A continuous‐flow technique for analysis of stoichiometry and transport kinetics of gastric H, K‐ATPase

Norberg, Lage; Mårdh, Sven

doi:10.1111/j.1748-1716.1990.tb09034.x

Cited by 6 publications

(1 citation statement)

References 26 publications

(13 reference statements)

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“…HCl is formed from Cl -and H + ; Clis passively released from oxyntic cells whereas H + is actively pumped from cells by the ATP-driven H + /K + -exchanger (H + /K + -ATPase or proton pump; Forte et al, 1980). While motility and pepsinogen production undoubtedly both contribute to the cost of gastric digestion, at least five lines of evidence emphasize the cost of acid production: (1) pythons maintain an intragastric pH of 1.5 in spite of the large buffering capacity of the rat meals for 5-7·days; (2) the production of such a quantity of HCl requires the proton pumps of the oxyntic cells to move H + from the cytosol into the gastric lumen against a concentration gradient in excess of a million-fold (Helander and Keeling, 1993); (3) the proton pumps operate via the hydrolysis of ATP with a stoichiometry of one H + pumped per ATP hydrolyzed (Reenstra and Forte, 1981;Norberg and Mårdh, 1990); (4) the gastric parietal cells of mammals contain the highest concentration of mitochondria (34-44% by volume) compared with any other mammalian cell type (Helander and Hirschowitz, 1972;Helander et al, 1986), and, in a preliminary study, I found python oxyntic cells to be 40% mitochondria by volume; and (5) acid secretion is absolutely dependent upon oxygen delivery (Forte et al, 1975;Berglindh, 1984). Collectively, these findings indicate that pythons expend considerable amounts of cellular energy via aerobic metabolic pathways to generate the vast quantity of HCl necessary to digest their large intact meals.…”

Section: Cost Of Gastric Digestionmentioning

confidence: 99%

Gastric function and its contribution to the postprandial metabolic response of the Burmese pythonPython molurus

Secor

2003

Journal of Experimental Biology

139

141

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SUMMARY The large intact prey ingested by Burmese pythons require considerable processing by the stomach before passage into the small intestine. To investigate the function and cost of gastric digestion and its contribution to postprandial metabolic response for the Burmese python, I examined the rate of gastric digestion, the postprandial profile of gastric pH and the effects of decreasing gastric workload on the metabolic cost of digestion, referred to as specific dynamic action (SDA). Ingested meal mass (equivalent to 25% of snake body mass) was reduced by 18% within 1 day postfeeding, by which time intragastric pH had decreased from 7.5 to 2. Gastric pH was maintained at 1.5 for the next 5–7 days, after which it returned to 7.5. The SDA generated by digesting an intact rat meal was reduced by 9.1%, 26.0%, 56.5% and 66.8%,respectively, when pythons were fed steak, ground rat, liquid diet or ground rat directly infused into the small intestine. The production of HCl and enzymes and other gastric functions represent an estimated 55% of the python's SDA generated from the digestion of an intact rodent meal. Additional contributors to SDA include protein synthesis (estimated 26%),gastrointestinal upregulation (estimated 5%) and the activities of the pancreas, gallbladder, liver, kidneys and intestines during digestion(estimated 14%). Operating on a `pay before pumping' principle, pythons must expend endogenous energy in order to initiate acid production and other digestive processes before ingested nutrients can be absorbed and channeled into metabolic pathways.

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Section: Cost Of Gastric Digestionmentioning

confidence: 99%

Gastric function and its contribution to the postprandial metabolic response of the Burmese pythonPython molurus

Secor

2003

Journal of Experimental Biology

139

141

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Integrative Physiology of Fasting

Secor

Carey

2016

Comprehensive Physiology

139

144

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Extended bouts of fasting are ingrained in the ecology of many organisms, characterizing aspects of reproduction, development, hibernation, estivation, migration, and infrequent feeding habits. The challenge of long fasting episodes is the need to maintain physiological homeostasis while relying solely on endogenous resources. To meet that challenge, animals utilize an integrated repertoire of behavioral, physiological, and biochemical responses that reduce metabolic rates, maintain tissue structure and function, and thus enhance survival. We have synthesized in this review the integrative physiological, morphological, and biochemical responses, and their stages, that characterize natural fasting bouts. Underlying the capacity to survive extended fasts are behaviors and mechanisms that reduce metabolic expenditure and shift the dependency to lipid utilization. Hormonal regulation and immune capacity are altered by fasting; hormones that trigger digestion, elevate metabolism, and support immune performance become depressed, whereas hormones that enhance the utilization of endogenous substrates are elevated. The negative energy budget that accompanies fasting leads to the loss of body mass as fat stores are depleted and tissues undergo atrophy (i.e., loss of mass). Absolute rates of body mass loss scale allometrically among vertebrates. Tissues and organs vary in the degree of atrophy and downregulation of function, depending on the degree to which they are used during the fast. Fasting affects the population dynamics and activities of the gut microbiota, an interplay that impacts the host's fasting biology. Fasting-induced gene expression programs underlie the broad spectrum of integrated physiological mechanisms responsible for an animal's ability to survive long episodes of natural fasting.

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Cell biology of gastric acid secretion

Helander¹,

Keeling²

1993

Baillière's Clinical Gastroenterology

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A continuous‐flow technique for analysis of stoichiometry and transport kinetics of gastric H, K‐ATPase

Cited by 6 publications

References 26 publications

Gastric function and its contribution to the postprandial metabolic response of the Burmese pythonPython molurus

Gastric function and its contribution to the postprandial metabolic response of the Burmese pythonPython molurus

Integrative Physiology of Fasting

Cell biology of gastric acid secretion

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