Analysis of cloned cDNAs differentially expressed in adapting remnant small intestine after partial resection.

After partial resection, the remnant small intestine undergoes an adaptive response. Little is known about the molecular and cellular basis of intestinal adaptation. To identify genes transcriptionally regulated in response to loss of functional bowel surface area, we have isolated cDNAs differentially expressed in the adaptive ileum 48 h after 70% proximal small intestinal resection. A cDNA library constructed from the remnant ileum of rats subjected to resection was screened using subtractive hybridization techniques. Several groups of cDNA clones that were induced during intestinal adaptation were isolated. The first included liver fatty acid binding protein, apolipoprotein A-IV, cellular retinol binding protein II, and ileal lipid binding protein. These all encode proteins involved in the absorption, metabolism, and trafficking of nutrients. A second group included the catalytic subunit of protein phosphatase 1 delta, a 78-kDa glucose-regulated protein (grp 78; a glucose-regulated member of the 70-kDa heat-shock protein family), and several pancreatitis-associated proteins. A third group of induced genes contained novel cDNAs. To better characterize the adaptive response, the temporal, spatial, and cellular patterns of expression of several of these genes were analyzed with the use of immunohistochemical and in situ hybridization techniques. These studies indicate that during early adaptation, genes involved in nutrient trafficking, protein processing, and cell cycle regulation are transcriptionally regulated in the residual small intestine in distinct temporal and regional patterns consistent with a complex multifaceted response to intestinal resection.

Fluorine nuclear magnetic resonance analysis of the ligand binding properties of two homologous rat cellular retinol-binding proteins expressed in Escherichia coli.

Comparative 19F NMR studies were performed on rat cellular retinol-binding protein (CRBP) and cellular retinol-binding protein II (CRBPII) to better understand their role in intracellular retinol metabolism within the polarized absorptive epithelial cells (enterocytes) of the intestine. Efficient incorporation of 6-fluorotryptophan (6-FTrp) into these homologous proteins was achieved by growing a tryptophan auxotroph of Escherichia coli, harboring prokaryotic expression vectors with either a full-length rat CRBPII or CRBP cDNA on defined medium supplemented with the analog. It is possible to easily distinguish resonances corresponding to 6-FTrp-apoCRBP, 6-FTrp-CRBP-retinol (or retinal), 6-FTrp-apoCRBPII, and 6-FTrp-CRBPII-retinol (or retinal). We were thus able to use 19F NMR spectroscopy to monitor transfer of all-trans-retinol and all-trans-retinal between CRBPII and CRBP in vitro. Retinol complexed to CRBPII is readily transferred to CRBP, whereas retinol complexed to CRBP is not readily transferred to CRBPII. We estimated that the Kd for CRBP-retinol is approximately 100-fold less than the Kd for CRBPII-retinol. Transfer of all-trans-retinal occurs readily from CRBPII to CRBP and from CRBP to CRBPII. Results from competitive binding studies with retinol and retinal indicated that there is a much larger difference between the affinities of CRBP for retinol and retinal than between the affinities of CRBPII for these two ligands. However, the differences in binding specificities reflect differences in how the two proteins interact with retinol, rather than with retinal. 19F NMR analysis of recombinant isotopically labeled proteins represents a sensitive new and useful method for monitoring retinoid flux between the CRBPs in vitro.