The long-term objectives of this renewal application are to develop a better understanding of the absorption process of vitamin H (biotin) in the human intestine, with specific focus on the molecular regulation of the involved transport system, i.e., the human sodium-dependent multivitamin transporter (hSMVT), as well as the mechanisms involved in the targeting and intracellular trafficking of the hSMVT protein to the apical membrane of human intestinal epithelial cells. Biotin, a member of the water-soluble family of vitamins, is essential for normal cellular functions, growth, and development. Biotin deficiency leads to serious clinical abnormalities that include neurological disorders, growth retardation, and dermal abnormalities. Humans and other mammals cannot synthesize biotin, and thus, must obtain the vitamin from exogenous sources via absorption in the intestine. Therefore, the intestine plays a central role in determining and regulating normal biotin body homeostasis. Studies from our laboratory over the past several years have cloned the rat intestinal biotin SMVT system, characterized the 5' regulatory region of its gene, and examined the effect of ontogeny on intestinal biotin uptake process. Much less, however, is currently known about the molecular regulation of the biotin uptake process in the human intestine, and how biotin deficiency and cell differentiation regulates the process. Nothing is also known about the cell biology of the hSMVT protein in intestinal epithelial cells with regards to the molecular mechanisms involved in its targeting to the apical membrane and intracellular trafficking. In recent preliminary studies, we have obtained evidence showing the existence of two promoters that drive the transcription of the hSMVT gene, and demonstrating that the human intestinal biotin uptake process is regulated (via transcriptional mechanisms) in biotin deficiency and during cell differentiation. We have also established the use of confocal imaging of living human intestinal epithelial Caco-2 cells to study the mechanisms involved in hSMVT targeting to the apical membrane and intracellular trafficking. We propose in this application to continue these investigations and describe three specific aims: I) To continue the characterization of the 5' regulatory region of the hSMVT gene in vitro in human intestinal epithelial cells, and to confirm activity and physiological relevance of the identified promoters in vivo in transgenic mice. II) To continue the characterization of the molecular mechanism(s) involved in the regulation of biotin uptake by human intestinal epithelial cells in biotin deficiency and during cell differentiation. Ill) To study the mechanisms involved in the targeting of the hSMVT protein to the apical membrane of the human intestinal epithelial cells, and to determine the mechanisms involved in its intracellular trafficking. Results of these studies should provide novel and valuable information regarding the molecular/cellular mechanisms involved in the regulation of the human intestinal biotin absorption process and the cell biology of the hSMVT system. This should ultimately assist us in the design of effective strategies to optimize biotin body homeostasis in conditions associated with biotin deficiency and sub-optimal levels.

Agency
National Institute of Health (NIH)
Institute
National Institute of Diabetes and Digestive and Kidney Diseases (NIDDK)
Type
Research Project (R01)
Project #
5R01DK058057-07
Application #
7125937
Study Section
Special Emphasis Panel (ZRG1-DIG-C (02))
Program Officer
May, Michael K
Project Start
2005-09-30
Project End
2010-07-31
Budget Start
2006-08-01
Budget End
2007-07-31
Support Year
7
Fiscal Year
2006
Total Cost
$285,471
Indirect Cost
Name
Southern California Institute for Research/Education
Department
Type
DUNS #
622027209
City
Long Beach
State
CA
Country
United States
Zip Code
90822
Sabui, Subrata; Kapadia, Rubina; Ghosal, Abhisek et al. (2018) Biotin and pantothenic acid oversupplementation to conditional SLC5A6 KO mice prevents the development of intestinal mucosal abnormalities and growth defects. Am J Physiol Cell Physiol 315:C73-C79
Subramanian, Veedamali S; Sabui, Subrata; Moradi, Hamid et al. (2018) Inhibition of intestinal ascorbic acid uptake by lipopolysaccharide is mediated via transcriptional mechanisms. Biochim Biophys Acta Biomembr 1860:556-565
Elahi, Asif; Sabui, Subrata; Narasappa, Nell N et al. (2018) Biotin Deficiency Induces Th1- and Th17-Mediated Proinflammatory Responses in Human CD4+ T Lymphocytes via Activation of the mTOR Signaling Pathway. J Immunol 200:2563-2570
Lakhan, Ram; Subramanian, Veedamali S; Said, Hamid M (2017) Role of MicroRNA-423-5p in posttranscriptional regulation of the intestinal riboflavin transporter-3. Am J Physiol Gastrointest Liver Physiol 313:G589-G598
Subramanian, Veedamali S; Srinivasan, Padmanabhan; Wildman, Alexis J et al. (2017) Molecular mechanism(s) involved in differential expression of vitamin C transporters along the intestinal tract. Am J Physiol Gastrointest Liver Physiol 312:G340-G347
Sabui, Subrata; Subramanian, Veedamali S; Kapadia, Rubina et al. (2017) Adaptive regulation of pancreatic acinar mitochondrial thiamin pyrophosphate uptake process: possible involvement of epigenetic mechanism(s). Am J Physiol Gastrointest Liver Physiol 313:G448-G455
Lakhan, Ram; Said, Hamid M (2017) Lipopolysaccharide inhibits colonic biotin uptake via interference with membrane expression of its transporter: a role for a casein kinase 2-mediated pathway. Am J Physiol Cell Physiol 312:C376-C384
Subramanian, Veedamali S; Constantinescu, Alexandru R; Benke, Paul J et al. (2017) Mutations in SLC5A6 associated with brain, immune, bone, and intestinal dysfunction in a young child. Hum Genet 136:253-261
Anandam, Kasin Yadunandam; Srinivasan, Padmanabhan; Subramanian, Veedamali S et al. (2017) Molecular mechanisms involved in the adaptive regulation of the colonic thiamin pyrophosphate uptake process. Am J Physiol Cell Physiol 313:C655-C663
Subramanian, Veedamali S; Sabui, Subrata; Teafatiller, Trevor et al. (2017) Structure/functional aspects of the human riboflavin transporter-3 (SLC52A3): role of the predicted glycosylation and substrate-interacting sites. Am J Physiol Cell Physiol 313:C228-C238

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