Regulation of Sterol Regulatory Element-binding Proteins in Hamster Intestine by Changes in Cholesterol Flux*

F. Jeffrey FieldDagger, Ella Born, Shubha Murthy, and Satya N. Mathur

From the Department of Internal Medicine and Department of Veterans Affairs, University of Iowa, Iowa City, Iowa 52242

Received for publication, December 4, 2000, and in revised form, February 12, 2001


    ABSTRACT
TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

A control chow diet or diets containing 1% cholesterol (cholesterol-enriched) or 4% cholestyramine and 0.15% lovastatin (cholesterol-depletion) were fed to hamsters for 2 weeks. Sterol regulatory element-binding protein (SREBP)-1a, SREBP-1c, SREBP-2, 3-hydroxy-3-methylglutaryl-coenzyme A reductase, 3-hydroxy-3-methylglutaryl-coenzyme A synthase, and LDL receptor mRNA levels and SREBP-1 and -2 protein expression were estimated in villus cell populations from duodenum, jejunum, and ileum. SREBP-1a was a minor transcript in hamster intestine, and its gene expression was not altered by changes in dietary cholesterol flux. In contrast, SREBP-1c gene expression was increased by dietary cholesterol and decreased by cholesterol depletion. mRNA levels for SREBP-2 and the other sterol-responsive genes were increased in intestines of animals on the cholesterol depletion diet but minimally suppressed if at all, by the diet enriched in cholesterol. In general, the amount of the precursor form of SREBP-1 was higher in cells of the upper villus and lower in cells of the lower villus. SREBP-2 precursor was higher in cells of the lower villus and lower in cells of the upper villus. Protein expression of precursor correlated with the location of gene expression for SREBPs. The amount of precursor mass of SREBP-2 was not altered by cholesterol feeding but was increased by cholesterol depletion. The mature form of SREBP-2 was in very low abundance and difficult to detect in intestines of animals fed control chow or cholesterol. It was readily detectable and increased in intestines of animals on the cholesterol-depletion diet. The diets did not significantly alter the amount of precursor or mature forms of SREBP-1. Cholesterol feeding had no effect on cholesterol or fatty acid synthesis, whereas synthesis of these lipids was increased in intestines of hamsters on the cholesterol-depleted diet. These results suggest that SREBP-1a has little or no role in regulating intestinal cholesterol synthesis. It is postulated that under basal conditions, SREBP-1c regulates intestinal fatty acid synthesis and SREBP-2 regulates cholesterol synthesis. Following marked changes in cholesterol flux across the intestine, SREBP-2 assumes the role of SREBP-1 and regulates both cholesterol and fatty acid synthesis in intestine.


    INTRODUCTION
TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

The cholesterol content of all cells is tightly controlled. When cholesterol is in excess, cells decrease both lipoprotein cholesterol uptake and cholesterol synthesis to prevent accumulation of this potentially toxic sterol. In contrast, when cells have insufficient cholesterol to meet their sterol requirements, lipoprotein cholesterol uptake is increased as are rates of cholesterol biosynthesis. This end product feedback mechanism of regulating the amount of cellular cholesterol has been extensively studied and characterized (for a review, see Ref. 1). Understanding of how a cell senses and regulates the amount of cholesterol has been advanced by the characterization of two transcription factors called sterol regulatory element-binding proteins (SREBPs),1 SREBP-1 and -2 (for a review, see Ref. 2). SREBPs are bound to membranes of the endoplasmic reticulum and nuclear envelope. Under conditions of cholesterol deficiency, a two-step proteolytic process releases from the membrane "precursor" protein a "mature" form of the protein (3). This active form of the protein enters the nucleus and binds to a 10-base pair sterol regulatory element that enhances the transcription of target genes that encode enzymes regulating cholesterol and fatty acid synthesis (4-8). SREBP-1 and -2 are derived from two separate genes. Two isoforms of SREBP-1 exist, 1a and 1c (9). SREBP-1a appears to be the more potent transcription factor and regulates genes of both fatty acid and cholesterol pathways (10). SREBP-1c, in contrast, tends to be more active in regulating genes of the fatty acid biosynthetic pathway (10). SREBP-2 preferentially enhances several genes of the cholesterol biosynthetic pathway (11-13).

We have recently characterized gene expression for SREBP-1 and -2 in hamster small intestine and have implicated SREBP-2 as responsible for regulating cholesterol synthesis and SREBP-1c as responsible for regulating fatty acid synthesis in intestine (14). We have also demonstrated that changes in cholesterol flux across the intestinal cell regulate gene expression of SREBP-1c and several sterol-responsive genes, including SREBP-2. In the present study, we have extended our investigations into the regulation of intestinal SREBPs by studying the regulation of SREBP gene and protein expression in hamster small intestine by changes in cholesterol flux. The results demonstrate that a diet enriched in cholesterol increases gene expression of SREBP-1c, whereas a cholesterol-depletion diet markedly decreases its expression. In contrast, a cholesterol-depletion diet results in a substantial increase in the expression of SREBP-2 and other sterol-responsive genes, HMG-CoA reductase, HMG-CoA synthase, and the LDL receptor, while dietary cholesterol had little, if any effect on the expression of these genes. In the intestines of hamsters on control or cholesterol diets, the mature form of SREBP-2 is in very low abundance. In intestines of animals on the cholesterol-depletion diet, the precursor and mature forms of SREBP-2 are increased.

    MATERIALS AND METHODS
TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

Tritiated water and [32P]UTP were purchased from PerkinElmer Life Sciences. Protease inhibitors, TRI REAGENT, INFINITY cholesterol reagent, and cholesterol were purchased from Sigma. MAXIscript T7 and RPA III kits were supplied by Ambion (Austin, TX). Medium M199 was from Life Technologies, Inc. Lovastatin was obtained from Merck. Cholestyramine was obtained from Bristol-Myers Squibb Co.

Animals-- Male Golden Syrian hamsters weighing 90-120 g were purchased from Harlan Sprague-Dawley, Inc. They were maintained for a week on NIH-31 modified mouse/rat diet number 7013 (Harlan/Teklad, Madison, WI) before starting the test diets. The animals were fed the test diets ad libitum, and the light cycle was 0600-1800 h. The control chow diet was prepared by adding 1% olive oil to Teklad 4% mouse/rat meal, number 7001. The cholesterol-enriched diet was prepared by dissolving 1% cholesterol in the olive oil and thoroughly mixing with the control chow diet. To prepare the cholesterol-depletion diet, the control chow diet was supplemented with 4% (w/w) cholestyramine and 0.15% (w/w) lovastatin (dissolved in olive oil). The start of the dietary period was staggered in the hamsters so that all animals were fed the respective diets for exactly 14 days.

Isolation of Enterocytes-- Hamsters were killed between 0800 and 0900 h by inhalation of CO2. The small intestine was removed in its entirety and placed in a beaker containing cold 0.9% saline. Isolated intestinal cells were prepared by a procedure described by Cartwright and Higgins that was modified for hamster intestine (14, 15). The lumen of the intestine was flushed with solution A (117 mM NaCl, 5.4 mM KCl, 0.96 mM NaH2PO4, 26 mM NaHCO3, 5 mM HEPES, 5.5 mM glucose) to remove fecal material and debris. The intestine was then filled with solution B (67.5 mM NaCl, 1.5 mM KCl, 0.96 mM NaH2PO4, 26 mM NaHCO3, 5 mM HEPES, 5.5 mM glucose, 27 mM sodium citrate) and placed in a beaker containing 0.9% saline at 37 °C. The beaker was gently agitated for 15 min. Solution B was removed, and the intestine was divided into three equal segments representing duodenum, jejunum, and ileum. Each segment was filled with solution C (115 mM NaCl, 5.4 mM KCl, 0.96 mM NaH2PO4, 26 mM NaHCO3, 1.5 mM EDTA, 0.5 mM dithiothreitol, 5 mM HEPES, 5.5 mM glucose) and placed in a beaker containing 0.9% saline at 37 °C. The beakers were gently agitated in a shaking water bath to isolate cells along the villus. Solution C was emptied into plastic conical centrifuge tubes every 5 min and replaced. The tubes containing the cells were kept on ice until 12 fractions were collected. Two sequential fractions were then pooled from the first eight fractions, and the last four fractions were combined to obtain a total of five fractions (16). Cells were collected by centrifugation at 1000 × g for 10 min at 4 °C.

Cholesterol and Fatty Acid Synthesis-- Cholesterol and fatty acid synthesis were estimated by incorporation of tritiated water into these lipids 4 h after intraperitoneal injection of 100 mCi of tritiated water (1 Ci/g; PerkinElmer Life Sciences) (17). Intestinal cell fractions were collected from duodenum, jejunum, and ileum as described above. The cells were then suspended in 2 ml of 90% methanol containing 0.5 M NaOH and kept in boiling water for 1 h to saponify the lipids. After adding an equal volume of acidic water, the lipids were extracted twice at pH 3.0 with 4 ml of hexanes. To remove residual labeled water, the hexane extract was washed once with 1 ml of acidic water. The hexanes were evaporated under a stream of nitrogen, and the lipids were dissolved in 0.1 ml of chloroform. Fatty acids and cholesterol were separated by thin layer chromatography on silica gel plates using hexanes/diethyl ether/acetic acid/methanol (70:30:1:1, v/v/v/v) as solvent. The lipids were visualized by exposure to iodine, and the radioactivity in fatty acids and cholesterol fractions was determined by scraping the bands and counting in a Packard Tricarb 2100-TR liquid scintillation counter.

Estimation of Cholesterol Mass-- Cellular lipids were extracted with hexane/isopropyl alcohol/water (3:2:0.1, v/v/v). Cholesteryl esters were separated from unesterified cholesterol by TLC on silica gel plates using a solvent system of hexanes/diethyl ether/acetic acid (80:20:1, v/v/v). The cholesteryl ester band was eluted from the silica gel by extraction with acidic water/chloroform/methanol (0.9:1:1, v/v/v). To each sample, 10 µg of cholesterol-free egg phosphatidylcholine was added, and the chloroform was evaporated under a stream of nitrogen. The sample containing cholesteryl esters or total cholesterol was dissolved by vortexing in 10 µl of isopropyl alcohol followed by 90 µl of water. The color was developed by adding 100 µl of a 2× solution of INFINITY cholesterol reagent. The samples were read at 500 nm with known plasma standards. Protein was estimated with BCA protein reagent purchased from Pierce.

RNase Protection Assays-- RNA was extracted from isolated cells with TRI REAGENT. The RNA probes to estimate mRNA for hamster SREBP-1a, SREBP-1c, SREBP-2, HMG-CoA reductase, HMG-CoA synthase, and LDL receptor were prepared as described by Shimomura et al. (12, 14). The RNA probe for SREBP-1c, however, contained 0.207 instead of 0.114 kilobases as described. pTRI RNA 18 S probe was obtained from Ambion (Austin, TX). The probes were labeled with [32P]UTP using MAXIscript T7 kit from Ambion. 20 µg of total RNA was used per assay. The assay was performed per a protocol for RPA III described by Ambion. The protected fragments were resolved on a 6% polyacrylamide gel. Radioactivity was measured by autoradiography using a Storm phosphor screen and quantitated using ImageQuant software (Molecular Dynamics, Sunnyvale, CA). To compare mRNA levels among hamsters on the three diets, RNA from a hamster on each of the three diets was analyzed by RNase protection assays simultaneously under identical conditions.

Immunoblot Analysis-- Immunoblot analysis was performed as we have described with the following modifications (18). The cell fractions from a hamster on one of the three diets were prepared each day. All buffers contained 50 µg/ml N-acetyl-leucyl-leucyl-norleucinal, 0.5 mM phenylmethylsulfonyl fluoride, 5 µg/ml pepstatin A, 10 µg/ml leupeptin, 1 mM pefabloc, 10 mM dithiothreitol, 2 µg/ml aprotinin, 0.1 mM zinc sulfate, and 0.1 mM copper sulfate. The cells were suspended in 20 mM Tris/HCl, pH 8, 150 mM NaCl, and 1 mM CaCl2 and kept on ice for 30 min with occasional mixing. The cells were homogenized by passing five times through a 25-gauge needle. Total membranes were prepared by centrifuging the homogenate for 45 min at 100,000 × g at 4 °C. The total membrane pellet was suspended in 0.1-0.4 ml of 125 mM Tris/HCl (pH 6), 2 mM CaCl2, 160 mM NaCl, 1% Triton X-100 and sonicated briefly. The membrane extract was subsequently centrifuged for 30 min at 19,000 × g at 4 °C. The supernatant was used for immunoblotting. Proteins were resolved by SDS-PAGE on the same day of preparation and blotted onto a polyvinylidene difluoride membrane. The blot was prepared, dried, stored, and probed using a nonblock technique described by Sadra et al. (19). Briefly, the blot was incubated with 1× TBS for 30 min followed by a rinse with water. It was air-dried for 15 min followed by three rinses with 1:1 methanol/water, kept in methanol for 2 min, and air-dried. It was stored at room temperature between two sheets of filter paper. All blots were dried under vacuum for 10 min just before probing with the antibodies. To compare the bands representing precursor and mature forms of SREBPs among hamsters on the three diets, one blot from a hamster on each of the three diets was probed simultaneously under identical conditions. The blots were incubated with the primary antibody for 1 h in Tris-buffered saline containing 1% goat or donkey serum, 2% nonfat milk, 0.1% Triton X-100. They were rinsed with Tris-buffered saline plus 0.1% Triton X-100 followed by secondary horseradish peroxidase antibody for 1 h in Tris-buffered saline containing 1% goat or donkey serum, 2% nonfat milk, 0.1% Triton X-100. Rabbit polyclonal antibody against hamster SREBP-2 (kindly provided by Dr. Jay Horton, Department of Molecular Genetics, Univ. of Texas Southwestern Medical Center, Dallas, TX.) and mouse monoclonal antibody against the amino-terminal end of human SREBP-1a, IgG-2A4, were used. Goat anti-rabbit horseradish peroxidase (A-6154; Sigma) or donkey anti-mouse horseradish peroxidase (code 715-035-150; Jackson Immunoresearch Laboratory Inc., West Grove, PA) were used as secondary antibodies. In preliminary experiments, nonspecific bands in the 80-150-kDa range were observed in the absence of primary monoclonal antibody when anti-mouse horseradish peroxidase antibodies were used that were not adsorbed for hamster proteins. The donkey anti-mouse horseradish peroxidase antibody did not react with hamster protein in the absence of the monoclonal antibody. The horseradish peroxidase signal was detected on the blots with SuperSignal West Femto maximum sensitivity substrate (Pierce).

Hepatic and intestinal mucosa nuclear and membrane fractions were prepared exactly as described by Sheng et al. (11).

Statistical Analysis-- To determine if the differences among the animals fed the three diets were significant, the data were analyzed at p < 0.05 by one-way analysis of variance and Student-Newman-Keuls method using SIGMASTAT software.

    RESULTS
TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

In hamsters ingesting a 1% cholesterol diet for 2 weeks, plasma cholesterol levels were increased 2.6-fold compared with levels observed in animals ingesting the chow diet, 100 ± 8.1 versus 262 ± 18 mg/dl, n = 8. Plasma cholesterol levels were markedly decreased in animals ingesting a cholesterol-depleted diet of cholestyramine and lovastatin, 9 ± 2.5 mg/dl, n = 8.

Gene Expression-- Following 2 weeks on the respective diets, the intestines were divided into three equal segments representing duodenum, jejunum, and ileum. Isolated cells were prepared from the three segments representing upper (fractions 1 and 2), middle (fractions 3 and 4), and lower (fraction 5) villus cells (14). RNA was extracted from the different cell populations, and mRNA levels were estimated by RNase protection assays for SREBP-1a, SREBP-1c, SREBP-2, HMG-CoA synthase, LDL receptor, and HMG-CoA reductase.

Fig. 1a shows a representative RNase protection assay from a single animal in each of the dietary groups. Fig. 1b shows the mRNA levels in the different cell populations of the villus in the three segments, and Fig. 1c shows the cumulative average of the mRNA levels in duodenum, jejunum, and ileum. From the data shown in the representative RNase protection assay, it is clear that, compared with SREBP-1a, SREBP-1c was the predominant transcript in the intestine of hamsters fed the control chow diet. Moreover, the expression of the transcript for SREBP-1c was highest in cells of the villus tip and decreased as cells of the lower villus were reached (Fig. 1, a and b). In contrast, expression of SREBP-2 and the other sterol-responsive genes was lowest in cells of the upper villus and increased as cells of the lower villus were reached. Compared with duodenum, expression of these genes was modestly higher in jejunum and ileum.


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Fig. 1.   Effect of diets on gene expressions of SREBP-1a, SREBP-1c, SREBP-2, HMG-CoA synthase, LDL receptor, and HMG-CoA reductase in hamster intestine. Isolated intestinal cells were prepared from duodenum, jejunum, and ileum of hamsters fed for 2 weeks a control chow diet or a cholesterol-rich (cholesterol) or cholesterol-depletion (cholestyramine plus lovastatin) diet as described under "Materials and Methods." RNA was isolated from each of the five fractions, and mRNA levels were estimated by RNase protection assay. 18 S rRNA was used as an internal control to confirm that equal amounts of RNA were used for the assays. Fraction 1 represents mRNA from cells of the uppermost villus, and fraction 5 represents mRNA from cells of the crypts. a, a representative RNase protection assay from a single hamster on each diet; b, mRNA levels for the genes in the different cell populations of the villus from duodenum, jejunum, and ileum. The data represent the means ± S.E. from three animals fed the respective diets. c, cumulative mRNA levels in duodenum, jejunum, and ileum. Open bar, control chow; diagonal bar, cholesterol-rich; cross-hatch bar, cholesterol-depletion. *, cholesterol-rich values are significantly different from control chow values at p < 0.05. **, cholesterol-depletion values are significantly different from control chow values at p < 0.05. ***, cholesterol-depletion values are significantly different from cholesterol-rich values at p < 0.05.

Compared with the expression of SREBP-1a in intestines of animals on the control chow diet, neither the cholesterol diet nor the cholesterol-depletion diet altered SREBP-1a gene expression (Fig. 1, b and c). In contrast, in hamsters ingesting the cholesterol diet compared with animals on the control chow diet, SREBP-1c expression was increased predominantly in cells of the upper villus. Moreover, there was a profound decrease in gene expression of SREBP-1c in all cells along the villus of the entire small intestine of hamsters fed the cholesterol-depleted diet.

In animals fed the cholesterol-depletion diet, SREBP-2, HMG-CoA synthase, HMG-CoA reductase, and LDL receptor gene expressions were dramatically increased in all cell populations of the villus and in all three segments of the small intestine (Fig. 1, b and c). In contrast, cholesterol feeding had minimal if any effect on mRNA levels of these genes.

Protein Expression-- In preliminary experiments, we found the mature form of both intestinal SREBPs to be in very low abundance and detection difficult. To help in identifying the bands representing precursor and mature peptides of SREBPs and to support our results in intestine, protein expression of SREBP-1 and -2 from livers and intestines of hamsters ingesting the three different diets was estimated.

Because of the relative paucity of recoverable protein in the five fractions of enterocytes prepared from the villus, it was not possible to isolate a nuclear and membrane fraction to estimate SREBP expression. Thus, to determine if a total membrane preparation could be used to estimate the amount of SREBPs in liver and intestine, we first prepared total membrane fractions from livers of hamsters on the respective diets. Fig. 2a shows an immunoblot for SREBP-1 and -2 using increasing amounts of a total membrane preparation isolated from the liver of one animal from each of the diets. From this blot, it is clear that compared with the hamster ingesting cholesterol, there was more precursor and mature form of SREBP-2 in hepatic membranes prepared from the hamster on the cholesterol-depleted diet. The results for SREBP-1 differed. Compared with the amount of the precursor form of SREBP-1 in the animal ingesting the cholesterol-depleted diet, there was more precursor of SREBP-1 in the liver of the hamster ingesting cholesterol. Two bands flanking the molecular marker of 66 kDa were observed for the mature peptide of SREBP-1. Both bands were reduced in the liver of the hamster ingesting the cholesterol-depletion diet. No clear changes were observed, however, in the mature peptide of the animal fed cholesterol. Total membranes were then prepared from the livers of three individual animals on the different diets, and the precursor and mature forms of SREBP-2 were analyzed (Fig. 2b). Compared with hamsters ingesting the cholesterol diet, both the precursor and mature forms of SREBP-2 were increased in livers of hamsters ingesting the cholesterol-depletion diet. Compared with animals fed the control chow, the precursor form of SREBP-2 was decreased in livers of animals fed cholesterol. The mature form was in low abundance in both control chow-fed and cholesterol-fed animals. No clear difference was observed in the mature form between these two dietary groups. These results lend support to the notion that total membranes prepared from cell fractions of intestines of hamsters on the respective diets could be used to estimate SREBP mass.


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Fig. 2.   Effect of diets on hepatic SREBP-1 and -2 mass. Total membranes were prepared from livers of hamsters fed control chow, cholesterol-rich or cholesterol-depletion diets. The membranes were analyzed for SREBP-1 and SREBP-2 mass by immunoblot as described under "Materials and Methods." a, an immunoblot from a single animal on each of the diets. 6-100 µg of protein was applied per lane. P, precursor form; M, mature forms. b, an immunoblot of total membranes prepared from livers of three individual animals fed the respective diets. P, precursor; M, mature. 50 µg of protein was applied per lane.

Isolated villus cell fractions were prepared from three intestinal segments of five animals on each of the diets. Total membranes were prepared, and the amount of SREBP expression was estimated. Fig. 3a shows a representative immunoblot of SREBP-1 and SREBP-2 from a single animal in each of the dietary groups. Because of the low abundance of the mature form of both SREBPs and to accurately measure changes in the amount of the precursor form, the blots were exposed to film for different times. The exposure time for estimating the amount of the precursor form was 3-4 times less than the exposure time used to detect and estimate the amount of the mature form. Fig. 3b shows the amount of the precursor form of SREBP-1 and -2 in the different cell populations of the villus in the three segments. Fig. 3c shows the cumulative average of the precursor mass in duodenum, jejunum, and ileum. The results depicted in the representative blot demonstrate that in membranes prepared from intestines of hamsters on all three diets, the precursor forms of both SREBP-1 and -2 were readily detectable. In general, in animals fed control chow and the cholesterol-enriched diets, the amount of the precursor form of SREBP-2 tended to be lower in membranes prepared from cells of the upper villus and higher in cells of the lower to middle villus. The reverse tended to be true for the precursor form of SREBP-1, particularly in the duodenum (Fig. 3, a and b). It should be appreciated here that the antibody for SREBP-1 detects the mass of both SREBP-1a and SREBP-1c. From the cumulative data shown in Figs. 3, b and c, it is apparent that the amount of precursor form of SREBP-2 in intestinal cells of animals fed the cholesterol-enriched diet was similar to the amount present in intestines of animals on the control chow diet. There was, however, significantly more SREBP-2 precursor in duodenum and jejunum of hamsters fed the cholesterol-depleted diet than in hamsters fed either the control chow or cholesterol diet. In ileum, significant differences in SREBP-2 precursor forms were only observed between hamsters ingesting the cholesterol-depleted diet and animals on control chow. The mature form of SREBP-2 was difficult to detect in intestines of animals fed the control chow or the cholesterol diet. In all five animals, a distinct band above background noise was never fully appreciated (Fig. 3a). However, in intestines of animals on the cholesterol-depleted diet, particularly in the proximal intestine, the mature form of SREBP-2 was readily detectable and was consistently increased. In contrast, although there was a tendency for SREBP-1 precursor to be present in higher amounts in jejunum of hamsters fed the cholesterol-enriched diet, because of variability among animals, this did not reach statistical significance (Fig. 3, b and c). Like the mature form of SREBP-2, the mature form of SREBP-1 was also in low abundance and difficult to detect. Although in Fig. 3a, it appears that the mature form of SREBP1 was increased in intestines of animals fed the cholesterol diet, the mature protein did not consistently appear as a distinct band. Thus, we were unable to make any conclusions regarding the regulation of mature SREBP-1 by dietary cholesterol.


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Fig. 3.   Effect of diets on intestinal SREBP-1 and -2 mass. Total membranes were prepared from cells isolated from the villus of duodenum, jejunum, and ileum of five hamsters fed the respective diets. The membranes were analyzed for SREBP-1 and SREBP-2 mass by immunoblot. a, a representative immunoblot from a single hamster on each diet. To detect and estimate the amount of precursor and mature forms, the blots were exposed for different times. Precursor forms of SREBP-1 and SREBP-2 were estimated after 30-s and 5-min exposure to film, respectively. Mature forms of SREBP-1 and SREBP-2 were estimated after 5- and 15-min exposure, respectively. P, precursor; M, mature. 125 µg of protein was applied per lane. Fraction 1 represents membranes prepared from cells of the upper villus (tips), and fraction 5 represents membranes prepared from cells of the crypts. b, the amount of precursor form of SREBP-1 and SREBP-2 in the different cell populations of the villus from duodenum, jejunum, and ileum. The data represent the means ± S.E. from five animals fed the respective diets. c, cumulative amounts of precursor forms of SREBP-1 and SREBP-2 in duodenum, jejunum, and ileum. The data represent the means ± S.E. of five animals fed the respective diets. Open bar, control chow; diagonal bar, cholesterol-rich; cross-hatched bar, cholesterol-depletion. **, cholesterol-depletion values are significantly different from control chow values at p < 0.05; ***, cholesterol-depletion values are significantly different from cholesterol-rich values at p < 0.05.

Cholesterol Mass-- To determine whether the diets altered the cholesterol content of cells along the intestine, cholesterol mass was estimated in the five villus cell populations of duodenum, jejunum, and ileum (Fig. 4). In all three segments of intestines of hamsters fed the control chow diet, there was a trend indicating more cholesterol mass in cells of the upper rather than the lower villus. Cholesterol feeding did not alter this trend but caused significant accumulation of cholesterol in all cell populations of the villus. More cholesterol accumulated in cells of the jejunum and ileum than duodenum. The cholesterol-depleted diet decreased the amount of cholesterol in intestines of these animals, except perhaps, in lower villus cells of the ileum. The cholesteryl ester content mirrored the results of total cholesterol, accounting for ~3%, 0.9%, and 9% of total cholesterol in intestinal cell fractions of animals on chow, cholesterol-depletion, and cholesterol-enriched diets, respectively.


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Fig. 4.   Effect of diets on intestinal cholesterol mass. Cholesterol mass was estimated in cell populations along the villus of duodenum, jejunum, and ileum of hamsters fed the respective diets. The data represent the means ± S.E. of nine animals on each diet. , control chow; down-triangle, cholesterol-rich; black-square, cholesterol-depletion. Fraction 1 represents cells of the upper villus, and fraction 5 represents cells of the crypts. Cumulative values for each segment are shown in the bar graph on the right. Open bar, control chow; diagonal bar, cholesterol-rich; cross-hatched bar, cholesterol-depletion. *, cholesterol-rich values are significantly different from control chow values at p < 0.05; **, cholesterol-depletion values are significantly different from control chow values at p < 0.05; ***, cholesterol-depletion values are significantly different from cholesterol-rich values at p < 0.05.

Cholesterol and Fatty Acid Synthesis-- Rates of cholesterol and fatty acid synthesis in intestinal cell fractions were estimated by tritiated water incorporation into cholesterol and fatty acids following the dietary periods (Fig. 5). In animals on all three diets, rates of cholesterol synthesis were lowest in cells of the villus tips and increased as cells of the lower villus were reached. Rates of cholesterol synthesis were similar in intestines of animals fed the chow or cholesterol-enriched diets. In contrast, rates of cholesterol synthesis were markedly increased in intestines of hamsters on the cholesterol-depletion diet.


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Fig. 5.   Effect of diets on intestinal cholesterol and fatty acid synthesis. Synthesis of cholesterol and fatty acids was estimated by incorporation of [3H]water into the lipids in cell populations along the villus of duodenum, jejunum, and ileum of hamsters fed control chow (), cholesterol-rich (down-triangle), or cholesterol-depletion (black-square) diets. The values represent the mean ± S.E. of three hamsters on each diet. Fraction 1 represents cells of the upper villus, and fraction 5 represents cells of the crypts. Cumulative values for each segment are shown in the bar graph on the right. Open bar, control chow; diagonal bar, cholesterol-rich; cross-hatched bar, cholesterol-depletion; **, cholesterol-depletion values are significantly different from control chow values at p < 0.05; ***, cholesterol-depletion values are significantly different from cholesterol-rich values at p < 0.05.

Rates of fatty acid synthesis were also similar in intestines of animals on control chow or cholesterol diets. In contrast, in all cells along the villus and in all three segments of small intestine, rates of fatty acid synthesis were increased in animals on the cholesterol-depletion diet.

    DISCUSSION
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ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

The results of this study clearly show that SREBP-1a is a minor transcript in intestinal cells. Moreover, gene expression of SREBP-1a in intestine was not altered by rather dramatic changes in cholesterol flux. These findings, taken together with earlier results in isolated intestinal segments, which showed that gene expression of SREBP-1a was not regulated by cholesterol flux, suggest that SREBP-1a does not regulate cholesterol synthesis in intestine (14). In a previous study, gene expression of SREBP-1a in livers of hamsters ingesting a cholesterol-enriched or a cholesterol-depletion diet was also not altered (conditions that would have had profound effects on hepatic cholesterol synthesis) (12). Because the liver and intestine account for most cholesterol synthesis within the body, the results from both studies suggest that SREBP-1a has only a small role in regulating total body cholesterol synthesis. This is not to imply that SREBP-1a does not regulate genes of the cholesterol biosynthetic pathway. This is clearly not the case. In livers of transgenic mice that overexpress a truncated form of SREBP-1a, massive accumulation of cholesterol occurs and rates of cholesterol synthesis and expressions of sterol-responsive genes are markedly increased (20). Furthermore, transfection of cultured cells with SREBP-1a increases rates of transcription of sterol-responsive genes (10). Despite these findings that support the view that SREBP-1a is a rather potent transcription factor for genes that regulate cholesterol synthesis, SREBP-1a does not appear to be an important regulator of cholesterol synthesis in hamster intestine or liver.

In contrast to SREBP-1a, changes in cholesterol flux do regulate gene expression of intestinal SREBP-1c and SREBP-2. The regulation of these genes by cholesterol flux, however, is not a simple matter. In cell culture experiments, changes in cholesterol flux cause coordinate regulation of expression of both SREBP-1 and -2 (21-23). It is quite obvious from the results presented here in intact animals that these transcripts are not coordinately regulated by cholesterol flux; in fact, quite the opposite is true. SREBP-1c is thought to be a weaker transcription factor than SREBP-1a and more specific for enhancing the transcription of genes in the fatty acid synthetic pathway (10). Transgenic animals overexpressing SREBP-1c in liver display a moderate increase in fatty acid synthesis without altering cholesterol synthesis (10). In our previous study, we postulated that SREBP-1c was responsible for regulating fatty acid synthesis but not cholesterol synthesis in intestine (14). The present results also support the notion that SREBP-1c plays little or no role in regulating cholesterol synthesis in intestine. In response to changes in cholesterol flux, changes in gene expression of SREBP-1c were reciprocal to the changes observed in expressions of the three sterol-responsive genes and to cholesterol synthesis. Whereas the previously observed correlation between SREBP-1c gene expression and fatty acid synthesis holds true in intestines of chow-fed animals (14), the present results might argue against a regulatory role for SREBP-1c in fatty acid synthesis in intestine following changes in cholesterol flux. Despite a profound decrease in SREBP-1c gene expression in intestines of hamsters ingesting the cholesterol-depletion diet, fatty acid synthesis in the intestines of these animals was enhanced severalfold. Moreover, cholesterol feeding caused a dramatic increase in gene expression of intestinal SREBP-1c, yet fatty acid synthesis in intestines of animals on the cholesterol-enriched diet was similar to animals on the chow diet. Thus, it would appear that, at least at a transcriptional level, SREBP-1c is responsible for maintaining basal levels of fatty acid synthesis in intestine. In response to changes in cholesterol flux, however, mechanisms other than those involving transcription of SREBP-1c need to be entertained.

A mechanism has now been provided that explains the regulation of SREBP-1c gene expression by changes in cholesterol flux. In a recent study performed in mice, Repa et al. (24) have shown that the SREBP-1c gene is a target of the nuclear receptor RXR/LXR transcription factor. By feeding mice either a high cholesterol diet or RXR/LXR agonists, both hepatic and intestinal mRNA levels and protein expression of SREBP-1c were increased. An RXR/LXR DNA-binding site in the promoter of SREBP-1c was identified and found to be required for this regulation. Despite an increase in SREBP-1c gene expression by cholesterol feeding, hepatic levels of the lipogenic target genes, fatty acid synthase and acetyl-CoA carboxylase, were not increased. Only stearoyl-CoA desaturase gene expression was increased in livers of mice ingesting cholesterol. Perhaps this lack of effect of cholesterol feeding on these lipogenic target genes explains why in the present study, fatty acid synthesis was not increased in intestines of animals having increased gene expression of SREBP-1c.

The present results would suggest that with changes in cholesterol flux, particularly cholesterol depletion, SREBP-2 assumes the role for regulating cholesterol and fatty acid synthesis in intestine. In intestines of hamsters fed the cholesterol-depletion diet, rates of cholesterol and fatty acid synthesis were increased, as were mRNA levels for SREBP-2 and the sterol-responsive genes. Moreover, the amount of precursor and mature forms of SREBP-2 was also increased. In transgenic animals overproducing the mature form of SREBP-2, hepatic fatty acid synthesis and triglyceride content were increased 4-fold (13). Thus, although SREBP-2 appears to be more specific for increasing the expression of genes of the cholesterol biosynthetic pathway, SREBP-2 can enhance fatty acid synthesis as well. Thus, under conditions of cholesterol depletion, we would postulate that SREBP-2 supplants the function of SREBP-1 in intestine and augments cholesterol and fatty acid synthesis.

In intestines of hamsters ingesting a cholesterol-enriched diet, a diet that increased plasma cholesterol levels 2-fold, mRNA levels of the sterol-responsive genes and SREBP-2 were minimally decreased if at all. Similarly, rates of cholesterol and fatty acid synthesis were not altered. This was somewhat unexpected. With a large influx of cholesterol, a more dramatic suppression of genes that regulate cholesterol metabolism and rates of cholesterol synthesis was expected. Perhaps this did not occur because cholesterol taken up from the lumen does not enter a critical "regulatory pool." The absorbed sterol escapes putative "cholesterol sensors" in endoplasmic reticulum or plasma membrane that would, in turn, down-regulate the SREBP pathway. A similar possible mechanism was postulated in experiments using CaCo-2 cells (25). Cholesterol taken up from micelles was shown to displace cholesterol of the plasma membrane, directing it to the ACAT pool for esterification and transport. Since plasma membrane serves as a large "sink" for absorbed cholesterol, it is likely that the SREBP pathway would not be activated or, at least, not activated until a certain threshold amount of cholesterol in plasma membrane (or endoplasmic reticulum) is reached. Another possible explanation for the modest changes observed in sterol-responsive gene expression by dietary cholesterol comes from results in chow-fed animals. In intestinal cells of these animals, there were abundant amounts of the precursor form of SREBP-2. The mature form, however, was not detectable. This implies that there is an adequate supply of cholesterol in these cells that prevents cleavage of the precursor protein. Thus, the expression of sterol-responsive genes, including SREBP-2 itself, and rates of cholesterol synthesis would be chronically suppressed. To demonstrate further suppression by dietary cholesterol might not be possible. This is not the first study that has failed to observe a significant decrease in intestinal cholesterol synthesis by dietary cholesterol in intact animals (for a review, see Ref. 26).

It has been postulated that in an intestinal absorptive cell there exists a regulatory pool of cholesterol whose size determines rates of cholesterol synthesis. Newly synthesized cholesterol, plasma membrane cholesterol, absorbed cholesterol, and cholesterol derived from lipoproteins contribute, albeit in different proportions, to this pool (27). The present data support this notion. In intestines of hamsters fed a chow diet, there was a clear trend for the rates of cholesterol synthesis and the expressions of sterol-responsive genes, SREBP-2, HMG-CoA reductase, HMG-CoA synthase, and the LDL receptor, to be lower in cells of the upper villus (most differentiated) and higher in cells of the distal villus (least differentiated). This suggests that compared with differentiated cells, the regulatory pool of cholesterol is smaller in undifferentiated cells, which in turn, enhances cholesterol synthesis by increasing the expression of genes in the cholesterol synthetic pathway via activation of the SREBP pathway. Indeed, assuming that cholesterol mass reflect differences in this regulatory cholesterol pool, cells of the upper villus did contain more cholesterol than cells of the lower villus. Moreover, feeding cholesterol markedly increased the amount of cellular cholesterol, particularly in cells of jejunum and ileum, without altering this gradient in cells along the villus. Thus, with cholesterol feeding, rates of cholesterol synthesis and expressions of sterol-responsive genes maintained a gradient along the villus axis that was similar to that observed in control chow-fed animals. In contrast, by feeding a cholesterol-depletion diet, this regulatory cholesterol pool would decrease, stimulating the SREBP pathway and enhancing transcription of genes that regulate cholesterol synthesis. Marked stimulation of the SREBP pathway obscured the gradient of cholesterol synthesis and gene expression that was appreciated along the villus axis in intestines of animals on chow and cholesterol diets. It seems clear in intestine, at least, that activation of the SREBP pathway by decreasing the regulatory cholesterol pool is a much stronger stimulus than suppressing the SREBP pathway by expanding the regulatory cholesterol pool by dietary cholesterol.

In the classic SREBP pathway described in cultured cells, cholesterol and fatty acid synthesis are enhanced by the cleavage of a membrane-bound precursor form of SREBP (regulated intramembrane proteolysis), releasing a nuclear or active form (28). This "mature" protein then enters the nucleus, binds to a sterol regulatory element in promoters of genes in these two pathways, and enhances their transcription (4-8). The results of this study, however, suggest another possible mechanism for the regulation of cholesterol and fatty acid synthesis by SREBPs in intestine. The correlation that was observed between gene expression and the amount of precursor mass of SREBP-1 and -2 in individual cell populations of the intestine, although not exact, was fairly striking. Because our antibody does not distinguish between SREBP-1a and -1c and will detect both, this correlation is best illustrated for SREBP-2. Both mRNA levels and precursor mass of SREBP-2 were lower in cells of the upper villus and higher in cells of the lower to middle villus. Moreover, in intestines of animals ingesting the cholesterol-depletion diet, there was a marked increase in both mRNA abundance and precursor mass of SREBP-2. It was only in intestines of this group of animals that the mature form of SREBP-2 could be detected. If regulated intramembrane proteolysis were the only mechanism for formation of the mature form following cholesterol depletion, it would have been expected that the amount of precursor mass would decrease as the amount of mature form increased. This did not occur. In fact, the amount of precursor mass markedly increased with cholesterol depletion. These findings are at least suggestive that in intestine, the mass of SREBP-2, both precursor and mature, is regulated at the level of transcription. Other investigators have also observed a dissociation between the amount of mature form of SREBP-1 and -2 and gene expression for enzymes involved in cholesterol and fatty acid synthesis, suggesting that the amount of the mature form can be regulated by changes in synthesis of its precursor (29, 30).

    ACKNOWLEDGEMENTS

We thank Dr. Jay Horton for helpful discussions throughout this work and Drs. M. S. Brown and J. L. Goldstein, Department of Molecular Genetics, University of Texas Southwestern Medical Center, Dallas, TX, for the SREBPs, HMG-CoA reductase, HMG-CoA synthase, and LDL receptor plasmids.

    FOOTNOTES

* This work was supported by the Department of Veterans Affairs and National Institutes of Health Grants HL49264 and 56032.The costs of publication of this article were defrayed in part by the payment of page charges. The article must therefore be hereby marked "advertisement" in accordance with 18 U.S.C. Section 1734 solely to indicate this fact.

Dagger To whom correspondence should be addressed. Tel.: 319-356-2579; Fax: 319-353-6399; E-mail: f-jeffrey-field@uiowa.edu.

Published, JBC Papers in Press, February 20, 2001, DOI 10.1074/jbc.M010917200

    ABBREVIATIONS

The abbreviations used are: SREBP, sterol regulatory element-binding protein; LDL, low density lipoproteins; HMG-CoA, 3-hydroxy-3-methylglutaryl-coenzyme A.

    REFERENCES
TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

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