Structural studies of the H+/oligopeptide transport system from rabbit small intestine.

A 127-kDa protein was identified as a component of the H+/oligopeptide transport system in brush-border membrane vesicles from rabbit small intestine by photoaffinity labeling with [3H]cephalexin and further photoreactive beta-lactam antibiotics and dipeptides. Reconstitution of stereospecific transport activity revealed the involvement of the 127-kDa protein in H+-dependent transport of oligopeptides and orally active alpha-amino-beta-lactam antibiotics (Kramer et al., Eur. J. Biochem. 204 (1992) 923-930). H+-Dependent transport activity was found in all segments of the small intestine concomitantly with the specific labeling of the 127-kDa protein. By enzymatic deglycosylation, fragments of Mr 116 and 95 kDa were obtained from the 127-kDa protein with endoglucosidase F and N-glycanase, whereas with endoglucosidase H, a fragment of Mr 116 kDa was formed. These findings indicate that the photolabeled 127-kDa protein is a microheterogenous glycoprotein. Surprisingly, it was found that the solubilized and purified 127-kDa protein showed enzymatic sucrase and isomaltase activity. Inhibition of the glucosidase activities with the glucosidase inhibitor HOE 120 influenced neither H+/oligopeptide transport nor photoaffinity labeling of the 127-kDa protein. With polyclonal antibodies raised against the purified 127-kDa protein, a coprecipitation of sucrase activity and the photolabeled 127-kDa beta-lactam antibiotic binding protein occurred. Target size analysis revealed a functional molecular mass of 165+/-17 kDa for photoaffinity labeling of the 127-kDa protein, suggesting a homo- or heterodimeric functional structure of the 127-kDa protein in the brush-border membrane. These findings indicate that the H+/oligopeptide binding protein of Mr 127000 is closely associated with the sucrase/isomaltase complex in the enterocyte brush-border membrane.

Topological photoaffinity labeling of the rabbit ileal Na+/bile-salt-cotransport system.

For the investigation of the topology of the rabbit ileal Na+/bile-salt-cotransport system, composed of a 93-kDa integral membrane protein and a peripheral 14-kDa bile-acid-binding protein (ILBP), we have synthesized photolabile dimeric bile-salt-transport inhibitors (photoblockers), G1-X-G2, where two bile acid moieties (G1 and G2) are tethered together via a spacer, X, and where one of the two bile acid moieties carries a photoactivatable group. These photoblockers specifically interact with the ileal Na+/bile-salt-cotransport system as demonstrated by a concentration-dependent inhibition of [3H]cholyltaurine uptake by rabbit ileal brush-border membrane vesicles and by inhibition of photolabeling of the 93-kDa and 14-kDa bile-salt-binding proteins by 7,7-azo and 3,3-azo derivatives of cholyltaurine. Ileal bile-salt uptake was specifically inhibited by the photoblockers, which were not taken up themselves by the small intestine as demonstrated by in vivo ileal perfusion. Dependent on the photoblocker used several polypeptides in the molecular-mass range of 14-130 kDa were labeled. The cytoplasmically attached 14-kDa ILBP was significantly labeled only by inhibitors that are photoactivatable in bile acid moiety G1, suggesting that during binding and translocation of a bile-salt molecule by the ileal bile-salt-transport system the steroid nucleus gets access to the cytoplasmic site of the ileal brush-border membrane first. Photoaffinity labeling in the frozen state with the transportable 3,3-azo and 7,7-azo derivatives of cholyltaurine revealed a time-dependent increase in the extent of labeling of the 14-kDa and 93-kDa proteins, suggesting a labeling of these proteins from the cytoplasmic site of the ileal brush-border membrane. By photoaffinity labeling in the frozen state with the various photoblockers time-dependent changes in the extent of photoaffinity labeling of bile-salt-binding proteins were observed, demonstrating the possibility of topological analysis of the rabbit ileal Na+/bile-salt-cotransport system.

The rabbit ileal lipid-binding protein. Gene cloning and functional expression of the recombinant protein.

A bile-acid-binding protein of Mr 14000 has been previously identified by photoaffinity labeling in rabbit ileal brush border membrane vesicles [Kramer et al. (1993) J. Biol. Chem. 268, 18035-18046]. This peripheral membrane-associated protein was purified and identified as an ileal lipid-binding protein. It was further shown to be identical to the cytosolic 14-kDa bile-acid-binding protein from the same tissue. Starting with sequence information from tryptic fragments, we cloned and sequenced the gene and its transcript. It has four exons (123, 176, 90, 115 bp) and three introns (1372, 2291, 3137 bp) and a similar structure as the genes from other members of the fatty-acid-binding protein family. The deduced protein has 128 amino acid residues and a calculated molecular mass of 14404 Da. It exhibits high similarity to its human (83%), mouse (77%), rat (76%) and porcine (72%) counterparts. Furthermore, the recombinant protein was produced in Escherichia coli and shown to be identical to native protein from ileal tissue. Functionality of the recombinant protein was demonstrated by labeling with various photoaffinity derivatives of bile acids. Ranking of the photolabeling efficiency of these probes towards the recombinant protein was comparable to the respective ranking towards the native protein. Polyclonal antibodies that were raised in hens against the recombinant protein, specifically recognized the ileal lipid-binding protein in the brush border membrane and cytosol from rabbit ileum. In contrast, no labeling was observed with jejunal tissue. Our results suggest a specific role of the membrane-associated ileal lipid-binding protein for the process of ileal bile acid uptake.