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Obesity-related genomic instability and altered xenobiotic metabolism: possible consequences for cancer risk and chemotherapy

Published online by Cambridge University Press:  28 July 2022

Ezgi Eyluel Bankoglu*
Affiliation:
Institute of Pharmacology and Toxicology, University of Wuerzburg, Wuerzburg, Germany
Helga Stopper
Affiliation:
Institute of Pharmacology and Toxicology, University of Wuerzburg, Wuerzburg, Germany
*
Author for correspondence: Ezgi Eyluel Bankoglu, E-mail: [email protected]
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Abstract

The increase in the prevalence of obesity has led to an elevated risk for several associated diseases including cancer. Several studies have investigated the DNA damage in human blood samples and showed a clear trend towards increased DNA damage in obesity. Reduced genomic stability is thus one of the consequences of obesity, which may contribute to the related cancer risk. Whether this is influenced by compromised DNA repair has not been elucidated sufficiently yet. On the other hand, obesity has also been linked to reduced therapy survival and increased adverse effects during chemotherapy, although the available data are controversial. Despite some indications that obesity might alter hepatic metabolism, current literature in humans is insufficient, and results from animal studies are inconclusive. Here we have summarised published data on hepatic drug metabolism to understand the impact of obesity on cancer therapy better. Furthermore, we highlight knowledge gaps in the interrelationship between obesity and drug metabolism from a toxicological perspective.

Type
Review
Creative Commons
Creative Common License - CCCreative Common License - BY
This is an Open Access article, distributed under the terms of the Creative Commons Attribution licence (http://creativecommons.org/licenses/by/4.0/), which permits unrestricted re-use, distribution and reproduction, provided the original article is properly cited.
Copyright
Copyright © The Author(s), 2022. Published by Cambridge University Press

Introduction

Obesity is one of the most important health problems of our century (Ref. Reference Kelly1). Today, the number one cause of mortality in the world is noncommunicable diseases and the major risk factors underlying noncommunicable diseases are insufficient physical activity, unhealthy diet and as combination of these two factors obesity (Ref. 2).

Susceptibility for many chronic diseases including cancer is increased by obesity (Refs 3, Reference Savini4). Almost 20% of all cancers are related to obesity and furthermore, being obese is a factor for poor prognosis in several cancers including breast and colorectal cancers (Ref. Reference Demark-Wahnefried5). It is therefore essential to understand how obesity affects cancer risk and its treatment efficiency for a growing number of patients.

The aim of this narrative review is to summarise the existing knowledge as well as to point out knowledge gaps in the field. For this, we have focused on the association between genomic instability, cancer risk and obesity. Furthermore, we discuss the influence of obesity on the outcome of chemotherapy, for which drug kinetics including metabolism is relevant. There are several other obesity-associated factors such as alterations in gut microbiome, hormonal and immune system status, which might be linked to cancer risk as well as influence cancer therapy. However, they are not within the scope of this review.

Search strategy and selection criteria

We intended to emphasise the relationship between obesity, genomic instability and cancer risk. In addition, we wanted to discuss the effect of being obese as cancer patient and the impact of obesity on cancer chemotherapeutic treatment and cytostatic drug metabolism. Finally, we planned to define knowledge gaps and indicate possible future research directions. The included articles were published from 2000 onwards. In addition, we conducted a manual search on reference lists of relevant articles in order to find additional references.

The following key words were included in our PubMed search: ‘DNA damage, genomic instability, DNA repair, cancer risk, obesity’, ‘drug metabolism, cytochrome P450, pharmacokinetic, cancer therapy, chemotherapy, obesity’. Based on the paper abstracts and availability, suitable publications for this narrative review were selected.

Influence of obesity on genomic stability

There are several studies which showed elevated DNA damage in obese subjects (Table 1). Most of these studies were conducted with blood samples. Comet assay, micronucleus test and fluorescence staining to determine phosphorylated H2Ax were the most commonly performed endpoints to measure DNA damage in humans.

Table 1. Influence of obesity on genomic stability

Increase (↑), decrease (↓) and no change (↔).

Micronucleus formation is a well-known endpoint for assessment of chromosomal damage. A micronucleus represents a chromosome or chromosomal fragment, which could not integrate into one of the daughter nuclei during mitosis (Ref. Reference Fenech6). An elevated micronucleus frequency in the peripheral blood mononuclear cells of obese subjects has been reported previously (Refs Reference Donmez-Altuntas7, Reference Bankoglu8, Reference Scarpato9). Furthermore, Bankoglu and colleagues have shown a significant reduction in micronucleus frequency of obese subjects following weight loss which was induced by bariatric surgery (Ref. Reference Bankoglu8). Micronuclei can arise from an aneugenic or a clastogenic effects (Ref. Reference Luzhna10). Clastogenic events are associated with DNA double-strand breaks, which in turn lead to the phosphorylation of histone 2Ax (termed γ-H2Ax), yielding a sensitive and reliable marker for DNA double-strand break detection (Ref. Reference Mah11). Scarpato et al. (Ref. Reference Scarpato9) investigated the DNA damage in peripheral blood mononuclear cells from overweight and obese children compared with normal weight children. Their findings revealed an increase in micronucleated and γ-H2Ax positive cells in overweight and obese children compared with normal weight children. In another study, γ-H2Ax analysis was performed in peripheral blood mononuclear cells (PBMCs) of obese and normal weight adolescents. The obese adolescents showed a higher frequency of γ-H2Ax positive cells compared with the normal weight adolescents (Ref. Reference Azzarà12).

The alkaline comet assay can detect single- and double-strand breaks. Modified comet assay versions can be used to measure specific lesions. For example, the detection of oxidised bases is enabled by the addition of formamidopyrimidine DNA glycosylase enzyme (Ref. Reference Collins13). Most of the studies that investigated the influence of obesity on DNA damage applied the alkaline and FPG comet assay. Using the alkaline comet assay in PBMCs from obese subjects, Włodarczyk et al. (Ref. Reference Włodarczyk14) showed an increase in DNA strand breaks compared with cells from normal weight individuals. Bukhari et al. (Ref. Reference Bukhari15) performed the alkaline comet assay with leucocytes from normal weight and obese subjects and their results indicated a higher DNA damage in leucocytes from obese subjects. Luperini et al. (Ref. Reference Luperini16) investigated the DNA damage in morbidly obese women compared with normal weight women by applying the FPG comet assay. Their findings showed a significant increase in DNA strand breaks and oxidised DNA bases in PBMCs of obese women. Also using the FPG comet assay, Bankoglu et al. (Refs Reference Bankoglu8, Reference Bankoglu17) found a significant reduction in DNA strand breaks but not in oxidative DNA lesions in PBMCs from obese subjects after a significant weight reduction induced by bariatric surgery.

Hofer et al. (Ref. Reference Hofer18) analysed the DNA damage in young healthy individuals and their findings showed a positive correlation between oxidative DNA damage measured by formamidopyrimidine DNA glycosylase (FPG) comet assay and body mass index (BMI) values (<24) in females. In another study, the alkaline comet assay was used to measure DNA strand breaks in breast cancer patients and healthy controls and BMI was a confounding factor influencing DNA damage. Interestingly, the DNA damage showed a positive correlation with BMI in breast cancer patients, but a negative correlation in healthy controls. In this study, the BMI was not different between the breast cancer patients and healthy controls and it was within the normal range (Ref. Reference Smith19).

Obesity has been linked to several factors that can contribute to increased genomic instability. Some of these factors can be listed as chronic inflammation, oxidative stress, altered levels of hormones such as insulin, formation of lipid peroxidation products and advanced glycation products. Setayesh and colleagues (Ref. Reference Setayesh20) published a detailed review on the impact of obesity on DNA stability, which provides an excellent overview of the contributing mechanistic factors.

Clearly, obesity is associated with increased DNA damage. However, under normal conditions DNA damage can be repaired efficiently by various DNA repair proteins and pathways. In order to understand the influence of obesity on genomic stability and cancer risk, the elucidation of the influence of obesity on DNA repair is essential. However, few studies regarding DNA repair in obesity in human are available. Wang et al. (Ref. Reference Wang21) identified a set of key drivers and genes which might be related to obesity (defined with several measures such as BMI, waist–hip ratio and computed tomography analysis) and most of these identified genes were important for cell cycle and DNA repair. In another study, Azzarà and colleagues analysed the DNA repair kinetics of mitomycin C-induced DNA damage in phytohaemagglutinin-stimulated peripheral blood lymphocytes by using γ-H2Ax staining. The same amount of in vitro mitomycin C treatment yielded a higher γ-H2Ax signal for PBMCs from obese adolescents compared with those from normal weight individuals after 2 h of treatment. However, after 4 h, the induced DNA damage was repaired more efficiently in the PBMCs from the obese individuals than in those from the normal weight individuals (Ref. Reference Azzarà12).

Nikodemova and colleagues investigated the effect of smoking on transcriptional differences (Ref. Reference Nikodemova22). Their findings showed gene expression differences between obese and non-obese smokers. In this study, obesity was linked to an altered expression of 29 genes. Among these genes, some were related to DNA damage response and repair, such as p53, RAD51 and GADD45A. This study indicated a possibility for increased susceptibility of obese subjects against environmental exposure. Tyson and colleagues studied the effect of micronutrient supplementation on nucleotide excision repair in PBMCs before and after 6 weeks of supplementation (Ref. Reference Tyson23). The study participants were genotyped for four polymorphisms in NER genes. There was no significant effect of individual polymorphisms or of micronutrient supplementation on NER capacity. However, the authors found a negative correlation between NER capacity and increasing BMI values.

Overall, the published studies indicate a possible modulatory role of obesity on DNA repair activity; however, further research is needed in this area.

Obesity and cancer risk

Accumulation of DNA damage because of missing or erroneous repair and increased genomic instability are key contributors to cancer development. There are several cohort studies that reported their observations regarding obesity and cancer risk (Table 2). The International Agency for Research on Cancer (IARC) reviewed these epidemiological studies together with studies in experimental animals and published an opinion paper on obesity and cancer in 2016 (Ref. Reference Lauby-Secretan24). In this, IARC deduced that obesity is a risk factor for several types of cancers (Ref. Reference Lauby-Secretan24). In the Norwegian Women and Cancer (NOWAC) study, the authors investigated the effect of body weight change and obesity-related cancer risk. They observed an overall increase in obesity-related cancer risk among overweight and obese women. In addition to this, a weight gain >10 kg over 6 years led to an increase in obesity-related cancer risk independent of BMI status at baseline (Ref. Reference da Silva25). Obesity is now widely accepted as one of the preventable cancer risk factors in addition to tobacco smoking (Refs Reference Brito26, 27, Reference Calle and Thun28). Birks and colleagues (Ref. Reference Birks29) published a systematic review on the impact of weight loss on cancer incidence and mortality. Their paper showed the beneficial effect of intentional weight loss (including bariatric surgery) on overall cancer risk. In this context, it is important to emphasise the relevance of sustaining an achieved weight loss. Teras et al. (Ref. Reference Teras30) investigated the effect of sustained weight loss on breast cancer in women. Sustained weight loss was defined as 2 or more kg lost in a first interval (5.2 years), which was not regained in the second interval (4 years). Their study showed a reduced breast cancer risk for women who managed to sustain weight loss, whereas women, who lost less than 9 kg and regained most of it had a similar breast cancer risk compared with the group without weight loss (Ref. Reference Teras30).

Table 2. Association between obesity, weight loss and cancer risk

Increase (↑), decrease (↓) and no change (↔).

Bankoglu et al. (Ref. Reference Bankoglu31) investigated the effect of a broad range of BMI on oxidative DNA damage. Their findings supported the possibility of a linear relationship between BMI and oxidative DNA lesions, although the number of subjects between BMI values 30 and 40 was too limited for a final interpretation. If linearity holds true, any amount of weight loss might be beneficial for reduction of the oxidative DNA damage in obese subjects.

In conclusion, weight loss can be beneficial for preventing obesity-related cancer, but the amount of required weight loss, the effect of weight loss methods and the consequences of a partial weight regain have not been fully elucidated.

In addition to endogenous factors, the link between obesity and cancer can also be influenced by exogenous risk factors. Since dietary exposure is one of the most common routes for chemical carcinogens, dietary preferences of individuals can shape the exposure pattern and their individual cancer risk. Metabolic enzymes can either convert a substance to an inactive metabolite and thus help in its elimination or can create reactive intermediates which can exert a toxic or mutagenic effect (Refs Reference Gonzalez and Kimura32, Reference Esteves33). Numerous carcinogens are metabolically activated or inactivated. Examples are dietary contaminants such as polycyclic aromatic hydrocarbons, the mycotoxin aflatoxin B1 or nitrosamines (Ref. Reference Sugimura34). The possible influence of external exposure and altered xenobiotic metabolism is discussed in the review by Setayesh and colleagues (Ref. Reference Setayesh20). From a toxicological perspective, obesity may affect the susceptibility to external exposures via alterations in xenobiotic metabolism. There are numerous publications which found differences in expression and/or activity of metabolising enzymes linked to obesity. We discuss these studies in the section ‘Influence of obesity on pharmacokinetic and dynamic processes’ in the context of the influence of obesity on pharmacokinetic and dynamic processes. However, to understand the possible effect of obesity on susceptibility of individuals to external exposure and the contribution of alterations in xenobiotic metabolism, human biomonitoring studies linking exposure data to cancer incidences and to metabolomics and transcriptomics data might be helpful.

Possible impact of obesity on cancer therapy

Since obesity is defined as a cancer risk factor, its increase in prevalence will contribute to new cancer cases as well as enhance the number of obese cancer patients (Ref. Reference Markham35). However, available information regarding the influence of obesity on prognosis and therapy outcome is limited (Table 3). Obesity has a strong association with several pathophysiological conditions, such as increased blood volume, low-grade inflammation, fatty liver, increased cardiac output and increased hepatic blood flow. The influence of these conditions on specific xenobiotic metabolism is not yet clear (Ref. Reference Brill36). Calle et al. (Ref. Reference Calle37) showed that BMI values equal to or greater than 40 lead to increased cancer mortality after 16 years of follow-up. They estimated that overweight and obesity might contribute with 14% to all cancer deaths in men and with 20% to all cancer deaths in women. For example, obesity is associated with reduced survival in breast cancer. Besides, obesity can lead to a poor prognosis for breast cancer (Refs Reference Jiralerspong and Goodwin38, Reference Protani39, Reference Chan40). Among colon cancer patients who received 5-fluorouracil-based adjuvant chemotherapy, obese and underweight but not overweight patients were affected by reduced survival outcome compared with normal weight patients (Ref. Reference Sinicrope41). In line with this study, the article from Renfro and colleagues revealed the relationship between BMI and colon cancer therapy outcome as J-shaped, with an overall better survival for overweight (non-obese) patients compared with underweight and obese patients with a BMI of 35 or more (Ref. Reference Renfro42). In contrast with these two studies, a better overall survival with higher BMI values was demonstrated for patients with metastatic colorectal cancer. Regarding side effects, higher BMI values were associated with higher risk for nausea, vomiting and peripheral neuropathy, whereas patients with lower BMI values had a higher risk for haematological toxicities (Ref. Reference Abdel-Rahman43). This different influence of obesity on cancer treatment side effects and treatment outcome is discussed in a recent review by Gallo and colleagues (Ref. Reference Gallo44).

Table 3. Impact of obesity on cancer therapy

Increase (↑) and decrease (↓).

Hourdequin and colleagues performed a meta-analysis comparing obese patients with normal weight patients after a chemotherapeutic drug dosing calculated with actual body weight. Their findings did neither indicate an increased chemotherapy toxicity nor reduced survival outcome in obese patients (Ref. Reference Hourdequin45). Lote et al. (Ref. Reference Lote46) investigated the side effect febrile neutropaenia in obese women with breast cancer and their findings did not reveal an increased toxicity for obese women. They recommend not to use a reduced chemotherapy dose for obese patients. Opposite to this, the GAIN study showed a higher toxicity of chemotherapy in those obese breast cancer patients, who received a dose which was adjusted to body surface area compared with unadjusted doses and to normal weight patients (Ref. Reference Furlanetto47). Sparreboom et al. (Ref. Reference Sparreboom48) studied the pharmacokinetics of eight anticancer drugs in lean and obese cancer patients. The drugs were administered intravenously and the dose for each drug was normalised according to body surface area. They found a significant increase in the clearance of cisplatin, paclitaxel and troxacitabine in obese compared with lean patients. However, the clearance of doxorubicin was significantly reduced in obese women, but not in men. This study showed that obesity may alter the pharmacokinetics of chemotherapeutic drugs in a sex-dependent and drug-specific manner. Guenancia and colleagues performed a meta-analysis to investigate the association between obesity/overweight and cardiotoxicity from anthracyclines in breast cancer therapy. Their study showed that being obese/overweight increased the risk of cardiotoxicity after anthracycline treatment (Ref. Reference Guenancia49). In another study, the effect of body composition on pharmacokinetics and toxicity of doxorubicin was studied in breast cancer patients. The study results revealed an increased doxorubicin exposure area under the curve (AUC) related to higher intra-abdominal fat content and indicated a higher risk for doxorubicin toxicity for patients with excess body fat. The authors suggested to use the body composition as a better marker for determining doses in chemotherapy than the body surface area (Ref. Reference Wong50). The dose of chemotherapeutics in cancer therapy is based on existing clinical trials and the calculated body surface area of a patient. However, many oncologists use an ideal body weight to calculate the drug doses in order to avoid possible overdosing and toxicity in obese patients (Refs Reference Lyman and Sparreboom51, Reference Griggs52). This might contribute to a reduced survival rate among obese patients. It is increasingly recognised that body surface area or BMI is not an accurate basis for the choice of the treatment doses.

In addition to altered kinetics, the state of obesity is likely to lead to modifications in protein expression and enzyme activity (Refs Reference O'Shea53, Reference Kudo54) which might be important for the uptake and transport or for the metabolism and excretion of chemotherapeutic drugs and other xenobiotics.

Understanding the interrelationship between obesity and drug efficiency better is crucial for reducing treatment side effects and mortality in cancer patients as well as for the adaptation of drug treatments to the rising incidence of obesity in general.

Influence of obesity on pharmacokinetic and dynamic processes

Variabilities in hepatic and extra-hepatic metabolic enzymes can lead to local and systemic toxicity in obese patients after exposure to both chemotherapeutic agents and environmental carcinogens. An altered activity of some drug metabolising enzymes in the obese state has been shown (Refs Reference O'Shea53, Reference Kudo54, Reference Ghose55, Reference Emery56). However, the available information in humans is limited to a few cytochrome P450 enzymes. Because of the limited number of studies in humans, we decided to include the existing rodent studies in this paper (Table 4).

Table 4. Influence of obesity on pharmacokinetic and pharmacodynamic processes in rodent obesity models and in humans

Increase (↑), decrease (↓) and no change (↔) compared with the control group and if not stated otherwise in liver tissue.

HO-1, haem oxygenase-1; NQO1, NAD(P)H quinone dehydrogenase; SULT, sulphotransferase family; UGT, UDP glucuronosyltransferase family; ABCB, ATP-binding cassette sub-family b; ABCC, ATP-binding cassette sub-family c; SLC, solute carrier family; SLCO, solute carrier organic anion transporter family; OATP1B1, organic anion transporting polypeptide 1B1; MDR, multi-drug resistance protein; MRP, multi-drug resistance-associated protein; GLUT4, glucose transporter type 4.

The mRNA and protein expression of CYP2E1 were analysed in liver, fat and kidney tissues of lean Zucker (+/+) rats which were either fed with a normal diet (ND) or a high-fat (HF) diet and obese Zucker (fa/fa) rats fed with ND (obese). Both ND and obese rats showed significantly higher levels of mRNA and protein expression for CYP2E1 in liver and fat tissues, but not in kidney tissue. In addition to the expression changes, an increase in the activity of CYP2E1 was measured after a single intravenous chlorzoxazone administration (Ref. Reference Khemawoot57). These results indicated an altered CYP2E1 activity in genetic as well as in diet-induced obesity models. In another study, the mRNA and protein expression of xenobiotic metabolising enzymes and transporters was analysed in liver and kidney samples from wild-type (C57BL/6) and obese mice (ob/ob). In the liver of obese mice, the expression of cytochrome P450 enzymes and efflux transporters was increased, whereas the expression of uptake transporters was decreased (Ref. Reference Cheng58). Jang et al. (Ref. Reference Jang59) used an HF diet-induced obesity model and analysed the mRNA and protein expression of organic cation transporter OCT1 in the liver of C57BL/6 mice. They found an increased mRNA and protein expression for OCT1 in the HF diet group. In parallel to this, obese mice showed an increase in the plasma and hepatic concentration of metformin after intraperitoneal or intravenous metformin application.

In another study, the authors tested the effect of bamboo extract on hepatic metabolising enzymes in C57BL/6J mice fed with standard diet and HF diet. Their results indicated significantly higher activity for CYP1A2 and CYP3A11 in the HF diet and bamboo extract-fed groups. However, the protein expression of these two enzymes showed no significant difference compared with that found in the mice fed with standard diet (Ref. Reference Koide60). The difference could be in the activity, which cannot be detected by expression measurements. Sawamoto and colleagues (Ref. Reference Sawamoto61) used lean Zucker (+/+) rats and obese Zucker (fa/fa) rats to understand their previous observation regarding the lower required maintenance dose of tacrolimus in obese patients compared with normal weight patients (BMI < 25) during a retrospective pharmacokinetic study. For this aim, a single-dose tacrolimus was administered either by intravenous injection or orally to the rats. The blood concentration–time profile of tacrolimus as well as the protein expression for CYP3A2 and P-glycoprotein in the liver and in the intestine were analysed. The results of this study demonstrated a significant reduction in protein expression of CYP3A2 in liver tissue of obese Zucker rats but not in intestine, whereas the expression of P-glycoprotein was increased in the intestine of obese Zucker rats but did not change in the liver. In addition, the blood concentration of tacrolimus was higher in obese Zucker rats after application via both routes, which indicated an increased bioavailability for tacrolimus and supported the patient study findings regarding lower maintenance dose of tacrolimus in obese patients.

Tomankova et al. (Ref. Reference Tomankova62) analysed the activity and expression of cytochrome P450 enzymes in liver, small intestine and colon samples of mice in which repeated injections of monosodium glutamate had been used to induce obesity. Body weight, plasma insulin and leptin levels were significantly higher in the obese group compared with the control. The obese mice showed increased expression and activity of some liver cytochrome P450 enzymes (CYP1A1/2, CYP2A5, CYP2E1 and CYP3A). There was no difference between the groups in the small intestine and colon samples. Ghoneim et al. (Ref. Reference Ghoneim63) used an HF diet-induced obesity model and analysed the mRNA and protein expression of CYP3A2, the mRNA expression of CYP7A1 and the expression of various drug transporters in the liver of Sprague-Dawley rats. The expression of CYP3A2 was significantly increased in the obese group compared with the control animals, whereas the expression of CYP7A1 remained unchanged. The ATP-binding cassette (Abc) transporters 1a, c2, b11 and b4, the solute carrier transporter 10a1 and the solute carrier organic anion transporter 1a4 showed an increased mRNA expression, whereas the mRNA expression for Abcc3 was significantly reduced.

In a study by Chiba and colleagues (Ref. Reference Chiba64), non-alcoholic fatty liver disease was induced in C57BL/6 mice by feeding a high-fat high-sucrose (HFHS) diet for 12 weeks. In addition to a standard diet group, the authors examined the protective effects of trans-resveratrol in HFHS diet mice. Animals in the HFHS group showed significantly higher body and liver weights, as well as increased accumulation of triglycerides and cholesterol. The mRNA expression of selected cytochrome P450 enzymes, except for Cyp3a11, was increased under the HFHS diet. The mRNA expression of Cyp3a11 was reduced. Trans-resveratrol slightly reduced lipid accumulation in the liver but failed to restore cytochrome P450 enzyme expression. The change in hepatic metabolism was studied only by mRNA expression analysis, which alone does not adequately represent the level of protein expression and activity of these enzymes.

Ning and Jeong (Ref. Reference Ning and Jeong65) applied an HF diet to CYP2D6 humanised transgenic (Tg-CYP2D6) mice. Tg-CYP2D6 mice were fed either with HF diet or control diet for 18 weeks. Mice in the HF diet group had higher body and liver weights compared with the mice under control diet. Hepatic mRNA levels of Cyp2d6 decreased slightly, but protein levels and activity did not differ between the diet groups. In addition to CYP2D6, the expression of other cytochrome P450 genes such as Cyp1a2 and Cyp2c37 was decreased in the HF diet group. The mRNA expression of Cyp2b10 and Cyp3a11 was higher in the HF diet group.

Sadler et al. (Ref. Reference Sadler66) studied the effect of cigarette smoke on cytochrome P450 enzyme activity in normal weight mice and obese mice fed with an HF diet. These animals were exposed to either active or passive cigarette smoke or filtered air. Their results showed decreased activity for many cytochrome P450 enzymes in the HF diet group alone. Simultaneous exposure to cigarette smoke and HF diet significantly increased the activity of several cytochrome P450 enzymes.

In the study by Sun et al. (Ref. Reference Sun67), C57BL/6J mice were fed with an HF diet for 10 weeks. This obesity mouse model was used to assess platelet aggregation and carotid arterial thrombosis in response to clopidogrel treatment. The results indicated impaired bioactivation of clopidogrel in obese mice because of downregulation of hepatic Cyp genes. The authors demonstrated reduced hepatic mRNA expression of Cyp2c genes, which is required for activation of the pro-drug clopidogrel.

In another study, Al Nebaihi and colleagues investigated the effect of an HF diet on cytochrome P450 enzymes in mice and rats and its influence on lidocaine metabolism (Ref. Reference Al Nebaihi68). Their results revealed reduced activity and expression of selected cytochrome P450 enzymes and reduction of the active lidocaine metabolite in mice and rats fed with the HF diet. These effects were normalised in rats by switching back to the standard.

Among the 12 studies described so far, five used a C57BL/6J mouse diet-induced obesity model. Of these, four analysed either the activity or expression of Cyp1a2 and three that of Cyp3a11. Although Koide et al. (Ref. Reference Koide60) determined increased activity for CYP1A2 and CYP3A11 in obese mice, Sadler and colleagues (Ref. Reference Sadler66) showed reduced activity of CYP1A2 and CYP3A11. Overall, these studies also demonstrated the importance of determining not only expression changes, but also enzyme activity, as alterations in metabolism were observed even with constant enzyme expression.

The listed studies employ a variety of ways to induce obesity. The cause of obesity is either genetic or diet induced and in the latter case the type of diet differs between studies. These differences might affect the grade of obesity as well as the manifestation of obesity-related comorbidities such as fatty liver, insulin intolerance and diabetes. Fatty liver and type 2 diabetes can affect hepatic health and metabolism, and a good characterisation of the progression of these comorbidities may contribute to a better understanding of the impact on liver metabolism.

The current literature regarding humans is usually limited to samples from morbidly obese patients without a healthy control group, as illustrated by the following studies. Ulvestad and colleagues (Ref. Reference Ulvestad69) analysed the protein expression of CYP3A4, the efflux transporter MDR1 and the organic anion transporter OATP1B1 in liver and small intestine biopsies from obese subjects. Their aim was to investigate the possible effect of the expression levels of these proteins on the pharmacokinetics of atorvastatin. They found a significant negative correlation between BMI values and protein expression of CYP3A4 in both tissues. In line with this, there was a negative correlation between BMI values and the oral clearance of atorvastatin. The protein expression of MDR1 or OATP1B1 in liver or intestine did not show a correlation with BMI values.

Lloret-Linares et al. (Ref. Reference Lloret-Linares70) collected jejunum tissue from morbidly obese subjects during Roux-en-Y gastric bypass surgery to study the association between obesity and the protein expression of CYP3A4, P-glycoprotein and multi drug resistance-associated proteins 2 and 3 (MRP2 and MRP3). In addition, they investigated the link between oral morphine pharmacokinetics in obese subjects and the jejunal expression of selected drug metabolising enzymes or drug transporters. For this, the oral pharmacokinetics of morphine (30 mg single dose) was analysed before the surgery. However, the pharmacokinetic parameters of morphine did not show any association with the jejunal protein expression for the selected drug metabolising enzymes or drug transporters. Overall, the protein expression in jejunum showed a large difference between individuals.

In another study, protein expression of metabolising enzymes in jejunal tissue samples from 28 morbidly obese subjects undergoing bariatric surgery was quantified (Ref. Reference Miyauchi71). The results showed a significant influence of BMI, gender and smoking on the expression of some metabolising enzymes. The protein expression of CYP1A2 was positively correlated with BMI (Ref. Reference Miyauchi71). Rodríguez-Morató and colleagues (Ref. Reference Rodríguez-Morató72) used drug probes (Karolinska cocktail including dextromethorphan, losartan, omeprazole, caffeine and paracetamol) to analyse the four major cytochrome P450 enzymes (CYP2D6, CYP3A4, CYP2C9 and CYP1A2) in normal weight, overweight and morbidly obese subjects before as well as 1 and 6 months after bariatric surgery. The estimated CYP3A4 activity was lower in morbidly obese subjects compared with normal weight controls and bariatric surgery helped to normalise its activity. The activity of CYP2D6 was higher in morbidly obese subjects than in normal weight controls. BMI did not have any effect on the activity of CYP2C9 and CYP1A2. Krogstad and colleagues (Ref. Reference Krogstad73) collected liver and small intestine biopsy samples from 20 obese patients undergoing gastric bypass surgery after 3 weeks of low-energy diet. Seven cytochrome P450 enzymes in these samples were examined. The results showed interindividual variability in the activity of the P450 enzymes. CYP2B6 activity correlated negatively with BMI. In a recent study from Krogstad and colleagues (Ref. Reference Krogstad74), liver biopsies from 36 individuals with a broad range of BMI (18–63) were analysed for an ex vivo activity of drug metabolising enzymes (CYP3A, CYP2B6, CYP3c8, CYP2D6, CYP2C9, CYP2C19 and CYP1A2). Their findings demonstrated a significant negative correlation between BMI and CYP3A activity in liver tissue. For the other CYP enzymes, there was no correlation. However, the enzyme activities for some of the selected CYPs (CYP2B6, CYP2C8, CYP2D6, CYP2C19 and CYP1A2) were not quantifiable because of either low enzyme activity or insufficient amount of tissue.

Overall, current literature explicitly aiming at metabolic enzymes in humans is limited to only a few cytochrome P450 enzymes. However, some additional published studies which used probe drugs to investigate drug clearance are reviewed elsewhere (see Refs Reference Brocks75, Reference Zarezadeh76). Drug clearance is influenced by alterations in expression/activity of drug metabolising enzymes, but also by other factors such as distribution within the body or blood flow, and therefore might not enable a direct conclusion regarding expression or activity of metabolic enzymes. Therefore, we focused in this review on articles that studied the expression and/or activity of metabolic enzymes.

The results from animal studies are ambiguous (Table 5). No consistent effect was observed for any of the investigated cytochrome P450 enzymes, except for CYP2B10 which was only assessed in mice at the RNA level. One reason may be that there are large differences in nutritional conditions and pathophysiology (fatty liver, type 2 diabetes, etc.) between the various rodent models.

Table 5. Summary for the effect of obesity on the most common studied cytochrome P450 enzymes in liver tissue from rodent obesity models of Table 4

Increase (↑), decrease (↓) and no change (↔) compared with the control group.

Extrapolation of animal data to humans can pose a great challenge because of cross-species differences in the expression of drug metabolising enzymes (Ref. Reference Hammer77). Although in vivo models are very useful to study complex disease models, additional research with modern cell culture techniques such as organoids or ‘human on a chip’ would provide further insights. Overall, well-designed studies to elucidate the effects of obesity on xenobiotic metabolism and the possible causes and affected enzymes or proteins are still needed.

Conclusions, knowledge gaps and future directions

The relationship between obesity, cancer risk and cancer survival is highly complex. Figure 1 gives an overview of endogenous and exogenous factors in obesity and their influence on cancer risk as well as cancer therapy. There are various additional factors that can modify the outcome; for example, the grade of obesity, existing comorbidities, sex and age of the patient, type of cancer and selected therapy approach.

Fig. 1. Overview on the relationship between obesity, cancer risk and cancer therapy. ang II: angiotensin II, IR: insulin resistance, T2DM: type 2 diabetes mellitus, NAFLD: non-alcoholic fatty liver disease.

The existing literature shows convincingly that obesity is a risk factor for several cancer types. However, the underlying mechanisms are not always clear. Elevated DNA damage is meanwhile well documented in obesity, although the causations are not only BMI dependent, but also linked to chronic inflammation (Ref. Reference Harvey78), oxidative stress (Refs Reference Bankoglu17, Reference Furukawa79, Reference Bankoglu80, Reference Marseglia81) and altered hormones such as insulin (Refs Reference Othman82, Reference Othman83). The vast majority of DNA damage can be eliminated by DNA repair mechanisms. Although there are some indications that DNA repair activity might be impaired in obesity, more research is needed to understand the role of DNA repair in the elevated cancer risk in obesity. In addition to all above specified endogenous cancer risk factors, exogenous risk factors can also play an important role in the obesity-related cancer risk. For example, lifestyle factors such as physical activity and nutritional preferences can contribute to cancer risk but can also be modified and play an important role in cancer prevention. Dietary preferences can modify the food-borne carcinogen exposure. For example, consuming ultra-processed food may increase the exposure to food additives and processing contaminants (Ref. Reference Kliemann84). Exposome research is a growing field which offers an approach to define the effects of endogenous and exogenous exposures to human health (Ref. Reference Zhang85). With increasing numbers of studies in this area, we will be able to define the external risk factors for obese individuals better.

Obesity may alter the susceptibility of an individual and thus modulate the response to an exposure. Regarding cancer therapy, poor prognosis, reduced survival and increased side effects are documented for obese patients in some studies. Dose adjustment in chemotherapy is critical for therapy success, but also for reducing side effects. Increased toxicity can lead to therapy interruptions and reduction of therapy success. Body surface area is one of the common methods for dose adjustment, but it might not be the best approach for obese patients. The American Society of Clinical Oncology (ASCO) recommends using full weight-based chemotherapy to treat obese patients with cancer, but also recommends a fixed dose only for some chemotherapeutics such as carboplatin. ASCO also states that further research is needed to understand the alterations in pharmacokinetic and pharmacogenetic parameters of chemotherapeutics for obese cancer patients (Ref. Reference Griggs52). We still have insufficient information on the influence of obesity on hepatic drug metabolism and drug clearance. An in-depth understanding on the role of obesity in xenobiotic metabolism can also help to adjust risk assessment for carcinogenic exposures to the increasing prevalence of obesity. Therefore, future studies addressing this question are essential.

Conflict of interest

The authors declare no conflict of interest.

References

Kelly, T et al. (2008) Global burden of obesity in 2005 and projections to 2030. International Journal of Obesity 32, 14311437.CrossRefGoogle ScholarPubMed
World Health Organisation. Noncommunicable diseases [Fact sheet], 13 April 2021. Available at https://www.who.int/news-room/fact-sheets/detail/noncommunicable-diseases.Google Scholar
World Health Organization. Obesity and Overweight, Fact sheet No. 311, 2015. Available at http://www.who.int/mediacentre/factsheets/fs311/en/.Google Scholar
Savini, I et al. (2013) Obesity-associated oxidative stress: strategies finalized to improve redox state. International Journal of Molecular Sciences 14, 1049710538.CrossRefGoogle ScholarPubMed
Demark-Wahnefried, W et al. (2012) The role of obesity in cancer survival and recurrence. Cancer Epidemiology, Biomarkers & Prevention 21, 12441259.CrossRefGoogle ScholarPubMed
Fenech, M (2007) Cytokinesis-block micronucleus cytome assay. Nature Protocols 2, 10841104.CrossRefGoogle ScholarPubMed
Donmez-Altuntas, H et al. (2014) Evaluation of chromosomal damage, cytostasis, cytotoxicity, oxidative DNA damage and their association with body-mass index in obese subjects. Mutation Research/Genetic Toxicology and Environmental Mutagenesis 771, 3036.CrossRefGoogle ScholarPubMed
Bankoglu, EE et al. (2018) Decreased chromosomal damage in lymphocytes of obese patients after bariatric surgery. Scientific Reports 8, 11195.CrossRefGoogle ScholarPubMed
Scarpato, R et al. (2010) Nuclear damage in peripheral lymphocytes of obese and overweight Italian children as evaluated by the γ-H2AX focus assay and micronucleus test. The FASEB Journal 25, 685693.CrossRefGoogle ScholarPubMed
Luzhna, L et al. (2013) Micronuclei in genotoxicity assessment: from genetics to epigenetics and beyond. Frontiers in Genetics 4. Available at https://doi.org/10.3389/fgene.2013.00131.CrossRefGoogle ScholarPubMed
Mah, LJ et al. (2010) γH2AX: a sensitive molecular marker of DNA damage and repair. Leukemia 24, 679686.CrossRefGoogle ScholarPubMed
Azzarà, A et al. (2016) Different repair kinetic of DSBs induced by mitomycin C in peripheral lymphocytes of obese and normal weight adolescents. Mutation Research 789, 914.CrossRefGoogle ScholarPubMed
Collins, AR (2004) The comet assay for DNA damage and repair. Molecular Biotechnology 26, 249.CrossRefGoogle ScholarPubMed
Włodarczyk, M et al. (2018) Anthropometric and dietary factors as predictors of DNA damage in obese women. Nutrients 10, 578.CrossRefGoogle ScholarPubMed
Bukhari, SA et al. (2010) Plasma homocysteine and DNA damage profiles in normal and obese subjects in the Pakistani population. Molecular Biology Reports 37, 289295.CrossRefGoogle ScholarPubMed
Luperini, BC et al. (2015) Gene polymorphisms and increased DNA damage in morbidly obese women. Mutation Research 776, 111117.CrossRefGoogle ScholarPubMed
Bankoglu, EE et al. (2020) Influence of bariatric surgery induced weight loss on oxidative DNA damage. Mutation Research 853, 503194.CrossRefGoogle ScholarPubMed
Hofer, T et al. (2006) DNA Oxidative damage and strand breaks in young healthy individuals: a gender difference and the role of life style factors. Free Radical Research 40, 707714.CrossRefGoogle ScholarPubMed
Smith, TR et al. (2003) DNA damage and breast cancer risk. Carcinogenesis 24, 883889.CrossRefGoogle ScholarPubMed
Setayesh, T et al. (2018) Impact of obesity and overweight on DNA stability: few facts and many hypotheses. Mutation Research, Reviews in Mutation Research 777, 6491.CrossRefGoogle ScholarPubMed
Wang, L et al. (2019) Integrating genetic, transcriptional, and biological information provides insights into obesity. International Journal of Obesity 43, 457467.CrossRefGoogle ScholarPubMed
Nikodemova, M et al. (2018) Transcriptional differences between smokers and non-smokers and variance by obesity as a risk factor for human sensitivity to environmental exposures. Environment International 113, 249258.CrossRefGoogle ScholarPubMed
Tyson, J et al. (2009) Inter-individual variation in nucleotide excision repair in young adults: effects of age, adiposity, micronutrient supplementation and genotype. British Journal of Nutrition 101, 13161323.CrossRefGoogle ScholarPubMed
Lauby-Secretan, B et al. (2016) Body fatness and cancer – viewpoint of the IARC working group. New England Journal of Medicine 375, 794798.CrossRefGoogle ScholarPubMed
da Silva, M et al. (2018) Excess body weight, weight gain and obesity-related cancer risk in women in Norway: the Norwegian women and cancer study. British Journal of Cancer 119, 646656.CrossRefGoogle ScholarPubMed
Brito, H et al. (2021) Obesity and cancer: the profile of a population who underwent bariatric surgery. Obesity Surgery 31, 46824691.CrossRefGoogle ScholarPubMed
D. The Lancet, Endocrinology (2020) The obesity–cancer link: of increasing concern. The Lancet Diabetes & Endocrinology 8, 175.CrossRefGoogle Scholar
Calle, EE and Thun, MJ (2004) Obesity and cancer. Oncogene 23, 63656378.CrossRefGoogle ScholarPubMed
Birks, S et al. (2012) A systematic review of the impact of weight loss on cancer incidence and mortality. Obesity Reviews 13, 868891.CrossRefGoogle ScholarPubMed
Teras, LR et al. (2020) Sustained weight loss and risk of breast cancer in women 50 years and older: a pooled analysis of prospective data. Journal of the National Cancer Institute 112, 929937.CrossRefGoogle ScholarPubMed
Bankoglu, EE et al. (2022) Short- and long-term reproducibility of the COMET assay for measuring DNA damage biomarkers in frozen blood samples of the EPIC-Heidelberg cohort. Mutation Research. Genetic Toxicology and Environmental Mutagenesis 874–875, 503442.CrossRefGoogle Scholar
Gonzalez, FJ and Kimura, S (2001) Understanding the role of xenobiotic-metabolism in chemical carcinogenesis using gene knockout mice. Mutation Research/Fundamental and Molecular Mechanisms of Mutagenesis 477, 7987.CrossRefGoogle ScholarPubMed
Esteves, F et al. (2021) The central role of cytochrome P450 in xenobiotic metabolism – a brief review on a fascinating enzyme family. Journal of Xenobiotics 11, 94114.CrossRefGoogle ScholarPubMed
Sugimura, T (2000) Nutrition and dietary carcinogens. Carcinogenesis 21, 387395.CrossRefGoogle ScholarPubMed
Markham, MJ et al. (2020) Clinical cancer advances 2020: annual report on progress against cancer from the American society of clinical oncology. Journal of Clinical Oncology 38, 1081.CrossRefGoogle ScholarPubMed
Brill, MJ et al. (2012) Impact of obesity on drug metabolism and elimination in adults and children. Clinical Pharmacokinetics 51, 277304.CrossRefGoogle ScholarPubMed
Calle, EE et al. (2003) Overweight, obesity, and mortality from cancer in a prospectively studied cohort of U.S. adults. New England Journal of Medicine 348, 16251638.CrossRefGoogle Scholar
Jiralerspong, S and Goodwin, PJ (2016) Obesity and breast cancer prognosis: evidence, challenges, and opportunities. Journal of Clinical Oncology 34, 42034216.CrossRefGoogle ScholarPubMed
Protani, M et al. (2010) Effect of obesity on survival of women with breast cancer: systematic review and meta-analysis. Breast Cancer Research and Treatment 123, 627635.CrossRefGoogle ScholarPubMed
Chan, DSM et al. (2014) Body mass index and survival in women with breast cancer-systematic literature review and meta-analysis of 82 follow-up studies. Annals of Oncology 25, 19011914.CrossRefGoogle ScholarPubMed
Sinicrope, FA et al. (2013) Body mass index at diagnosis and survival among colon cancer patients enrolled in clinical trials of adjuvant chemotherapy. Cancer 119, 15281536.CrossRefGoogle ScholarPubMed
Renfro, LA et al. (2014) ACCENT-based web calculators to predict recurrence and overall survival in stage III colon cancer. Journal of the National Cancer Institute 106 Available at https://doi.org/10.1093/jnci/dju333.CrossRefGoogle ScholarPubMed
Abdel-Rahman, O (2019) Effect of body mass Index on 5-FU-based chemotherapy toxicity and efficacy among patients with metastatic colorectal cancer; a pooled analysis of 5 randomized trials. Clinical Colorectal Cancer 18, e385e393.CrossRefGoogle ScholarPubMed
Gallo, M et al. (2021) Expected and paradoxical effects of obesity on cancer treatment response. Reviews in Endocrine and Metabolic Disorders 22, 681702.CrossRefGoogle ScholarPubMed
Hourdequin, KC et al. (2013) Toxic effect of chemotherapy dosing using actual body weight in obese versus normal-weight patients: a systematic review and meta-analysis. Annals of Oncology 24, 29522962.CrossRefGoogle ScholarPubMed
Lote, H et al. (2016) Febrile neutropenia rates according to body mass index and dose capping in women receiving chemotherapy for early breast cancer. Clinical Oncology 28, 597603.CrossRefGoogle ScholarPubMed
Furlanetto, J et al. (2016) Higher rate of severe toxicities in obese patients receiving dose-dense (dd) chemotherapy according to unadjusted body surface area: results of the prospectively randomized GAIN study. Annals of Oncology 27, 20532059.CrossRefGoogle ScholarPubMed
Sparreboom, A et al. (2007) Evaluation of alternate size descriptors for dose calculation of anticancer drugs in the obese. Journal of Clinical Oncology 25, 47074713.CrossRefGoogle ScholarPubMed
Guenancia, C et al. (2016) Obesity as a risk factor for anthracyclines and trastuzumab cardiotoxicity in breast cancer: a systematic review and meta-analysis. Journal of Clinical Oncology 34, 31573165.CrossRefGoogle ScholarPubMed
Wong, AL et al. (2014) Body fat composition impacts the hematologic toxicities and pharmacokinetics of doxorubicin in Asian breast cancer patients. Breast Cancer Research and Treatment 144, 143152.CrossRefGoogle ScholarPubMed
Lyman, GH and Sparreboom, A (2013) Chemotherapy dosing in overweight and obese patients with cancer. Nature Reviews, Clinical Oncology 10, 451459.CrossRefGoogle ScholarPubMed
Griggs, JJ et al. (2012) Appropriate chemotherapy dosing for obese adult patients with cancer: American Society of Clinical Oncology clinical practice guideline. Journal of Clinical Oncology 30, 15531561.CrossRefGoogle ScholarPubMed
O'Shea, D et al. (1994) Effect of fasting and obesity in humans on the 6-hydroxylation of chlorzoxazone: a putative probe of CYP2E1 activity. Clinical Pharmacology and Therapeutics 56, 359367.CrossRefGoogle ScholarPubMed
Kudo, T et al. (2009) Altered expression of CYP in TSOD mice: a model of type 2 diabetes and obesity. Xenobiotica 39, 889902.CrossRefGoogle Scholar
Ghose, R et al. (2011) Role of high-fat diet in regulation of gene expression of drug metabolizing enzymes and transporters. Life Sciences 89, 5764.CrossRefGoogle ScholarPubMed
Emery, MG et al. (2003) CYP2E1 activity before and after weight loss in morbidly obese subjects with nonalcoholic fatty liver disease. Hepatology (Baltimore, MD) 38, 428435.CrossRefGoogle ScholarPubMed
Khemawoot, P et al. (2007) Obesity-induced increase of CYP2E1 activity and its effect on disposition kinetics of chlorzoxazone in Zucker rats. Biochemical Pharmacology 73, 155162.CrossRefGoogle ScholarPubMed
Cheng, Q et al. (2008) Drug-metabolizing enzyme and transporter expression in a mouse model of diabetes and obesity. Molecular Pharmaceutics 5, 7791.CrossRefGoogle Scholar
Jang, EH et al. (2010) Increased expression of hepatic organic cation transporter 1 and hepatic distribution of metformin in high-fat diet-induced obese mice. Drug Metabolism and Pharmacokinetics 25, 392397.CrossRefGoogle ScholarPubMed
Koide, CLK et al. (2011) The effect of bamboo extract on hepatic biotransforming enzymes – findings from an obese–diabetic mouse model. Journal of Ethnopharmacology 133, 3745.CrossRefGoogle ScholarPubMed
Sawamoto, K et al. (2014) Mechanisms of lower maintenance dose of tacrolimus in obese patients. Drug Metabolism and Pharmacokinetics 29, 341347.CrossRefGoogle ScholarPubMed
Tomankova, V et al. (2015) Altered cytochrome P450 activities and expression levels in the liver and intestines of the monosodium glutamate-induced mouse model of human obesity. Life Sciences 133, 1520.CrossRefGoogle ScholarPubMed
Ghoneim, RH et al. (2015) Effect of a high-fat diet on the hepatic expression of nuclear receptors and their target genes: relevance to drug disposition. British Journal of Nutrition 113, 507516.CrossRefGoogle ScholarPubMed
Chiba, T et al. (2016) Diet-induced non-alcoholic fatty liver disease affects expression of major cytochrome P450 genes in a mouse model. Journal of Pharmacy and Pharmacology 68, 15671576.CrossRefGoogle ScholarPubMed
Ning, M and Jeong, H (2017) High-fat diet feeding alters expression of hepatic drug-metabolizing enzymes in mice. Drug Metabolism and Disposition: The Biological Fate of Chemicals 45, 707711.CrossRefGoogle ScholarPubMed
Sadler, NC et al. (2018) High-fat diets alter the modulatory effects of xenobiotics on cytochrome P450 activities. Chemical Research in Toxicology 31, 308318.CrossRefGoogle ScholarPubMed
Sun, Y et al. (2020) Clopidogrel resistance in a murine model of diet-induced obesity is mediated by the interleukin-1 receptor and overcome with DT-678. Arteriosclerosis, Thrombosis, and Vascular Biology 40, 15331542.CrossRefGoogle Scholar
Al Nebaihi, HM et al. (2020) Dietary-induced obesity, hepatic cytochrome P450, and lidocaine metabolism: comparative effects of high-fat diets in mice and rats and reversibility of effects with normalization of diet. Journal of Pharmaceutical Sciences 109, 11991210.CrossRefGoogle Scholar
Ulvestad, M et al. (2013) Impact of OATP1B1, MDR1, and CYP3A4 expression in liver and intestine on interpatient pharmacokinetic variability of atorvastatin in obese subjects. Clinical Pharmacology & Therapeutics 93, 275282.CrossRefGoogle ScholarPubMed
Lloret-Linares, C et al. (2016) Oral morphine pharmacokinetic in obesity: the role of P-glycoprotein, MRP2, MRP3, UGT2B7, and CYP3A4 Jejunal contents and obesity-associated biomarkers. Molecular Pharmaceutics 13, 766773.CrossRefGoogle ScholarPubMed
Miyauchi, E et al. (2016) Quantitative atlas of cytochrome P450, UDP-glucuronosyltransferase, and transporter proteins in jejunum of morbidly obese subjects. Molecular Pharmaceutics 13, 26312640.CrossRefGoogle ScholarPubMed
Rodríguez-Morató, J et al. (2019) Short- and medium-term impact of bariatric surgery on the activities of CYP2D6, CYP3A4, CYP2C9, and CYP1A2 in morbid obesity. Scientific Reports 9, 20405.CrossRefGoogle Scholar
Krogstad, V et al. (2020) A comparative analysis of cytochrome P450 activities in paired liver and small intestinal samples from patients with obesity. Drug Metabolism and Disposition 48, 8.CrossRefGoogle ScholarPubMed
Krogstad, V et al. (2021) Correlation of body weight and composition with hepatic activities of cytochrome P450 enzymes. Journal of Pharmaceutical Sciences 110, 432437.CrossRefGoogle ScholarPubMed
Brocks, D et al. (2022) Piecing together human adult comparative pharmacokinetic trials and rodent studies: what happens to drug clearance in obesity? Journal of Pharmacy & Pharmaceutical Sciences 25, 4168.CrossRefGoogle ScholarPubMed
Zarezadeh, M et al. (2021) The effect of obesity, macronutrients, fasting and nutritional status on drug-metabolizing cytochrome P450s: a systematic review of current evidence on human studies. European Journal of Nutrition 60, 29052921.CrossRefGoogle ScholarPubMed
Hammer, H et al. (2021) Cross-species analysis of hepatic cytochrome P450 and transport protein expression. Archives of Toxicology 95, 117133.CrossRefGoogle ScholarPubMed
Harvey, AE et al. (2011) The growing challenge of obesity and cancer: an inflammatory issue. Annals of the New York Academy of Sciences 1229, 4552.CrossRefGoogle Scholar
Furukawa, S et al. (2004) Increased oxidative stress in obesity and its impact on metabolic syndrome. Journal of Clinical Investigation 114, 17521761.CrossRefGoogle ScholarPubMed
Bankoglu, EE et al. (2016) Impact of weight loss induced by gastric bypass or caloric restriction on oxidative stress and genomic damage in obese Zucker rats. Free Radical Biology and Medicine 94, 208217.CrossRefGoogle ScholarPubMed
Marseglia, L et al. (2014) Oxidative stress in obesity: a critical component in human diseases. International Journal of Molecular Sciences 16, 378400.CrossRefGoogle ScholarPubMed
Othman, EM et al. (2013) Insulin mediated DNA damage in mammalian colon cells and human lymphocytes in vitro. Mutation Research 745–746, 3439.CrossRefGoogle ScholarPubMed
Othman, EM et al. (2016) Metformin protects kidney cells from insulin-mediated genotoxicity in vitro and in male Zucker diabetic fatty rats. Endocrinology 157, 548559.CrossRefGoogle ScholarPubMed
Kliemann, N et al. (2022) Ultra-processed foods and cancer risk: from global food systems to individual exposures and mechanisms. British Journal of Cancer 127, 1420. Available at https://doi.org/10.1038/s41416-022-01749-y.CrossRefGoogle ScholarPubMed
Zhang, P et al. (2021) Defining the scope of exposome studies and research needs from a multidisciplinary perspective. Environmental Science & Technology Letters 8, 839852.CrossRefGoogle ScholarPubMed
Scarpato, R et al. (2011) Nuclear damage in peripheral lymphocytes of obese and overweight Italian children as evaluated by the gamma-H2AX focus assay and micronucleus test. FASEB Journal 25, 685693.CrossRefGoogle ScholarPubMed
Figure 0

Table 1. Influence of obesity on genomic stability

Figure 1

Table 2. Association between obesity, weight loss and cancer risk

Figure 2

Table 3. Impact of obesity on cancer therapy

Figure 3

Table 4. Influence of obesity on pharmacokinetic and pharmacodynamic processes in rodent obesity models and in humans

Figure 4

Table 5. Summary for the effect of obesity on the most common studied cytochrome P450 enzymes in liver tissue from rodent obesity models of Table 4

Figure 5

Fig. 1. Overview on the relationship between obesity, cancer risk and cancer therapy. ang II: angiotensin II, IR: insulin resistance, T2DM: type 2 diabetes mellitus, NAFLD: non-alcoholic fatty liver disease.