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Aspirin, NSAIDs, and Colorectal Cancer: Possible Involvement in an Insulin-Related Pathway

¹ Health Research Center and ² Department of Pathology, School of Medicine, University of Utah, Salt Lake City, UT; ³ Kaiser Permanente Medical Research Program, Oakland, CA; ⁴ University of California at Irvine, Irvine, CA

Requests for reprints: Martha L. Slattery, Health Research Center, University of Utah, 375 Chipeta Way, Suite A, Salt Lake City, UT 84108. Phone: (801) 585-6955; Fax: (801) 581-3623. E-mail: mslatter{at}hrc.utah.edu

	Abstract

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Introduction: Aspirin and nonsteroidal anti-inflammatory drugs (NSAIDs) have been shown to reduce risk of colorectal cancer. Although inhibition of cyclooxygenase (COX)-2 is generally thought to be the relevant mechanism, aspirin-like drugs apparently are involved in other pathways and mechanisms. We explore the associations between aspirin/NSAIDs, the insulin-related pathway, and the risk of colorectal cancer. Methods: Genetic polymorphisms of five genes identified as being involved in an insulin-related pathway were genotyped using data collected in a case-control study of 1346 incident colon cancer cases and 1544 population-based controls and 952 incident rectal cancer cases and 1205 controls. Genotypes assessed were the 3' untranslated region poly(A) and the intron 8 BsmI polymorphisms of the VDR gene, a CA repeat polymorphism of the IGF1 gene, the A/C polymorphism at nucleotide –202 of the IGFBP3, the Gly972Arg polymorphism of the IRS1 gene, and the Gly1057Asp polymorphism of the IRS2 gene. Results: Use of aspirin and NSAIDs was associated with a decreased risk of colorectal cancer, with slightly greater protection from NSAIDs than aspirin for rectal cancer. We observed a significant interaction between IRS1 genotype and aspirin/NSAIDs use and risk of colorectal cancer. Relative to the GR/RR IRS1 genotype, a protective effect from the GG IRS1 genotype was seen in those who did not use NSAIDs; use of NSAIDs was protective for all genotypes. These associations were especially strong for those diagnosed prior to age 65 (P interaction = 0.0006). We also observed a significant interaction between aspirin/NSAIDs use and the VDR gene. Having the SS or BB VDR genotypes reduced risk of colorectal cancer among non-aspirin/NSAID users; however, aspirin/NSAIDs reduced risk for all VDR genotypes. Conclusions: These data support the protective effect of aspirin and NSAIDs on colorectal cancer risk. In addition, the observed interactions for aspirin/NSAIDs and IRS1 and VDR genotypes suggest that mechanisms other than COX-2 inhibition may be contributing to the protective effect of aspirin and NSAIDs on colorectal cancer risk.

	Introduction

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Use of aspirin and nonsteroidal anti-inflammatory drugs (NSAIDs) have been associated with reduced risk of colorectal cancer in both case-control and cohort studies (1–8). Although fewer studies of rectal cancer and aspirin and NSAIDs have been reported, there are reports of these agents having chemopreventive properties for rectal cancer as well (4, 9, 10). Studies of colorectal adenomas provide additional support for the protective effect of aspirin/NSAIDs on reducing the likelihood of colorectal polyp recurrence (11, 12). The mechanism of protection has been proposed to be inhibition of a cyclooxygenase (COX)-2 pathway, a pathway that involves the regulation of prostaglandin synthesis and related cell growth (7, 13). Other studies, although not directly related to colorectal cancer, suggest possible biological mechanisms for the action of aspirin and NSAIDs that do not involve COX-2 pathway (14–16). One proposed mechanism involves aspirin/NSAID effects on an insulin-related pathway (17). Because inflammation is one condition that is thought to promote insulin resistance (17), aspirin/NSAIDs may reduce inflammation and therefore impact colorectal cancer risk by altering insulin resistance.

The hypothesis that an insulin-related pathway and insulin resistance is involved in the etiology of colon cancer has been constructed through a variety of research results (17). Diet and life-style factors, such as physical activity and body mass index (BMI), have been associated with insulin levels as well as with colon cancer (18, 19). A growing body of research suggests that insulin and insulin-like growth factors may be associated with colon cancer (20–22).

The insulin-like growth factor 1 (IGF1), insulin-like growth factor binding protein 3 (IGFBP3), insulin receptor substrate 1 (IRS1), insulin receptor substrate 2 (IRS2), and the vitamin D receptor (VDR) genes have been proposed as being directly or indirectly involved in insulin-related pathways. Polymorphisms of these genes have been identified, some of which have been shown to have effects on insulin resistance and/or colon cancer risk. High IGF1 levels have been associated with an increased risk of colorectal cancer, and variation in serum IGF1 levels is associated with a polymorphism 1 kb upstream of the transcription start site (23). This is a CA repeat polymorphism, and the most common allele contains 19 CA repeats and is denoted "192" for the size of the PCR product (23). In men, serum IGF1 concentrations were lower with the 192/192 genotype than for other IGF1 genotypes, so one could predict that this genotype might be associated with a decreased risk of colorectal cancer. High levels of IGFBP3 have been associated with a reduced risk of colorectal cancer (24). An A/C polymorphism at nucleotide –202 is associated with different levels of IGFBP3 in a dose response fashion (i.e., AA > AC > CC). The AC or CC genotypes would thus be predicted to be associated with an increased risk of colorectal cancer. Polymorphisms of the VDR gene have been associated with colorectal cancer and adenomas (25–28); in particular, an intron 8 BsmI polymorphism (denoted B for absence of restriction site) and a relatively short 3' untranslated region poly(A) (donated S for short), which are in linkage disequilibrium, have been reported to be protective against colonic adenomas and prostate cancer, respectively (25, 29). In a previous study of a relatively small number of colon cancer cases, we saw a mild protective effect of these VDR genotypes (28). There are also data showing an association between VDR and insulin, IGF1, and IGFBP3 levels (30–32). A recent report also showed that mice lacking a VDR receptor had lower serum insulin levels than mice with a functional receptor (33). A Gly972Arg (G972R) polymorphism in the IRS1 gene has been associated with insulin resistance and type 2 diabetes and might therefore be associated with an increased risk of colorectal cancer. The Gly1057Asp IRS2 polymorphism has been associated with obesity; therefore, a plausible link to insulin resistance and colorectal cancer exists (34). Interaction between aspirin/NSAIDs and these genes may provide insight into the hypothesis that use of aspirin/NSAIDs alters colorectal cancer risk through an insulin-related pathway.

In this study, we report associations between aspirin/NSAIDs and rectal cancer; we have previously reported similar associations for colon cancer (8). We evaluate genetic polymorphisms involved in the insulin pathway and their interaction with aspirin/NSAIDs in affecting the risk of developing colon and rectal cancer. We report associations for men and women as well as by age at time of diagnosis. We evaluate these factors because many risk factors for colorectal cancer have been shown to differ by age and sex.

	Methods

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Study Population
Participants in the study were from the northern California Kaiser Permanente Medical Care Program (KPMCP) and Utah. All eligible cases within these defined geographic areas were identified as possible study participants. Two study populations are included in these analyses. The first study includes cases and controls from a population-based case-control study of first primary colon cancer (International Classification of Diseases, Second Edition codes 18.0 and 18.2–18.9) diagnosed between October 1, 1991 and September 30, 1994. The second study includes cases with a first primary tumor in the rectosigmoid junction or rectum, who were identified between May 1997 and May 2001 in Utah and KPMCP. Case eligibility was verified by the Surveillance Epidemiology and End Results cancer registries in northern California and in Utah. In both studies, cases were identified using rapid-reporting systems and eligibility included being between 30 and 79 years old at time of diagnosis, English speaking, mentally competent to complete the interview, no previous history of colorectal cancer (35), and no known (as indicated on the pathology report) familial adenomatous polyposis, ulcerative colitis, or Crohn's disease.

Controls were matched to cases by sex and by 5-year age groups. At the KPMCP, controls were randomly selected from membership lists; in Utah, controls 65 years and older were randomly selected from the Health Care Financing Administration lists and controls younger than 65 years were randomly selected from driver's license lists. The analysis includes 1346 colon cancer cases and 1544 controls interviewed between February 1991 and May 1994 and 952 rectal cancer cases and 1205 controls interviewed between October 1997 and January 2002. For the colon study, 80.8% of cases and 71.6% of controls whom we were able to contact were interviewed; for the rectal study, we interviewed 73.2% of cases and 68.8% of controls contacted. Response rates, or the number interviewed over all persons identified, were 71.8% for colon cancer cases and 68.0% for controls selected for the colon cancer study and 65.2% of cases and 65.3% of controls for the rectal cancer study.

Genetic Variants
DNA was extracted from peripheral blood leukocytes. Of the colon cancer cases and controls who were interviewed, 1048 cases and 1194 controls had DNA available for analysis. Of the 952 rectal cancer cases and 1205 controls interviewed, 827 cases and 1031 controls had DNA extracted. Of these, genotypic data were available for 793 rectal cancer cases and 994 controls for VDR, 792 rectal cancer cases and 985 controls for IGF1, 794 rectal cancer cases and 989 controls for IGFBP3, 796 rectal cancer cases and 988 controls for IRS1, and 775 cases and 984 controls for IRS2.

VDR. Intron 8 BsmI polymorphism: Genomic DNA was amplified and digested as described previously (28). Presence of the restriction site was scored as allele "b" and absence of the restriction site was scored as allele "B." 3' Untranslated region poly(A) repeat: Genomic DNA was amplified and allele length was determined as described previously (28). Repeat length was classified as short (14–17 repeats) or S or long (18–22 repeats) or L or as described by Ingles et al. (29).

IRS1. The G972R polymorphism was detected using PCR amplification with primers 5'-CTTCTGTCAGGTGTCCATCC and 5'-TGGCGAGGTGTCCACGTAGC and subsequent BstNI digestion (36). PCR cycling consisted of an initial denaturation at 94°C for 2 min, 10 cycles at 94°C, 60°C, and 72°C for 10 s each followed by 30 cycles at 94°C, 55°C, and 72°C for 10 s each. Genotypes were scored as either G for glycine or R for arginine (absence or presence of the restriction site, respectively).

IRS2. The G1057D (G>A) polymorphism was detected using a previously described TaqMan assay (Ehrmann et al.) with minor modifications. Primer and probe sequences for the TaqMan assay were as follows: primer IRS2-F 5'GGA GCT GTA CCG CCT GCC3' , primer IRS2-R 5'ACC AAA AGC CAT CTC GGT GT3' , G-probe FAM-CCG GGC GCC GCC TCA T-Trauma, and A-probe VIC-CCG ACG CCG CCT CAT CGT T-Tamra. Each 17 µl PCR reaction contained 20ng genomic DNA, 900 nM of each primer, 130 nM of each TaqMan probe, and 8.5 µl TaqMan 2x Universal PCR Master Mix (contains AmpErase UNG and AMpliTaq Gold enzymes, dNTPs, and reaction buffer). PCR was carried out under the following conditions: 95°C for 10 min, followed by 40 cycles of 95°C for 15 sec, and 62°C for 1 minute using the BIO-RAD IQ detection system. The fluorescence of each sample was collected and analyzed version 3.0 of the iCycler IQ Real-Time detection software.

IGF1. The IGF1 CA repeat was PCR amplified using primers IGF1-F 5'-GCTAGCCAGCTGGTGTTATT and IGF1-R 5'-ACCACTCTGGGAGAAGGGTA (37). PCR conditions consisted of a 2-min denaturation at 94°C followed by 30 cycles of 94°C for 10 s, 57°C for 10 s, and 72°C for 15 s. The IGF1 products were electrophoresed on 6% denaturing polyacrylamide gels at 70 W for 3 h. The gels were dried and exposed to X-ray film. Alleles were assigned by size of fragment (in bp) and classified as "192" or "no 192." "192" is the PCR product size of the most common allele, which contains 19 CA repeats.

IGFBP3. The A/C single nucleotide polymorphism at nucleotide –202 was evaluated by PCR amplification using primers F 5'-CCACGAGGTACACACGAATG and R3 5'-TGAGCAGCCGGGGCCGAG and Alw21I digestion (38). Amplitaq gold (0.5 units) and 5% DMSO were used to increase efficiency of amplification. PCR conditions were 9-min initial denaturation at 95°C followed by 40 cycles at 95°C for 10 s and 66°C for 20 s. The resulting PCR product was digested with Alw21I (4 units) at 37°C overnight. Digested products were separated on a 2% Nusieve gel stained with ethidium bromide and visualized with UV light. Genotypes were scored by the presence of the A/C allele; band sizes of 242 and 162 corresponded to the A allele, while band sizes of 288 and 162 corresponded to the C allele.

Questionnaire Data
Data were collected by trained interviewers; quality control procedures have been described previously (39). The referent period was the calendar year 2 years prior to date of diagnosis or interview. Regular use of aspirin and NSAID use was collected. Regular use was defined as using at least thrice a week for 1 month or more. Year started and stopped using aspirin and NSAIDs were collected. Other questionnaire data included information on physical activity, diet, family history of cancer, and recalled height and weight 2 years prior to interview.

Statistical Methods
SAS Statistical Package, Version 8.2 was used to conduct the analysis. The B and b BsmI VDR alleles are highly associated with the S and L poly(A) alleles, respectively. Because we did not have data on both polymorphisms for all cases, we combined the polymorphism results and report the genotypes as BB or SS, bb or LL, or other (most of which are Bb/SL). Separate analyses of BsmI and poly(A) polymorphisms showed no additional associations (data not shown). Among those that had data for both genotypes, 97% of those with the LL genotype also had the bb genotype; between SS and BB, there was 95% agreement; and between LS and Bb, there was 96% agreement. The IRS1 polymorphism was designated as GG or GR/RR. IGF1 genotypes were homozygous 192/192, heterozygote 192/no 192 alleles, or homozygous with no 192 alleles. IGFBP3 was categorized as CC, CA, or AA genotypes. IRS2 was genotyped as GG, GD, or DD. Tumor site was defined as proximal (cecum through transverse colon), distal (splenic flexure, descending, and sigmoid colon), and rectal (rectosigmoid junction and rectum).

Nonconditional logistic regression analysis was done to generate odds ratios (OR) and 95% confidence intervals (CI). In these models, the following factors were adjusted: age at diagnosis or selection; gender (for combined analysis); long-term, vigorous, leisure time physical activity; BMI (kg/m²); energy intake; dietary fiber; calcium; and usual number of cigarettes smoked. Age-specific analyses were done assessing those diagnosed after age 65 and 65 or younger. Sex-specific analysis for men and women was done. Statistical differences in effect were tested by determining the relative excess risk from interaction (RERI) and corresponding 95% CI as well as by testing for significant differences in slopes using the Wald ² test. The RERI (40) provides insight into differences that might be expected on an additive scale of interaction, while the test for differences in slopes is related to multiplicative interaction.

	Results

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Colon cancer cases were slightly older than rectal cancer cases (Table 1). For both colon and rectal cancer, cases were more likely to be male than female. Thirty percent of the population reported taking aspirin on a regular basis, while about 25% reported using NSAIDs drugs regularly. Colon cancer cases were slightly less likely to have the BB BsmI or SS poly(A) VDR genotype while they were slightly more likely to have the GR/RR genotypes of IRS1.

	Discussion

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There is a great deal of evidence that aspirin/NSAIDs have effects on insulin resistance. It has been long known that salicylates have a hypoglycemic effect and that they reduce fasting blood glucose in diabetic persons (44–48). High doses of salicylates have been shown to reverse hyperglycemia, hyperinsulinemia, and dyslipidemia in obese rodents by sensitizing insulin signaling (49). In patients with type 2 diabetes, aspirin treatment has been shown to reduce fasting plasma glucose, total cholesterol, C-reactive protein, triglycerides, and insulin clearance; aspirin reduced hepatic glucose production and improved insulin-stimulated peripheral glucose uptake by 20% (50). Aspirin/NSAID influence on insulin resistance appears to be independent of COX-2 inhibition, instead involving inhibition of nuclear factor-B and IB and/or activation of peroxisome proliferator-activated receptors (49). An interaction between aspirin and IRS1 in antagonizing effects of tumor necrosis factor- (TNF-) has also been reported. TNF-, a major cause of insulin resistance in obesity and inflammation, has been reported to inhibit insulin-induced glucose uptake by targeting components of the insulin signaling cascade, one of which is insulin receptor substrate (51–55). IRS1 is the major cytoplasmic substrate of the insulin receptor in most insulin-sensitive tissues and is necessary for maintenance of metabolic homeostasis. Aspirin has been shown to inhibit the TNF--induced serine phosphorylation of IRS1 through inhibition of multiple serine kinases, including IB kinase (50).

The results of our current study support the notion that aspirin/NSAIDs may be altering colorectal cancer risk at least in part through effects on insulin resistance, as we saw interactions between aspirin/NSAID use and polymorphisms in genes in an insulin-related pathway. The nature of this interaction was that certain genotypes (i.e., SS or BB of VDR and GG of IRS1) showed a protective effect only in those who were not taking aspirin/NSAIDs; those taking aspirin/NSAIDs were protected against colorectal cancer regardless of genotype (Tables 3 and 4). Effects of these polymorphisms are only seen in those whose insulin-related pathway and insulin resistance have not been already down-regulated by aspirin/NSAIDs. These genes and their respective polymorphisms are plausible candidates for effects on colon cancer risk and/or insulin resistance. The G972R IRS1 polymorphism has been associated with a 50% reduction in insulin sensitivity (55), so the GG genotype would be predicted to decrease insulin resistance and the risk of colorectal cancer. VDR is involved in many pathways in addition to insulin, so the observed interaction between VDR and aspirin/NSAIDs could suggest the possibility of other pathways and mechanisms. However, vitamin D-related compounds can inhibit cancer cell growth possibly through interference with insulin-like growth factors or by altering insulin levels (56, 57) and VDR also is thought to be involved in IGFBP3 regulation (58). There are also data showing an association between VDR and insulin, IGF1, and IGFBP3 levels (30–32) as well as a report showing that mice lacking functional VDR have lower insulin levels (33). The particular genotypes we identify as protective have also been shown to be protective against colonic adenomas and prostate cancer (25, 29, 59) and in our previous smaller study of colonic adenocarcinoma (28).

Among women (data not shown in tables), we also observed a significant interaction between aspirin/NSAIDs and an IGFBP3 polymorphism such that aspirin use was of greatest benefit to those with the CC genotype. High levels of IGFBP3 have been associated with a reduced risk of colorectal cancer (60) and an A-to-C substitution in nucleotide –202 has been shown to result in different serum levels of IGFBP3 in a dose response fashion (i.e., AA > AC > CC; Ref. 38). Given the lower levels of IGFBP3 among those with the CC IGFBP3 genotype, it is reasonable that this group would indeed benefit the most from using aspirin/NSAIDs.

These data provide support for NSAIDs reducing the risk of rectal cancer for both men and women as well as for the reduced risk detected previously for colon cancer (8). Of interest is the observation that although aspirin reduced the risk of rectal cancer among women, it was not associated with reduced risk of rectal cancer among men. On the other hand, NSAIDs were associated with reduced risk of rectal cancer in both men and women. Although most studies show inverse associations between current use of aspirin/NSAIDs for colorectal cancer in both men and women, some have shown stronger associations for more proximal tumors or for women (2, 9, 10, 41).

There are limitations to the study. First, only five polymorphisms along a complex pathway have been examined. Second, we could not directly observe the effect of aspirin on the insulin pathway but can only infer that this might be important given the interaction of IRS1 with colorectal cancer. Although our sample was large, we were limited in power to precisely assess interactions, especially for rare genotypes. Associations detected with aspirin and NSAIDs are comparable with those detected in other case-control and cohort studies. This is one of the largest, if not the largest, study to evaluate risk factors for rectal cancer. Because data were collected in the same manner for both colon and rectal studies, we are able to compare associations from measurements of exposure collected in the same manner for both cancer sites.

In summary, we have demonstrated that use of NSAIDs reduce risk of rectal cancer. The IRS1 homozygous GG genotype and the VDR BB or SS genotypes significantly reduced risk of cancer in the absence of using NSAIDs, while those who used aspirin/NSAIDs did not experience reduction in risk beyond that from the drugs themselves. These data provide some support for an aspirin/NSAIDs effect on a non-COX-2 disease pathway. Replication of these results by others will provide support for the hypothesized role of aspirin/NSAIDs in an insulin-related pathway.

	Acknowledgments

 
We thank Thao Tran and Kazuko Yakumo for contributions in genotyping and Sandra Edwards, Karen Curtin, Roger Edwards, Leslie Palmer, Donna Schaffer, and Judy Morse for contributions in data collection and analysis.

	Footnotes

 
Grant support: National Cancer Institute grants CA48998 and CA85846 (M. S.), Utah Cancer Registry (contract N01-PC-67000 from the National Cancer Institute), State of Utah Department of Health, Northern California Cancer Registry, and Sacramento Tumor Registry.

The costs of publication of this article were defrayed in part by the payment of page charges. This article must therefore be hereby marked advertisement in accordance with 18 U.S.C. Section 1734 solely to indicate this fact.

Received 8/ 8/03; revised 11/26/03; accepted 12/ 9/03.

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