novel Insights into the Pig Gut Microbiome Using Metagenome-Assembled Genomes

Author

Devin B. Holman, Arun Kommadath, Jeffrey P. Tingley, and D. Wade Abbott

Subjects

metagenome-assembled genomes, antimicrobial resistance, CAZymes, swine, gut microbiome, metagenomics, Microbiology, QR1-502

Abstract

ABSTRACT Pigs are among the most numerous and intensively farmed food-producing animals in the world. The gut microbiome plays an important role in the health and performance of swine and changes rapidly after weaning. Here, fecal samples were collected from pigs at 7 different times points from 7 to 140 days of age. These swine fecal metagenomes were used to assemble 1,150 dereplicated metagenome-assembled genomes (MAGs) that were at least 90% complete and had less than 5% contamination. These MAGs represented 472 archaeal and bacterial species, and the most widely distributed MAGs were the uncultured species Collinsella sp002391315, Sodaliphilus sp004557565, and Prevotella sp000434975. Weaning was associated with a decrease in the relative abundance of 69 MAGs (e.g., Escherichia coli) and an increase in the relative abundance of 140 MAGs (e.g., Clostridium sp000435835, Oliverpabstia intestinalis). Genes encoding for the production of the short-chain fatty acids acetate, butyrate, and propionate were identified in 68.5%, 18.8%, and 8.3% of the MAGs, respectively. Carbohydrate-active enzymes associated with the degradation of arabinose oligosaccharides and mixed-linkage glucans were predicted to be most prevalent among the MAGs. Antimicrobial resistance genes were detected in 327 MAGs, including 59 MAGs with tetracycline resistance genes commonly associated with pigs, such as tet(44), tet(Q), and tet(W). Overall, 82% of the MAGs were assigned to species that lack cultured representatives indicating that a large portion of the swine gut microbiome is still poorly characterized. The results here also demonstrate the value of MAGs in adding genomic context to gut microbiomes. IMPORTANCE Many of the bacterial strains found in the mammalian gut are difficult to culture and isolate due to their various growth and nutrient requirements that are frequently unknown. Here, we assembled strain-level genomes from short metagenomic sequences, so-called metagenome-assembled genomes (MAGs), that were derived from fecal samples collected from pigs at multiple time points. The genomic context of a number of antimicrobial resistance genes commonly detected in swine was also determined. In addition, our study connected taxonomy with potential metabolic functions such as carbohydrate degradation and short-chain fatty acid production.

Published

2022

12. Evaluation of Rumen Fermentation and Microbial Adaptation to Three Red Seaweeds Using the Rumen Simulation Technique

Author

Stephanie A. Terry, Ana M. Krüger, Paulo M. T. Lima, Robert J. Gruninger, D. Wade Abbott, and Karen A. Beauchemin

Subjects

rumen simulation technique, methane production, seaweed, rumen fermentation, Veterinary medicine, SF600-1100, Zoology, QL1-991

Abstract

Several red seaweeds have been shown to inhibit enteric CH4 production; however, the adaptation of fermentation parameters to their presence is not well understood. The objective of this study was to examine the effect of three red seaweeds (Asparargopsis taxiformis, Mazzaella japonica, and Palmaria mollis) on in vitro fermentation, CH4 production, and adaptation using the rumen simulation technique (RUSITEC). The experiment was conducted as a completely randomized design with four treatments, duplicated in two identical RUSITEC apparatus equipped with eight fermenter vessels each. The four treatments included the control and the three red seaweeds added to the control diet at 2% diet DM. The experimental period was divided into four phases including a baseline phase (d 0–7; no seaweed included), an adaptation phase (d 8–11; seaweed included in treatment vessels), an intermediate phase (d 12–16), and a stable phase (d 17–21). The degradability of organic matter (p = 0.04) and neutral detergent fibre (p = 0.05) was decreased by A. taxiformis during the adaptation phase, but returned to control levels in the stable phase. A. taxiformis supplementation resulted in a decrease (p < 0.001) in the molar proportions of acetate, propionate, and total volatile fatty acid (VFA) production, with an increase in the molar proportions of butyrate, caproate, and valerate; the other seaweeds had no effect (p > 0.05) on the molar proportions or production of individual VFA. A. taxiformis was the only seaweed to suppress CH4 production (p < 0.001), with the suppressive effect increasing (p < 0.001) across phases. Similarly, A. taxiformis increased (p < 0.001) the production of hydrogen (H2, %, mL/d) across the adaptation, intermediate, and stable phases, with the intermediate and stable phases having greater H2 production than the adaptation phase. In conclusion, M. japonica and P. mollis did not impact rumen fermentation or inhibit CH4 production within the RUSITEC. In contrast, we conclude that A. taxiformis is an effective CH4 inhibitor and its introduction to the ruminal environment requires a period of adaptation; however, the large magnitude of CH4 suppression by A. taxiformis inhibits VFA synthesis, which may restrict the production performance in vivo.

Published

2023

13. Correction to: Combined whole cell wall analysis and streamlined in silico carbohydrate‑active enzyme discovery to improve biocatalytic conversion of agricultural crop residues

Author

Jeffrey P. Tingley, Kristin E. Low, Xiaohui Xing, and D. Wade Abbott

Subjects

Fuel, TP315-360, Biotechnology, TP248.13-248.65

Abstract

An amendment to this paper has been published and can be accessed via the original article.

Published

2021

14. Combined whole cell wall analysis and streamlined in silico carbohydrate-active enzyme discovery to improve biocatalytic conversion of agricultural crop residues

Author

Jeffrey P. Tingley, Kristin E. Low, Xiaohui Xing, and D. Wade Abbott

Subjects

Agriculture, Crop residues, Biomass conversion, Carbohydrate-active enzyme, Plant cell wall, Glycosidic linkage analysis, Fuel, TP315-360, Biotechnology, TP248.13-248.65

Abstract

Abstract The production of biofuels as an efficient source of renewable energy has received considerable attention due to increasing energy demands and regulatory incentives to reduce greenhouse gas emissions. Second-generation biofuel feedstocks, including agricultural crop residues generated on-farm during annual harvests, are abundant, inexpensive, and sustainable. Unlike first-generation feedstocks, which are enriched in easily fermentable carbohydrates, crop residue cell walls are highly resistant to saccharification, fermentation, and valorization. Crop residues contain recalcitrant polysaccharides, including cellulose, hemicelluloses, pectins, and lignin and lignin-carbohydrate complexes. In addition, their cell walls can vary in linkage structure and monosaccharide composition between plant sources. Characterization of total cell wall structure, including high-resolution analyses of saccharide composition, linkage, and complex structures using chromatography-based methods, nuclear magnetic resonance, -omics, and antibody glycome profiling, provides critical insight into the fine chemistry of feedstock cell walls. Furthermore, improving both the catalytic potential of microbial communities that populate biodigester reactors and the efficiency of pre-treatments used in bioethanol production may improve bioconversion rates and yields. Toward this end, knowledge and characterization of carbohydrate-active enzymes (CAZymes) involved in dynamic biomass deconstruction is pivotal. Here we overview the use of common “-omics”-based methods for the study of lignocellulose-metabolizing communities and microorganisms, as well as methods for annotation and discovery of CAZymes, and accurate prediction of CAZyme function. Emerging approaches for analysis of large datasets, including metagenome-assembled genomes, are also discussed. Using complementary glycomic and meta-omic methods to characterize agricultural residues and the microbial communities that digest them provides promising streams of research to maximize value and energy extraction from crop waste streams.

Published

2021

15. Quantifying fluorescent glycan uptake to elucidate strain-level variability in foraging behaviors of rumen bacteria

Author

Leeann Klassen, Greta Reintjes, Jeffrey P. Tingley, Darryl R. Jones, Jan-Hendrik Hehemann, Adam D. Smith, Timothy D. Schwinghamer, Carol Arnosti, Long Jin, Trevor W. Alexander, Carolyn Amundsen, Dallas Thomas, Rudolf Amann, Tim A. McAllister, and D. Wade Abbott

Subjects

Microbiome, Carbohydrate, Rumen, Glycoside hydrolase, Fluorescent polysaccharides, Yeast mannan, Microbial ecology, QR100-130

Abstract

Abstract Gut microbiomes, such as the microbial community that colonizes the rumen, have vast catabolic potential and play a vital role in host health and nutrition. By expanding our understanding of metabolic pathways in these ecosystems, we will garner foundational information for manipulating microbiome structure and function to influence host physiology. Currently, our knowledge of metabolic pathways relies heavily on inferences derived from metagenomics or culturing bacteria in vitro. However, novel approaches targeting specific cell physiologies can illuminate the functional potential encoded within microbial (meta)genomes to provide accurate assessments of metabolic abilities. Using fluorescently labeled polysaccharides, we visualized carbohydrate metabolism performed by single bacterial cells in a complex rumen sample, enabling a rapid assessment of their metabolic phenotype. Specifically, we identified bovine-adapted strains of Bacteroides thetaiotaomicron that metabolized yeast mannan in the rumen microbiome ex vivo and discerned the mechanistic differences between two distinct carbohydrate foraging behaviors, referred to as “medium grower” and “high grower.” Using comparative whole-genome sequencing, RNA-seq, and carbohydrate-active enzyme fingerprinting, we could elucidate the strain-level variability in carbohydrate utilization systems of the two foraging behaviors to help predict individual strategies of nutrient acquisition. Here, we present a multi-faceted study using complimentary next-generation physiology and “omics” approaches to characterize microbial adaptation to a prebiotic in the rumen ecosystem. Video abstract

Published

2021

16. Host responses to Clostridium perfringens challenge in a chicken model of chronic stress

Author

Sarah J. M. Zaytsoff, Sarah M. Lyons, Alexander M. Garner, Richard R. E. Uwiera, Wesley F. Zandberg, D. Wade Abbott, and G. Douglas Inglis

Subjects

Clostridium perfringens, Physiological stress, Small intestine, Corticosterone, Necrotic enteritis, Diseases of the digestive system. Gastroenterology, RC799-869

Abstract

Abstract Background This study utilized a chicken model of chronic physiological stress mediated by corticosterone (CORT) administration to ascertain how various host metrics are altered upon challenge with Clostridium perfringens. Necrotic enteritis (NE) is a disease of the small intestine of chickens incited by C. perfringens, which can result in elevated morbidity and mortality. The objective of the current study was to investigate how physiological stress alters host responses and predisposes birds to subclinical NE. Results Birds administered CORT exhibited higher densities of C. perfringens in their intestine, and this corresponded to altered production of intestinal mucus. Characterization of mucus showed that C. perfringens treatment altered the relative abundance of five glycans. Birds inoculated with C. perfringens did not exhibit evidence of acute morbidity. However, histopathologic changes were observed in the small intestine of infected birds. Birds administered CORT showed altered gene expression of tight junction proteins (i.e. CLDN3 and CLDN5) and toll-like receptors (i.e. TLR2 and TLR15) in the small intestine. Moreover, birds administered CORT exhibited increased expression of IL2 and G-CSF in the spleen, and IL1β, IL2, IL18, IFNγ, and IL6 in the thymus. Body weight gain was impaired only in birds that were administered CORT and challenged with C. perfringens. Conclusion CORT administration modulated a number of host functions, which corresponded to increased densities of C. perfringens in the small intestine and weight gain impairment in chickens. Importantly, results implicate physiological stress as an important predisposing factor to NE, which emphasizes the importance of managing stress to optimize chicken health.

Published

2020

17. Approaches to Investigate Selective Dietary Polysaccharide Utilization by Human Gut Microbiota at a Functional Level

Author

Leeann Klassen, Xiaohui Xing, Jeffrey P. Tingley, Kristin E. Low, Marissa L. King, Greta Reintjes, and D. Wade Abbott

Subjects

microbiome, carbohydrate, carbohydrate-active enzyme, phylogeny, next-generation physiology, carbohydrate probe, Microbiology, QR1-502

Abstract

The human diet is temporally and spatially dynamic, and influenced by culture, regional food systems, socioeconomics, and consumer preference. Such factors result in enormous structural diversity of ingested glycans that are refractory to digestion by human enzymes. To convert these glycans into metabolizable nutrients and energy, humans rely upon the catalytic potential encoded within the gut microbiome, a rich collective of microorganisms residing in the gastrointestinal tract. The development of high-throughput sequencing methods has enabled microbial communities to be studied with more coverage and depth, and as a result, cataloging the taxonomic structure of the gut microbiome has become routine. Efforts to unravel the microbial processes governing glycan digestion by the gut microbiome, however, are still in their infancy and will benefit by retooling our approaches to study glycan structure at high resolution and adopting next-generation functional methods. Also, new bioinformatic tools specialized for annotating carbohydrate-active enzymes and predicting their functions with high accuracy will be required for deciphering the catalytic potential of sequence datasets. Furthermore, physiological approaches to enable genotype-phenotype assignments within the gut microbiome, such as fluorescent polysaccharides, has enabled rapid identification of carbohydrate interactions at the single cell level. In this review, we summarize the current state-of-knowledge of these methods and discuss how their continued development will advance our understanding of gut microbiome function.

Published

2021

18. Development of a Real-Time Pectic Oligosaccharide-Detecting Biosensor Using the Rapid and Flexible Computational Identification of Non-Disruptive Conjugation Sites (CINC) Biosensor Design Platform

Author

Dustin D. Smith, Joshua P. King, D. Wade Abbott, and Hans-Joachim Wieden

Subjects

computational biosensor design, molecular dynamics, fluorescence, rapid kinetics, carbohydrate detection, oligogalacturonides, Chemical technology, TP1-1185

Abstract

Fluorescently labeled, solute-binding proteins that change their fluorescent output in response to ligand binding are frequently used as biosensors for a wide range of applications. We have previously developed a “Computational Identification of Non-disruptive Conjugation sites” (CINC) approach, an in silico pipeline utilizing molecular dynamics simulations for the rapid design and construction of novel protein–fluorophore conjugate-type biosensors. Here, we report an improved in silico scoring algorithm for use in CINC and its use in the construction of an oligogalacturonide-detecting biosensor set. Using both 4,5-unsaturated and saturated oligogalacturonides, we demonstrate that signal transmission from the ligand-binding pocket of the starting protein scaffold to the CINC-selected reporter positions is effective for multiple different ligands. The utility of an oligogalacturonide-detecting biosensor is shown in Carbohydrate Active Enzyme (CAZyme) activity assays, where the biosensor is used to follow product release upon polygalacturonic acid (PGA) depolymerization in real time. The oligogalacturonide-detecting biosensor set represents a novel enabling tool integral to our rapidly expanding platform for biosensor-based carbohydrate detection, and moving forward, the CINC pipeline will continue to enable the rational design of biomolecular tools to detect additional chemically distinct oligosaccharides and other solutes.

Published

2022

19. Molecular basis of an agarose metabolic pathway acquired by a human intestinal symbiont

Author

Benjamin Pluvinage, Julie M. Grondin, Carolyn Amundsen, Leeann Klassen, Paul E. Moote, Yao Xiao, Dallas Thomas, Nicholas A. Pudlo, Anuoluwapo Anele, Eric C. Martens, G. Douglas Inglis, Richard E. R. Uwiera, Alisdair B. Boraston, and D. Wade Abbott

Subjects

Science

Abstract

Polysaccharides are the primary structural cell wall and energy storage molecules of seaweed. Here, the authors show how the geographically restricted dietary polysaccharide agarose is selectively utilized by the human intestinal bacterium Bacteroides uniformis, providing insight into how carbohydrate metabolism evolves within the human microbiome.

Published

2018

20. SACCHARIS: an automated pipeline to streamline discovery of carbohydrate active enzyme activities within polyspecific families and de novo sequence datasets

Author

Darryl R. Jones, Dallas Thomas, Nicholas Alger, Ata Ghavidel, G. Douglas Inglis, and D. Wade Abbott

Subjects

Carbohydrate active enzyme, Carbohydrate, Phylogeny, Enzyme discovery, Bioprocessing, Fuel, TP315-360, Biotechnology, TP248.13-248.65

Abstract

Abstract Background Deposition of new genetic sequences in online databases is expanding at an unprecedented rate. As a result, sequence identification continues to outpace functional characterization of carbohydrate active enzymes (CAZymes). In this paradigm, the discovery of enzymes with novel functions is often hindered by high volumes of uncharacterized sequences particularly when the enzyme sequence belongs to a family that exhibits diverse functional specificities (i.e., polyspecificity). Therefore, to direct sequence-based discovery and characterization of new enzyme activities we have developed an automated in silico pipeline entitled: Sequence Analysis and Clustering of CarboHydrate Active enzymes for Rapid Informed prediction of Specificity (SACCHARIS). This pipeline streamlines the selection of uncharacterized sequences for discovery of new CAZyme or CBM specificity from families currently maintained on the CAZy website or within user-defined datasets. Results SACCHARIS was used to generate a phylogenetic tree of a GH43, a CAZyme family with defined subfamily designations. This analysis confirmed that large datasets can be organized into sequence clusters of manageable sizes that possess related functions. Seeding this tree with a GH43 sequence from Bacteroides dorei DSM 17855 (BdGH43b, revealed it partitioned as a single sequence within the tree. This pattern was consistent with it possessing a unique enzyme activity for GH43 as BdGH43b is the first described α-glucanase described for this family. The capacity of SACCHARIS to extract and cluster characterized carbohydrate binding module sequences was demonstrated using family 6 CBMs (i.e., CBM6s). This CBM family displays a polyspecific ligand binding profile and contains many structurally determined members. Using SACCHARIS to identify a cluster of divergent sequences, a CBM6 sequence from a unique clade was demonstrated to bind yeast mannan, which represents the first description of an α-mannan binding CBM. Additionally, we have performed a CAZome analysis of an in-house sequenced bacterial genome and a comparative analysis of B. thetaiotaomicron VPI-5482 and B. thetaiotaomicron 7330, to demonstrate that SACCHARIS can generate “CAZome fingerprints”, which differentiate between the saccharolytic potential of two related strains in silico. Conclusions Establishing sequence-function and sequence-structure relationships in polyspecific CAZyme families are promising approaches for streamlining enzyme discovery. SACCHARIS facilitates this process by embedding CAZyme and CBM family trees generated from biochemically to structurally characterized sequences, with protein sequences that have unknown functions. In addition, these trees can be integrated with user-defined datasets (e.g., genomics, metagenomics, and transcriptomics) to inform experimental characterization of new CAZymes or CBMs not currently curated, and for researchers to compare differential sequence patterns between entire CAZomes. In this light, SACCHARIS provides an in silico tool that can be tailored for enzyme bioprospecting in datasets of increasing complexity and for diverse applications in glycobiotechnology.

Published

2018

21. Expeller-Pressed Canola (Brassica napus) Meal Modulates the Structure and Function of the Cecal Microbiota, and Alters the Metabolome of the Pancreas, Liver, and Breast Muscle of Broiler Chickens

Author

G. Douglas Inglis, Benjamin D. Wright, Stephanie A. Sheppard, D. Wade Abbott, Matt A. Oryschak, and Tony Montina

Subjects

broiler chickens, canola meal, cecum, microbiota, pancreas, liver, Veterinary medicine, SF600-1100, Zoology, QL1-991

Abstract

The inoculation of one-day-old broiler chicks with the cecal contents from a mature broiler breeder resulted in a highly diverse and uniform cecal bacterial community. CM did not affect feed consumption, weight gain, nor the richness, evenness, or diversity of the cecal bacterial community. However, the structure of the bacterial community was altered in birds fed the CM diet. Although the CM diet was formulated to contain equivalent metabolizable energy to the control diet, it contained more dietary fiber. The abundance of bacterial families, including those that are known to contain species able to metabolize fiber was altered (e.g., bacteria within the families, Methanobacteriaceae, Atopobiaceae, Prevotellaceae, Clostridiales Family XIII, Peptostreptococcaceae, and Succinivibrionaceae), and concentrations of SCFAs were higher in the ceca of birds fed the CM diet. Moreover, concentrations of isoleucine, isobutyrate, glutamate, and 2-oxoglutarate were higher, whereas concentrations of phenyllactic acid, indole, glucose, 3-phenylpropionate, and 2-oxobutyrate were lower in the digesta of chickens that were fed CM. The metabolic profiles of pancreas, liver, and breast muscle tissues of birds fed the CM diet differed from control birds. Metabolites that were associated with energy production, protection against oxidative stress, and pathways of amino acid and glycerophospholipid metabolism had altered concentrations in these tissues. Some of the observed changes in metabolite levels may indicate an increased disease risk in birds fed the CM diet (e.g., pancreatitis), and others suggested that birds mounted metabolic response to offset the adverse impacts of CM (e.g., oxidative stress in the liver).

Published

2021

22. Seaweed and Seaweed Bioactives for Mitigation of Enteric Methane: Challenges and Opportunities

Author

D. Wade Abbott, Inga Marie Aasen, Karen A. Beauchemin, Fredrik Grondahl, Robert Gruninger, Maria Hayes, Sharon Huws, David A. Kenny, Sophie J. Krizsan, Stuart F. Kirwan, Vibeke Lind, Ulrich Meyer, Mohammad Ramin, Katerina Theodoridou, Dirk von Soosten, Pamela J. Walsh, Sinéad Waters, and Xiaohui Xing

Subjects

methane emissions, rumen, ruminants, seaweeds, bioactive components, bromoform, Veterinary medicine, SF600-1100, Zoology, QL1-991

Abstract

Seaweeds contain a myriad of nutrients and bioactives including proteins, carbohydrates and to a lesser extent lipids as well as small molecules including peptides, saponins, alkaloids and pigments. The bioactive bromoform found in the red seaweed Asparagopsis taxiformis has been identified as an agent that can reduce enteric CH4 production from livestock significantly. However, sustainable supply of this seaweed is a problem and there are some concerns over its sustainable production and potential negative environmental impacts on the ozone layer and the health impacts of bromoform. This review collates information on seaweeds and seaweed bioactives and the documented impact on CH4 emissions in vitro and in vivo as well as associated environmental, economic and health impacts.

Published

2020

23. Combinatorial Glycomic Analyses to Direct CAZyme Discovery for the Tailored Degradation of Canola Meal Non-Starch Dietary Polysaccharides

Author

Kristin E. Low, Xiaohui Xing, Paul E. Moote, G. Douglas Inglis, Sivasankari Venketachalam, Michael G. Hahn, Marissa L. King, Catherine Y. Tétard-Jones, Darryl R. Jones, William G. T. Willats, Bogdan A. Slominski, and D. Wade Abbott

Subjects

canola meal, Brassica napus L., CAZymes, enzyme discovery, glycosidic linkage analysis, glycome profiling, Biology (General), QH301-705.5

Abstract

Canola meal (CM), the protein-rich by-product of canola oil extraction, has shown promise as an alternative feedstuff and protein supplement in poultry diets, yet its use has been limited due to the abundance of plant cell wall fibre, specifically non-starch polysaccharides (NSP) and lignin. The addition of exogenous enzymes to promote the digestion of CM NSP in chickens has potential to increase the metabolizable energy of CM. We isolated chicken cecal bacteria from a continuous-flow mini-bioreactor system and selected for those with the ability to metabolize CM NSP. Of 100 isolates identified, Bacteroides spp. and Enterococcus spp. were the most common species with these capabilities. To identify enzymes specifically for the digestion of CM NSP, we used a combination of glycomics techniques, including enzyme-linked immunosorbent assay characterization of the plant cell wall fractions, glycosidic linkage analysis (methylation-GC-MS analysis) of CM NSP and their fractions, bacterial growth profiles using minimal media supplemented with CM NSP, and the sequencing and de novo annotation of bacterial genomes of high-efficiency CM NSP utilizing bacteria. The SACCHARIS pipeline was used to select plant cell wall active enzymes for recombinant production and characterization. This approach represents a multidisciplinary innovation platform to bioprospect endogenous CAZymes from the intestinal microbiota of herbivorous and omnivorous animals which is adaptable to a variety of applications and dietary polysaccharides.

Published

2020

24. Butyrate Supplementation at High Concentrations Alters Enteric Bacterial Communities and Reduces Intestinal Inflammation in Mice Infected with Citrobacter rodentium

Author

Janelle A. Jiminez, Trina C. Uwiera, D. Wade Abbott, Richard R. E. Uwiera, and G. Douglas Inglis

Subjects

butyrate, Citrobacter rodentium, inflammation, intestine, mice, microbiota, Microbiology, QR1-502

Abstract

ABSTRACT Butyrate is a short-chain fatty acid by-product of the microbial fermentation of dietary fermentable materials in the large intestine; it is the main energy source for enterocyte regeneration, modulates the enteric microbial community, and contributes to increasing host health via mechanisms that are relatively poorly defined. Limited research has examined the therapeutic potential of butyrate using models of enteric inflammation incited by pathogenic organisms. We used Citrobacter rodentium to incite acute Th1/Th17 inflammation to ascertain the impact of butyrate on the host-microbiota relationship. Rectal administration of 140 mM butyrate to mice increased fecal concentrations of butyrate and increased food consumption and weight gain in mice infected with C. rodentium. Histological scores of colonic inflammation were lower in infected mice administered 140 mM butyrate. Expression of Il10, Tgfβ, and Muc2 was elevated in noninfected mice administered butyrate in comparison to mice not administered butyrate. Infected mice administered butyrate displayed elevated expression of genes necessary for pathogen clearance (i.e., Il17A and Il1β) and of genes involved in epithelial barrier repair and restoration (i.e., Relmβ, Tff3, and Myd88). Butyrate supplemented to inflamed colons increased the abundances of Proteobacteria and Lachnospiraceae and reduced the abundance of Clostridiaceae species. Mice with enteritis that were administered butyrate also exhibited an increased abundance of mucus-associated bacteria. In summary, rectal administration of butyrate increased feed consumption and weight gain, ameliorated C. rodentium-induced cell injury through enhanced expression of immune regulation and tissue repair mechanisms, and increased the abundance of butyrate-producing bacteria in mice with enteritis. IMPORTANCE The study findings provide evidence that administration of butyrate in a dose-dependent manner can increase weight gain in infected mice, enhance clearance of the infection, reduce inflammation through altered cytokine expression, and enhance tissue repair and mucus secretion. Moreover, butyrate treatment also affected the abundance of bacterial populations in both noninflamed and inflamed intestines. Notably, this investigation provides foundational information that can be used to determine the effects of prebiotics and other functional foods on the production of butyrate by enteric bacteria and their impact on intestinal health and host well-being.

Published

2017

25. A Genome-Wide Association Study to Identify Diagnostic Markers for Human Pathogenic Campylobacter jejuni Strains

Author

Cody J. Buchanan, Andrew L. Webb, Steven K. Mutschall, Peter Kruczkiewicz, Dillon O. R. Barker, Benjamin M. Hetman, Victor P. J. Gannon, D. Wade Abbott, James E. Thomas, G. Douglas Inglis, and Eduardo N. Taboada

Subjects

Campylobacter jejuni, genome sequence, genome-wide association study, clinical association, molecular marker discovery, linkage analysis, Microbiology, QR1-502

Abstract

Campylobacter jejuni is a leading human enteric pathogen worldwide and despite an improved understanding of its biology, ecology, and epidemiology, limited tools exist for identifying strains that are likely to cause disease. In the current study, we used subtyping data in a database representing over 24,000 isolates collected through various surveillance projects in Canada to identify 166 representative genomes from prevalent C. jejuni subtypes for whole genome sequencing. The sequence data was used in a genome-wide association study (GWAS) aimed at identifying accessory gene markers associated with clinically related C. jejuni subtypes. Prospective markers (n = 28) were then validated against a large number (n = 3,902) of clinically associated and non-clinically associated genomes from a variety of sources. A total of 25 genes, including six sets of genetically linked genes, were identified as robust putative diagnostic markers for clinically related C. jejuni subtypes. Although some of the genes identified in this study have been previously shown to play a role in important processes such as iron acquisition and vitamin B5 biosynthesis, others have unknown function or are unique to the current study and warrant further investigation. As few as four of these markers could be used in combination to detect up to 90% of clinically associated isolates in the validation dataset, and such markers could form the basis for a screening assay to rapidly identify strains that pose an increased risk to public health. The results of the current study are consistent with the notion that specific groups of C. jejuni strains of interest are defined by the presence of specific accessory genes.

Published

2017

26. Erratum to: The nasopharyngeal microbiota of beef cattle before and after transport to a feedlot

Author

Devin B. Holman, Edouard Timsit, Samat Amat, D. Wade Abbott, Andre G. Buret, and Trevor W. Alexander

Subjects

Microbiology, QR1-502

Published

2017

27. Metabolism of a hybrid algal galactan by members of the human gut microbiome

Author

Craig S. Robb, Joanne K. Hobbs, Benjamin Pluvinage, Greta Reintjes, Leeann Klassen, Stephanie Monteith, Greta Giljan, Carolyn Amundsen, Chelsea Vickers, Andrew G. Hettle, Rory Hills, null Nitin, Xiaohui Xing, Tony Montina, Wesley F. Zandberg, D. Wade Abbott, and Alisdair B. Boraston

Subjects

Cell Biology, Molecular Biology

Abstract

Native porphyran is a hybrid of porphryan and agarose. As a common element of edible seaweed, this algal galactan is a frequent component of the human diet. Bacterial members of the human gut microbiota have acquired polysaccharide utilization loci (PULs) that enable the metabolism of porphyran or agarose. However, the molecular mechanisms that underlie the deconstruction and use of native porphyran remains incompletely defined. Here, we have studied two human gut bacteria, porphyranolytic Bacteroides plebeius and agarolytic Bacteroidesuniformis, that target native porphyran. This reveals an exo-based cycle of porphyran depolymerization that incorporates a keystone sulfatase. In both PULs this cycle also works together with a PUL-encoded agarose depolymerizing machinery to synergistically reduce native porphyran to monosaccharides. This provides a framework for understanding the deconstruction of a hybrid algal galactan, and insight into the competitive and/or syntrophic relationship of gut microbiota members that target rare nutrients.

Published

2022

28. Glycogen-Degrading Activities of Catalytic Domains of α-Amylase and α-Amylase-Pullulanase Enzymes Conserved in Gardnerella spp. from the Vaginal Microbiome

Author

Pashupati Bhandari, Jeffrey Tingley, D. Wade Abbott, and Janet E. Hill

Subjects

Molecular Biology, Microbiology

Abstract

Increased abundance of Gardnerella spp. is a diagnostic characteristic of bacterial vaginosis, an imbalance in the human vaginal microbiome associated with troubling symptoms, and negative reproductive health outcomes, including increased transmission of sexually transmitted infections and preterm birth. Competition for nutrients is likely an important factor in causing dramatic shifts in the vaginal microbial community, but little is known about the contribution of bacterial enzymes to the metabolism of glycogen, a major food source available to vaginal bacteria.

Published

2023

29. Visualization of Carbohydrate Uptake Using Fluorescent Polysaccharides

Author

Greta Reintjes, Leeann Klassen, and D. Wade Abbott

Published

2023

30. Glycogen degrading activities of catalytic domains of α-amylase and α-amylase-pullulanase enzymes conserved inGardnerellaspp. from the vaginal microbiome

Author

Pashupati Bhandari, Jeffrey Tingley, D. Wade Abbott, and Janet E. Hill

Abstract

Gardnerellaspp. are associated with bacterial vaginosis, in which normally dominant lactobacilli are replaced with facultative and anaerobic bacteria includingGardnerellaspp. Co-occurrence of multiple species ofGardnerellais common in the vagina and competition for nutrients such as glycogen likely contributes to the differential abundances ofGardnerellaspp. Glycogen must be digested into smaller components for uptake; a process that depends on the combined action of glycogen degrading enzymes. In this study, the ability of culture supernatants of 15 isolates ofGardnerellaspp. to produce glucose, maltose, maltotriose and maltotetraose from glycogen was demonstrated. Carbohydrate active enzymes were identified bioinformatically inGardnerellaproteomes using dbCAN2. Identified proteins included a single domain α-amylase (EC 3.2.1.1) (encoded by all 15 isolates) and an α-amylase-pullulanase (EC 3.2.1.41) containing amylase, carbohydrate binding modules and pullulanase domains (14/15 isolates). To verify the sequence-based functional predictions, the amylase and pullulanase domains of the α-amylase-pullulanase, and the single domain α-amylase were each produced inE. coli. The α-amylase domain from the α-amylase-pullulanase released maltose, maltotriose and maltotetraose from glycogen, and the pullulanase domain released maltotriose from pullulan and maltose from glycogen, demonstrating that theGardnerellaα-amylase-pullulanase is capable of hydrolyzing α-1,4 and α-1,6 glycosidic bonds. Similarly, the single domain α-amylase protein also produced maltose, maltotriose and maltotetraose from glycogen. Our findings show thatGardnerellaspp. produce extracellular amylase enzymes as ‘public goods’ that can digest glycogen into maltose, maltotriose and maltotetraose that can be used by the vaginal microbiota.ImportanceIncreased abundance ofGardnerellaspp. is a diagnostic characteristic of bacterial vaginosis, an imbalance in the human vaginal microbiome associated with troubling symptoms, and negative reproductive health outcomes, including increased transmission of sexually transmitted infections and preterm birth. Competition for nutrients is likely an important factor in causing dramatic shifts in the vaginal microbial community but little is known about the contribution of bacterial enzymes to the metabolism of glycogen, a major food source available to vaginal bacteria. The significance of our research is characterizing the activity of enzymes conserved inGardnerellaspecies that contribute to the ability of these bacteria to utilize glycogen.

Published

2022

31. Quantifying fluorescent glycan uptake to elucidate strain-level variability in foraging behaviors of rumen bacteria

Author

Carol Arnosti, D. Wade Abbott, Adam D. Smith, Tim A. McAllister, Trevor W. Alexander, Timothy Schwinghamer, Jan-Hendrik Hehemann, Rudolf Amann, Dallas Thomas, Darryl R. Jones, Jeffrey P Tingley, Carolyn Amundsen, Greta Reintjes, Leeann Klassen, and L. Jin

Subjects

Microbiology (medical), Glycan, Carbohydrate, Rumen, medicine.medical_treatment, Foraging, Computational biology, Microbiology, Genome, Fluorescence, lcsh:Microbial ecology, 03 medical and health sciences, Microbial ecology, Polysaccharides, medicine, Animals, Bacteroides, Microbiome, 030304 developmental biology, Fluorescent Dyes, 2. Zero hunger, 0303 health sciences, biology, Bacteria, 030306 microbiology, Fluorescent polysaccharides, Prebiotic, Research, biology.organism_classification, Gastrointestinal Microbiome, Yeast mannan, Metabolic pathway, Metagenomics, Glycoside hydrolase, biology.protein, lcsh:QR100-130, Cattle, Bacteroides thetaiotaomicron

Abstract

Gut microbiomes, such as the microbial community that colonizes the rumen, have vast catabolic potential and play a vital role in host health and nutrition. By expanding our understanding of metabolic pathways in these ecosystems, we will garner foundational information for manipulating microbiome structure and function to influence host physiology. Currently, our knowledge of metabolic pathways relies heavily on inferences derived from metagenomics or culturing bacteria in vitro. However, novel approaches targeting specific cell physiologies can illuminate the functional potential encoded within microbial (meta)genomes to provide accurate assessments of metabolic abilities. Using fluorescently labeled polysaccharides, we visualized carbohydrate metabolism performed by single bacterial cells in a complex rumen sample, enabling a rapid assessment of their metabolic phenotype. Specifically, we identified bovine-adapted strains of Bacteroides thetaiotaomicron that metabolized yeast mannan in the rumen microbiome ex vivo and discerned the mechanistic differences between two distinct carbohydrate foraging behaviors, referred to as “medium grower” and “high grower.” Using comparative whole-genome sequencing, RNA-seq, and carbohydrate-active enzyme fingerprinting, we could elucidate the strain-level variability in carbohydrate utilization systems of the two foraging behaviors to help predict individual strategies of nutrient acquisition. Here, we present a multi-faceted study using complimentary next-generation physiology and “omics” approaches to characterize microbial adaptation to a prebiotic in the rumen ecosystem. Video abstract Supplementary Information The online version contains supplementary material available at 10.1186/s40168-020-00975-x.

Published

2021

32. Structural compositions and biological activities of cell wall polysaccharides in the rhizome, stem, and leaf of Polygonatum odoratum (Mill.) Druce

Author

Jing Li, Shih-Yi Hsiung, Mu-Rong Kao, Xiaohui Xing, Shu-Chieh Chang, Damao Wang, Pei-Yun Hsieh, Pi-Hui Liang, Zaibiao Zhu, Ting-Jen Rachel Cheng, Jiun-Jie Shie, Jing-Ping Liou, D. Wade Abbott, Sung Won Kwon, and Yves S.Y. Hsieh

Subjects

Plant Extracts, Organic Chemistry, Polygonatum, Livsmedelsvetenskap, Granulocyte-Macrophage Colony-Stimulating Factor, Water, General Medicine, Plants, Farmaceutiska vetenskaper, Biochemistry, MALDI-TOF-MS, Analytical Chemistry, Plant Leaves, Pharmaceutical Sciences, Mice, Cell Wall, Polysaccharides, Granulocyte Colony-Stimulating Factor, Animals, GC-MS, HPAEC-PAD, Linkage analysis, Rhizome, Food Science

Abstract

Polygonatum odoratum is a perennial rhizomatous medicinal plant and different plant parts have been used in the treatment of various ailments. Herein, we have investigated the structural compositions of rhizome, leaf, and stem cell walls. We found 30–44% of polysaccharides in these wall preparations were cyclohexanediaminetetraacetic acid (CDTA) extractable, the proportion of heteromannans (HMs) in the rhizome is nearly three-fold compared to that of the leave and stem. The pectic polysaccharides of the rhizome are also structurally more diverse, with arabinans and type I and type II arabinogalactans being richest as shown by linkage study of the sodium carbonate (Na2CO3) extract. In addition, the 2-linked Araf was rhizome-specific, suggesting the cell walls in the rhizome had adapted to a more complex structure compared to that of the leaf and stem. Water-soluble polysaccharide fractions were also investigated, high proportion of Man as in 4-linked Manp indicated high proportion of HMs. The 21.4 kDa pectic polysaccharides and HMs derived from rhizome cell walls induced specific immune response in mice macrophage cells producing IL-1α and hematopoietic growth factors GM-CSF and G-CSF in vitro. QC 20221012

Published

2022

33. Dissecting the Pyrenophora tritici-repentis (tan spot of wheat) pangenome

Author

Ryan Gourlie, Megan McDonald, Mohamed Hafez, Rodrigo Ortega-Polo, Kristin E. Low, D. Wade Abbott, Stephen E. Strelkov, Fouad Daayf, and Reem Aboukhaddour

Abstract

We sequenced the genome of a global collection (40 isolates) of the fungus Pyrenophora tritici-repentis (Ptr), a major foliar pathogen of wheat and model for the evolution of necrotrophic pathogens. Ptr exhibited an open-pangenome, with 43% of genes in the core set and 57% defined as accessory (present in only a subset of isolates), of which 56% were singleton genes (present in only one isolate). A clear distinction between pathogenic and non-pathogenic genomes was observed in size, gene content, and phylogenetic relatedness. Chromosomal rearrangements and structural organization, specifically around the effector coding genes, were explored further using the annotated genomes of two isolates sequenced by PacBio RS II and Illumina HiSeq. The Ptr genome exhibited major chromosomal rearrangements, including chromosomal fusion, translocation, and segment duplications. An intraspecies translocation of ToxA, the necrosis-inducing effector-coding gene, was facilitated within Ptr via a 143 kb ‘Starship’ transposon (dubbed ‘Horizon’). Additionally, ToxB, the gene encoding the chlorosis-inducing effector, was clustered as three copies on a 294 kb transposable element in a ToxB-producing isolate. ToxB and its carrying transposon were missing from the ToxB non-coding reference isolate, but the homolog toxb and the transposon were both present in another non-coding isolate. The Ptr genome also appears to exhibit a ‘one-compartment’ organization, but may still possess a ‘two-speed genome’ that is facilitated by copy-number variation as reported in other fungal pathosystems.IMPORTANCEPtr is one of the most destructive wheat pathogens worldwide. Its genome is a mosaic of present and absent effectors, and serves as a model for examining the evolutionary processes behind the acquisition of virulence in necrotrophs and disease emergence. In this work, we took advantage of a diverse collection of pathogenic Ptr isolates with different global origins and applied short- and long-read sequencing technologies to dissect the Ptr genome. This study provides comprehensive insights into the Ptr genome and highlights its structural organization as an open pangenome with ‘one-compartment’. In addition, we identified the potential involvement of transposable elements in genome expansion and the movement of virulence factors. The ability of effector-coding genes to shuffle across chromosomes on large transposons was illustrated by the intraspecies translocation of ToxA and the multi-copy ToxB. In terms of gene contents, the Ptr genome exhibits a large percentage of orphan genes, particularly in non-pathogenic or weakly-virulent isolates.

Published

2022

34. Diverse events have transferred genes for edible seaweed digestion from marine to human gut bacteria

Author

Nicholas A. Pudlo, Gabriel Vasconcelos Pereira, Jaagni Parnami, Melissa Cid, Stephanie Markert, Jeffrey P. Tingley, Frank Unfried, Ahmed Ali, Neha J. Varghese, Kwi S. Kim, Austin Campbell, Karthik Urs, Yao Xiao, Ryan Adams, Duña Martin, David N. Bolam, Dörte Becher, Emiley A. Eloe-Fadrosh, Thomas M. Schmidt, D. Wade Abbott, Thomas Schweder, Jan Hendrik Hehemann, and Eric C. Martens

Subjects

human gut microbiome, Bacteria, Immunology, Seaweed, lateral gene transfer, Microbiology, Article, Gastrointestinal Microbiome, Polysaccharides, Medical Microbiology, Virology, Humans, Bacteroides, Parasitology, Digestion, polysaccharide metabolism, Life Below Water, Nutrition

Abstract

Humans harbor numerous species of colonic bacteria that digest fiber polysaccharides in commonly consumed terrestrial plants. More recently in history, regional populations have consumed edible macroalgae seaweeds containing unique polysaccharides. It remains unclear how extensively gut bacteria have adapted to digest these nutrients. Here, we show that the ability of gut bacteria to digest seaweed polysaccharides is more pervasive than previously appreciated. Enrichment-cultured Bacteroides harbor previously discovered genes for seaweed degradation, which have mobilized into several members of this genus. Additionally, other examples of marine bacteria-derived genes, and their mobile DNA elements, are involved in gut microbial degradation of seaweed polysaccharides, including genes in gut-resident Firmicutes. Collectively, these results uncover multiple separate events that have mobilized the genes encoding seaweed degrading-enzymes into gut bacteria. This work further underscores the metabolic plasticity of the human gut microbiome and global exchange of genes in the context of dietary selective pressures.

Published

2022

35. Glycoside hydrolase from the GH76 family indicates that marine Salegentibacter sp. Hel_I_6 consumes alpha-mannan from fungi

Author

Vipul Solanki, Karen Krüger, Conor J. Crawford, Alonso Pardo-Vargas, José Danglad-Flores, Kim Le Mai Hoang, Leeann Klassen, D. Wade Abbott, Peter H. Seeberger, Rudolf I. Amann, Hanno Teeling, and Jan-Hendrik Hehemann

Subjects

Mannans, Glycoside Hydrolases, Bacteroidetes, ddc:570, Fungi, Humans, Microbiology, Ecosystem, Ecology, Evolution, Behavior and Systematics

Abstract

Seminar, Bremen, Germany; The ISME journal 16(7), 1818 - 1830 (2022). doi:10.1038/s41396-022-01223-w, Microbial glycan degradation is essential to global carbon cycling. The marine bacterium Salegentibacter sp. Hel_I_6 (Bacteroidota) isolated from seawater off Helgoland island (North Sea) contains an α-mannan inducible gene cluster with a GH76 family endo-α-1,6-mannanase (ShGH76). This cluster is related to genetic loci employed by human gut bacteria to digest fungal α-mannan. Metagenomes from the Hel_I_6 isolation site revealed increasing GH76 gene frequencies in free-living bacteria during microalgae blooms, suggesting degradation of α-1,6-mannans from fungi. Recombinant ShGH76 protein activity assays with yeast α-mannan and synthetic oligomannans showed endo-α-1,6-mannanase activity. Resolved structures of apo-ShGH76 (2.0 Å) and of mutants co-crystalized with fungal mannan-mimicking α-1,6-mannotetrose (1.90 Å) and α-1,6-mannotriose (1.47 Å) retained the canonical (α/α)6 fold, despite low identities with sequences of known GH76 structures (GH76s from gut bacteria, Published by Nature Publishing Group, Basingstoke

Published

2022

36. Corticosterone-mediated physiological stress modulates hepatic lipid metabolism, metabolite profiles, and systemic responses in chickens

Author

Richard R. E. Uwiera, Gerlinde A. S. Metz, Catherine L. J. Brown, D. Wade Abbott, Sarah J. M. Zaytsoff, G. Douglas Inglis, and Tony Montina

Subjects

0301 basic medicine, medicine.medical_specialty, endocrine system, Anabolism, Metabolite, lcsh:Medicine, Biology, Article, Avian Proteins, 03 medical and health sciences, chemistry.chemical_compound, Corticosterone, Stress, Physiological, Internal medicine, Animal physiology, medicine, Metabolome, polycyclic compounds, Metabolomics, Animals, Bursa of Fabricius, lcsh:Science, Multidisciplinary, Lipogenesis, lcsh:R, 0402 animal and dairy science, Lipid metabolism, 04 agricultural and veterinary sciences, Metabolism, 040201 dairy & animal science, 030104 developmental biology, Endocrinology, chemistry, Gene Expression Regulation, Liver, lcsh:Q, Fat metabolism, Chickens, hormones, hormone substitutes, and hormone antagonists

Abstract

The impact of physiological stress on lipid metabolism, the metabolome, and systemic responses was examined in chickens. To incite a stress response, birds were continuously administered corticosterone (CORT) in their drinking water at three doses (0 mg/L, 10 mg/L, and 30 mg/L), and they were sampled 1, 5, and 12 days after commencement of CORT administration. Corticosterone administration to birds differentially regulated lipogenesis genes (i.e. FAS, ACC, ME, and SREBF1), and histopathological examination indicated lipid deposition in hepatocytes. In addition, CORT affected water-soluble metabolite profiles in the liver, as well as in kidney tissue and breast muscle; thirteen unique metabolites were distinguished in CORT-treated birds and this was consistent with the dysregulation of lipid metabolism due to physiological stress. Acute phase responses (APRs) were also altered by CORT, and in particular, expression of SAA1 was decreased and expression of CP was increased. Furthermore, CORT administration caused lymphoid depletion in the bursa of Fabricius and elevated IL6 and TGFβ2 mRNA expression after 5 and 12 days of CORT administration. Collectively, incitement of physiological stress via administration of CORT in chickens modulated host metabolism and systemic responses, which indicated that energy potentials are diverted from muscle anabolism during periods of stress.

Published

2019

37. Construction of a highly selective and sensitive carbohydrate-detecting biosensor utilizing Computational Identification of Non-disruptive Conjugation sites (CINC) for flexible and streamlined biosensor design

Author

Dustin D. Smith, Dylan Girodat, D. Wade Abbott, and Hans-Joachim Wieden

Subjects

0303 health sciences, Biomedical Engineering, Biophysics, Carbohydrates, General Medicine, Biosensing Techniques, 010402 general chemistry, Ligands, 01 natural sciences, 0104 chemical sciences, 03 medical and health sciences, Spectrometry, Fluorescence, Electrochemistry, 030304 developmental biology, Biotechnology, Fluorescent Dyes

Abstract

Fluorescently-labeled solute-binding proteins that alter their fluorescence output in response to ligand binding have been utilized as biosensors for a variety of applications. Coupling protein ligand binding to altered fluorescence output often requires trial and error-based testing of both multiple labeling positions and fluorophores to produce a functional biosensor with the desired properties. This approach is laborious and can lead to reduced ligand binding affinity or altered ligand specificity. Here we report the Computational Identification of Non-disruptive Conjugation sites (CINC) for streamlined identification of fluorophore conjugation sites. By exploiting the structural dynamics properties of proteins, CINC identifies positions where conjugation of a fluorophore results in a fluorescence change upon ligand binding without disrupting protein function. We show that a CINC-developed maltooligosaccharide (MOS)-detecting biosensor is capable of rapid (k

Published

2021

38. Characterization of an α-Glucosidase Enzyme Conserved in Gardnerella spp. Isolated from the Human Vaginal Microbiome

Author

D. Wade Abbott, Pashupati Bhandari, David R. J. Palmer, Janet E. Hill, and Jeffrey P Tingley

Subjects

0303 health sciences, CAZy, biology, Glycogen, 030306 microbiology, Maltose, biology.organism_classification, medicine.disease, Microbiology, 03 medical and health sciences, chemistry.chemical_compound, chemistry, Gardnerella, biology.protein, medicine, Glycoside hydrolase, Amylase, Bacterial vaginosis, Molecular Biology, Bacteria, 030304 developmental biology

Abstract

Gardnerella spp. in the vaginal microbiome are associated with bacterial vaginosis, in which a lactobacillus-dominated community is replaced with mixed bacteria, including Gardnerella species. Co-occurrence of multiple Gardnerella species in the vaginal environment is common, but different species are dominant in different women. Competition for nutrients, including glycogen, could play an important role in determining the microbial community structure. Digestion of glycogen into products that can be taken up and further processed by bacteria requires the combined activities of several enzymes collectively known as amylases, which belong to glycoside hydrolase family 13 (GH13) within the CAZy classification system. GH13 is a large and diverse family of proteins, making prediction of their activities challenging. SACCHARIS annotation of the GH13 family in Gardnerella resulted in identification of protein domains belonging to eight subfamilies. Phylogenetic analysis of predicted amylase sequences from 26 genomes demonstrated that a putative α-glucosidase-encoding sequence, CG400_06090, was conserved in all Gardnerella spp. The predicted α-glucosidase enzyme was expressed, purified, and functionally characterized. The enzyme was active on a variety of maltooligosaccharides with maximum activity at pH 7. Km, kcat, and kcat/Km values for the substrate 4-nitrophenyl α-d-glucopyranoside were 8.3 μM, 0.96 min-1, and 0.11 μM-1 min-1, respectively. Glucose was released from maltose, maltotriose, maltotetraose, and maltopentaose, but no products were detected when the enzyme was incubated with glycogen. Our findings show that Gardnerella spp. produce an α-glucosidase enzyme that may contribute to the multistep process of glycogen metabolism by releasing glucose from maltooligosaccharides. IMPORTANCE Increased abundance of Gardnerella spp. is a diagnostic characteristic of bacterial vaginosis, an imbalance in the human vaginal microbiome associated with troubling symptoms, and negative reproductive health outcomes, including increased transmission of sexually transmitted infections and preterm birth. Competition for nutrients is likely an important factor in causing dramatic shifts in the vaginal microbial community but little is known about the contribution of bacterial enzymes to the metabolism of glycogen, a major carbon source available to vaginal bacteria. The significance of our research is characterizing the activity of an enzyme conserved in Gardnerella species that likely contributes to the ability of these bacteria to utilize glycogen.

Published

2021

39. Characterization of an α-Glucosidase Enzyme Conserved in

Author

Pashupati, Bhandari, Jeffrey P, Tingley, David R J, Palmer, D Wade, Abbott, and Janet E, Hill

Subjects

Gardnerella, Microbiota, Temperature, alpha-Glucosidases, Hydrogen-Ion Concentration, Kinetics, Bacterial Proteins, Enzyme Stability, Vagina, Humans, Female, Amino Acid Sequence, Sequence Alignment, Phylogeny, Research Article

Abstract

Gardnerella spp. in the vaginal microbiome are associated with bacterial vaginosis, in which a lactobacillus-dominated community is replaced with mixed bacteria, including Gardnerella species. Co-occurrence of multiple Gardnerella species in the vaginal environment is common, but different species are dominant in different women. Competition for nutrients, including glycogen, could play an important role in determining the microbial community structure. Digestion of glycogen into products that can be taken up and further processed by bacteria requires the combined activities of several enzymes collectively known as amylases, which belong to glycoside hydrolase family 13 (GH13) within the CAZy classification system. GH13 is a large and diverse family of proteins, making prediction of their activities challenging. SACCHARIS annotation of the GH13 family in Gardnerella resulted in identification of protein domains belonging to eight subfamilies. Phylogenetic analysis of predicted amylase sequences from 26 genomes demonstrated that a putative α-glucosidase-encoding sequence, CG400_06090, was conserved in all Gardnerella spp. The predicted α-glucosidase enzyme was expressed, purified, and functionally characterized. The enzyme was active on a variety of maltooligosaccharides with maximum activity at pH 7. K(m), k(cat), and k(cat)/K(m) values for the substrate 4-nitrophenyl α-d-glucopyranoside were 8.3 μM, 0.96 min(−1), and 0.11 μM(−1) min(−1), respectively. Glucose was released from maltose, maltotriose, maltotetraose, and maltopentaose, but no products were detected when the enzyme was incubated with glycogen. Our findings show that Gardnerella spp. produce an α-glucosidase enzyme that may contribute to the multistep process of glycogen metabolism by releasing glucose from maltooligosaccharides. IMPORTANCE Increased abundance of Gardnerella spp. is a diagnostic characteristic of bacterial vaginosis, an imbalance in the human vaginal microbiome associated with troubling symptoms, and negative reproductive health outcomes, including increased transmission of sexually transmitted infections and preterm birth. Competition for nutrients is likely an important factor in causing dramatic shifts in the vaginal microbial community but little is known about the contribution of bacterial enzymes to the metabolism of glycogen, a major carbon source available to vaginal bacteria. The significance of our research is characterizing the activity of an enzyme conserved in Gardnerella species that likely contributes to the ability of these bacteria to utilize glycogen.

Published

2021

40. Erratum to: Predicted Input of Uncultured Fungal Symbionts to a Lichen Symbiosis from Metagenome-Assembled Genomes

Author

David Díaz-Escandón, Gulnara Tagirdzhanova, Paul Saary, Robert D. Finn, Toby Spribille, D. Wade Abbott, and Jeffrey P Tingley

Subjects

Genetics, Cystobasidiomycetes, Symbiosis, Metagenomics, Fungus, Biology, Tremellomycetes, biology.organism_classification, Lichen, Genome, Ecology, Evolution, Behavior and Systematics, Thallus

Abstract

Basidiomycete yeasts have recently been reported as stably associated secondary fungal symbionts of many lichens, but their role in the symbiosis remains unknown. Attempts to sequence their genomes have been hampered both by the inability to culture them and their low abundance in the lichen thallus alongside two dominant eukaryotes (an ascomycete fungus and chlorophyte alga). Using the lichen Alectoria sarmentosa, we selectively dissolved the cortex layer in which secondary fungal symbionts are embedded to enrich yeast cell abundance and sequenced DNA from the resulting slurries as well as bulk lichen thallus. In addition to yielding a near-complete genome of the filamentous ascomycete using both methods, metagenomes from cortex slurries yielded a 36- to 84-fold increase in coverage and near-complete genomes for two basidiomycete species, members of the classes Cystobasidiomycetes and Tremellomycetes. The ascomycete possesses the largest gene repertoire of the three. It is enriched in proteases often associated with pathogenicity and harbors the majority of predicted secondary metabolite clusters. The basidiomycete genomes possess ∼35% fewer predicted genes than the ascomycete and have reduced secretomes even compared with close relatives, while exhibiting signs of nutrient limitation and scavenging. Furthermore, both basidiomycetes are enriched in genes coding for enzymes producing secreted acidic polysaccharides, representing a potential contribution to the shared extracellular matrix. All three fungi retain genes involved in dimorphic switching, despite the ascomycete not being known to possess a yeast stage. The basidiomycete genomes are an important new resource for exploration of lifestyle and function in fungal-fungal interactions in lichen symbioses.

Published

2021

41. Engineering dual-glycan responsive expression systems for tunable production of heterologous proteins in Bacteroides thetaiotaomicron

Author

Richard McLean, Darryl R. Jones, Carolyn Amundsen, Brent Selinger, G. Douglas Inglis, Marshall B. Smith, Julie M. Grondin, and D. Wade Abbott

Subjects

0301 basic medicine, Glycan, Glycoside Hydrolases, Expression systems, Transgene, Genetic Vectors, 030106 microbiology, lcsh:Medicine, Molecular cloning, Article, 03 medical and health sciences, Polysaccharides, Arabinogalactan, Gene Order, Humans, Luciferase, Transgenes, Promoter Regions, Genetic, lcsh:Science, Regulation of gene expression, Multidisciplinary, biology, Chemistry, lcsh:R, Gene Expression Regulation, Bacterial, Chromosomes, Bacterial, biology.organism_classification, Recombinant Proteins, Cell biology, Bacteroides thetaiotaomicron, 030104 developmental biology, Gene Targeting, biology.protein, lcsh:Q, Bacteroides, Genetic Engineering, Microbial genetics, Plasmids

Abstract

Genetically engineering intestinal bacteria, such as Bacteroides thetaiotaomicron (B. theta), holds potential for creating new classes of biological devices, such as diagnostics or therapeutic delivery systems. Here, we have developed a series of B. theta strains that produce functional transgenic enzymes in response to dextran and arabinogalactan, two chemically distinct glycans. Expression systems for single glycan induction, and a novel “dual-glycan” expression system, requiring the presence of both dextran and arabinogalactan, have been developed. In addition, we have created two different chromosomal integration systems and one episomal vector system, compatible with engineered recipient strains, to improve the throughput and flexibility of gene cloning, integration, and expression in B. theta. To monitor activity, we have demonstrated the functionality of two different transgenic enzymes: NanoLuc, a luciferase, and BuGH16C, an agarase from the human intestinal bacterium, Bacteroides uniforms NP1. Together this expression platform provides a new collection of glycan-responsive tools to improve the strength and fidelity of transgene expression in B. theta and provides proof-of-concept for engineering more complex multi-glycan expression systems.

Published

2019

42. Metabolism of a hybrid algal galactan by members of the human gut microbiome

Author

Craig S, Robb, Joanne K, Hobbs, Benjamin, Pluvinage, Greta, Reintjes, Leeann, Klassen, Stephanie, Monteith, Greta, Giljan, Carolyn, Amundsen, Chelsea, Vickers, Andrew G, Hettle, Rory, Hills, Nitin, Xiaohui, Xing, Tony, Montina, Wesley F, Zandberg, D Wade, Abbott, and Alisdair B, Boraston

Subjects

Bacteria, Polysaccharides, Sepharose, Humans, Galactans, Gastrointestinal Microbiome

Abstract

Native porphyran is a hybrid of porphryan and agarose. As a common element of edible seaweed, this algal galactan is a frequent component of the human diet. Bacterial members of the human gut microbiota have acquired polysaccharide utilization loci (PULs) that enable the metabolism of porphyran or agarose. However, the molecular mechanisms that underlie the deconstruction and use of native porphyran remains incompletely defined. Here, we have studied two human gut bacteria, porphyranolytic Bacteroides plebeius and agarolytic Bacteroides uniformis, that target native porphyran. This reveals an exo-based cycle of porphyran depolymerization that incorporates a keystone sulfatase. In both PULs this cycle also works together with a PUL-encoded agarose depolymerizing machinery to synergistically reduce native porphyran to monosaccharides. This provides a framework for understanding the deconstruction of a hybrid algal galactan, and insight into the competitive and/or syntrophic relationship of gut microbiota members that target rare nutrients.

Published

2021

43. Predicted Input of Uncultured Fungal Symbionts to a Lichen Symbiosis from Metagenome-Assembled Genomes

Author

Gulnara Tagirdzhanova, Paul Saary, Jeffrey P Tingley, David Díaz-Escandón, D Wade Abbott, Robert D Finn, and Toby Spribille

Subjects

0106 biological sciences, AcademicSubjects/SCI01140, Lichens, extracellular matrix, Secondary Metabolism, yeast, 01 natural sciences, 03 medical and health sciences, Ascomycota, Cell Wall, Genetics, Symbiosis, genome, Ecology, Evolution, Behavior and Systematics, 030304 developmental biology, Secretome, metagenomics, 0303 health sciences, Basidiomycota, AcademicSubjects/SCI01130, Fungal Polysaccharides, Metagenome, Lecanoromycetes, Genome, Fungal, Erratum, mycoparasite, Research Article, 010606 plant biology & botany

Abstract

Basidiomycete yeasts have recently been reported as stably associated secondary fungal symbionts of many lichens, but their role in the symbiosis remains unknown. Attempts to sequence their genomes have been hampered both by the inability to culture them and their low abundance in the lichen thallus alongside two dominant eukaryotes (an ascomycete fungus and chlorophyte alga). Using the lichen Alectoria sarmentosa, we selectively dissolved the cortex layer in which secondary fungal symbionts are embedded to enrich yeast cell abundance and sequenced DNA from the resulting slurries as well as bulk lichen thallus. In addition to yielding a near-complete genome of the filamentous ascomycete using both methods, metagenomes from cortex slurries yielded a 36- to 84-fold increase in coverage and near-complete genomes for two basidiomycete species, members of the classes Cystobasidiomycetes and Tremellomycetes. The ascomycete possesses the largest gene repertoire of the three. It is enriched in proteases often associated with pathogenicity and harbors the majority of predicted secondary metabolite clusters. The basidiomycete genomes possess ∼35% fewer predicted genes than the ascomycete and have reduced secretomes even compared with close relatives, while exhibiting signs of nutrient limitation and scavenging. Furthermore, both basidiomycetes are enriched in genes coding for enzymes producing secreted acidic polysaccharides, representing a potential contribution to the shared extracellular matrix. All three fungi retain genes involved in dimorphic switching, despite the ascomycete not being known to possess a yeast stage. The basidiomycete genomes are an important new resource for exploration of lifestyle and function in fungal–fungal interactions in lichen symbioses.

Published

2021

44. Combined whole cell wall analysis and streamlined in silico carbohydrate-active enzyme discovery to improve biocatalytic conversion of agricultural crop residues

Author

D. Wade Abbott, Xiaohui Xing, Kristin E. Low, and Jeffrey P Tingley

Subjects

0106 biological sciences, Crop residue, Crop residues, Bioconversion, lcsh:Biotechnology, Glycosidic linkage analysis, Biomass, Review, Management, Monitoring, Policy and Law, Raw material, complex mixtures, 01 natural sciences, Applied Microbiology and Biotechnology, lcsh:Fuel, 03 medical and health sciences, chemistry.chemical_compound, lcsh:TP315-360, lcsh:TP248.13-248.65, Lignin, Plant cell wall, Cellulose, Phylogeny, 030304 developmental biology, Carbohydrate-active enzyme, 0303 health sciences, Biomass conversion, Renewable Energy, Sustainability and the Environment, food and beverages, Functional genomics, Agriculture, Glycome, General Energy, chemistry, Biofuel, Biochemical engineering, 010606 plant biology & botany, Biotechnology

Abstract

The production of biofuels as an efficient source of renewable energy has received considerable attention due to increasing energy demands and regulatory incentives to reduce greenhouse gas emissions. Second-generation biofuel feedstocks, including agricultural crop residues generated on-farm during annual harvests, are abundant, inexpensive, and sustainable. Unlike first-generation feedstocks, which are enriched in easily fermentable carbohydrates, crop residue cell walls are highly resistant to saccharification, fermentation, and valorization. Crop residues contain recalcitrant polysaccharides, including cellulose, hemicelluloses, pectins, and lignin and lignin-carbohydrate complexes. In addition, their cell walls can vary in linkage structure and monosaccharide composition between plant sources. Characterization of total cell wall structure, including high-resolution analyses of saccharide composition, linkage, and complex structures using chromatography-based methods, nuclear magnetic resonance, -omics, and antibody glycome profiling, provides critical insight into the fine chemistry of feedstock cell walls. Furthermore, improving both the catalytic potential of microbial communities that populate biodigester reactors and the efficiency of pre-treatments used in bioethanol production may improve bioconversion rates and yields. Toward this end, knowledge and characterization of carbohydrate-active enzymes (CAZymes) involved in dynamic biomass deconstruction is pivotal. Here we overview the use of common “-omics”-based methods for the study of lignocellulose-metabolizing communities and microorganisms, as well as methods for annotation and discovery of CAZymes, and accurate prediction of CAZyme function. Emerging approaches for analysis of large datasets, including metagenome-assembled genomes, are also discussed. Using complementary glycomic and meta-omic methods to characterize agricultural residues and the microbial communities that digest them provides promising streams of research to maximize value and energy extraction from crop waste streams.

Published

2021

45. Expeller-Pressed Canola (

Author

D. Wade Abbott, Benjamin D. Wright, G. Douglas Inglis, Tony Montina, Matt A. Oryschak, and Stephanie A. Sheppard

Subjects

canola meal, Metabolite, Biology, medicine.disease_cause, liver, Article, Cecum, chemistry.chemical_compound, lcsh:Zoology, Metabolome, medicine, microbiota, Food science, lcsh:QL1-991, pancreas, broiler chickens, cecum, Meal, lcsh:Veterinary medicine, General Veterinary, Broiler, medicine.anatomical_structure, chemistry, lcsh:SF600-1100, Animal Science and Zoology, metabolome, medicine.symptom, Isoleucine, Weight gain, Oxidative stress, breast muscle

Abstract

Simple Summary The impact of a broiler chicken diet that is supplemented with canola meal (CM) on the cecal microbiota, growth, and metabolome of broiler chickens was examined. CM did not affect feed consumption, weight gain, nor the richness, evenness, or diversity of the cecal bacterial community. However, CM affected the structure of the bacterial microbiota, the concentrations of short-chain fatty acids (SCFAs) were elevated, and the abundance of bacterial taxa known to ferment dietary fiber were more abundant in the ceca of birds fed the CM diet. Nuclear magnetic resonance spectroscopy metabolomics was applied, and a number of metabolites that were associated with SCFA metabolism were differentially regulated in cecal digesta. The supplementation of diet with CM also affected the metabolic profiles of the pancreas, liver, and breast muscle (e.g., metabolites that are associated with energy production, protection against oxidative stress, and pathways of amino acid and glycerophospholipid metabolism). In summary, broiler chickens that were fed a diet supplemented with CM showed equivalent feed consumption and growth, but CM affected the composition and function of the cecal microbiota, and the metabolome of the pancreas, liver, and breast muscle of birds indicating the possibility of an increased disease risk. The study also demonstrated the utility of using metabolomics to ascertain impacts of diet on the microbiota and host tissues, and identified biomarkers to facilitate subsequent evaluation in production settings. Abstract The inoculation of one-day-old broiler chicks with the cecal contents from a mature broiler breeder resulted in a highly diverse and uniform cecal bacterial community. CM did not affect feed consumption, weight gain, nor the richness, evenness, or diversity of the cecal bacterial community. However, the structure of the bacterial community was altered in birds fed the CM diet. Although the CM diet was formulated to contain equivalent metabolizable energy to the control diet, it contained more dietary fiber. The abundance of bacterial families, including those that are known to contain species able to metabolize fiber was altered (e.g., bacteria within the families, Methanobacteriaceae, Atopobiaceae, Prevotellaceae, Clostridiales Family XIII, Peptostreptococcaceae, and Succinivibrionaceae), and concentrations of SCFAs were higher in the ceca of birds fed the CM diet. Moreover, concentrations of isoleucine, isobutyrate, glutamate, and 2-oxoglutarate were higher, whereas concentrations of phenyllactic acid, indole, glucose, 3-phenylpropionate, and 2-oxobutyrate were lower in the digesta of chickens that were fed CM. The metabolic profiles of pancreas, liver, and breast muscle tissues of birds fed the CM diet differed from control birds. Metabolites that were associated with energy production, protection against oxidative stress, and pathways of amino acid and glycerophospholipid metabolism had altered concentrations in these tissues. Some of the observed changes in metabolite levels may indicate an increased disease risk in birds fed the CM diet (e.g., pancreatitis), and others suggested that birds mounted metabolic response to offset the adverse impacts of CM (e.g., oxidative stress in the liver).

Published

2021

46. Seaweed and Seaweed Bioactives for Mitigation of Enteric Methane: Challenges and Opportunities

Author

Mohammad Ramin, Sinead M. Waters, Pamela Walsh, D. Wade Abbott, Stuart F. Kirwan, Fredri Grondahl, Sharon Huws, Maria Hayes, Xiaohui Xing, Karen A. Beauchemin, Inga Marie Aasen, Katerina Theodoridou, David A. Kenny, Dirk von Soosten, Vibeke Lind, Sophie J. Krizsan, Robert J. Gruninger, and Ulrich Meyer

Subjects

Methane emissions, RUSITEC, methane emissions, phlorotannins, carbohydrates, Review, alkaloids, bacteriocins, Enteric methane, bromoform, lipids, 03 medical and health sciences, Nutrient, Algae, saponins, lcsh:Zoology, 14. Life underwater, Food science, lcsh:QL1-991, 030304 developmental biology, 2. Zero hunger, 0303 health sciences, rumen, lcsh:Veterinary medicine, General Veterinary, biology, 0402 animal and dairy science, 04 agricultural and veterinary sciences, 15. Life on land, biology.organism_classification, 040201 dairy & animal science, 6. Clean water, animal studies, seaweeds, bioactive components, 13. Climate action, ruminants, peptides, Environmental science, lcsh:SF600-1100, Animal Science and Zoology, Asparagopsis taxiformis, Sustainable production

Abstract

Simple Summary The need to become more efficient in agriculture and the food industry exists parallel to the challenge of climate change. Meat and dairy production is the target of much scrutiny due to methane (CH4) emissions and global warming. On the other hand, it should be noted that two-thirds of the world’s agricultural land consists of pastures and permanent grasslands and is used for livestock grazing. This land is predominantly unsuitable for arable purposes but facilitates the production of high-quality human-edible protein in the form of ruminant animal-derived meat and milk. This makes a significant contribution to feeding the world’s population. There is a need to reduce CH4 emissions, however, and several approaches are being researched currently. Seaweeds are diverse plants containing bioactives that differ from their terrestrial counterparts and they are increasingly under investigation as a feed supplement for the mitigation of enteric CH4. Seaweeds are rich in bioactives including proteins, carbohydrates and to a lesser extent lipids, saponins, alkaloids and peptides. These bioactives could also play a role as feed ingredients to reduce enteric CH4. This review collates information on seaweeds and seaweed bioactives and their potential to impact on enteric CH4 emissions. Abstract Seaweeds contain a myriad of nutrients and bioactives including proteins, carbohydrates and to a lesser extent lipids as well as small molecules including peptides, saponins, alkaloids and pigments. The bioactive bromoform found in the red seaweed Asparagopsis taxiformis has been identified as an agent that can reduce enteric CH4 production from livestock significantly. However, sustainable supply of this seaweed is a problem and there are some concerns over its sustainable production and potential negative environmental impacts on the ozone layer and the health impacts of bromoform. This review collates information on seaweeds and seaweed bioactives and the documented impact on CH4 emissions in vitro and in vivo as well as associated environmental, economic and health impacts.

Published

2020

47. Combinatorial Glycomic Analyses to Direct CAZyme Discovery for the Tailored Degradation of Canola Meal Non-Starch Dietary Polysaccharides

Author

Marissa L. King, Darryl R. Jones, William G.T. Willats, G. Douglas Inglis, Michael G. Hahn, Paul E. Moote, Catherine Tétard-Jones, Xiaohui Xing, Sivasankari Venketachalam, D. Wade Abbott, Bogdan A. Slominski, and Kristin E. Low

Subjects

Microbiology (medical), food.ingredient, Starch, canola meal, enzyme discovery, Brassica napus L, Polysaccharide, Microbiology, Article, Cell wall, Glycomics, 03 medical and health sciences, chemistry.chemical_compound, food, Virology, glycosidic linkage analysis, plant cell wall, Food science, Canola, lcsh:QH301-705.5, 030304 developmental biology, chemistry.chemical_classification, 0303 health sciences, biology, 030306 microbiology, biology.organism_classification, intestinal microbiome, glycome profiling, lcsh:Biology (General), chemistry, non-starch polysaccharides, Bacteroides, Digestion, Bacteria, CAZymes

Abstract

Canola meal (CM), the protein-rich by-product of canola oil extraction, has shown promise as an alternative feedstuff and protein supplement in poultry diets, yet its use has been limited due to the abundance of plant cell wall fibre, specifically non-starch polysaccharides (NSP) and lignin. The addition of exogenous enzymes to promote the digestion of CM NSP in chickens has potential to increase the metabolizable energy of CM. We isolated chicken cecal bacteria from a continuous-flow mini-bioreactor system and selected for those with the ability to metabolize CM NSP. Of 100 isolates identified, Bacteroides spp. and Enterococcus spp. were the most common species with these capabilities. To identify enzymes specifically for the digestion of CM NSP, we used a combination of glycomics techniques, including enzyme-linked immunosorbent assay characterization of the plant cell wall fractions, glycosidic linkage analysis (methylation-GC-MS analysis) of CM NSP and their fractions, bacterial growth profiles using minimal media supplemented with CM NSP, and the sequencing and de novo annotation of bacterial genomes of high-efficiency CM NSP utilizing bacteria. The SACCHARIS pipeline was used to select plant cell wall active enzymes for recombinant production and characterization. This approach represents a multidisciplinary innovation platform to bioprospect endogenous CAZymes from the intestinal microbiota of herbivorous and omnivorous animals which is adaptable to a variety of applications and dietary polysaccharides.

Published

2020

48. Approaches to Investigate Selective Dietary Polysaccharide Utilization by Human Gut Microbiota at a Functional Level

Author

Marissa L King, Greta Reintjes, Leeann Klassen, Kristin E. Low, D. Wade Abbott, Jeffrey P Tingley, and Xiaohui Xing

Subjects

Microbiology (medical), Glycan, next-generation physiology, Mini Review, lcsh:QR1-502, Structural diversity, microbiome, carbohydrate probe, Computational biology, Biology, phylogeny, Microbiology, lcsh:Microbiology, 03 medical and health sciences, Human gut, Functional methods, Microbiome, 030304 developmental biology, 2. Zero hunger, 0303 health sciences, fluorescent polysaccharides, 030306 microbiology, carbohydrate, Dietary Polysaccharide, biology.protein, carbohydrate-active enzyme, Digestion, Function (biology)

Abstract

The human diet is temporally and spatially dynamic, and influenced by culture, regional food systems, socioeconomics, and consumer preference. Such factors result in enormous structural diversity of ingested glycans that are refractory to digestion by human enzymes. To convert these glycans into metabolizable nutrients and energy, humans rely upon the catalytic potential encoded within the gut microbiome, a rich collective of microorganisms residing in the gastrointestinal tract. The development of high-throughput sequencing methods has enabled microbial communities to be studied with more coverage and depth, and as a result, cataloging the taxonomic structure of the gut microbiome has become routine. Efforts to unravel the microbial processes governing glycan digestion by the gut microbiome, however, are still in their infancy and will benefit by retooling our approaches to study glycan structure at high resolution and adopting next-generation functional methods. Also, new bioinformatic tools specialized for annotating carbohydrate-active enzymes and predicting their functions with high accuracy will be required for deciphering the catalytic potential of sequence datasets. Furthermore, physiological approaches to enable genotype-phenotype assignments within the gut microbiome, such as fluorescent polysaccharides, has enabled rapid identification of carbohydrate interactions at the single cell level. In this review, we summarize the current state-of-knowledge of these methods and discuss how their continued development will advance our understanding of gut microbiome function.

Published

2020

49. New mechanistic insight into the digestion of complex dietary fibre by rumen microbiota using combinatorial high-resolution glycomic and transcriptomic analyses

Author

Tim A. McAllister, Michael G. Hahn, Ajay Badhan, Sivasankari Venketachalam, Rodrigo OrtegoPolo, Kristin E. Low, Darryl R. Jones, D. Wade Abbott, Mohammad Raza Marami Milani, and Xiaohui Xing

Subjects

Transcriptome, Biochemistry, Chemistry, Rumen microbiota, Dietary fibre, food and beverages, High resolution, Digestion

Abstract

Background The rumen microbial community is considered the most efficient anaerobic digestive ecosystem known, yet less than half of the energy in low quality forages is actually metabolized. There is a knowledge gap regarding the specific factors that impede the ruminal digestion of plant cell walls or if rumen microbiota have the functional potential and activities to overcome these constraints. To address these issues, innovative experimental methods may provide a high-resolution understanding of the cell wall chemistries and higher-order structures that are resistant to microbial digestion and how they interact with the functional activities of the rumen microbial community. Results With this goal, we characterized the total tract indigestible residue (TTIR) from cattle fed a high-forage diet containing low-quality straw using two comparative glycomic approaches: ELISA-based glycome profiling and glycosidic linkage analysis. Using these techniques, we successfully detected numerous and diverse cell wall glycan epitopes in barley straw and TTIR and determined their relative abundance pre- and post-intestinal digestion. Of these, xyloglucans and heteroxylans were the most recalcitrant to digestion. Linkage analysis identified indigestible linkages consistent with the polysaccharide epitopes identified by ELISA-based glycome analysis. To determine if residual plant polysaccharides within TTIR could be metabolised, rumen microbiota from cannulated cattle fed barley straw were incubated with barley straw and TTIR in in vitro batch cultures. Transcript coding for carbohydrate-active enzymes (CAZymes) were identified and characterized for their contribution to cell wall digestion based on glycomic analyses, comparative gene expression profiles, and associated CAZyme families. High-resolution phylogenetic fingerprinting of these sequences revealed encoded enzymes with activities predicted to cleave the primary linkages within heteroxylan and arabinan. Conclusion This experimental platform provides unprecedented precision in the understanding of forage structure and digestibility, which can inform next-generation solutions to improve the growth of ruminants fed low quality forages and enhance the use of crop residues as a feedstock.

Published

2020

50. Characterization of an α-glucosidase enzyme conserved in Gardnerella spp. isolated from the human vaginal microbiome

Author

Pashupati Bhandari, Jeffrey P. Tingley, David R. J. Palmer, D. Wade Abbott, and Janet E. Hill

Subjects

chemistry.chemical_classification, 0303 health sciences, biology, Glycogen, 030306 microbiology, Maltose, biology.organism_classification, Microbiology, 03 medical and health sciences, chemistry.chemical_compound, Enzyme, chemistry, Gardnerella, biology.protein, Glycoside hydrolase, Amylase, Anaerobic bacteria, Bacteria, 030304 developmental biology

Abstract

Gardnerellaspp. in the vaginal microbiome are associated with bacterial vaginosis, a dysbiosis in which a lactobacilli dominant microbial community is replaced with mixed aerobic and anaerobic bacteria includingGardnerellaspecies. The co-occurrence of multipleGardnerellaspecies in the vaginal environment is common, but different species are dominant in different women. Competition for nutrients, particularly glycogen present in the vaginal environment, could play an important role in determining the microbial community structure. Digestion of glycogen into products that can be taken up and further processed by bacteria requires the combined activities of several enzymes collectively known as amylases, which belong to glycoside hydrolase family 13 (GH13) within the CAZy classification system. GH13 is a large and diverse family of proteins, making prediction of their activities challenging. SACCHARIS annotation of the GH13 family inGardnerellaresulted in identification of protein domains belonging to eight subfamilies. Phylogenetic analysis of predicted amylase sequences from 26Gardnerellagenomes demonstrated that a putative α-glucosidase-encoding sequence, CG400_06090, was conserved in all species in the genus. The predicted α-glucosidase enzyme was expressed, purified and functionally characterized. The enzyme was active on a variety of maltooligosaccharides over a broad pH range (4.0 - 8) with maximum activity at pH 7. TheKm,kcatandkcat/Kmvalues for the substrate 4-nitrophenyl α-D-glucopyranoside were 8.3 μM, 0.96 min-1and 0.11 μM-1min-1respectively. Glucose was released from maltose, maltotriose, maltotetraose and maltopentaose, but no products were detected on thin layer chromatography when the enzyme was incubated with glycogen. Our findings show thatGardnerellaspp. produce an α-glucosidase enzyme that may contribute to the complex and multistep process of glycogen metabolism by releasing glucose from maltooligosaccharides.

Published

2020