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Query: UMLS:C0038187 (
starvation
)
24,951
document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)
Cell proliferation and differentiation are influenced by environmental factors, including the extracellular pH. We recently showed, using an ex vivo organ culture system of human mucosal
Barrett
's esophageal biopsies, that acid has a highly variable effect on cell proliferation and differentiation depending on the pattern of acid exposure. Study of the mechanisms underlying these dynamic effects of acid on this premalignant intestinal-like epithelium is hampered by lack of an immortalized cell line. We therefore investigated the effect of acid exposure on the human colonic carcinoma cell line HT29, chosen because of its intestinal cell derivation and its ability to differentiate in vitro. HT29 cells exposed to pH 5 medium either continuously (up to 3 weeks), or as a short (1 hour) pulse, were compared with cells cultured at pH 7.4. Villin expression was induced only by long term acid exposure, and correlated with the development of differentiated polarized cells that contain a brush border and microvillus inclusions. Chronic acid exposure arrested cell proliferation, whereas a 1 hour acid-pulse enhanced cell proliferation, as determined by [3H]thymidine incorporation assays and proliferating cell nuclear antigen expression. Serum
starvation
attenuated the hyperproliferative effect of an acid-pulse. In addition, the doubling time of at least the first cell cycle after an acid-pulse was shortened. The Na/H exchanger is likely to play a role since the hyperproliferative acid-induced response was blocked by amiloride; and the activity of the exchanger was increased at acidic pH as determined by 22Na uptake. These results support a role for extracellular pH on cell proliferation and differentiation of HT29 cells. Furthermore, these findings parallel the dynamic effects of acid on
Barrett's esophagus
, and suggest that HT29 cells could serve as an in vitro model for studying the mechanism of acid modulation in
Barrett's esophagus
.
...
PMID:Acid modulation of HT29 cell growth and differentiation. An in vitro model for Barrett's esophagus. 909 48
The human oesophageal epithelium is subject to damage from thermal stresses and low extracellular pH that can play a role in the cancer progression sequence, thus identifying a physiological model system that can be used to determine how stress responses control carcinogenesis. The classic heat shock protein HSP70 is not induced but rather is down-regulated after thermal injury to squamous epithelium ex vivo; this prompted a longer-term study to address the nature of the heat shock response in this cell type. An ex vivo epithelial culture system was subsequently used to identify three major proteins of 78, 70, and 58 kDa, whose steady-state levels are elevated after heat shock. Two of the three heat shock proteins were identified by mass spectrometric sequencing to be the calcium-calmodulin homologue transglutaminase-3 (78 kDa) and a recently cloned oesophageal-specific gene called C1orf10, which encodes a 53-kDa putative calcium binding protein we have named squamous epithelial heat shock protein 53 (SEP53). The 70-kDa heat shock protein (we have named SEP70) was not identifiable by mass spectrometry, but it was purified and studied immunochemically to demonstrate that it is distinct from HSP70 protein. Monoclonal antibodies to SEP70 protein were developed to indicate that: (a) SEP70 is induced by exposure of cultured cells to low pH or glucose
starvation
, under conditions where HSP70 protein was strikingly down-regulated; and (b) SEP70 protein exhibits variable expression in preneoplastic
Barrett
's epithelium under conditions where HSP70 protein is not expressed. These results indicate that human oesophageal squamous epithelium exhibits an atypical heat shock protein response, presumably due to the evolutionary adaptation of cells within this organ to survive in an unusual microenvironment exposed to chemical, thermal and acid reflux stresses.
...
PMID:The human oesophageal squamous epithelium exhibits a novel type of heat shock protein response. 1160 97
Barrett's oesophagus
(BO) and oesophageal adenocarcinoma (OAC) are regarded as complications of gastro-oesophageal reflux disease, although all the factors that contribute to the development of these lesions are unknown. Acid suppressive drugs are widely used for symptomatic therapy of reflux disease but may induce hypersecretion of gastrin peptides. Amidated gastrin (G-17) has been shown to be a growth factor for OAC cells. We have examined the effects of glycine-extended gastrin (G-Gly), an alternative product of progastrin processing on apoptosis in the QhERT
Barrett
's oesophageal cell line and OE33 and BIC-1 OAC cells. G-Gly inhibited serum-
starvation
and camptothecin-induced apoptosis in all three cell lines, G-17 was only effective in OE33 cells. By contrast to the effects of G-17, the anti-apoptotic effect of G-Gly was independent of both the CCK(2) receptor and cyclo-oxygenase-2 activity. G-Gly stimulated JAK2 phosphorylation and kinase activity and JAK2-dependent STAT3 phosphorylation and transcriptional activity. G-Gly also increased mRNA and protein levels of the anti-apoptotic proteins survivin and BCL2L1 but did not affect the levels of BAD, BAX or BCL-2. Novel small molecule inhibitors of JAK2 and STAT3 as well as STAT3 siRNA blocked the anti-apoptotic effects of G-Gly and inhibited the induction of survivin and BCL2L1 in OE33 cells. We conclude that G-Gly inhibits apoptosis in BO and OAC via mechanisms distinct from those activated by G-17 and involving JAK2 and STAT3 activation. Release of gastrin peptides in response to acid suppressive therapy may adversely influence the dynamics of the epithelium in BO.
...
PMID:Glycine-extended gastrin inhibits apoptosis in Barrett's oesophageal and oesophageal adenocarcinoma cells through JAK2/STAT3 activation. 1915 90
Plant vascular systems are constructed by specific cell wall modifications through which cells are highly specialized to make conduits for water and nutrients. Xylem vessels are formed by thickened cell walls that remain after programmed cell death, and serve as water conduits from the root to the shoot. In contrast, phloem tissues consist of a complex of living cells, including sieve tube elements and their neighboring companion cells, and translocate photosynthetic assimilates from mature leaves to developing young tissues. Intensive studies on the content of vascular flow fluids have unveiled that plant vascular tissues transport various types of gene product, and the transport of some provides the molecular basis for the long-distance communications. Analysis of xylem sap has demonstrated the presence of proteins in the xylem transpiration stream. Recent studies have revealed that
CLE
and CEP peptides secreted in the roots are transported to above ground via the xylem in response to plant-microbe interaction and soil nitrogen
starvation
, respectively. Their leucine-rich repeat transmembrane receptors localized in the shoot phloem are required for relaying the signal from the shoot to the root. These findings well-fit to the current scenario of root-to-shoot-to-root feedback signaling, where peptide transport achieves the root-to-shoot signaling, the first half of the signaling process. Meanwhile, it is now well-evidenced that proteins and a range of RNAs are transported via the phloem translocation system, and some of those can exert their physiological functions at their destinations, including roots. Thus, plant vascular systems may serve not only as conduits for the translocation of essential substances but also as long-distance communication pathways that allow plants to adapt to changes in internal and external environments at the whole plant level.
...
PMID:Dynamics of long-distance signaling via plant vascular tissues. 2585 14
Organ-to-organ communication is indispensable for higher organisms to maintain homeostasis over their entire life. Recent findings have uncovered that plants, like animals, mediate organ-to-organ communication by long-distance signaling through the vascular system. In particular, xylem-mobile secreted peptides have attracted much attention as root-to-shoot long-distance signaling molecules in response to fluctuating environmental nutrient status. Several leguminous
CLE
peptides induced by rhizobial inoculation act as 'satiety' signals in long-distance negative feedback of nodule formation. By contrast, Arabidopsis CEP family peptides induced by local nitrogen (N)-
starvation
behave as systemic 'hunger' signals to promote compensatory N acquisition in other parts of the roots. Xylem sap peptidomics also implies the presence of still uncharacterized long-distance signaling peptides. This review highlights the current understanding of and new insights into the mechanisms and functions of root-to-shoot long-distance peptide signaling during environmental responses.
...
PMID:Long-distance peptide signaling essential for nutrient homeostasis in plants. 2755 46
