Your search keyword '"Douglas J, Kenny"' showing total 7 results

1. Sugar loading is not required for phloem sap flow in maize plants

Author

Benjamin A. Babst, David M. Braun, Abhijit A. Karve, R. Frank Baker, Thu M. Tran, Douglas J. Kenny, Julia Rohlhill, Jan Knoblauch, Michael Knoblauch, Gertrud Lohaus, Ryan Tappero, Sönke Scherzer, Rainer Hedrich, and Kaare H. Jensen

Subjects

Plant Science

Abstract

Phloem transport of photoassimilates from leaves to non-photosynthetic organs, such as the root and shoot apices and reproductive organs, is crucial to plant growth and yield. For nearly 90 years, evidence has been generally consistent with the theory of a pressure-flow mechanism of phloem transport. Central to this hypothesis is the loading of osmolytes, principally sugars, into the phloem to generate the osmotic pressure that propels bulk flow. Here we used genetic and light manipulations to test whether sugar import into the phloem is required as the driving force for phloem sap flow. Using carbon-11 radiotracer, we show that a maize sucrose transporter1 (sut1) loss-of-function mutant has severely reduced export of carbon from photosynthetic leaves (only ~4% of the wild type level). Yet, the mutant remarkably maintains phloem pressure at ~100% and sap flow speeds at ~50–75% of those of wild type. Potassium (K+) abundance in the phloem was elevated in sut1 mutant leaves. Fluid dynamic modelling supports the conclusion that increased K+ loading compensated for decreased sucrose loading to maintain phloem pressure, and thereby maintained phloem transport via the pressure-flow mechanism. Furthermore, these results suggest that sap flow and transport of other phloem-mobile nutrients and signalling molecules could be regulated independently of sugar loading into the phloem, potentially influencing carbon–nutrient homoeostasis and the distribution of signalling molecules in plants encountering different environmental conditions.

Published

2022

2. Ruminococcus gnavus , a member of the human gut microbiome associated with Crohn’s disease, produces an inflammatory polysaccharide

Author

Hera Vlamakis, Douglas J. Kenny, Matthew T. Henke, Jon Clardy, Ramnik J. Xavier, and Chelsi D. Cassilly

Subjects

0301 basic medicine, Rhamnose, microbiome, Gut flora, Inflammatory bowel disease, 03 medical and health sciences, chemistry.chemical_compound, 0302 clinical medicine, inflammatory bowel disease, Ruminococcus gnavus, Gene cluster, medicine, Glycosyl, Secretion, Microbiome, Multidisciplinary, biology, Chemistry, medicine.disease, biology.organism_classification, 3. Good health, 030104 developmental biology, Biochemistry, polysaccharide, Physical Sciences, 030217 neurology & neurosurgery

Abstract

Significance The bacteria that live within the human gut play crucial roles in regulating our primary metabolism, protecting us from pathogens, and developing our immune system. Imbalances in bacterial community structure have been implicated in many diseases, such as Crohn’s disease, an inflammatory bowel disease. We found and characterized an inflammatory polysaccharide produced by the gut bacterium Ruminococcus gnavus, populations of which bloom during flares of symptoms in patients with Crohn’s disease. This molecule induces the production of inflammatory cytokines like TNFα by dendritic cells and may contribute to the association between R. gnavus and Crohn’s disease. This work establishes a plausible molecular mechanism that may explain the association between a member of the gut microbiome and an inflammatory disease., A substantial and increasing number of human diseases are associated with changes in the gut microbiota, and discovering the molecules and mechanisms underlying these associations represents a major research goal. Multiple studies associate Ruminococcus gnavus, a prevalent gut microbe, with Crohn’s disease, a major type of inflammatory bowel disease. We have found that R. gnavus synthesizes and secretes a complex glucorhamnan polysaccharide with a rhamnose backbone and glucose sidechains. Chemical and spectroscopic studies indicated that the glucorhamnan was largely a repeating unit of five sugars with a linear backbone formed from three rhamnose units and a short sidechain composed of two glucose units. The rhamnose backbone is made from 1,2- and 1,3-linked rhamnose units, and the sidechain has a terminal glucose linked to a 1,6-glucose. This glucorhamnan potently induces inflammatory cytokine (TNFα) secretion by dendritic cells, and TNFα secretion is dependent on toll-like receptor 4 (TLR4). We also identify a putative biosynthetic gene cluster for this molecule, which has the four biosynthetic genes needed to convert glucose to rhamnose and the five glycosyl transferases needed to build the repeating pentasaccharide unit of the inflammatory glucorhamnan.

Published

2019

3. Gut Microbiota Regulation of T Cells During Inflammation and Autoimmunity

Author

Douglas J. Kenny, Eric M. Brown, and Ramnik J. Xavier

Subjects

CD4-Positive T-Lymphocytes, 0301 basic medicine, Host immunity, Immunology, Autoimmunity, Inflammation, Biology, Gut flora, medicine.disease_cause, Inflammatory bowel disease, Immunomodulation, 03 medical and health sciences, 0302 clinical medicine, Immune system, Immune Tolerance, medicine, Animals, Homeostasis, Humans, Immunology and Allergy, Intestinal Mucosa, Barrier function, Inflammatory Bowel Diseases, medicine.disease, biology.organism_classification, Gastrointestinal Microbiome, Diabetes Mellitus, Type 1, 030104 developmental biology, 030220 oncology & carcinogenesis, Cytokine secretion, medicine.symptom

Abstract

The intestinal microbiota plays a crucial role in influencing the development of host immunity, and in turn the immune system also acts to regulate the microbiota through intestinal barrier maintenance and immune exclusion. Normally, these interactions are homeostatic, tightly controlled, and organized by both innate and adaptive immune responses. However, a combination of environmental exposures and genetic defects can result in a break in tolerance and intestinal homeostasis. The outcomes of these interactions at the mucosal interface have broad, systemic effects on host immunity and the development of chronic inflammatory or autoimmune disease. The underlying mechanisms and pathways the microbiota can utilize to regulate these diseases are just starting to emerge. Here, we discuss the recent evidence in this area describing the impact of microbiota-immune interactions during inflammation and autoimmunity, with a focus on barrier function and CD4+ T cell regulation.

Published

2019

4. Sa1540: SYNTHETIC BIOTIC MEDICINE PRODUCING AHR METABOLITES FOR THE TREATMENT OF INFLAMMATORY BOWEL DISEASE

Author

Chun-Cheih Chao, Jenny Shu, Starsha Kolodziej, Catherine Monahan, Michael James, Douglas J. Kenny, Mylene Perreault, Vincent Isabella, and David Hava

Subjects

Hepatology, Gastroenterology

Published

2022

5. Cholesterol Metabolism by Uncultured Human Gut Bacteria Influences Host Cholesterol Level

Author

Douglas J. Kenny, Ramachandran S. Vasan, Hera Vlamakis, Dmitry Shungin, Nitzan Koppel, Damian R. Plichta, Beverly Fu, Stanley Y. Shaw, A. Brantley Hall, Emily P. Balskus, and Ramnik J. Xavier

Subjects

microbial dark matter, microbiome, Gut flora, Microbiology, Article, hydroxysteroid dehydrogenase, 03 medical and health sciences, chemistry.chemical_compound, Feces, 0302 clinical medicine, Metabolomics, coprostanol, Virology, Humans, Microbiome, 030304 developmental biology, Clostridium cluster IV, 0303 health sciences, biology, Bacteria, Framingham Heart Study, Cholesterol, Human microbiome, Biochemistry and Molecular Biology, biology.organism_classification, Lipid Metabolism, metagenomic species, Sterol, Gastrointestinal Microbiome, Coprostanol, Cholestanol, chemistry, Metagenomics, Parasitology, lipids (amino acids, peptides, and proteins), Oxidoreductases, 030217 neurology & neurosurgery, Biokemi och molekylärbiologi

Abstract

Summary The human microbiome encodes extensive metabolic capabilities, but our understanding of the mechanisms linking gut microbes to human metabolism remains limited. Here, we focus on the conversion of cholesterol to the poorly absorbed sterol coprostanol by the gut microbiota to develop a framework for the identification of functional enzymes and microbes. By integrating paired metagenomics and metabolomics data from existing cohorts with biochemical knowledge and experimentation, we predict and validate a group of microbial cholesterol dehydrogenases that contribute to coprostanol formation. These enzymes are encoded by ismA genes in a clade of uncultured microorganisms, which are prevalent in geographically diverse human cohorts. Individuals harboring coprostanol-forming microbes have significantly lower fecal cholesterol levels and lower serum total cholesterol with effects comparable to those attributed to variations in lipid homeostasis genes. Thus, cholesterol metabolism by these microbes may play important roles in reducing intestinal and serum cholesterol concentrations, directly impacting human health., Graphical Abstract, Highlights • Bioinformatics enabled discovery of ismA, a microbial cholesterol dehydrogenase • Metagenomic species with ismA genes form coprostanol in microbial communities • ismA+ species are associated with decreased fecal and serum cholesterol in humans • Effect sizes of ismA+ species on serum cholesterol are on par with human genetics, The consequences of cholesterol metabolism by the gut microbiome were largely unknown. Kenny, Plichta et al. identified and characterized microbial cholesterol dehydrogenase enzymes encoded by uncultured metagenomic species of bacteria. The presence of these cholesterol-metabolizing bacteria is associated with decreased stool and serum total cholesterol in human cohorts.

Published

2020

6. Engineering chemical interactions in microbial communities

Author

Douglas J. Kenny and Emily P. Balskus

Subjects

0301 basic medicine, Ecology, Microbiota, 030106 microbiology, Chemical signaling, Context (language use), General Chemistry, Chemical interaction, Biology, Chemical communication, Plant Roots, 03 medical and health sciences, Multicellular organism, 030104 developmental biology, Animals

Abstract

Microbes living within host-associated microbial communities (microbiotas) rely on chemical communication to interact with surrounding organisms. These interactions serve many purposes, from supplying the multicellular host with nutrients to antagonizing invading pathogens, and breakdown of chemical signaling has potentially negative consequences for both the host and microbiota. Efforts to engineer microbes to take part in chemical interactions represent a promising strategy for modulating chemical signaling within these complex communities. In this review, we discuss prominent examples of chemical interactions found within host-associated microbial communities, with an emphasis on the plant-root microbiota and the intestinal microbiota of animals. We then highlight how an understanding of such interactions has guided efforts to engineer microbes to participate in chemical signaling in these habitats. We discuss engineering efforts in the context of chemical interactions that enable host colonization, promote host health, and exclude pathogens. Finally, we describe prominent challenges facing this field and propose new directions for future engineering efforts.

Published

2018

7. Sugar loading is not required for phloem sap flow in maize plants

Author

Benjamin A, Babst, David M, Braun, Abhijit A, Karve, R, Frank Baker, Thu M, Tran, Douglas J, Kenny, Julia, Rohlhill, Jan, Knoblauch, Michael, Knoblauch, Gertrud, Lohaus, Ryan, Tappero, Sönke, Scherzer, Rainer, Hedrich, and Kaare H, Jensen

Subjects

Plant Leaves, Phloem, Plants, Sugars, Zea mays

Abstract

Phloem transport of photoassimilates from leaves to non-photosynthetic organs, such as the root and shoot apices and reproductive organs, is crucial to plant growth and yield. For nearly 90 years, evidence has been generally consistent with the theory of a pressure-flow mechanism of phloem transport. Central to this hypothesis is the loading of osmolytes, principally sugars, into the phloem to generate the osmotic pressure that propels bulk flow. Here we used genetic and light manipulations to test whether sugar import into the phloem is required as the driving force for phloem sap flow. Using carbon-11 radiotracer, we show that a maize sucrose transporter1 (sut1) loss-of-function mutant has severely reduced export of carbon from photosynthetic leaves (only ~4% of the wild type level). Yet, the mutant remarkably maintains phloem pressure at ~100% and sap flow speeds at ~50-75% of those of wild type. Potassium (K

Published

2019