Published online before print December 18, 2008

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(American Journal of Pathology. 2009;174:54-62.)
© 2009 American Society for Investigative Pathology
DOI: 10.2353/ajpath.2009.080602

Renal Ischemia-Induced Cholesterol Loading

Transcription Factor Recruitment and Chromatin Remodeling along the HMG CoA Reductase Gene

Masayo Naito^*, Karol Bomsztyk and Richard A. Zager^*

From the Fred Hutchinson Cancer Research Center^*, Seattle; and the Department of Medicine, University of Washington, Seattle, Washington

	Abstract

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Acute kidney injury evokes renal tubular cholesterol synthesis. However, the factors during acute kidney injury that regulate HMG CoA reductase (HMGCR) activity, the rate-limiting step in cholesterol synthesis, have not been defined. To investigate these factors, mice were subjected to 30 minutes of either unilateral renal ischemia or sham surgery. After 3 days, bilateral nephrectomy was performed and cortical tissue extracts were prepared. The recruitment of RNA polymerase II (Pol II), transcription factors (SREBP-1, SREBP-2, NF-B, c-Fos, and c-Jun), and heat shock proteins (HSP-70 and heme oxygenase-1) to the HMGCR promoter and transcription region (start/end exons) were assessed by Matrix ChIP assay. HMGCR mRNA, protein, and cholesterol levels were determined. Finally, histone modifications at HMGCR were assessed. Ischemia/reperfusion (I/R) induced marked cholesterol loading, which corresponded with elevated Pol II recruitment to HMGCR and increased expression levels of both HMGCR protein and mRNA. I/R also induced the binding of multiple transcription factors (SREBP-1, SREBP-2, c-Fos, c-Jun, NF-B) and heat shock proteins to the HMGCR promoter and transcription regions. Significant histone modifications (increased H3K4m3, H3K19Ac, and H2A.Z variant) at these loci were also observed but were not identified at either the 5' and 3' HMGCR flanking regions (±5000 bps) or at negative control genes (β-actin and β-globin). In conclusion, I/R activates the HMGCR gene via multiple stress-activated transcriptional and epigenetic pathways, contributing to renal cholesterol loading.

There are undoubtedly multiple pathways by which injured renal tubular cells acquire resistance to further damage. The one that has been most widely recognized is the induction of cytoprotective stress proteins, such as the heat shock protein-70 (HSP-70), HSP-32 (ie, heme oxygenase-1; HO-1), and ferritin.^8,9,20,21 Alterations in lipid homeostasis may also be involved. For example, arachidonic acid release from phospholipids,^22-24 as well as sphingomyelin-generated sphingolipid products,^25-27 can evoke a cytoprotective response. Probably the most consistent, and stable, renal injury-induced lipid alteration is renal tubular cholesterol accumulation.^15,28-34 For example, in each of the above-mentioned models of renal cytoresistance (IR; myoglobinuric acute renal failure, glomerulonephritis, nephrotoxins, heat shock, ureteral obstruction, endotoxemia), an 25 to 50% sustained increase in renal tubular cholesterol concentrations result.^28-34 The precise mechanism(s) by which excess cholesterol exerts its protective action remains to be defined. However, the available data suggest that cholesterol increases plasma membrane and mitochondrial membrane rigidity, and this serves to maintain mitochondrial energetics and plasma membrane integrity during superimposed ischemic or toxic attack.^28,30,32 Of note, after injury cholesterol accumulation and cytoresistance are not renal-specific phenomena. For example, we have observed that when acute myelogenous leukemia cells are exposed to cancer chemotherapeutic agents, cholesterol accumulates, conferring resistance to further chemotherapy.^35-37 Therefore, the mechanisms that are responsible for injury-induced cholesterol accumulation likely have broad-based biological relevance.

Evidence gathered to date indicates that increased tubular cell cholesterol synthesis can contribute to the cholesterol loading state after injury. This assertion is based on observations that statin-mediated inhibition of HMG CoA reductase, the rate-limiting enzyme in cholesterol synthesis, abrogates cholesterol accumulation after injury.^31,35-39 However, whether increased cholesterol synthesis reflects increased HMGCR gene transcription, and which transcription factors might stimulate this response, have not been assessed. Hence, the present study was undertaken to explore the following issues: i) Does renal ischemic preconditioning activate the HMGCR gene (as assessed by RNA polymerase II recruitment to its transcription sites)? ii) If so, which transcription factor(s) might be involved? iii) Do epigenetic modifications exist at the HMGCR gene, potentially facilitating an increased transcriptional state? Investigations into each of these issues form the basis of this study.

	Materials and Methods

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Ischemia-Reperfusion Injury

Male CD 1 mice (30 to 35 g; Charles River Laboratories, Wilmington, MA), maintained under routine vivarium conditions and subjected to Institutional Animal Care and Use Committee approved protocols were used for all experiments. They were subjected to 30 minutes of left renal pedicle occlusion performed through an abdominal incision under pentobarbital anesthesia (40 to 50 mg/kg; IP) and followed by two-layer abdominal wall suturing. Approximately 72 hours after surgery, they were re-anesthetized, and bilateral nephrectomy was performed.

Analyses

The renal cortices were dissected (4°C) and subjected to either lipid, protein, or RNA extraction or chromatin cross linking (formalin).⁴⁰ Lipid extracts were analyzed for free and esterified cholesterol levels by gas chromatography (expressed as nmol/µmol phospholipid phosphate).^29,40 Protein samples were probed for HMGCR protein by Western blotting/chemiluminescence.³¹ HMGCR mRNA was quantified by competitive polymerase chain reaction (PCR) (expressed as a ratio to simultaneously measured GAPDH product).³⁴ The validity of using the contralateral kidneys as controls was ascertained by identifying a lack of cholesterol/cholesterol ester accumulation in them, compared with kidneys obtained from six mice undergoing sham unilateral ischemia surgery.

Microplate-Based Matrix Chromatin Immunoprecipitation (ChIP)

Supplies and Equipment

ChIP assays were done using the Matrix ChIP platform in 96-well polystyrene high-binding capacity microplates (no. 9018; Corning, Corning, NY).⁴¹ The following reagents and equipment were used: protein A (no. P7837; Sigma, St. Louis, MO); proteinase K (no. 25530hyphen]015; Invitrogen, Carlsbad, CA); formaldehyde (no. 2106-02; J.T. Baker, Phillipsburg, NJ); bovine serum albumin (no. A9647, Sigma); phenylmethyl sulfonyl fluoride (no. P-7626, Sigma); leupeptin (no. L-2884, Sigma); SYBR Green PCR master mix (2xSensiMix, no. QT6T3; Quantace, Norwood, MA); salmon sperm DNA (no. D1626, Sigma); Misonix Sonicator 3000 with micro tip (no. S3000; Misonix, Farmingdale, NY); ultrasonic bath (no. B3510-MT CPN-952-316; Branson, Danbury, CT); heat blocks (analog heat block, no. 13259032: VWR Scientific, West Chester, PA; Isotemp 125: Fisher Scientific, Pittsburgh, PA); quantitative PCR (ABI 7900HT system; ABI Biotechnology, Foster City, CA); and MixMate (Eppendorf, Westbury, NY).

Buffers

The following buffers were used: phosphate-buffered saline (PBS): 137 mmol/L NaCl, 10 mmol/L Na phosphate, 2.7 mmol/L KCl, pH 7.4; TE buffer: 10 mmol/L Tris, 1 mmol/L ethylenediaminetetraacetic acid, pH 7.0; immunoprecipitation (IP) buffer: 150 mmol/L NaCl, 50 mmol/L Tris-HCl, pH 7.5, 5 mmol/L ethylenediaminetetraacetic acid, NP-40 (0.5% v/v), Triton X-100 (1.0% v/v); blocking buffer: 5% bovine serum albumin, 100 µg/ml sheared salmon sperm DNA in IP buffer; elution buffer: 25 mmol/L Tris base, 1 mmol/L ethylenediaminetetraacetic acid, pH 9.8, 200 µg/ml proteinase K (20 mg/ml stock, stored at –20°C).

Sonication of Renal Cortex Chromatin

Approximately 25 mg of minced renal cortex was fixed with formaldehyde (final concentration 1.42% in PBS for 15 minutes; 22°C) and then quenched with 125 mmol/L glycine (5 minutes, 22°C). The cross-linked tissues were then extensively washed with PBS (4°C). To shear the chromatin, the washed cross-linked tissue pellets were resuspended in 1 ml of IP buffer (containing the following inhibitors: 0.5 mmol/L dithiothreitol, 10 µg/ml leupeptin, 0.5 mmol/L phenylmethyl sulfonyl fluoride, 30 mmol/L p-nitrophenyl phosphate, 10 mmol/L NaF, 0.1 mmol/L Na₃VO₄, 0.1 mmol/L Na₂MoO₄, and 10 mmol/L β-glycerophosphate) and sheared using six rounds of sonication (power 5, 15 seconds, on ice). The suspension was cleared by centrifugation at 12,000 x g (10 minutes at 4°C), and the supernatant, representing sheared chromatin, was aliquoted and stored at –80°C.

Immunoprecipitation and DNA Isolation

Ninety-six-well plates were washed once with 200 µl of PBS per well and were incubated overnight with 0.2 µg of protein A in 100 µl of PBS per well. After washing (200 µl of PBS per well), well walls were blocked with 200 µl of blocking buffer (15 to 60 minutes, 22°C). The wells were cleared and the used antibodies (Table 1) were added with 100 µl of blocking buffer per well (60 minutes, 22°C). Chromatin samples (5.0-µl chromatin preparations/100 µl of blocking buffer) were added (100 µl/well) and plates were floated in an ultrasonic water bath (60 minutes, 4°C) to accelerate protein-antibody binding.⁴¹ The wells were washed three times with 200 µl of IP buffer and 1 times with 200 µl of TE buffer. Wells were incubated with 100 µl of elution buffer (15 minutes at 55°C, followed by 15 minutes at 95°C). Total DNA (input) was isolated using the same plate and concurrently with immunoprecipitated DNA by suspending 5.0 µl of chromatin in 100 µl of elution buffer (15 minutes at 55°C, followed by 15 minutes at 95°C). DNA samples were stored (–20°C) in the same Matrix ChIP plates for repeated use.

ChIP DNA samples were assayed by qPCR. The reaction mixture contained 2.5 µl of 2x SYBR Green PCR master mix (SensiMix, Quantace), 2.3 µl of DNA template, and 0.2 µl of primers (10 µmol/L) in 5-µl final volume in a 384-well optical reaction plate (Applied Biosystems, Foster City, CA). Amplification (three step, 40 cycles), data acquisition, and analyses were done using the 7900HT real-time PCR system and SDS Enterprise Database (Applied Biosystems). All PCR reactions were run in triplicate. At least four samples were run for each determination. The used qPCR primers are presented in Table 2 . PCR calibration curves were generated for each primer pair from a dilution series of total mouse sheared genomic DNA. The PCR primer efficiency curve was fit to cycle threshold (Ct) versus log_e (genomic DNA dilutions) using an r-squared best fit. DNA concentration values for each ChIP and input DNA samples were calculated from their respective average Ct values. Final results were expressed as percent input DNA.⁴¹

All values are presented as means ± 1 SEM. Paired Student’s t-test was used to compare results obtained from left versus right kidney samples. Comparisons between different mice were performed by unpaired Student’s t-test. An n of four to eight tissue samples were used for all comparisons. Significance was judged by a P value of <0.05.

	Results

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We previously demonstrated that by 18 to 24 hours after ischemia-reperfusion (I/R) injury, an 25 to 50% increase in renal cortical cholesterol levels result.²⁸ The present study demonstrates the durability of this response: at 3 days after unilateral renal ischemia, a time that corresponds to persistent renal tubular histological injury (Figure 1) , cholesterol levels were elevated by 35%, compared to the values observed in contralateral (nonischemic) control kidneys (Figure 2 , left). Of note, the contralateral controls retained normal cholesterol levels, compared to sham-operated animals (data not shown). This indicates that the postischemic kidney elevations reflected the impact of I/R, rather than a nonspecific adaptation to surgical stress. The free cholesterol levels were accompanied by an approximate sixfold increase in cholesterol ester content (Figure 2 , middle). Because acyl transferase-mediated esterification represents a shunting of excess free cholesterol into the cholesterol ester storage pool,⁴⁰ cholesterol ester serves as a biomarker for degrees of cell cholesterol/sterol excess.^29,42

View larger version (102K): [in this window] [in a new window]   Figure 1. Renal histological injury, as assessed at 3 days after unilateral ischemic injury. As a frame of reference for interpreting the biochemical data, 4-µm kidney sections were cut from 10% formalin-fixed tissues and stained with H&E. Extensive proximal tubular necrosis and cast formation was observed in the renal cortex (A) and in the outer medullary stripe (B). C: The contralateral kidney manifested normal histology. Thus, extensive renal injury was present in the kidney samples that were used to study the HMG CoA reductase pathway.

View larger version (35K): [in this window] [in a new window]   Figure 2. Free cholesterol (left), cholesterol esters (middle), and HMG CoA reductase (HMGCR) protein levels (right, by Western blot) were assessed 3 days after unilateral I/R and in contralateral (CL) control kidneys. An 35% increase in free cholesterol levels was observed. This was accompanied by a sixfold increase in cholesterol esters, a cholesterol storage form. Increases in HMGCR protein were also observed, the magnitude of which paralleled the extent of the free cholesterol accumulation (each 35%).

To gain additional support for the concept that I/R activates the HMGCR gene, HMGCR mRNA levels were assessed. As shown in Figure 3A , at both 4 and 72 hours after ischemia, HMGCR mRNA levels were elevated by 30 to 35%, quantitatively paralleling the HMGCR protein and cholesterol increases. The 4-hour mRNA elevations are noteworthy in that they preceded any increase in renal cholesterol content (data not shown), suggesting mechanistic relevance. HMGCR mRNA levels were still increased at the 72-hour time point, a time of marked cholesterol excess. Because suppressed HMGCR mRNA would be expected with cholesterol overload, a failure of feedback inhibition of mevalonate/cholesterol signaling pathway(s) clearly existed.^43-46

View larger version (24K): [in this window] [in a new window]   Figure 3. A: HMGCR mRNA levels in control and post-I/R cortical kidney samples obtained at 4 or 72 hours after surgery were quantified by PCR. In both instances, an 30% increase in mRNA levels was observed (expressed as a ratio to GAPDH). B: RNA polymerase II (Pol II) densities were assessed at the HMGCR promoter, and at the start and end exons of the HMGCR gene (exons 1 and 19). I/R caused a small, albeit statistically significant, Pol II increase at the HMGCR promoter. Conversely, I/R induced an approximately threefold increase in Pol II at both exons 1 and 19. As expected, the absolute Pol II amounts in both the control and post-I/R kidneys were greater at the start versus the end exon.

The maintenance of cellular cholesterol homeostasis is generally believed to be under the transcriptional control of SREBP-2, and to a lesser extent, SREBP-1.^43-45 Under conditions of normal cholesterol supply, the SREBPs bind cholesterol and remain inactive, being anchored within the endoplasmic reticulum.^43-47 Under conditions of cholesterol depletion, the SREBPs are mobilized from the endoplasmic reticulum, and they are escorted to the Golgi apparatus by SCAP (SREBP-cleavage-activating protein). Two proteolytic steps then ensue (via S1P and S2P), generating active transcription factors. These gain nuclear access via importin β, and they then bind to multiple genes that regulate lipid synthesis (including HMGCR). Under conditions of cholesterol excess, these signaling pathways should be suppressed. Therefore, to assess whether SREBP signaling is activated by I/R, SREBP-1 and SREBP-2 densities at the HMGCR promoter were determined. As shown in Figure 4 , approximately threefold elevations of both SREBPs were observed at the promoter region. This indicates both a failure of physiological suppression and that the SREBPs likely participate in mediating the cholesterol loading state. The reason for the inappropriate SREBP nuclear translocation in the setting of cholesterol excess remains unknown. However, one possibility is that I/R activates intracellular/endoplasmic reticulum proteases, causing nonphysiological SREBP-endoplasmic reticulum release.

View larger version (30K): [in this window] [in a new window]   Figure 4. The HMGCR promoter region was probed for: i) sterol-responsive element binding proteins (SREBP 1, 2); ii) general transcription factors (NF-B, c-FOS, c-Jun); and iii) two heat shock proteins (HSP-70 and HSP-32, ie, HO-1). I/R caused twofold to threefold increases in the densities of both SREBP 1 and 2 at the HMGCR promoter. Significantly greater amounts of NF-B, c-Fos, c-Jun, HSP-70, and HO-1 were also observed in the I/R versus control kidneys. Thus, multiple factors appear to activate HMGCR transcription as part of the stress response.

Recently, there have been suggestions that transcription factors can bind along the length of an activated gene, rather than simply being confined to the promoter region. For example, Martone and colleagues⁶⁰ documented NF-B along the length of chromosome 22. This suggests that in addition to initiation of transcription, the classical transcription factor(s) may also participate in elongation and pre-mRNA processing. To test whether the above noted changes in NF-B, c-Fos, c-Jun, HO-1, and HSP-70 might extend beyond the promoter, each was probed at both start and end exons of the HMGCR gene. As shown in Figure 5 , the postischemic kidneys did, indeed, demonstrate increased amounts of each of these five proteins at these loci. Thus, these findings seemingly provide a new paradigm for stress-mediated cholesterol accumulation: the stress response, in this case induced by I/R, leads to binding of not only SREBPs, but also of inducible transcription factors, as well as HSPs, to the HMGCR promoter and transcribed regions.

View larger version (27K): [in this window] [in a new window]   Figure 5. Localization of general transcription factors (NF-B, c-Fos, c-Jun), HSP-70, and HO-1, at the start and end HMGCR exons. I/R induced significant increases of each protein at both HMGCR exons 1 and 19, compared to control kidneys. The absolute levels were consistently greater at the start versus the end exon (as would be expected with gene transcription).

View larger version (16K): [in this window] [in a new window]   Figure 6. Assessments performed at a control gene (β-actin, exon 1). I/R did not significantly alter Pol II levels at β-actin, exon 1, serving as a negative control for the data shown at the right of Figure 2 . Furthermore, I/R did not impact NF-B, c-Fos, or c-Jun binding to β-actin, (negative control for the data in Figure 4 ). Finally, no difference in the extent of trimethylation of histone 3 lysine 4 (H3K4m3) was observed, indicating the relative specificity for data presented in Figure 8 . [Note: H3K9AC and H2A.Z variants at β-actin were not assessed.]

View larger version (17K): [in this window] [in a new window]   Figure 7. Assessments performed at the β-globin gene. As additional controls for the experiments depicted in Figures 1 to 5 and Figure 7 , the SREBPs, general transcription factors, heat shock proteins, and histone modifications/variants were assessed at the normally silent β-globin gene (assessed between exon 1 and intron 1). In no instance was a statistically significant difference observed between control and the I/R kidney samples. Not shown (because of a different y axis scale), the amount of H3K4m3 was also not increased by I/R (2.2% versus 2.5% input for control and I/R samples; NS).

View larger version (28K): [in this window] [in a new window]   Figure 8. Histone variant H2A.Z levels and H3 histone modifications at the HMGCR promoter, and along the gene. I/R caused a twofold to fourfold increase in the amounts of H2A.Z variant and of H3K4m3 at all assessed sites. H3 lysine 19 acetylation was also increased at exons 1 and 19 (but not at the promoter).

	Discussion

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The purpose of this study was to focus on the molecular determinant(s) of just one critical cholesterol homeostatic pathway: the HMGCR gene. The stimulus for this investigation was the present observation that I/R caused increases in both HMGCR protein and its cognate mRNA. Hence, we sought to gain further support for increased HMGCR activity by attempting to document increased Pol II recruitment to multiple loci within the transcribed and promoter regions. Because this was observed, as discussed at length in the Results section, we sought to identify the transcription factors that might be involved. The results obtained indicated that classic sterol regulatory transcription factors (SREBP-1, SREBP-2), stress-activated transcription factors (NF-B, c-Fos, C-Jun), and heat shock proteins (HSP-70, HO-1) may all play a role. That non-SREBP gene-activating elements may impact HMGCR regulation during cell stress represents, to the best of our knowledge, a novel insight.

Finally, we sought to test the hypothesis that I/R-induced HMGCR activation might either arise from, or conceivably induce, histone modifications at its gene loci. The results obtained support this possibility given that three potential gene activating epigenetic modifications at the HMGCR promoter and along the gene (increased H3K4m3, H3K9Ac, and H2A.Z) were observed. It remains to be proven that these modifications are mechanistically involved in activating the HMGCR gene, and hence, culminate in increased Pol II recruitment. An answer to this question remains a goal for future studies. These will undoubtedly require techniques to alter specific histone modifications at specific locations within the genome. Until such methodologies are available, the physiological relevance of the dramatic H3K4m3, H3K9AC, and H2A.Z changes noted in this study must be considered speculative as of this time.

	Footnotes

 
Address reprint requests to Richard A. Zager, M.D., Fred Hutchinson Cancer Research Center, 1100 Fairview Ave. N, Room D2-190, Seattle, WA 98109. E-mail: dzager{at}fhcrc.org

Supported by the National Institutes of Health (research grants DK-R37-38431 and DK-68520 to R.A.Z.; and DK-R37-45978 and GM45134 to K.B.).

Accepted for publication September 19, 2008.

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