2013
DOI: 10.1242/jeb.088203
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Cold exposure increases intestinal paracellular permeability to nutrients in the mouse

Abstract: SUMMARYIn situations of increased energy demand and food intake, animals can often acclimate within several days. The intestine generally responds to elevated digestive demand by increasing in size. However, there is likely a limit to how quickly the intestine can grow to meet the new demand. We investigated the immediate and longer-term changes to intestinal properties of the mouse when suddenly exposed to 4°C. We hypothesized that paracellular permeability to nutrients would increase as part of an immediate … Show more

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Cited by 12 publications
(12 citation statements)
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“…The data suggest a signaling mechanism linking adiposity, hypothalamic neuropeptide gene expression, and intestinal growth, where the latter two changes may act to increase energy assimilation to counteract the energy loss in the adipose tissue. In fact, energy restriction, lactation, and cold exposure, each of which reduces adiposity and plasma leptin, also increased energy intake and the intestinal weight (8,30,40,46). By changing the protein to WPI, and bearing in mind the effect on the intestinal mechanisms of energy absorption and presumed energy loss, the above effects of the low sucrose were accentuated.…”
Section: Discussionmentioning
confidence: 99%
“…The data suggest a signaling mechanism linking adiposity, hypothalamic neuropeptide gene expression, and intestinal growth, where the latter two changes may act to increase energy assimilation to counteract the energy loss in the adipose tissue. In fact, energy restriction, lactation, and cold exposure, each of which reduces adiposity and plasma leptin, also increased energy intake and the intestinal weight (8,30,40,46). By changing the protein to WPI, and bearing in mind the effect on the intestinal mechanisms of energy absorption and presumed energy loss, the above effects of the low sucrose were accentuated.…”
Section: Discussionmentioning
confidence: 99%
“…These differences were interpreted as a flexible phenotypic response to the higher rates of food intake necessary to satisfy the higher energetic demands of wintering in Norway (Summers et al, 1998). Such phenotypic changes in gut morphology and function are well documented in many species in response to a variety of environmental and lifehistory stimuli (Clissold et al, 2013;Dykstra and Karasov, 1992;Price et al, 2013;Starck, 1999). However, given the identical holding conditions of our experimental setup, differences between the subspecies noted here probably represent intrinsic adaptations rather than phenotypic responses.…”
Section: Discussionmentioning
confidence: 99%
“…We have since extended our measurements to include more birds, several bat species, other small nonflying mammals, and a lizard (12,14,27,28,67,75,76,78,87,88,107) (Price E, Karasov W, unpublished observations). In FIGURE 6A, we have plotted the 7 bats, 19 birds, 1 lizard, and 18 nonflying mammals for which we could find measurements of the fractional absorption of the following nutrient-sized probes: Diet was not a significant factor in either set.…”
Section: Meeting Absorptive Demand With Smaller Intestines Via Highermentioning
confidence: 99%