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Year : 2020  |  Volume : 17  |  Issue : 2  |  Page : 77-83

Cancer aetiology and progression: The crucial link between genome, epigenome and metabolome

1 Department of Biochemistry, Federal University Dutse, Dutse, Nigeria
2 Department of Medicine, Muhammad Abdullahi Wase Teaching Hospital, Kano, Nigeria

Date of Submission26-Jan-2020
Date of Decision22-Feb-2020
Date of Acceptance11-Jun-2020
Date of Web Publication9-Oct-2020

Correspondence Address:
Dr. Salihu Ismail Ibrahim
Department of Biochemistry, Federal University Dutse, Dutse
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Source of Support: None, Conflict of Interest: None

DOI: 10.4103/njbcs.njbcs_2_20

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Genomic and metabolic profiles of cancer cells differ significantly from normal cells. Cancer cells utilise nutrients with an impaired metabolic process to maintain their high metabolic demands to adapt and proliferate. Metabolic rewiring in cancer cells has profound effects on the regulation of gene expression and vice versa. Genomic and metabolomic interactions are highly intertwined in both normal and cancer cells. Genomic components affect the metabolomic activities by modulating the expression of genes that regulate the metabolome. Inversely the metabolome, in turn, coordinates and provide a favourable microenvironment for genomic expression of metabolome regulating enzymes. The review aims to understand the link between genomic and metabolomic processes, their point of interaction, shared process, including dependent and independent networks in understanding cancer aetiology and progression. We systematically searched PubMed, Hinari, Google scholar and Nature journals to identify potentially relevant articles. We included reports that met the following criteria: (1) current knowledge on the cause of cancer as explained by genetic mutation, and (2) examine to what extent the mutation is determined by the metabolome. We also reviewed epigenetic aberration as hallmark of cancer aetiology. We discussed that the interaction between the genomic and metabolomic components is indispensable for the normal metabolic processes. Anything that alters the interplay of these processes will definitely cause impairment in the interaction and overall compromise in the entire genomic, metabolic, and cellular processes. Understanding the complex interaction between genome, epigenome, and metabolome is crucial to gain a greater insight into unravelling cancer pathogenesis and in the onset and progression of cancers and the potential of designing novel therapeutic strategies.

Keywords: Cancer, genome, metabolome, mutation, nutrition

How to cite this article:
Ibrahim SI, Muhammad FY. Cancer aetiology and progression: The crucial link between genome, epigenome and metabolome. Niger J Basic Clin Sci 2020;17:77-83

How to cite this URL:
Ibrahim SI, Muhammad FY. Cancer aetiology and progression: The crucial link between genome, epigenome and metabolome. Niger J Basic Clin Sci [serial online] 2020 [cited 2021 Apr 22];17:77-83. Available from: https://www.njbcs.net/text.asp?2020/17/2/77/297599

  Introduction Top

Cancer is a disease that arises from the transformation of normal cells into tumour cells in a multistage process believed to be caused by the interaction between a person's genetic predisposition and three categories of external agents, which includes: physical, biological, and chemical agents that result in a mutation. Among the various agents, tobacco use is the most important risk factor for cancer and is responsible for approximately 22% of cancer deaths.[1] Cancer-causing infections, such as hepatitis and human papillomavirus, are responsible for up to 25% of cancer cases in low- and middle-income countries.[2]

Cancer has many causes that promote uncontrolled cell division leading to an overgrown group of cells called a tumour and the spread of tumour cells throughout the body to form new tumours, a process called metastasis. Genetic mutations play a major role in the development of certain types of cancers. Mutations have been associated with specific genes that may predispose individuals to develop certain cancers. Such examples are oncogenes that normally carry out basic cellular functions, generally related to the regulation of cell division. However, several types of events can change a proto-oncogene into an oncogene. One of the main ways in which proto-oncogenes can be changed into their cancer-causing (oncogenic) state is by mutation. Mutation can be spontaneous or environmentally induced, which occurs in a proto-oncogene of a single cell, which then undergoes multiple cell divisions to form a tumour. Tumour cells respond to their microenvironment, which can include hypoxia and malnutrition, and adapt their metabolism to survive and grow. In hypoxia, glucose utilisation through the pentose phosphate pathway can be promoted by direct modification of metabolic enzymes by reactive oxygen species[3] or glycosylation.[4] Glycogen accumulates in various cancer cell lines and hypoxic tumors, and inhibition of glycogen breakdown results in p53-induced senescence due to high levels of reactive oxygen species.[5]

Many hypotheses and theories, such as the somatic mutation theory and tissue organisation field theory, have been proposed to explain the origin of cancer cells and how they develop, such as their heterogenetic morphology, increased proliferation, metastatic capacity, and invasive behaviour. One such prominent and most widely accepted theory is the somatic mutation theory, where it is believed that cancers are caused by gene mutations in a cell.

  Mutation and Cancer Top

The mutation theory started with the formulation of the idea that cancer cells developed from the body's own cells.[6] This was later followed by one plausible explanation given by Bauer that cancers were likely caused by mutations.[7] The discovery of the three-dimensional structure of DNA by Watson and Crick[8] supports the credence to the concept that damage to DNA molecules can lead to mutation and cancer.[9] In 1969, Ashley went further to state that cancer may be the result of just 3–7 mutations.[10] Since then, studies have proposed the different number of possible mutations that are necessary to cause a normal cell to change into a cancer cell. One of such studies is the large-scale sequencing studies by Greenman et al.,[11] which showed that the prevalence and signature of somatic mutations in human cancers are highly variable [Table 1].
Table 1: Somatic mutation prevalence by cancer type

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A new paradigm shift has occurred to somatic mutation theory, where it was recognised that not just one, but several mutations are required to cause cancer in a cell. Mutations have increasingly been perceived as the causal event in the origin of the vast majority of cancers, even as clinical data show little support for this theory.

The mutation theory emphasises the dominant role of the genomic component to explain carcinogenesis. However, recent clinical studies suggest that carcinogenesis requires more than mutations in order for cancer to develop. Somatic mutations are continuously being questioned as drivers of carcinogenesis,[12],[13] and some cancers have been reported to be not associated with any mutation.[14],[15] For example, it was found in a study with three ependymoma brain tumours subtypes that not all cancers are caused by mutation, one subtype creates a new tumour-driving gene, another lacks tumour-driving mutations but has aberrant epigenetic modifications, and a third shows neither gene mutations nor epigenetic aberrations.[13],[14] In another different yet similar study, thousands of mutations were found in cancer-relevant genes, including cancer-driver genes, in normal eyelid epidermis that rarely develops cancers.[16] Normal tissues have been reported to display massive genetic changes, including changes in cancer-initiating and cancer-driving genes, but do not develop into cancer. Somatic mutations occur in the genomes of all dividing cells, both normal and neoplastic. However in cancer, the somatic mutation has been classified into 'driver' mutations which confer a growth advantage on the cell in which they occur and are causally implicated in the development of cancer and 'passenger' mutations which have been reported to be biologically neutral and do not confer growth advantage to cancer cells.[11] It has been postulated that only a small number of driver mutations lead to cancer while the remaining passenger mutations play no causal role in carcinogenesis.[17],[18],[19]

It has been reported that an increase in the intrinsic mutation rate to be the driving force of tumorigenesis where it was postulated that most sporadic tumours start to grow with a normal mutation rate and probably continue to do so as successive mutations occur which provide a selective advantage and lead to clonal expansion [Figure 1]. Although some tumours will acquire a mutator phenotype before they present clinically, it is not necessary to invoke an increased mutation rate to explain cancer, even in tumours that carry multiple mutations.[20] The process of tumorigenesis is a form of evolution: mutation and selection are the essential components of this process. The relative importance of these components remains controversial.
Figure 1: Transformation of normal cells into a tumor (Google)

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The mutator phenotype hypothesis postulates that an initial mutator mutation generates further mutations, including mutations in additional genetic stability genes, resulting in a cascade of mutations throughout the genome.[21] Mutator phenotype can result from mechanisms other than mutations in critical genes. Profound effects on the evolution of tumour cells, including increased mutagenesis, can be caused by processes such as aberrant gene expression[22] or DNA methylation.[23] Tomlinson and Bodmer[24] have presented a mathematical model indicating that an increase in mutation rate is not essential for tumour development and that clonal selection followed by clonal expansion can account for thousands of mutations in colon cancer cells. They conclude that an increase in mutation rate in tumours is an epiphenomenon and is not responsible for tumour progression. Although many assumptions in their model differ from those embodied in the mutator phenotype hypothesis, the major difference is the 5000 division cycles undergone by normal colonic stem cells. Importantly, in tissues other than colon or skin, stem cells are unlikely to undergo that many divisions and thus would not accumulate large numbers of mutations. Although the lack of measurements of mutation rates in stem cells, the observed increase in mutation frequencies in human kidney tubule cells during the human life span is at most 5-fold.[25]

It remains to be determined whether the acquisition of a mutator phenotype underlies tumour progression and when the enhancement in mutation rate occurs during the life of tumours. In order for a mutator phenotype to be necessary for tumour progression, it would have to occur early and result in the accumulation of large numbers of random mutations. The existence of multiple mutations in cancer cells has important implications. The presence of large number of random mutations in a tumour cell population provides abundant, diverse genetic variants for the selection of mutants that specify the cancer phenotype. It may be possible to stratify tumours based on the frequency of random mutations in the genome; tumours with fewer mutations may be less likely to become resistant to chemotherapeutic agents.[26]

The question is if mutations exclusively cause cancer, then how can we explain the existence of cancer without mutation and mutation without cancer as reported in previous studies? One plausible explanation is that genes may carry the potential to cause cancer, but epigenetic and metabolic conditions determine the expression of that gene into a cancerous mutation. The metabolic condition may determine the state of epigenetic conditions, which in turn may dictate how genes are expressed. Many experiments have clearly shown that cells exposed to a non-physiological environment such as toxic agents,[27] inflammation,[28],[29] low pH,[30],[31] hypoxia,[32] infection,[33] irradiation,[34] and others can induce significant genetic, metabolic, morphological and cell behaviour changes that can initiate alteration of the epigenetic micro environment in a negative way that can result in cancer development. It is well known from several studies that cancer cells are surrounded by massive environmental changes,[35],[36] which can have a great impact on cancer development.

  Epigenetic of Cancers Top

Metabolic and epigenetic conditions and nutritional status are fundamental aspects of cellular adaptation to the environment. The human genome is dynamically regulated by the metabolome. Alterations in the genome, epigenome or metabolome may drive aberrant gene expression, which in turn, may contribute to tumour development and progression. Epigenetic dysfunction can have profound effects on the regulation of gene expression. Epigenetic regulation of gene expression can be highly plastic and responsive to various environmental factors.[37],[38],[39] Epigenetic dysfunction modifies metabolism by directly affecting the expression of metabolic enzymes and altering the signal transduction cascades involved in the control of cell metabolism [Figure 2].
Figure 2: Epigenetic modification of normal cells (original)

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The cell's environment is perfectly balanced for the cell's metabolic, molecular and nutritional processes. If the cell's precisely and perfectly balanced processes become disturbed irreversibly, then the cell will be forced to undergo a functional and/or structural adjustment by creating a new equilibrium point that may be detrimental to the overall cellular processes, once this new equilibrium point becomes established within the cell. The new established equilibrium condition will disrupt previous dependent cellular processes and override the existing regulatory processes, resulting in the disruption of primarily ordered cellular processes, thereby creating a new cellular order.

The cell exchanges nutrients between intra and extracellular environments, because of that capability, the cell can maintain normal physiological processes under certain and specific conditions. Under these exclusive conditions, a cell controls and provides optimal reaction conditions for the synthesis of essential and degradation of harmful waste metabolites generated during metabolic processes. The structural order and the functionality of proteins, enzymes are highly dependent on conditions such as pH, electrolyte concentration and temperature.[40],[41] The functional and physical interaction of these enzymes and proteins with pH, temperature, ions and other metabolites determines physiological or pathological outcomes. For example, varying pH levels may have a direct effect on the activity of many enzymes and proteins due to the presence of ionisable residues in the catalytic site of most enzymes. Changes in pH levels may result in a conformational change in enzyme structure, leading to an alteration in substrate accessibility to the catalytic site and, ultimately, loss of function of the enzyme. It has long been known that the microenvironment in tumors of both animals and humans is acidic as compared with that in normal tissues because of elevation in anaerobic as well as aerobic glycolysis in tumours.[42],[43],[44],[45],[46],[47] Tumour acidosis may result from the accumulation of H+ ions as an initial consequence of alterations in the pH of the cytosolic compartment of cells, which cannot withstand acidification, and gives rise to the delicate balance between the intracellular pH (pHi) and the extracellular pH (pHe) which trigger various adaptations to maintain an optimal pH balance at the same time determine the new behavior of cells in an acidic environment.

  Metabolome and Cancer Top

Cancer cells have high metabolic demands, and they utilise nutrients with an altered metabolic programme to support their high proliferative rates and adapt to the hostile tumour microenvironment. Cancer cells have been shown to have high rates of glucose consumption and production of lactate despite bioavailability of sufficient oxygen for complete oxidation of glucose, a process termed the Warburg effect.[48]

Changes in the expression levels of metabolic enzymes, expression of alternative enzyme isoforms or mutations in genes encoding metabolic enzymes have all been implicated in altering the metabolism of tumours.[49] Oncogenic and tumour suppressor pathways that drive cancer development have been shown to promote these metabolic features, which are, therefore, stably propagated throughout tumour development. This has raised hopes that metabolic enzymes comprise good targets for cancer therapy.[50],[51] High-glucose catabolism in mitochondria through pyruvate carboxylase has also been observed in human glioblastoma tumours of diverse genetic backgrounds.[52]

It has long been known that tumours can be acidified by the induction of hyperglycemia by administration of excess glucose.[53],[54],[55] Cancer cells could metabolize glucose via glycolysis to generate lactate, instead of oxidative phosphorylation (OXPHOS), even in the presence of normal oxygen levels.[48],[55],[56],[57] Cancer cells exhibit high rates of glucose fermentation to lactate even when growing in aerobic conditions, a phenotype known as aerobic glycolysis or the Warburg effect.[58] Glucose has been reported to be the main source of lactate generation in cancer cell metabolism.[59] Cancer cells convert most incoming glucose to lactate.[35],[48] Clinical studies showed that a high level of lactate was a strong prognostic indicator of increased metastasis and poor overall survival.[36],[60],[61],[62],[63] Lactate and proton together prevented cancer cells from glucose deprivation-induced death.[64] Lactate and proton are important for cancer cells to survive through harsh conditions.[65] Lactic acidosis exhibited multifaceted roles in skewing macrophages,[66] inhibiting the function of cytotoxic T-cells,[67] altering cancer cell metabolism[68],[69],[70] promoting tumour angiogenesis[36],[70] and inducing chromosomal instability.[71]

Glutamine, as well as glucose has been reported to be one of the most important nutrients to be metabolized more abundantly than other non-essential amino acids.[72] Glutamine metabolism not only provides a source for the synthesis of macromolecules, such as lipids, proteins, and nucleotides, but also supports nicotinamide adenine dinucleotide phosphate production and anaplerosis in proliferating tumor cells.[73]

It can clearly be seen that cancer cells need a stable microenvironment favorable for growth and proliferation to continue dividing and invading new territories. It can be speculated that before cancer initiates and develops in a particular tissue it has to create the favourable environment by acidifying that environment, as acidification will force many non-acid-dependent processes to a stop, thereby favouring cancer machinery to initiate, develop and invade. Apart from metabolising glucose, cancer cells are addicted to glutamine. By means of a process known as glutaminolysis, cancer cells could divert a major fraction of glutamine to replenish the tricarboxylic acid cycle.[74],[75],[76] Hence, glutaminolysis supplies biosynthetic precursors for nucleotides, proteins and glutathione biosynthesis in tumorigenesis.[77],[78]

Metabolic rewiring in cancer has profound effects on the regulation of gene expression. Although metabolite profiles might have little impact on the genetic level, it appears that they have a fundamental role in epigenetic regulation of gene expression. Epigenetics refers to heritable changes in gene expression, which are not a consequence of alterations in the DNA sequence. Epigenetic regulation of gene expression can be highly plastic and responsive to various environmental clues.[37],[38],[39] Epigenetics, which principally involved the chemical modification of DNA and histones, represents an innate mechanism that links nutritional status to gene expression [Figure 3]. As such, metabolic rewiring could hijack the epigenome machinery in cancer cells to transmit a mitogenic gene expression profile.[79],[80],[81] Reciprocally, epigenetic deregulation in cancer mediates, at least in part, to the altered expression of genes involved in cellular metabolism. Accelerated glycolysis in cancer contributes to histone acetylation via citrate and acetyl CoA. Histone acetylation in cells is regulated by glucose flux in a dose-dependent manner[82] and elevated glycolysis in cancer is associated with global histone hyperacetylation.[83] An increased contribution of acetate to acetyl-coA and histones has also been observed in mouse liver cancer models,[84] orthotopically implanted human GBM tumours in mice, as well as human patients,[85] which could reflect an increased presence of hypoxic regions in these tumours.[86]
Figure 3: Metabolome as a product of genome (original)

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  Conclusion Top

Understanding the interplay between genomic and metabolomic modulators may serve as a potential factor to target the mechanism of cancer initiation, development and progression. New approach to cancer therapy is required in order to take into consideration of the potential impact of the tumor microenvironment and metabolism. Recent cancer metabolism studies in higher organisms are uncovering the influence of metabolic interactions with the environment.

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  [Table 1]


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