The question of how starch digestion works is one of great importance to human health because starch is a major component of the human diet. Plants make this polysaccharide molecule during photosynthesis as a way of storing energy, and foods like potatoes, wheat and rice are all rich in starch. It is a major source of dietary glucose, the main sugar the human body uses for fuel.
Dietary glucose and the physiology of starch digestion figures prominently in digestive and liver diseases, food intolerances, diabetes and obesity, and the new work has implications for all these conditions as well as other areas of human health.
In the last few years, scientists have come to appreciate the outsized role played in healthy gut physiology by a rich ecosystem of "good" bacteria residing in the gut -- referred to collectively as the gut microbiome. Whenever we eat vegetables, enzymes produced by these bacteria break the starch molecules down into smaller component pieces, like glucose, which are then absorbed through the gut into the bloodstream.
The makeup of the organisms in the gut microbiome has been a hot topic because of these linkages to human health, and earlier studies have shown how altering the microbiome of mice directly affects their weight, turning fat mice thin and vice versa. Major research projects started in the United States and elsewhere are aiming to identify and analyze all the micro-organisms in the human gut.
The University of Waterloo team, led by David Rose, has been working out the detailed molecular mechanisms for individual enzymes and other molecules involved in starch digestion. They are looking at component pieces of large complexes of molecules known as starch utilization systems, one of the two major systems in the intestinal microbiome helping to break down starch.
At the American Crystallographic Association (ACA) 2015 Meeting, which will be held in Philadelphia from July 25-29, 2015, Rose's graduate student, Marcia Chaudet will present biochemical activity data as well as crystal structures of two proteins known as GH31 enzymes that help to break down starch as part of these starch utilization systems.
"Based on the structures we have so far, we can make predictions about specificity," said Rose. "Such structural information can reveal subtle points about the physiology that would otherwise be hidden and may be impossible to predict. It can also guide the development of chemical compounds [a basic approach to pharmaceutical drug development]."
This is significant, he added, because if you can figure out which enzymes are primarily responsible for binding to and digesting starch, then you might be able to design drugs that would fine-tune that activity, allowing you to better regulate blood glucose levels and address diseases where this physiology is at play.
The abstract, "Feeding our Gut Microbes: Structural insights into sugar digestion in the human colon" is authored by M. Chaudet and D. Rose. It will be presented on Wednesday, July 29th, at 11:20 AM in Freedom Ballroom at the Sheraton Philadelphia Downtown Hotel.
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MORE ABOUT THE MEETING
More than 700 professionals and students from more than 20 countries and from diverse areas across industry and academia are expected to attend the American Crystallographic Association (ACA) 65th annual meeting in Philadelphia, from July 25-29, the largest crystallography conference of the year in the United States.
All scientific sessions, workshops, poster sessions, and events will be held at the Sheraton Philadelphia Downtown Hotel. To obtain more information or free registration for press, please contact Jason Socrates Bardi at: 240-535-4954 or [email protected]
USEFUL LINKS
Main meeting website: http://www.amercrystalassn.org/2015-mtg-homepageScientific program: http://www.amercrystalassn.org/2015-scientific-programHotel: http://www.sheratonphiladelphiadowntown.comTwitter: #ACAPhilly
ABOUT THE SCIENCE OF CRYSTALLOGRAPHY
Crystallography is a field that lies at the crossroads of biology, chemistry, physics and materials science. Researchers from areas as far flung as genomics, geology, medicine and manufacturing use it to uncover the exact arrangements of atoms within molecules and bulk materials -- information of keen interest to modern science because it helps to define the real-life chemical and physical properties of materials. The structures uncovered by crystallography are also of profound importance to humanity because they are routinely used to guide the creation of new lifesaving drugs, improve manufacturing processes and make new materials that impact our economy and our world.
ABOUT ACA
The American Crystallographic Association (ACA) was founded in 1949 through a merger of the American Society for X-Ray and Electron Diffraction (ASXRED) and the Crystallographic Society of America (CSA). The objective of the ACA is to promote interactions among scientists who study the structure of matter at atomic (or near atomic) resolution. These interactions will advance experimental and computational aspects of crystallography and diffraction. They will also promote the study of the arrangements of atoms and molecules in matter and the nature of the forces that both control and result from them. See: http://www.amercrystalassn.org
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Meeting Link: American Crystallographic Association (ACA) 2015 Annual Meeting