人小肠肽转运体hPepT1的底物上调
Substrate upregulation of the human small intestinal peptide transporter, hPepT1.
作者信息
Walker D, Thwaites D T, Simmons N L, Gilbert H J, Hirst B H
机构信息
Department of Physiological Sciences, University of Newcastle upon Tyne, Newcastle Upon Tyne NE2 4HH, UK.
出版信息
J Physiol. 1998 Mar 15;507 ( Pt 3)(Pt 3):697-706. doi: 10.1111/j.1469-7793.1998.697bs.x.
Abstract
- Molecular mechanisms underlying physiological adaptation to increased levels of dietary peptides have been elucidated by studying the response to the substrate glycyl-L-glutamine (Gly-Gln) of the proton-coupled peptide transporter, hPepT1, in the Caco-2 human intestinal cell line. Vmax for apical uptake of [14C]glycyl-[14C]sarcosine was increased 1.64 (+/- 0.34)-fold after incubation of Caco-2 cells for 3 days in a peptide-rich medium (4 mM Gly-Gln replacing 4 mM Gln). 2. A full-length Caco-2 hPepT1 cDNA clone was identical to human small intestinal hPepT1 with the exception of a single amino acid substitution Ile-662 to Val. Transcript sizes, on Northern blots of Caco-2 poly(A)+ RNA probed with a 630 bp 5' hPepT1 cDNA probe, correspond to the reported band pattern seen with human small intestinal RNA. The dipeptide-induced increase in substrate transport was accompanied by a parallel increase of 1.92 (+/- 0.30)-fold (n = 9) in hPepT1 mRNA. This was in part due to an increase in hPepT1 mRNA half-life from 8.9 +/- 1.1 to 12.5 +/- 1.6 h (n = 3), but the increase in half-life does not account fully for the observed increase in mRNA levels, suggesting that there was also a dipeptide-mediated increase in hPepT1 transcription. 3. Anti-hPepT1-specific antipeptide antibodies localized hPepT1 exclusively to the apical membrane of human small intestinal enterocytes and Caco-2 cells. Gly-Gln supplementation of media resulted in a 1.72 (+/- 0.26)-fold (n = 5) increase in staining intensity of Caco-2 cells. 4. We conclude that Caco-2 cells provide an appropriate model for the study of adaptation of intestinal hPepT1, at the molecular level, to increased levels of dietary peptide. The magnitude of functional increase in apical peptide transport activity in response to Gly-Gln can be fully accounted for by the increased levels of hPepT1 protein and mRNA, the latter mediated by both enhanced hPepT1 mRNA stability and increased transcription. The signalling pathway between increased dietary peptide and hPepT1 upregulation, therefore, involves direct action on the enterocyte, independent of hormonal and/or neural control.
摘要
- 通过研究质子偶联肽转运体hPepT1对底物甘氨酰-L-谷氨酰胺(Gly-Gln)在Caco-2人肠细胞系中的反应,阐明了生理适应饮食肽水平升高的分子机制。在富含肽的培养基(用4 mM Gly-Gln替代4 mM Gln)中培养Caco-2细胞3天后,[14C]甘氨酰-[14C]肌氨酸顶端摄取的Vmax增加了1.64(±0.34)倍。2. 一个全长Caco-2 hPepT1 cDNA克隆与人类小肠hPepT1相同,只是有一个氨基酸替换,即Ile-662变为Val。用630 bp 5' hPepT1 cDNA探针探测Caco-2多聚腺苷酸加尾RNA的Northern印迹上的转录本大小,与报道的人类小肠RNA的条带模式一致。二肽诱导的底物转运增加伴随着hPepT1 mRNA平行增加1.92(±0.30)倍(n = 9)。这部分是由于hPepT1 mRNA半衰期从8.9±1.1小时增加到12.5±1.6小时(n = 3),但半衰期的增加并不能完全解释观察到的mRNA水平增加,表明也有二肽介导的hPepT1转录增加。3. 抗hPepT1特异性抗肽抗体将hPepT1仅定位在人类小肠肠上皮细胞和Caco-2细胞的顶端膜上。培养基中添加Gly-Gln导致Caco-2细胞染色强度增加1.72(±0.26)倍(n = 5)。4. 我们得出结论,Caco-2细胞为在分子水平上研究肠道hPepT1对饮食肽水平升高的适应性提供了一个合适的模型。顶端肽转运活性对Gly-Gln反应的功能增加幅度可以完全由hPepT1蛋白和mRNA水平的增加来解释,后者是由hPepT1 mRNA稳定性增强和转录增加介导的。因此,饮食肽增加与hPepT1上调之间的信号通路涉及对肠上皮细胞的直接作用,独立于激素和/或神经控制。
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本文引用的文献
1
Peptides in human nutrition.人类营养中的肽。
Nutr Res Rev. 1989 Jan;2(1):87-108. doi: 10.1079/NRR19890009.
2
Nutrient regulation of human intestinal sugar transporter (SGLT1) expression.人类肠道糖转运蛋白(SGLT1)表达的营养调控
Gut. 1997 Jul;41(1):56-9. doi: 10.1136/gut.41.1.56.
3
Lactase and sucrase-isomaltase gene expression during Caco-2 cell differentiation.Caco-2细胞分化过程中的乳糖酶和蔗糖酶-异麦芽糖酶基因表达。
Biochem J. 1995 Jun 15;308 ( Pt 3)(Pt 3):769-75. doi: 10.1042/bj3080769.
4
Rapid enhancement of brush border glucose uptake after exposure of rat jejunal mucosa to glucose.大鼠空肠黏膜暴露于葡萄糖后刷状缘葡萄糖摄取迅速增强。
Gut. 1996 Oct;39(4):545-50. doi: 10.1136/gut.39.4.545.
5
Regulation of the mRNA-binding protein AUF1 by activation of the beta-adrenergic receptor signal transduction pathway.通过β-肾上腺素能受体信号转导途径的激活对mRNA结合蛋白AUF1进行调控。
J Biol Chem. 1996 Apr 5;271(14):8493-501. doi: 10.1074/jbc.271.14.8493.
6
Identification and characterization of a 44 kDa protein that binds specifically to the 3'-untranslated region of CYP2a5 mRNA: inducibility, subcellular distribution and possible role in mRNA stabilization.一种与CYP2a5 mRNA 3'-非翻译区特异性结合的44 kDa蛋白质的鉴定与特性:诱导性、亚细胞分布及其在mRNA稳定中的可能作用。
Biochem J. 1996 Feb 1;313 ( Pt 3)(Pt 3):1029-37. doi: 10.1042/bj3131029.
7
Inhibition of the H+/peptide cotransporter in the human intestinal cell line Caco-2 by cyclic AMP.环磷酸腺苷对人肠上皮细胞系Caco-2中H⁺/肽共转运体的抑制作用。
Biochem Biophys Res Commun. 1996 Jan 17;218(2):461-5. doi: 10.1006/bbrc.1996.0082.
8
Cloning and characterization of a rat H+/peptide cotransporter mediating absorption of beta-lactam antibiotics in the intestine and kidney.大鼠H⁺/肽共转运体的克隆与特性研究,该转运体介导β-内酰胺类抗生素在肠道和肾脏中的吸收。
J Pharmacol Exp Ther. 1995 Dec;275(3):1631-7.
9
Regulation of the ovine intestinal Na+/glucose co-transporter (SGLT1) is dissociated from mRNA abundance.绵羊肠道钠/葡萄糖共转运体(SGLT1)的调节与mRNA丰度无关。
Biochem J. 1993 Apr 15;291 ( Pt 2)(Pt 2):435-40. doi: 10.1042/bj2910435.
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