Alex H. Gordon scite author profile

The human gastrointestinal microbiota functions as an important mediator of diet for host metabolism. To evaluate how consumed diets influence the gut environment, we carried out simultaneous interrogations of distal gut microbiota and metabolites in samples from healthy children in Egypt and the United States. While Egyptian children consumed a Mediterranean diet rich in plant foods, U.S. children consumed a Western diet high in animal protein, fats, and highly processed carbohydrates. Consistent with the consumed diets, Egyptian gut samples were enriched in polysaccharide-degrading microbes and end products of polysaccharide fermentation, and U.S. gut samples were enriched in proteolytic microbes and end products of protein and fat metabolism. Thus, the intestinal microbiota might be selected on the basis of the diets that we consume, which can open opportunities to affect gut health through modulation of gut microbiota with dietary supplementations.

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Substituent groups linked by alkali‐labile bonds to arabinose and xylose residues of legume, grass and cereal straw cell walls and their fate during digestion by rumen microorganisms

Chesson¹,

Gordon²,

Lomax³

1983

J Sci Food Agric

165

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The distribution of alkali labile substituents of the neutral sugar components of hemicellulose in unfractionated cell walls of early-and late-cut perennial ryegrass, wheat and barley straw, and white clover, before and after extended incubation in the rumen, was determined by a modified methylation technique. Xylose residues were found to be extensively substituted, with 50% of residues in the Gramineae and 75 % in white clover carrying substituent groups on 0-2 and/or 0 -3 . Acetyl groups could account for 50-70% of substitutions, the remainder being to unknown cell wall components. The distribution of alkali-labile substituents of xylose was the same in the original plant material as in residues recovered from the rumen, and was not affected by delignification under conditions which preserved the acetyl content of cell walls. Arabinose residues were heavily substituted at 0-5, with 40-60% of residues from the Gramineae, but only 10% of residues from the white clover, carrying substituent groups at this site. Linkages to 0 -5 of arabinose were preserved during digestion and accumulated in residues recovered from the rumen. In all plants examined, the extent of 0-5 substitution strongly correlated with the proportion of total phenolics (r = 0.844) and total phenolics minus phenolic acids (r = 0.779) present. The correlation was improved when restricted to the Gramineae (r=0.879 and 0.881 respectively). Within the Gramineae, the increase in the extent of substitution to 0-5 of arabinose correlated well with the increase in the proportion of total material in digested residues (r = 0.899). As correlations were retained or improved when values for phenolic acids were subtracted from total phenolics, and as the proportion of phenolic acids decreased during digestion, it is suggested that linkages to 0-5 of arabinose represent one form of lignin-carbohydrate bonding. The importance of such linkages to the control of polysaccharide degradation and the effect of their cleavage by alkali-treatment is discussed.

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Dietary Fatty Acids Sustain the Growth of the Human Gut Microbiota

Agans

Gordon

Kramer

et al. 2018

Appl Environ Microbiol

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While a substantial amount of dietary fats escape absorption in the human small intestine and reach the colon, the ability of resident microbiota to utilize these dietary fats for growth has not been investigated in detail. In this study we used an multi-vessel simulator system of the human colon to reveal that human gut microbiota is able to utilize typically consumed dietary fatty acids to sustain growth. Gut microbiota adapted quickly to a macronutrient switch from a balanced Western diet type medium to its variant lacking carbohydrates and proteins. We defined specific genera that increased their abundance on the fats-only medium, including, , and several genera of class Gammaproteobacteria. In contrast, abundances of well-known glycan and protein degraders including, , and were reduced in such conditions. Predicted prevalences of microbial genes coding for fatty acid degradation enzymes and anaerobic respiratory reductases were significantly increased in the fats-only environment, whereas the abundance of glycan degradation genes was diminished. These changes also resulted in lower microbial production of short chain fatty acids and antioxidants. Our findings provide justification for the previously observed alterations in gut microbiota observed in human and animal studies of high-fat diets. Increased intake of fats in many developed countries raised awareness of potentially harmful and beneficial effects of high fat consumption on human health. Some dietary fats escape digestion in the small intestine and reach the colon where they can be metabolized by gut microbiota. We show that human gut microbes are able to maintain a complex community when supplied with dietary fatty acids as the only nutrient and carbon sources. Such fatty acid based growth leads to lower production of short chain fatty acids and antioxidants by community members, which might potentially have negative health consequences on the host.

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Co-operative action by endo- and exo-β-(1→3)-glucanases from parasitic fungi in the degradation of cell-wall glucans of Sclerotinia sclerotiorum (Lib.) de Bary

Jones¹,

Gordon²,

Bacon³

1974

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1. Two fungi, Coniothyrium minitans Campbell and Trichoderma viride Pers. ex Fr., were grown on autoclaved crushed sclerotia of the species Sclerotinia sclerotiorum, which they parasitize. 2. In vitro the crude culture filtrates would lyse walls isolated from hyphal cells or the inner pseudoparenchymatous cells of the sclerotia, in which a branched beta-(1-->3)-beta-(1-->6)-glucan, sclerotan, is a major constituent. 3. Chromatographic fractionation of the enzymes in each culture filtrate revealed the presence of several laminarinases, the most active being an exo-beta-(1-->3)-glucanase, known from previous studies to attack sclerotan. Acting alone this brought about a limited degradation of the glucan, but the addition of fractions containing an endo-beta-(1-->3)-glucanase led to almost complete breakdown. A similar synergism between the two enzymes was found in their lytic action on cell walls. 4. When acting alone the endo-beta-(1-->3)-glucanase had a restricted action, the products including a trisaccharide, tentatively identified as 6(2)-beta-glucosyl-laminaribiose. 5. These results are discussed in relation to the structure of the cell walls and of their glucan constituents.

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Preparation and composition of mesophyll, epidermis and fibre cell walls from leaves of perennial ryegrass (lolium perenne) and italian ryegrass (lolium multiflorum)

Gordon¹,

Lomax²,

Dalgarno³

et al. 1985

J Sci Food Agric

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Cells of mesophyll, epidermis and residual fibrous material were obtained from leaves of Italian and perennial ryegrass harvested at different stages of maturity by mechanical disruption of leaf tissue. Mesophyll cells were selectively removed by filtration through 0.045 mm nylon mesh and remaining non-mesophyll cells centrifuged in metrizamide solutions (56-58% wt to vol.) of known density (1.308-1.329 gcm' at 5°C) to obtain a pure epidermis cell fraction and a residual fibre fraction. Whole mesophyll cells contributed 63-72%, epidermis 12-15% and the fibre fraction 15-24% to the total leaf dry matter. Fibre values were higher in late-cut samples. Cell walls were prepared from mesophyll and epidermis cells by disruption and washing to remove cell contents. Fibre cells were judged free of cell contents and received no further treatment. Examination of cell wall preparations by light and electron microscopy showed that both mesophyll and epidermis preparations were essentially free from contaminating material. Mesophyll cell walls were uniformly thin ~ (200 nm) while those of epidermis ranged from 200&3000nm at the outer face, thinning to 300nm or less at the inner surface. An electron-light layer (cuticle) of approximately 200 nm thickness was present covering the outer face of the epidermis. The fibre fraction largely consisted of sclerenchyma, but contained, in addition, other vascular cells, detached annular rings and heavily silicified leaf hairs. Analysis of cell walls accounted for 85-90% of dry matter. Cellulose was the major component of all cell walls examined (approximately 40% of dry matter) with xylose residues accounting for a further 11% of mesophyll, 13.5-17.5% of epidermis and 21-25% of fibre cell walls. Arabinose was low in fibre cells but was present in much higher proportions in mesophyll and epidermis walls. The ratio of arabinose to xylose was approximately 1:1.5 for mesophyll, 1:2.5 for epidermis and 1:7.0 for the fibre fraction. The molar ratio acetyl to xylose remained fairly constant at 1:4 regardless of the grass, cell type or maturity of the sample. The uronic acid content of epidermis was higher than that in other cell types and showed an increase with increasing maturity of the grass, reaching over 9 % in late-cut samples. Total phenolic material represented 2-3% of mesophyll and epidermis cell walls and 6 % of fibre walls. Ferulic acid alone was released from the primary cell walls by saponification and p-coumaric and ferulic acids from the secondary-thickened fibre walls. Crude protein values (Nx6.25) were high in mesophyll cell wall preparations and low in epidermis and fibre cell walls. Amino acid patterns were similar for both grasses and cell types but hydroxyproline was found in greater amounts in fibre cell walls than in either epidermis or mesophyll.

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Alex H. Gordon

Differences in Gut Metabolites and Microbial Composition and Functions between Egyptian and U.S. Children Are Consistent with Their Diets

Substituent groups linked by alkali‐labile bonds to arabinose and xylose residues of legume, grass and cereal straw cell walls and their fate during digestion by rumen microorganisms

Dietary Fatty Acids Sustain the Growth of the Human Gut Microbiota

Co-operative action by endo- and exo-β-(1→3)-glucanases from parasitic fungi in the degradation of cell-wall glucans of Sclerotinia sclerotiorum (Lib.) de Bary

Preparation and composition of mesophyll, epidermis and fibre cell walls from leaves of perennial ryegrass (lolium perenne) and italian ryegrass (lolium multiflorum)

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