It is estimated that most colon cancers can be attributed to dietary causes. We have hypothesized that diet influences the health of the colonic mucosa through interaction with the microbiota and that it is the milieu interior that regulates mucosal proliferation and therefore cancer risk. To validate this further, we compared colonic contents from healthy 50- to 65-y-old people from populations with high and low risk, specifically low risk Native Africans (cancer incidence <1:100,000; n = 17), high risk African Americans (risk 65:100,000; n = 17), and Caucasian Americans (risk 50:100,000; n = 18). Americans typically consume a high-animal protein and -fat diet, whereas Africans consume a staple diet of maize meal, rich in resistant starch and low in animal products. Following overnight fasting, rapid colonic evacuation was performed with 2 L polyethylene glycol. Total colonic evacuants were analyzed for SCFA, vitamins, nitrogen, and minerals. Total SCFA and butyrate were significantly higher in Native Africans than in both American groups. Colonic folate and biotin content, measured by Lactobacillus rhamnoses and Lactobacillus plantarum ATCC 8014 bioassay, respectively, exceeded normal daily dietary intakes. Compared with Africans, calcium and iron contents were significantly higher in Caucasian Americans and zinc content was significantly higher in African Americans, but nitrogen content did not differ among the 3 groups. In conclusion, the results support our hypothesis that the microbiota mediates the effect diet has on colon cancer risk by their generation of butyrate, folate, and biotin, molecules known to play a key role in the regulation of epithelial proliferation.
SUMMARYWe report a detailed functional characterization of an Arabidopsis isopropylmalate dehydrogenase (AtI-PMDH1) that is involved in both glucosinolate biosynthesis and leucine biosynthesis. AtIPMDH1 shares high homology with enzymes from bacteria and yeast that are known to function in leucine biosynthesis. In plants, AtIPMDH1 is co-expressed with nearly all the genes known to be involved in aliphatic glucosinolate biosynthesis. Mutation of AtIPMDH1 leads to a significant reduction in the levels of free leucine and of glucosinolates with side chains of four or more carbons. Complementation of the mutant phenotype by ectopic expression of AtIPMDH1, together with the enzyme's substrate specificity, implicates AtIPMDH1 in both glucosinolate and leucine biosynthesis. This functional assignment is substantiated by subcellular localization of the protein in the chloroplast stroma, and the gene expression patterns in various tissues. Interestingly, AtIPMDH1 activity is regulated by a thiol-based redox modification. This work characterized an enzyme in plants that catalyzes the oxidative decarboxylation step in both leucine biosynthesis (primary metabolism) and methionine chain elongation of glucosinolates (specialized metabolism). It provides evidence for the hypothesis that the two pathways share a common origin, and suggests a role for redox regulation of glucosinolate and leucine synthesis in plants.
Symbiotic nitrogen fixation, the process whereby nitrogen-fixing bacteria enter into associations with plants, provides the major source of nitrogen for the biosphere. Nitrogenase, a bacterial enzyme, catalyzes the reduction of atmospheric dinitrogen to ammonium. In rhizobialeguminous plant symbioses, the current model of nitrogen transfer from the symbiotic form of the bacteria, called a bacteroid, to the plant is that nitrogenase-generated ammonia diffuses across the bacteroid membrane and is assimilated into amino acids outside of the bacteroid. We purified soybean nodule bacteroids by a procedure that removed contaminating plant proteins and found that alanine was the major nitrogencontaining compound excreted. Bacteroids incubated in the presence of 15 N 2 excreted alanine highly enriched in 15 N. The ammonium in these assays neither accumulated significantly nor was enriched in 15 N. The results demonstrate that a transport mechanism rather than diffusion functions at this critical step of nitrogen transfer from the bacteroids to the plant host. Alanine may serve only as a transport species, but this would permit physiological separation of the transport of fixed nitrogen from other nitrogen metabolic functions commonly mediated through glutamate.In 1956 (1), ammonium was shown to be the product of nitrogenase, the bacterial enzyme that reduces atmospheric dinitrogen. In free-living, nitrogen-fixing microorganisms, the nitrogenase-generated ammonium is assimilated into glutamate through the glutamine synthetase͞glutamate synthase pathway. Various transaminases utilize glutamate to generate all of the other amino acids, which are then used to synthesize proteins, nucleic acids and other nitrogen-containing molecules.In rhizobia-leguminous plant symbioses, the majority of the dinitrogen reduced by the microsymbionts, referred to as bacteroids, is transferred to the plant. Because the rhizobia are physically separated from the plant cytosol by a plant-derived symbiosome membrane, the ammonium must move across the bacteroid and symbiosome membranes. The ammonia diffusion hypothesis has been the prevalent model surmising the initial steps of leguminous nodule nitrogen transfer. In this model, the product of nitrogenase exists in two forms within the cell, ammonium [NH 4 ϩ ] and ammonia [NH 3 ], which are readily interconvertible. The ammonium ion cannot diffuse across membranes, but ammonia is believed to diffuse freely out of the bacteroid. Once outside the bacteroid but within the symbiosome space, the ammonia may either diffuse or be transported across the symbiosome membrane (2) where it is assimilated by the host plant into glutamate by the concerted action of glutamine synthetase and glutamate synthase. Glutamate serves as the central nitrogen metabolite in the plant nodule cells for the synthesis of the other amino acids, nucleic acids, and other nitrogen-containing compounds such as ureides that are the principal nitrogen compounds transported from the nodules to the plant shoots and leaves o...
Currently incurable, prostate cancer metastasis has a remarkable ability to spread to the skeleton. Previous studies demonstrated that interactions mediated by the cancer-associated Thomsen-Friedenreich glycoantigen (TF-Ag) and the carbohydrate-binding protein galectin-3 play an important role in several rate-limiting steps of cancer metastasis such as metastatic cell adhesion to bone marrow endothelium, homotypic tumor cell aggregation, and clonogenic survival and growth. This study investigated the ability of a synthetic small-molecular-weight nontoxic carbohydrate-based TF-Ag mimic lactulose-L-leucine (Lac-L-Leu) to inhibit these processes in vitro and, ultimately, prostate cancer bone metastasis in vivo. Using an in vivo mouse model, based on intracardiac injection of human PC-3 prostate carcinoma cells stably expressing luciferase, we investigated the ability of Lac-L-Leu to impede the establishment and growth of bone metastasis. Parallel-flow chamber assay, homotypic aggregation assay, modified Boyden chamber assay, and clonogenic growth assay were used to assess the effects of Lac-L-Leu on tumor cell adhesion to the endothelium, homotypic tumor cell aggregation, transendothelial migration, and clonogenic survival and growth, respectively. We report that daily intraperitoneal administration of Lac-L-Leu resulted in a three-fold (P < .05) decrease in metastatic tumor burden compared with the untreated control. Mechanistically, the effect of Lac-L-Leu, which binds and inhibits galectins by mimicking essential structural features of the TF-Ag, was associated with a dose-dependent inhibition of prostate cancer cell adhesion to bone marrow endothelium, homotypic aggregation, transendothelial migration, and clonogenic growth. We conclude that small-molecular-weight carbohydrate-based compounds targeting β-galactoside-mediated interactions could provide valuable means for controlling and preventing metastatic prostate cancer spread to the skeleton.
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