NCBI Taxonomy: 41993
Ceratozamia (ncbi_taxid: 41993)
found 45 associated metabolites at genus taxonomy rank level.
Ancestor: Zamiaceae
Child Taxonomies: Ceratozamia mexicana, Ceratozamia hildae, Ceratozamia tenuis, Ceratozamia robusta, Ceratozamia matudae, Ceratozamia sabatoi, Ceratozamia mirandae, Ceratozamia mixeorum, Ceratozamia morettii, Ceratozamia zoquorum, Ceratozamia delucana, Ceratozamia becerrae, Ceratozamia alvarezii, Ceratozamia latifolia, Ceratozamia vovidesii, Ceratozamia zaragozae, Ceratozamia norstogii, Ceratozamia decumbens, Ceratozamia brevifrons, Ceratozamia miqueliana, Ceratozamia leptoceras, Ceratozamia santillanii, Ceratozamia kuesteriana, Ceratozamia huastecorum, Ceratozamia hondurensis, Ceratozamia totonacorum, unclassified Ceratozamia, Ceratozamia fuscoviridis, Ceratozamia euryphyllidia, Ceratozamia microstrobila, Ceratozamia chimalapensis, Ceratozamia whitelockiana, Ceratozamia chamberlainii, Ceratozamia subroseophylla
Macrozamin
Macrozamin is a glycoside. (Z)-methyl-oxido-[[(2S,3R,4S,5S,6R)-3,4,5-trihydroxy-6-[[(2S,3R,4S,5R)-3,4,5-trihydroxytetrahydropyran-2-yl]oxymethyl]tetrahydropyran-2-yl]oxymethylimino]ammonium is a natural product found in Macrozamia communis, Dioon spinulosum, and other organisms with data available. Macrozamin is a major constituent principle of Cycads. Macrozamin has carcinogenic, mutagenic, teratogenic and neurotoxic properties[1].
Cycasin
Cycasin is an alkaloid from seeds of the false sago Cycas circinalis and sago cycas Cycas revoluta (Cycadaceae). Carcinogen of significance in human nutrition; but in practice the toxin is present in the seeds of the plant and the pith is used as a food source. Isolated from human milk D009676 - Noxae > D002273 - Carcinogens D009676 - Noxae > D009498 - Neurotoxins
Methane
Methane (CH4), is a gas produced by a group of colonic anaerobes, absorbed from the colon and excreted in expired air. As a result, breath CH4 excretion can be used as an indicator of the in situ activity of the methanogenic flora. All CH4 produced in human beings is a metabolic product of intestinal bacteria, and about 50\\% of CH4 produced in the gut is absorbed and excreted in expired air. Because there appears to be no catabolism of this gas by other colonic organisms or host cells, breath CH4 measurements provide a rapid, simple means of semi quantitatively assessing the ongoing in situ metabolism of the methanogenic flora. It could seem likely that the intracolonic activity of a variety of bacteria similarly might be assessed quantitatively via analysis of expired air. However, the application of this methodology has been confounded by the rapid catabolism of many volatile bacterial products by other bacteria or human tissue. A striking aspect of the studies of breath CH4 measurements is the enormous individual variations in the excretion of this gas. Virtually all children under 5 years of age and 66\\% of the adult population do not exhale appreciable quantities of CH4. The remaining 34\\% of the adult population has appreciable breath methane concentrations of up to 80 ppm (mean, 15.2 ppm; median, 11.8 ppm). On this basis the population can be divided into CH4 producers or nonproducers, although a more accurate term would be to define subjects as being low or high CH4 producers. The primary methanogen present in the human colon, Methanobrevibacter smithii, produces methane via a reaction that relies entirely on H2 produced by other organisms to reduce CO2 to CH4. Thus, breath CH4 concentrations might be expected to mirror breath H2 concentrations; however, the high levels of CH4 observed in the fasting state may result from H2 derived from endogenous rather than dietary substrates. A diverse assortment of conditions has been associated with a high prevalence of methane producers including diverticulosis, cystic fibrosis, high fasting serum cholesterol levels, encopresis in children, and aorto-iliac vascular disease, whereas obesity (measured as skin-fold thickness) was related inversely to methane production. The challenge that remains is to determine to what extent methanogens actively influence body physiology vs. simply serve as passive indicators of colonic function. (PMID: 16469670, Clinical Gastroenterology and Hepatology Volume 4, Issue 2, February 2006, Pages 123-129). Methane can be found in Desulfovibrio, Methanobacterium, Methanobrevibacter, Methanococcus, Methanocorpusculum, Methanoculleus, Methanoflorens, Methanofollis, Methanogenium, Methanomicrobium, Methanopyrus, Methanoregula, Methanosaeta, Methanosarcina, Methanosphaera, Methanospirillium, Methanothermobacter (Wikipedia). Methane (CH4), is a gas produced by a group of colonic anaerobes, absorbed from the colon and excreted in expired air. As a result, breath CH4 excretion can be used as an indicator of the in situ activity of the methanogenic flora. All CH4 produced in human beings is a metabolic product of intestinal bacteria, and about 50\\% of CH4 produced in the gut is absorbed and excreted in expired air. Because there appears to be no catabolism of this gas by other colonic organisms or host cells, breath CH4 measurements provide a rapid, simple means of semi quantitatively assessing the ongoing in situ metabolism of the methanogenic flora. It could seem likely that the intracolonic activity of a variety of bacteria similarly might be assessed quantitatively via analysis of expired air. However, the application of this methodology has been confounded by the rapid catabolism of many volatile bacterial products by other bacteria or human tissue. A striking aspect of the studies of breath CH4 measurements is the enormous individual variations in the excretion of this gas. Virtually all children under 5 years of age and 66\\% of the adult population do not exhale appreciable quantities of CH4. The remaining 34\\% of the adult population has appreciable breath methane concentrations of up to 80 ppm (mean, 15.2 ppm; median, 11.8 ppm). On this basis the population can be divided into CH4 producers or nonproducers, although a more accurate term would be to define subjects as being low or high CH4 producers. The primary methanogen present in the human colon, Methanobrevibacter smithii, produces methane via a reaction that relies entirely on H2 produced by other organisms to reduce CO2 to CH4. Thus, breath CH4 concentrations might be expected to mirror breath H2 concentrations; however, the high levels of CH4 observed in the fasting state may result from H2 derived from endogenous rather than dietary substrates. A diverse assortment of conditions has been associated with a high prevalence of methane producers including diverticulosis, cystic fibrosis, high fasting serum cholesterol levels, encopresis in children, and aorto-iliac vascular disease, whereas obesity (measured as skin-fold thickness) was related inversely to methane production. The challenge that remains is to determine to what extent methanogens actively influence body physiology vs. simply serve as passive indicators of colonic function. (PMID: 16469670, Clinical Gastroenterology and Hepatology Volume 4, Issue 2, February 2006, Pages 123-129) [HMDB]
Triphasiaxanthin
Triphasiaxanthin is found in fruits. Triphasiaxanthin is a constituent of fruit of Triphasia trifolia (limeberry). Constituent of fruit of Triphasia trifolia (limeberry). Triphasiaxanthin is found in fruits.
Triphasiaxanthin
methane
A one-carbon compound in which the carbon is attached by single bonds to four hydrogen atoms. It is a colourless, odourless, non-toxic but flammable gas (b.p. -161degreeC).