critical review
- Wk. 4 Article Review-I. Download Wk. 4 Article Review-I. Xenobiotic Metabolomics: Major Impact on the Metabolome.
- Wk. 4 Article Review-II Download Wk. 4 Article Review-II Retinoid-xenobiotic interactions: the Ying and the Yang
- Wk. 4 Article Review-III Download Wk. 4 Article Review-III Dietary effects on cytochromes P450, xenobiotic metabolism, and toxicity
-
Wk.4ArticleReview-I.pdf
-
Wk.4ArticleReview-II.pdf
-
Wk.4ArticleReview-III.pdf
Xenobiotic Metabolomics: Major Impact on the Metabolome
Caroline H. Johnson1, Andrew D. Patterson2, Jeffrey R. Idle3, and Frank J. Gonzalez1
1Laboratory of Metabolism, Center for Cancer Research, National Cancer Institute, National Institutes of Health, Bethesda, Maryland 20892; [email protected], [email protected]
2Department of Veterinary and Biomedical Sciences and The Center for Molecular Toxicology and Carcinogenesis, The Pennsylvania State University, University Park, Pennsylvania 16802; [email protected]
3Hepatology Research Group, Department of Clinical Research, University of Bern, 3010 Bern, Switzerland; [email protected]
Abstract
Xenobiotics are encountered by humans on a daily basis and include drugs, environmental
pollutants, cosmetics, and even components of the diet. These chemicals undergo metabolism and
detoxication to produce numerous metabolites, some of which have the potential to cause
unintended effects such as toxicity. They can also block the action of enzymes or receptors used
for endogenous metabolism or affect the efficacy and/or bioavailability of a coadministered drug.
Therefore, it is essential to determine the full metabolic effects that these chemicals have on the
body. Metabolomics, the comprehensive analysis of small molecules in a biofluid, can reveal
biologically relevant perturbations that result from xenobiotic exposure. This review discusses the
impact that genetic, environmental, and gut microflora variation has on the metabolome, and how
these variables may interact, positively and negatively, with xenobiotic metabolism.
Keywords
pharmacometabolomics; gut microflora; interindividual variation; metabotype; UPLC; mass spectrometry
INTRODUCTION
Xenobiotics are foreign compounds that include not only drugs but also environmental
pollutants, dietary supplements, and food additives. Human exposure to xenobiotics is
pervasive; in a human lifetime, one might be exposed to 1–3 million xenobiotics (1). These
compounds can be toxic or harmless, but nonetheless they are treated by the body as foreign.
They are metabolized and ultimately eliminated through the urine, bile, and feces.
Xenobiotics can be eliminated unchanged, but the vast majority utilize endogenous
DISCLOSURE STATEMENT
The authors have no affiliations, memberships, funding, or financial holdings that might be perceived as affecting the objectivity of this review.
HHS Public Access Author manuscript Annu Rev Pharmacol Toxicol. Author manuscript; available in PMC 2018 December 20.
Published in final edited form as: Annu Rev Pharmacol Toxicol. 2012 ; 52: 37–56. doi:10.1146/annurev-pharmtox-010611-134748.
A uthor M
anuscript A
uthor M anuscript
A uthor M
anuscript A
uthor M anuscript
mechanisms such as enzymatic functionalization and/or conjugation reactions that facilitate
their elimination, and they use processes that are also involved in the metabolism and
transport of endogenous compounds such as bilirubin, lipids, and steroids. Thus, it is
important to have a comprehensive knowledge of in vivo xenobiotic metabolism so that
potential problems such as the generation of reactive metabolites or bioavailability issues
when coadministering a drug can be ascertained. Metabolomics—the unbiased global survey
of low-molecular-weight molecules or metabolites in a biofluid, cell, tissue, organ, or
organism— represents an ideal solution for understanding and measuring the impact of
xenobiotic exposure on a biological system. The term metabolome was first used in 1998 (2)
and has been defined since as “the set of metabolites synthesized by a biological system” (3,
p. 155); it encompasses all the small metabolites present in a particular biofluid (urine,
blood, sebum, cerebral spinal fluid, saliva), cell, or tissue. As metabolites are the ultimate
downstream products of genomic, transcriptomic, and/or proteomic perturbations, changes
in metabolite concentration and/or flux can reveal biologically relevant changes to the
system.
MANIPULATION OF THE METABOLOME
Genetic and Environmental Influences on the Metabolome
The metabolome can vary among individuals owing to numerous genetic and environmental
factors. Environmental influences include diet, stress, medication, lifestyle, and disease.
Genetic variation includes gender, epigenetics, and polymorphisms in genes encoding
xenobiotic-metabolizing components such as Phase I and II enzymes, transporters, receptors,
and ion channels. Age is also another host factor that can have physiological effects and thus
affect xenobiotic metabolism and elimination. The gut microflora or microbiome of an
individual represents yet another source of extragenomic variation. The combination of all
these factors contributes to interindividual differences, but the interplay between genetic
variation and environmental exposure can further confound results. For example,
environmental exposures and disease can induce epigenetic changes (DNA methylation,
histone modification) that potentially affect drug-metabolizing enzyme activity and capacity;
these effects, in turn, can influence the efficacy and toxicity of a drug among individuals (4).
Genetic Variation
Genetic variation, although a major factor in defining the metabolomes of various
populations, can also be masked by environmental influences. Recent large-scale human
population studies have illustrated how genetic and environmental differences can impact the
metabolome. Twenty-four-hour urine samples collected from 17 distinct populations in
Japan, China, the United States, and the United Kingdom were analyzed by nuclear
magnetic resonance (NMR) spectroscopy-based metabolomics, and the analysis revealed
that geographic differences were a stronger influence than that of gender. Environmental
pressure was also seen among the metabolic phenotypes of Japanese living in Japan and
Japanese living in the United States. These two populations were well differentiated even
though they were genetically similar, whereas the populations from the United States and the
United Kingdom had similar metabolomes (5). Therefore, environmental factors such as
Johnson et al. Page 2
Annu Rev Pharmacol Toxicol. Author manuscript; available in PMC 2018 December 20.
A uthor M
anuscript A
uthor M anuscript
A uthor M
anuscript A
uthor M anuscript
lifestyle and diet have large effects on the metabolome and may even overshadow genetic
inputs.
Genetic polymorphisms in key drug-metabolizing enzymes can influence the route of
metabolism, and ultimately the bioavailability, efficacy (in the case of drugs), and toxicity of
xenobiotics. Phase I metabolizing enzymes such as the cytochrome P450 (CYP) superfamily
add functional groups that allow for direct excretion or the addition of conjugates that render
the compounds more hydrophilic. CYPs are regulated by nuclear receptors, including
pregnane X receptor (PXR), constitutive androstane receptor (CAR), peroxisome
proliferator-activated receptor α (PPARα), and the aryl hydrocarbon receptor (AHR). There
is a wide range of variation in the expression of the CYP enzymes and nuclear receptors
among individuals; this is due not only to genetic polymorphisms but also to differences that
result from age, gender (progesterone can induce CYP3A4 in women), body weight, and
disease (liver diseases in particular can affect the capacity of a drug-metabolizing enzyme).
The Phase II conjugating enzymes uridine 5’-diphospho-glucuronosyltransferases (UGTs),
sulfotransferases, N-acetyltransferases, and glutathione 5-transferases are also subject to
genetic polymorphisms, some of which cause debilitating diseases. For example, a UGT
polymorphism involving the UGT1A1*28 allele has been linked to Gilbert’s syndrome (6),
in which UGT1A1 has much lower activity, and subjects may develop hyperbilirubinemia
owing to lack of conjugation and elimination of bilirubin. Xenobiotic metabolism can also
be affected by other chemicals in tobacco smoke (7), alcohol (8), and industrial pollutants
[2,3,7,8-tetrachlorodibenzo-p-dioxin activates AHR (9)], and, of course, by coadministration
of pharmaceutical drugs. St. John’s Wort, a dietary supplement for the treatment of mild
depression, is an agonist for PXR, which induces the expression of CYP3A4. Thus, when St.
John’s Wort is coadministered with other drugs such as digoxin (10) and oral contraceptives
(estrogen and progestin) (11), a marked decrease in the plasma concentrations of these drugs
is seen, resulting in lower efficacy. Another interference can come from dietary grapefruit
ingestion, which inhibits drug-metabolizing enzymes such as CYP3A4 and drug transporters
(12). Grapefruit-drug interactions have been seen with antihypertensives, antimicrobials,
benzodiazepines, antihistamines, statins, and chemotherapeutics (13). Therefore, it is
important to establish the exact metabolic pathway and mechanisms of these xenobiotics to
determine the metabolites produced and their effects on the metabolome.
The Microbiome and Metabolome
The metabolome of an organism is also influenced by the symbiotic gut microflora or
microbiome. The metabolome of an individual can contain metabolites that are formed
through the actions of the gut microbiota, and metabolism by these microbes may directly
affect the metabolome of the host. Hippurate and phenylacetylglycine, for example, are seen
in the urinary metabolome and are formed from the microbial breakdown of larger dietary
phenols and phenylalanine, respectively. They generally reflect small disturbances to the
host’s environmental conditions (14). The gut microflora have been associated with diseases
such as inflammatory bowel disease (15), obesity (16), and diabetes (17). In humans, gut
microflora influence immunity and anaerobic metabolism of peptides and proteins, are a
defense against pathogens, and influence the development of intestinal microvilli of the
organism (18).
Johnson et al. Page 3
Annu Rev Pharmacol Toxicol. Author manuscript; available in PMC 2018 December 20.
A uthor M
anuscript A
uthor M anuscript
A uthor M
anuscript A
uthor M anuscript
Most importantly, with respect to metabolomics, gut microflora are involved in the
metabolism of xenobiotics. Dehydroxylation, decarboxylation, dealkylation, dehalogenation,
and deamination reactions have been reported as gut microflora–mediated reactions (19).
They can influence the xenobiotic metabolite pool among individuals, and this influence
may have major consequences for toxicity. Gut microflora stability itself can be affected by
xenobiotics, in particular digoxin (20), which increases susceptibility to enteric infections
(21). Antibiotic treatment in particular disturbs gut microflora equilibrium and affects many
metabolic pathways, such as those involved in bile acid synthesis and steroid metabolism
(22, 23). Other xenobiotics including those in dark chocolate (21), pomegranate by-products
(24), and probiotics (25) have also been shown to modulate the gut microflora environment.
Phase I and II xenobiotic metabolism is influenced by the gut microflora. p-Cresol sulfate,
phenyl sulfate, and indoxyl sulfate are bacterial metabolites of tyrosine and have been
observed to be elevated by the action of gut microbes (26, 27). Given that sulfation is a key
element of Phase II drug metabolism, this also has implications for xenobiotic elimination.
Furthermore, some microbial species can produce xenobiotics, requiring further metabolism
by the host by CYP enzymes (19). Lhoste et al. (28) reported an example of this in which
germ-free and human microflora–inoculated rats had different levels of UGT, glutathione 5-
transferase, and CYP2C11 enzyme induction when administered catechins. Xenobiotic
metabolism in germ-free or conventionally raised mice also showed different metabolism of
barbiturates owing to gut microflora-influenced liver expression of CAR and PXR (29).
Considering the degree of contribution of the microbiome to the metabolome and the effects
of genetic and environmental stimuli on both, gut flora metabolism adds a further dimension
of complexity to the host’s overall metabolome and an extra source of interindividual
variation.
The concept of a metabotype encompasses all the genetic, environmental, and gut microflora
modifications that are not necessarily readily observable, and it gives each individual a
defining metabolomic fingerprint. The metabotype idea was first conceived and defined as
“a probabilistic multiparametric description of an organism in a given physiological state
based on analysis of its cell types, biofluids or tissues” (30, p. 173). As outlined in Figure 1,
genetic and environmental factors can affect each other and give rise to interindividual
variation and thus a unique metabotype. If one wishes to observe the effect of a specific
intervention on an organism, the metabotype is an important consideration, in particular
during drug development and in defining the drug’s metabolic fate. Patient stratification in
clinical trials may start to rely more on metabotypes so that a population of responders/
nonresponders can be defined; this definition could result in greater success in drug
development by simultaneously considering environmental as well as genomic factors.
Analysis of the Metabolome
Metabolomics was developed to identify and quantitate perturbations in the metabolome
caused by genetic or environmental pressures. The analytical platforms used for
metabolomics have been discussed extensively elsewhere (31–33). In brief, they include
NMR spectroscopy and mass spectrometry (MS) coupled to chemometric or multivariate
data analysis. No single platform can capture the whole metabolome owing to the different
Johnson et al. Page 4
Annu Rev Pharmacol Toxicol. Author manuscript; available in PMC 2018 December 20.
A uthor M
anuscript A
uthor M anuscript
A uthor M
anuscript A
uthor M anuscript
physical properties of metabolites, so the sample type and chemical constituents to be
measured determine which system is optimal. Numerous NMR spectroscopic methods have
been applied in metabolomics analysis, including magic-angle spinning (34); pulse
sequences to optimize metabolite recovery, such as the Carr- Purcell-Meiboom-Gill spin
echo sequence, which attenuates broad protein and lipoprotein signals (35); and the use of
various nuclides such as 1H, 19F, 13C, and 31P. For sample introduction onto the mass
spectrometer, the instrument can be connected to gas chromatography (GC), capillary
electrophoresis (CE), or liquid chromatography (LC) systems. Ultraperformance liquid
chromatography (UPLC) is the LC system of choice, preferred over the standard high-
performance liquid chromatography (HPLC) system. When combined with orthogonal
quadrupole time-of-flight (QTOF) MS, UPLC provides the advantage of high peak
resolution with a lower limit of detection for ions and accurate mass determination (32).
Recent advances in GC-MS technology for metabolomics analysis include the GCxGC-
TOF-MS system, which allows for a much more complex sample analysis that can detect
thousands more peaks. It uses two orthogonal separation phases, expanding the
chromatographic plane and thus creating additional peak capacity in which peaks can be
resolved. This setup enhances resolution and reduces the problem of coeluting peaks (36).
Accurate quantitation can then be carried out by triple-quadrupole MS through multiple
reaction monitoring to verify the concentration of the biomarker in each sample.
The most common chemometric techniques for data analysis include dimension-reduction
methods such as principal components analysis, projection to latent structures discriminant
analysis (PLS-DA), and orthogonal projection to latent structures. These methods are useful
for revealing any systematic variation in the data and for finding patterns or groupings. As a
complementary approach, the machine-learning algorithm Random Forests has been
implemented in some metabolomics studies (37–40). This method is particularly superior for
handling high-dimension data and provides a robust measurement of misclassification error
(32). Another advancement in data analysis tools for metabolomics is the release of XCMS
Online (https://xcmsonline.scripps.edu), which is a user-friendly program allowing the
processing and analyzing of MS data. New innovative technologies and data processing
techniques as well as enhancements to databases and data analysis methods are constantly
under development to further optimize metabolomics as a powerful and essential analytical
technique that can be applied in most academic settings. In addition, The Human
Metabolome Database (http://www.hmdb.ca) and the METLIN Metabolite Database (http://
metlin.scripps.edu) are of great value for interpretation of metabolomics data and metabolite
identification.
APPLICATIONS OF METABOLOMICS IN XENOBIOTIC STUDIES
Knowing the metabolic fate of a xenobiotic will greatly aid in understanding its potential
toxicity and also its mechanism of toxicity. Global metabolomics approaches can determine
changes to metabolic pathways that may not be seen through normal, targeted biochemical
assays or may not be present owing to the time delay from gene product to metabolic
product. Multivariate data analysis and LC-MS were first combined for detection of
xenobiotic metabolites by Plumb et al. (41). Since then, UPLC-MS-based metabolomics in
particular have been applied successfully to numerous xenobiotic studies (see Table 1) and
Johnson et al. Page 5
Annu Rev Pharmacol Toxicol. Author manuscript; available in PMC 2018 December 20.
A uthor M
anuscript A
uthor M anuscript
A uthor M
anuscript A
uthor M anuscript
have revealed novel metabolites and pathways (42–52). Many of these novel metabolites
were discovered for xenobiotics that are used by a large percentage of the population. Thus,
metabolomics has expanded the knowledge surrounding these xenobiotics and led the way to
understanding their metabolism, side effects, and possible health consequences. A good
example of the power of using metabolomics for xenobiotic research involves
acetaminophen (APAP) metabolism. Although this over-the-counter analgesic has been
available for more than 50 years, three new metabolites of APAP—S-(5-acetylamino-2-
hydroxyphenyl)mercaptopyruvic acid; 3,3′-biacetaminophen; and a benzothiazine
compound—were recently discovered, which was surprising considering the wealth of
knowledge surrounding APAP and its metabolism (46). Recently published studies discussed
below further demonstrate the value and power of UPLC-MS-based metabolomics for
xenobiotic and toxicology research.
Cyclophosphamide and Ifosfamide
Cyclophosphamide (CP) and ifosfamide (IF) are isomeric prodrugs used in cancer
chemotherapy. Both drugs undergo complex Phase I and II metabolism to numerous
metabolites. However, treatment with IF is known to cause nephrotoxicity and neurotoxicity,
whereas CP treatment does not. Selective IF toxicity is thought to result from the production
of 2-chloroacetaldehyde. The latter is converted to 2-chloroacetic acid (CAA), which can
react with cellular thiols to produce S-carboxymethylcysteine (SCMC) and thiodiglycolic
acid (TDGA). Although it is possible that SCMC and TDGA can induce encephalopathy and
mitochondrial dysfunction via IF dosing, there are no reports to suggest CP toxicity from
SCMC and TDGA production.
UPLC-ESI-QTOFMS-based metabolomics (i.e., metabolomics based on ultraperformance
liquid chromatography–electrospray ionization–quadrupole time-of-flight mass
spectrometry) was thus employed to perform a comprehensive comparative analysis of IF
and CP metabolism. This was to determine whether IF or CP produced additional
metabolites that could contribute to the observed pathologies. Twenty-four-hour urine
samples were collected and analyzed from C57BL/6 mice dosed with IF (50 mg kg–1) or CP
(50 mg kg–1) (43). Multivariate data analysis, specifically orthogonal projection to latent
structures models, revealed 12 IF and 11 CP urinary metabolites, five of which were novel.
A range of metabolic reactions produced the 23 metabolites, including dechloroethylation,
hydroxylation, ketonization, dehydroxylation, alkylation, ring-opening, and conjugation
reactions (Figure 2). Metabolomics revealed that one of the differences observed between
the two prodrugs was increased excretion of CP ring-opened and ketonized metabolites
compared with IF. In addition, the dechloroethylation reaction produced higher
concentrations of IF metabolites than CP metabolites (twofold). CAA was also produced
from the dechloroethylation reactions, which, in turn, produced SCMC and TDGA. SCMC
and TDGA excretion was quantitated by triple-quadrupole MS, revealing that SCMC urinary
excretion increased 32-fold and 44-fold above endogenous levels after administration of IF
and CP. TDGA urinary excretion was increased by 14-fold and 17-fold after treatment with
IF and CP, respectively. There were no significant differences in SCMC and TDGA
excretion between the two prodrugs, which verified that the SCMC and TDGA metabolites
did not confer toxicity with CP administration.
Johnson et al. Page 6
Annu Rev Pharmacol Toxicol. Author manuscript; available in PMC 2018 December 20.
A uthor M
anuscript A
uthor M anuscript
A uthor M
anuscript A
uthor M anuscript
Hence, the results from this study (43) instead suggested that the toxic nature of IF could
actually be derived from the CAA metabolite itself. The relative excretion of the
dechloroethylated metabolites was much greater from IF dosing compared with CP dosing,
signifying that CAA was produced in higher quantities upon IF administration, but because
of the unstable nature of CAA, it was not quantified. As there was no significant difference
between IF and CP with regard to SCMC and TDGA production, another mechanism of
reaction may exist. Indeed, others observed a decrease in IF-induced nephropathy and
glutathione depletion when IF was combined with N-acetylcysteine administration (53). In
theory, this experiment would have produced N-acetyl SCMC, which would have blocked
the production of TDGA, thus implying that TDGA is in fact the toxic metabolite. Another
mechanism of IF toxicity could have resulted from favorable glutathione versus cysteine
conjugation of CAA, which may have led to glutathione depletion. This then directs further
studies on the differential metabolism and toxicity of the prodrugs to focus on the potential
of CAA as a contributing toxicity factor.
Fenofibrate
Fibrate drugs are used for treatment of dyslipidemia resulting from increasing fatty acid β-
oxidation; lower serum triglycerides result in reduced insulin resistance (54). Fenofibrate is
well tolerated, but some adverse effects have been observed in rodent model systems,
predominantly increased oxidative stress and myotoxicity (55–57). In humans, fenofibrate
increases serum creatinine levels (58) and is associated with renal disorders (59); these
scenarios are infrequent, but the toxicology of fenofibrate in humans is a concern. Fibrates
are agonists of the nuclear receptor PPARα that control expression of genes involved in lipid
oxidation, gluconeogenesis, and amino acid metabolism (60, 61). Chronic dosing of fibrates
to rats, which activates PPARα, can result in hepatotoxicity and hepatocarcinogenesis, but
the same is not seen in humans and nonhuman primates (61, 62). Fibrate metabolites may
therefore contribute to the toxicity seen in rats. Three comprehensive UPLC-ESI-QTOFMS-
based metabolomics studies were carried out to ascertain the full metabolic map of
fenofibrate in different species. Previously, fenofibrate metabolites were reported in rats,
guinea pigs, dogs, and humans. Fenofibric acid (FA) and reduced fenofibric acid (RFA) were
seen in all species (63, 64), whereas fenofibric acid ester glucuronide (FAEG) and reduced
fenofibric acid ester glucuronide (RFAEG) were seen in all species except dog (65). The
metabolomics studies analyzed fenofibrate metabolism in cynomolgus monkeys
- WE OFFER THE BEST CUSTOM PAPER WRITING SERVICES. WE HAVE DONE THIS QUESTION BEFORE, WE CAN ALSO DO IT FOR YOU.
- Assignment status: Already Solved By Our Experts
- (USA, AUS, UK & CA PhD. Writers)
- CLICK HERE TO GET A PROFESSIONAL WRITER TO WORK ON THIS PAPER AND OTHER SIMILAR PAPERS, GET A NON PLAGIARIZED PAPER FROM OUR EXPERTS
QUALITY: 100% ORIGINAL PAPER – NO ChatGPT.NO PLAGIARISM – CUSTOM PAPER
Looking for unparalleled custom paper writing services? Our team of experienced professionals at AcademicWritersBay.com is here to provide you with top-notch assistance that caters to your unique needs.
We understand the importance of producing original, high-quality papers that reflect your personal voice and meet the rigorous standards of academia. That’s why we assure you that our work is completely plagiarism-free—we craft bespoke solutions tailored exclusively for you.
Why Choose AcademicWritersBay.com?
- Our papers are 100% original, custom-written from scratch.
- We’re here to support you around the clock, any day of the year.
- You’ll find our prices competitive and reasonable.
- We handle papers across all subjects, regardless of urgency or difficulty.
- Need a paper urgently? We can deliver within 6 hours!
- Relax with our on-time delivery commitment.
- We offer money-back and privacy guarantees to ensure your satisfaction and confidentiality.
- Benefit from unlimited amendments upon request to get the paper you envisioned.
- We pledge our dedication to meeting your expectations and achieving the grade you deserve.
Our Process: Getting started with us is as simple as can be. Here’s how to do it:
- Click on the “Place Your Order” tab at the top or the “Order Now” button at the bottom. You’ll be directed to our order form.
- Provide the specifics of your paper in the “PAPER DETAILS” section.
- Select your academic level, the deadline, and the required number of pages.
- Click on “CREATE ACCOUNT & SIGN IN” to provide your registration details, then “PROCEED TO CHECKOUT.”
- Follow the simple payment instructions and soon, our writers will be hard at work on your paper.
AcademicWritersBay.com is dedicated to expediting the writing process without compromising on quality. Our roster of writers boasts individuals with advanced degrees—Masters and PhDs—in a myriad of disciplines, ensuring that no matter the complexity or field of your assignment, we have the expertise to tackle it with finesse. Our quick turnover doesn’t mean rushed work; it means efficiency and priority handling, ensuring your deadlines are met with the excellence your academics demand.