We have applied our new high yield, membrane-impermeant, protein cross-linking reagents (J.V. Staros, 1982. Biochemistry 21:3950-3955) together with chymotryptic digestion of the surface of intact erythrocytes (T.L. Steck, B. Ramos, and E. Strapazon, 1976. Biochemistry 15:1154-1161) in an investigation of the topology of the extracytoplasmic domain of the anion exchange channel of intact human erythrocytes. In intact erythrocytes, these cross-linking reagents have been shown to cross-link subunits of the anion exchange channel to dimers in the extracytoplasmic domain of the protein. Chymotryptic treatment of intact erythrocytes has been shown to cleave subunits of the anion exchange channel into two fragments of distinct Mr. Sequential treatment of intact erythrocytes with either of two membrane-impermeant cross-linkers, followed by digestion with chymotrypsin, yields chymotryptic fragments of the anion exchange channel cross-linked to one another. The cross-linked products observed appear to arise by cross-linking of unlike chymotryptic fragments, whether the cross-links are intersubunit or intrasubunit. These results are consistent with a model of the anion exchange channel in which the subunits form a head-to-head dimer with a twofold center of symmetry perpendicular to the plane of the membrane.
Microsomal triglyceride transfer protein (MTP) is a carrier of triglyceride essential for the assembly of apolipoprotein (apo)B-containing lipoproteins by the liver and the small intestine. Its role in triglyceride transfer in tissues that do not secrete lipoproteins has not been explored. In particular, MTP would seem to be a candidate for a role in triglyceride metabolism within the adipocyte. To test this hypothesis, we probed adipocytes for the presence of MTP. Immunohistochemical and biochemical studies demonstrate MTP in adipocytes from brown and white fat depots of mice and human, as well as in 3T3-L1 cells. Confocal microscopy revealed MTP throughout 3T3 cells; however, MTP fluorescence was prominent in juxtanuclear areas. In differentiated 3T3 cells MTP fluorescence was very striking around lipid droplets. In vitro lipid transfer assays demonstrated the presence of triglyceride transfer activity within microsomal fractions isolated from rat adipose tissue. In addition, quantitative rtPCR studies showed that MTP expression in mouse white fat depots was approximately 1% of MTP expression in mouse liver. MTP mRNA in differentiated 3T3 cells was approximately 13% of liver expression. Our results provide unequivocal evidence for the presence of MTP in adipocytes and present new possibilities for defining the mechanisms by which triglyceride is stored and/or hydrolyzed and mobilized.
1, 2)]. It was first isolated from bovine liver microsomes by Wetterau and Zilversmit (3) and later from rat liver and intestine (4), and it was shown to transfer lipid between phosholipid membranes. Its role in the assembly of lipoproteins was predicted but not defined until the discovery that abetalipoproteinemia, a rare genetic disorder leading to markedly decreased plasma levels of apolipoprotein B (apoB) and triglycerides, was a result of mutations in the MTP gene (5). Development of pharmacologic inhibitors of the transfer activity of MTP further underscored the role of MTP in lipoprotein assembly. These inhibitors substantially decrease apoB and triglyceride secretion by cells in culture (6-8), block production of VLDL in rodent models, and normalize plasma lipoprotein levels in Watanabe heritable hyperlipidemic rabbits (9). Finally, studies have shown that expression of apoB truncations ( Ͼ apoB-29) in nonlipoprotein-producing cells is accompanied by secretion of only trace amounts of the protein unless MTP is also expressed (10-13).The assumption that MTP is localized within the endoplasmic reticulum (ER) of the cell (14) has been based on several observations: 1 ) MTP was initially isolated from a microsomal fraction that consists primarily of the smooth and rough ER; 2 ) MTP is essential for VLDL production, and the most widely accepted model for VLDL assembly, the two-step model, predicts that both steps occur within the ER (15); and 3 ) MTP forms a heterodimer with protein disulfide isomerase (PDI) (14), and PDI contains a Lys-Asp-Glu-Leu (KDEL) sequence that retains it within the ER (16). It could therefore be assumed that the KDEL sequence would prevent the MTP/PDI complex from moving out of the ER to the Golgi apparatus.Studies from our laboratory have suggested that MTP is not restricted to the ER but is present within the Golgi apparatus. By comparing the composition of nascent VLDL recovered from the rough ER with VLDL recovered from Golgi apparatus-rich fractions of rat liver, we estimated that Abbreviations: ER, endoplasmic reticulum; McA, McArdle-RH7777; MTP, microsomal triglyceride transfer protein; PDI, protein disulfide isomerase.
Estrogen (E2) has been shown to induce the biosynthesis of retinoic acid (RA) in rat uterus. Here we examined whether E2 could directly induce the enzymes involved in this process by using the ovariectomized rat. A retinol dehydrogenase that we have previously described, eRolDH, and the retinal dehydrogenase, RalDH II, were found to have markedly increased uterine mRNA levels within 4 h of E2 administration, independent of the prior administration of puromycin. eRolDH and RalDH II and their mRNAs were also increased in uteri of rats during estrus. This indicated that RA biosynthesis in rat uterus is directly controlled by E2 and provides a direct link between the action of a steroid hormone and retinoid action. We also examined the cell-specific localization of RalDH II by immunohistochemistry. The enzyme was observed in the stromal compartment, particularly in cells close to the uterine lumenal epithelium. eRolDH was observed only in the lining epithelial cells. Taken together with the previous observations of cellular retinol-binding protein and cellular retinoic acid-binding protein, type two also being expressed in the lumenal epithelium, we propose that RA production is compartmentalized, with retinol oxidation occurring in the lumenal epithelium and subsequent oxidation of retinal to RA occurring in the underlying stromal cells.
Immunohistochemical and biochemical approaches were utilized to compare the expression of microsomal triglyceride transfer protein (MTP) and cellular retinol binding protein II (CRBPII) with the expression of apolipoprotein (apo)B and apoA-I along the entire length of the small intestine in mice. MTP is expressed in villus-associated enterocytes along the length of the small intestine. Maximal expression occurs within the first 20% of the intestine and decreases to less than 3% of maximum in the distal third of the intestine. The expression of CRBPII is nearly identical with that of MTP. Peak expression of apoB and apoA-I occurs in the first 25% of the intestine; however, expression in the most distal segments of the intestine is 10%-15% of maximum expression. In mice fed a Western diet for 3 weeks the expression of MTP and CRBPII was elevated in the distal regions of the intestine, whereas the expression patterns for apoB and apoA-I were similar to those found in mice on control diets. We conclude that the patterns of expression, as well as the regulation of MTP and CRBPII, are similar. However, the expression and regulation of these two proteins differ from those of apoB and apoA-I. In particular, the expression of MTP is not coordinated with the expression of apoB, even though the two proteins are essential for the assembly and secretion of chylomicrons.
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