Hostname: page-component-78c5997874-t5tsf Total loading time: 0 Render date: 2024-11-10T10:42:46.472Z Has data issue: false hasContentIssue false

Genome-health nutrigenomics and nutrigenetics: nutritional requirements or ‘nutriomes’ for chromosomal stability and telomere maintenance at the individual level

Symposium on ‘Diet and cancer’

Published online by Cambridge University Press:  15 April 2008

Caroline Bull
Affiliation:
CSIRO Human Nutrition, PO Box 10041, Adelaide BC, South Australia 5000, Australia
Michael Fenech*
Affiliation:
CSIRO Human Nutrition, PO Box 10041, Adelaide BC, South Australia 5000, Australia
*
*Corresponding author: Dr Michael Fenech, fax +618 8303 8896, email michael.fenech@csiro.au
Rights & Permissions [Opens in a new window]

Abstract

It is becoming increasingly evident that (a) risk for developmental and degenerative disease increases with more DNA damage, which in turn is dependent on nutritional status, and (b) the optimal concentration of micronutrients for prevention of genome damage is also dependent on genetic polymorphisms that alter the function of genes involved directly or indirectly in the uptake and metabolism of micronutrients required for DNA repair and DNA replication. The development of dietary patterns, functional foods and supplements that are designed to improve genome-health maintenance in individuals with specific genetic backgrounds may provide an important contribution to an optimum health strategy based on the diagnosis and individualised nutritional prevention of genome damage, i.e. genome health clinics. The present review summarises some of the recent knowledge relating to micronutrients that are associated with chromosomal stability and provides some initial insights into the likely nutritional factors that may be expected to have an impact on the maintenance of telomeres. It is evident that developing effective strategies for defining nutrient doses and combinations or ‘nutriomes’ for genome-health maintenance at the individual level is essential for further progress in this research field.

Type
Research Article
Copyright
Copyright © The Authors 2008

Abbreviations:
MTHFR

methylenetetrahydrofolate reductases

PARP

poly(ADP-ribose) polymerase

TANK

tankyrase

TL

telomere length

TRF

telomere repeat-binding factors

The central role of the genetic code in determining genome stability and related health outcomes such as developmental defects and degenerative diseases including cancer is well established(Reference Ames1Reference Thompson and Schild10). In addition, it is evident that DNA metabolism and repair is dependent on a wide variety of dietary factors that act as cofactors or substrates in these fundamental metabolic pathways(Reference Ames1Reference Fenech5). DNA is continuously under threat of major mutations from conception onwards by a variety of mechanisms that include: point mutation; base modification as a result of reactive molecules such as the hydroxyl radical; chromosome breakage and rearrangement; chromosome loss or gain; gene silencing as a result of inappropriate methylation of CpG at promoter sequences; activation of parasitic DNA expression as a result of reduced methylation of CpG; silencing of housekeeping genes as a result of DNA hypermethylation of CpG islands in gene promoter regions; accelerated telomere shortening or dysfunction(Reference Egger, Liang, Aparicio and Jones6Reference Rajagopalan and Lengauer8). The main challenge to a healthy and long life is the ability to continue to replace senescent cells in the body with fresh new cells with normal genotypes and gene expression patterns that are tissue-appropriate. Understanding the nutritional requirements for genome-health maintenance of stem cells is essential in this context, but has so far not been adequately explored.

While much has been learnt of the genes involved in DNA metabolism and repair and their role in a variety of pathologies, such as defects in BRCA1 and BRCA2 genes that cause increased risk for breast cancer(Reference Nathanson, Wooster, Weber and Nathanson9, Reference Thompson and Schild10), much less is known of the impact of cofactor and/or micronutrient deficiency or excess on the fidelity of DNA replication and efficiency of DNA repair. For example, a deficiency in a micronutrient required as a cofactor or as an integral part of the structure of a DNA repair gene (e.g. Zn as a component of the DNA repair glycosylase OGG1 involved in the removal of oxidised guanine or Mg as a cofactor for several DNA polymerases) could mimic the effect of a genetic polymorphism that reduces the activity of that enzyme(Reference Ames1Reference Ames3). Thus, nutrition has a critical role in DNA metabolism and repair, and this awareness is leading to the development of the new fields of genome-health nutrigenomics and genome-health nutrigenetics(Reference Fenech5). The critical aim of these fields is to define optimal dietary intakes for the prevention of DNA damage and aberrant gene expression for genetic subgroups and ultimately for each individual.

Evidence linking genome damage with adverse health outcomes

Genome damage impacts on all stages of life. There is good evidence to show that infertile couples exhibit a higher rate of genome damage than fertile couples(Reference Trkova, Kapras, Bobkova, Stankova and Mejsnarova11) when their chromosomal stability is measured in lymphocytes using the cytokinesis block micronucleus assay(Reference Fenech12, Reference Fenech13) (see Fig. 1). Infertility may be a result of a reduced production of germ cells because genome damage effectively causes programmed cell death or apoptosis, which is one of the mechanisms by which grossly mutated cells are normally eliminated(Reference Narula, Kilen, Ma, Kroeger, Goldberg and Woodruff14Reference Hsia, Millar, King, Selfridge, Redhead, Melton and Saunders16). When the latter mechanism fails reproductive cells with genomic abnormalities may survive, leading to serious developmental defects(Reference Liu, Blasco, Trimarchi and Keefe17, Reference Vinson and Hales18). That an elevated rate of chromosomal damage is a cause of cancer has been demonstrated by ongoing prospective cohort studies in European countries that have shown a 2–3-fold increased risk of cancer in those individuals whose chromosomal damage rate in lymphocytes is in the highest tertile when measured 10–20 years before cancer incidence is measured(Reference Bonassi, Hagmar and Stromberg19). It has also been shown that an elevated micronucleus frequency, a robust biomarker of chromosome breakage or loss, in lymphocytes predicts cancer risk in man(Reference Bonassi, Znaor and Ceppi20). Chromosomal damage is also associated with accelerated ageing and neurodegenerative diseases(Reference Thompson and Schild10, Reference Fenech21Reference Migliore, Scarpato, Coppede, Petrozzi, Bonucelli and Rodilla27). Those individuals with accelerated ageing syndromes as a result of redox imbalances (e.g. Down syndrome) and/or suboptimal DNA repair (e.g. carriers of deleterious mutations in the ATM or BRCA1 genes) may be particularly susceptible to the genome-damaging effects of suboptimal micronutrient intake(Reference Thiel and Fowkes28Reference Iarmarcovai, Bonassi, Botta, Baan and Orsière31).

Fig. 1. Expression of micronuclei and nucleoplasmic bridges during nuclear division. Micronuclei originate from either (1) lagging whole chromosomes (A) that are unable to engage with the mitotic spindle because of a defect in the spindle or a defect in the centromere–kinetochore complex required to engage with the spindle, or (2) an acentric chromosome fragment originating from a chromosome break (A and B) that lags behind at anaphase because it lacks a centromere–kinetochore complex. Mis-repair of two chromosome breaks may lead to an asymmetrical chromosome rearrangement producing a dicentric (i.e. two centromeres) chromosome and an acentric fragment (B); frequently the centromeres of the dicentric chromosome are pulled to opposite poles of the cell at anaphase resulting in the formation of a nucleoplasmic bridge between the daughter nuclei. Nucleoplasmic bridges are frequently accompanied by a micronucleus originating from the associated acentric chromosome fragment. Nucleoplasmic bridges may also originate from dicentric chromosomes caused by telomere end fusions. As micronuclei and nucleoplasmic bridges are only expressed in cells that have completed nuclear division it is necessary to score these genome instability biomarkers specifically in once-divided cells. This process is readily accomplished by blocking cytokinesis using cytochalasin-B (for a more detailed explanation, see Fenech(Reference Fenech7, Reference Fenech12, Reference Fenech13)).

The concept of genome damage as a marker of nutritional deficiency

There is overwhelming evidence that several micronutrients (vitamins and minerals) are required as cofactors for enzymes or as part of the structure of proteins (metalloenzymes) involved in DNA synthesis and repair, prevention of oxidative damage to DNA and maintenance methylation of DNA. The role of micronutrients in the maintenance of genome stability has recently been extensively reviewed(Reference Ames1, Reference Ames and Wakimoto2, Reference Fenech and Ferguson4, Reference Fenech32). The main point is that genome damage caused by moderate micronutrient deficiency is of the same order of magnitude as the genome-damage levels caused by exposure to sizeable doses of environmental genotoxins such as chemical carcinogens, UV radiation and ionising radiation, about which there is already a heightened level of concern. A telling example from the authors' laboratory is the observation that chromosomal damage in cultured human lymphocytes caused by reducing folate concentration (within the normal physiological range) from 120 nmol/l to 12 nmol/l is equivalent to that induced by an acute exposure to low linear-energy-transfer ionising radiation (e.g. X-rays) at 0·2 Gy, a dose of radiation that is approximately ten times greater than the annual allowed safety limit of exposure for radiation workers(Reference Fenech5). If moderate deficiency in just one micronutrient can cause sizeable DNA damage it is reasonable to be concerned about the possibility of additive or synergistic effects of multiple moderate deficiencies on genome stability. Clearly, there is a need to start exploring the genotoxic effects of multiple micronutrient deficiencies, as well as excesses, which are prevalent in human populations. This aspect is analogous to genetic studies that explore, for example, the combined effects of polymorphisms in DNA repair genes on DNA damage.

Results from a recent population study suggest that at least nine micronutrients affect genome stability in human subjects in vivo

The results have recently been reported of a cytogenetic epidemiological study of 190 healthy individuals (mean age 47·8 years, 46% males) designed to determine the association between dietary intake, measured using an FFQ, and genome damage in lymphocytes(Reference Fenech, Baghurst, Luderer, Turner, Record, Ceppi and Bonassi33), measured using the cytokinesis-block micronucleus assay (see Fig. 2). Multivariate analysis of baseline data shows that (a) the highest tertile of intake of vitamin E, retinol, folate, nicotinic acid (preformed) and Ca is associated with significant reductions in micronucleus frequency (%), i.e. −28, −31, −33, −46 and −49 respectively (all P<0·005) relative to the lowest tertile of intake and (b) the highest tertile of intake of riboflavin, pantothenic acid and biotin is associated with significant increases in micronucleus frequency (%), i.e. +36 (P=0·054), +51 (P=0·021) and +65 (P=0·001) respectively relative to the lowest tertile of intake (Fig. 2). The mid-tertile of β-carotene intake is associated with an 18% reduction in micronucleus frequency (P=0·038); however, the highest tertile of intake (>6400 μg/d) results in an 18% increment in micronucleus frequency. There was an interest in investigating the combined effects of Ca or riboflavin with folate consumption because epidemiological evidence suggests that these dietary factors tend to interact in modifying the risk of cancer(Reference Lamprecht and Lipkin34Reference Xu, Luo and Chang36) and they are also associated with reduced risk of osteoporosis and hip fracture(Reference Cagnacci, Baldassari, Rivolta, Arangino and Volpe37Reference Macdonald, McGuigan, Fraser, New, Ralston and Reid39). Interactive additive effects were observed, such as the protective effect of increased Ca intake (–46%) and the exacerbating effect of riboflavin (+42%) on increased genome damage caused by low folate intake. The results from this study illustrate the strong impact of a wide variety of micronutrients and their interactions on genome health depending on the level of intake.

Fig. 2. Percentage variation in genome damage for the mid-tertile of intake (□) and the highest tertile of intake (■) of vitamin E, calcium, folate, retinol, nicotinic acid, β-carotene, riboflavin, pantothenic acid and biotin relative to the lowest tertile of intake in an Australian cohort of healthy adults. Genome damage rate was measured in peripheral blood lymphocytes using the cytokinesis-block micronucleus assay (for more details, see Fenech et al.(Reference Fenech, Baghurst, Luderer, Turner, Record, Ceppi and Bonassi33)). The percentage variations in genome damage were significant: *P<0·006.

The amount of micronutrients that appear to be protective against genome damage vary greatly between foods (Fig. 3) and careful choice is needed to design dietary patterns optimised for genome-health maintenance. As dietary choices vary between individuals, because of taste preferences that may be genetically determined or cultural or religious constraints, several options are required and supplements may be needed to cover gaps in micronutrient requirements. Clearly, the development of nutrient-dense foods and ingredients, such as aleurone flour, which is rich in bioavailable folate as well as other micronutrients required for DNA replication and repair(Reference Fenech, Noakes, Clifton and Topping40, Reference Beetstra, Salisbury, Turner, Altree, McKinnon, Suthers and Fenech41), is essential in making it feasible for individuals to achieve their daily nutrient requirements for genome-health maintenance without intake of excess energy.

Fig. 3. Content of micronutrients associated with reduced DNA damage in selected common foods. The height of each bar for each micronutrient within the separate foods corresponds to the amount of the micronutrient expressed as the percentage of the minimum daily intake associated with a reduced micronucleus frequency index in lymphocytes as determined in the study of Fenech et al.(Reference Fenech, Baghurst, Luderer, Turner, Record, Ceppi and Bonassi33). The relative contribution of each of the micronutrients (if present) is indicated by the height of each specifically coloured bar. The nutrient content of the foods was determined using published food content tables(Reference Paul and Southgate122). (), Calcium; (), folate; (), niacin; (), vitamin E; (), β-carotene; (), retinol.

An important consequence of these considerations is also the need to start defining RDA for all nutrients based on prevention or minimisation of genome damage.

Genome-health nutrigenomics and genome-health nutrigenetics

Two of the important emerging areas of nutrition science are the fields of nutrigenomics and nutrigenetics. The term nutrigenomics refers to the effect of diet on DNA stability and gene expression. The term nutrigenetics refers to the impact of genetic differences between individuals in their response to a specific dietary pattern, functional food or supplement for a specific health outcome. The specific fields of genome-health nutrigenomics(Reference Fenech5) and genome-health nutrigenetics are proposed on the premise that a more useful approach to the prevention of diseases caused by genome damage is to take into consideration that (a) inappropriate nutrient supply can cause sizeable levels of genome mutation and alter expression of genes required for genome maintenance and (b) common genetic polymorphisms may alter the activity of genes that affect the bioavailability of micronutrients and/or the affinity for micronutrient cofactors in key enzymes involved in DNA metabolism or repair. Supplementation of the diet with appropriate minerals and vitamins could, in some cases, help overcome inherited metabolic blocks in key DNA maintenance pathways(Reference Fenech, Aitken and Rinaldi42, Reference Ames43). Increasing the concentration of a cofactor by supplementation is expected to be particularly effective when a mutation (polymorphism) in a gene decreases the binding affinity for its cofactor resulting in a lower reaction rate. The interaction between genotype and diet in modulating risk is emerging as an exciting area of research in relation to micronutrient effects on DNA. This position is illustrated by results from studies on the common mutations in the methylenetetrahydrofolate reductase (MTHFR) gene and other genes in the folate–methionine cycle in relation to their modulating affect on risk of developmental defects and cancer(Reference Skibola, Smith, Kane, Roman, Rollinson, Cartwright and Morgan44Reference Fenech46). Recent results from the authors' laboratory have shown that there are important significant interactions between the MTHFR C677T polymorphism, its cofactor riboflavin and folic acid in relation to chromosomal instability(Reference Kimura, Umegaki, Higuchi, Thomas and Fenech47). This relationship is demonstrated by (a) the reduction in nuclear bud frequency (a biomarker of gene amplification) in TT homozygotes relative to CC homozygotes for the MTHFR C677T mutation and (b) the observation that a high riboflavin concentration increases nuclear bud frequency under low folic acid conditions (12 nm-folic acid), probably by increasing MTHFR activity, which diverts folate away from dTTP synthesis, increasing the odds for uracil incorporation into DNA, chromosome breaks, the generation of breakage–fusion–bridge cycles and subsequent gene amplification and nuclear bud formation(Reference Kimura, Umegaki, Higuchi, Thomas and Fenech47). Clearly, the relative impact of genetic factors and nutrients on genome maintenance and their interactions needs better understanding so that appropriate knowledge on the most critical factors is developed. In vitro studies on the interactive effects of folic acid deficiency and inherited mutations in the MTHFR, BRCA1 and BRCA2 genes indicate that moderate deficiency in folic acid has a stronger impact on genome instability, measured by the cytokinesis-block micronucleus assay, than these important inherited mutations(Reference Kimura, Umegaki, Higuchi, Thomas and Fenech47, Reference Fenech, Noakes, Clifton and Topping48), which again emphasises the magnitude of the impact of diet on genome maintenance. While cytogenetic assays such as the cytokinesis-block micronucleus assay are the most practical tools to study the effects of nutrients on chromosomal instability, further insights into the effects of nutrients on the genome may be obtained by studying alterations to critical regions of chromosomes such as the telomeres.

Telomeres

Telomeres are nucleoprotein structures that cap the ends of chromosomes, maintain chromosome stability and prevent end-to-end fusion of chromosomes during cell division(Reference Gisselsson and Hoglund49Reference Blasco52). These structures play a pivotal role in maintaining overall chromosome stability, as well as triggering a signal for normal ageing cells to senesce when telomeres become dysfunctional(Reference Blasco52). Degradation of telomeres has been shown to lead to whole chromosomal instability, via telomere end fusion, and the generation of breakage–fusion–bridge cycles within chromosomes, which leads to gene amplification and gene dosage imbalance, an important risk factor for cancer(Reference Mariani, Meneghetti, Formentini, Neri, Cattini, Ravaglia, Forti and Facchini53Reference Hande, Samper, Lansdorp and Blasco55). Telomere shortening has also been proposed as one of the fundamental mechanisms that determine the rate of ageing in cells(Reference Rodier, Kim, Nijjar, Yaswen and Campisi50, Reference Puzianowska-Kuznicka and Kuznicki56, Reference Krtolica57). Extensive evidence demonstrates the impact of dietary and environmental factors on chromosome stability(Reference Fenech32, Reference Fenech, Baghurst, Luderer, Turner, Record, Ceppi and Bonassi33, Reference Liu, Wang, Hu, Ding and Xu58Reference Crott and Fenech63); however, there is limited knowledge of their impact specifically on telomere length (TL) and telomere structural integrity. Accordingly, knowledge of the impact that dietary and environmental factors have on telomeres is important for the maintenance of stem cells in a genomically-stable condition, as well as being crucial for the prevention of degenerative diseases of ageing, immune dysfunctions and cancers. The present section and subsequent sections of the present review will outline the structure of the telosome (the telomere and associated proteins) and discuss the potential impact of dietary deficiencies on this structure. In particular, there will be discussion of the plausibility that folate and nicotinic acid deficiencies together with increased oxidative stress may accelerate telomere dysfunction. Such metabolic imbalances may possibly explain the observed associations between telomere shortening and a number of conditions including obesity, psychological stress, immune dysfunction, cancer and CVD(Reference Brouilette, Singh, Thompson, Goodall and Samani64Reference Fitzpatrick, Kronmal, Gardner, Psaty, Jenny, Tracy, Walston, Kimura and Aviv69).

Telomere structure and the telosome

Telomeric DNA in vertebrates is composed of tandem repeats of the hexamer (TTAGGG)n, 8–15 kb in length in human subjects(Reference Blasco52). As a result of the end-replication problem, whereby DNA polymerases are unable to copy the final linear stretch of the lagging strand, each time DNA is replicated a small stretch of telomeric DNA is lost(Reference Blackburn70). When TL is critically short a DNA damage response is triggered that results in chromosomal end-to-end fusions or cell arrest and apoptosis(Reference Rodier, Kim, Nijjar, Yaswen and Campisi50, Reference Blasco52). The rate of telomere shortening appears to vary between age-groups, between genders and even between chromosomes of the same cells, with each chromosome arm having an age-specific TL and erosion pattern(Reference Mayer, Brüderlein, Perner, Waibel, Holdenried, Ciloglu, Hasel, Mattfeldt, Nielsen and Möller71). This variation results in a heterogeneity in chromosome-specific TL shortening with age. On average, males have shorter telomeres with age and a faster rate of telomere loss compared with females in all age-categories, a possible factor influencing the differences in life expectancy between the genders(Reference Mayer, Brüderlein, Perner, Waibel, Holdenried, Ciloglu, Hasel, Mattfeldt, Nielsen and Möller71).

The structure of telomeres involves a T-loop at the end of the chromosome, formed by the 3′OH G-strand overhang(Reference Blasco52, Reference Colgin and Reddel72, Reference Greider73). This structure protects the telomere from degradation by nucleases and minimises the possibility of it being mistakenly targeted as a double strand break requiring repair(Reference Baumgartner and Lundblad74). A number of proteins are associated with telomeric DNA. These proteins are collectively known as the shelterin complex or the telosome. The key proteins include telomere repeat-binding factors (TRF) 1 and 2, TRF1-interacting nuclear factor, repressor/activator protein and protection of telomeres 1(Reference de Lange75). TRF1 and TRF2 both bind directly to double-stranded DNA and form complexes at either end of the telomere(Reference Blasco52, Reference de Lange75). TRF1 forms a multiprotein complex incorporating tankyrase (TANK) 1 and other poly(ADP-ribose) polymerase (PARP) molecules that play a role in TL maintenance(Reference Blasco52). The TRF2 complex binds to a long (150–200 nucleotides) 3′OH G-strand overhang and plays a role in protecting the chromosome from end fusion to other chromosomes(Reference Blasco52, Reference van Steensel, Smogorzewska and de Lange76), with TRF1-interacting nuclear factor providing a bridging structure between TRF1 and TRF2(Reference Liu, O'Connor, Qin and Songyang77).

Telomere length, telosome integrity and disease

Shortened telomeres result in a high level of chromosome instability, leading to loss of cell viability, and are associated with ageing-related pathologies including heart failure, immunosenescence (infections), digestive tract atrophies, infertility, reduced viability of stem cells, reduced angiogenic potential, reduced wound healing and loss of body mass(Reference Blasco52, Reference Blackburn70). Several premature-ageing syndromes, such as Werner and Bloom syndrome and aplastic anaemia, show an accelerated rate of telomere shortening, resulting in an early onset of ageing-related pathologies(Reference Blasco52). Shortened telomeres have been strongly implicated in breast, prostate and colo-rectal cancers and certain leukaemias as a consequence of mitotic disturbances such as structural rearrangements of chromosomes, loss of whole chromosomes, and nucleoplasmic bridges arising from end fusion(Reference Griffith, Bryant, Fordyce, Gilliland, Joste and Moyzis78Reference DePinho and Polyak85).

Telomerase, a reverse transcriptase, extends telomeres, replacing lost telomeric DNA. It is usually only substantially expressed in certain cells in the body, such as stem cells and germ cells, where it is necessary to maintain TL at approximately 15 kb(Reference Bodnar, Ouellette, Frolkis, Holt, Chiu, Morin, Harley, Shay, Lichtsteiner and Wright86). The enzyme consists of two main subunits, telomerase reverse transcriptase and telomerase RNA component. Telomerase recognises and binds to the 3′OH overhang, where it then extends the DNA using an RNA molecule as a template, encoded by the telomerase RNA component subunit(Reference Blasco52). Late-stage cancer cells often have very short telomeres, indicative of their long proliferative history; however, 80–90% of these cells have been shown to have active telomerase, thus facilitating their immortality(Reference Blasco52, Reference Reddel87). As a result, blocking telomerase activity is of great interest as a cancer therapy, as it may be targeted without affecting healthy somatic cells that do not normally express telomerase to the same extent as cancer cells(Reference Mabruk and O'Flatharta88). An alternative mechanism for telomere elongation, termed ALT, exists whereby DNA from one telomere anneals with the complementary strand of another, acting as a primer for the synthesis of new telomere repeat sequences(Reference Reddel87). This mechanism has been shown to be active in some telomerase-negative cancer cells, and may in some circumstances function in addition to active telomerase(Reference Reddel87).

The addition of new repeat sequences at telomeres is a tightly regulated process for maintaining TL within a certain range, as well as ensuring senescence signals occur at an appropriate point in the life of the cell. Deletion mutant studies conducted in Saccharomyces cerevisiae indicate that >150 genes may be involved (directly or indirectly) in the regulation of TL, with approximately one-third of these genes resulting in telomere elongation(Reference Askree, Yehuda, Smolikov, Gurevich, Hawk, Coker, Krauskopf, Kupiec and McEachern89). Substantial alterations in the expression or binding capacity of telosome proteins may modify access to telomerase and the extent of telomere elongation(Reference Liu, O'Connor, Qin and Songyang77, Reference Opresko, Fan, Danzy, Wilson and Bohr90). Epigenetic controls are another mechanism that has been shown to play an important role in telomere integrity, with mouse models deficient in DNA methyltransferases showing dramatically elongated telomeres compared with wild-type controls(Reference Gonzalo, Jaco, Fraga, Chen, Li, Esteller and Blasco91). The lack of DNA methyltransferases results in an increase in telomeric recombination (indicated by sister-chromatid exchanges involving telomeric sequences) and the presence of ALT-associated promyelocytic leukaemia bodies, an event common to specific cancers(Reference Gonzalo, Jaco, Fraga, Chen, Li, Esteller and Blasco91). Telomeric DNA repeats are typically unmethylated at cytosine, while subtelomeric DNA is usually heavily methylated. Reduced DNA methyltransferase activity results in hypomethylation of subtelomeric repeats, altered configuration of the proteins associated with the telomere, increased homologous recombination of telomeric sequences, increased access of telomerase to the telomeric DNA and an increase in TL. These observations suggest that methylation of subtelomeric DNA may play a role in maintaining telomere structural stability by repressing homologous recombination and possibly prevention of excessive telomere elongation and telomere end fusions via recombination(Reference Gonzalo, Jaco, Fraga, Chen, Li, Esteller and Blasco91, Reference Blasco92).

Folate and telomere integrity

Folate is essential in the cell for the synthesis of dTTP from dUMP(Reference Fenech and Ferguson4, Reference Blount, Mack, Wehr, MacGregor, Hiatt, Wang, Wickramasinghe, Everson and Ames93). Under folate-deficient conditions uracil is incorporated into DNA instead of thymidine, leading to chromosome breakage and micronucleus formation(Reference Blount, Mack, Wehr, MacGregor, Hiatt, Wang, Wickramasinghe, Everson and Ames93Reference Crott, Mashiyama, Ames and Fenech96). Glycosylases excise uracil from the newly-synthesised strand resulting in abasic sites and DNA damage because simultaneous excision of uracil and/or other damaged DNA bases on opposite strands of DNA within twelve bases of each other has been shown to result in double-strand DNA breaks(Reference Fenech32, Reference Blount, Mack, Wehr, MacGregor, Hiatt, Wang, Wickramasinghe, Everson and Ames93Reference Dianov, Timchenko, Sinitsina, Kuzminov, Medvedev and Salganik95). Several in vitro studies have demonstrated that human cells show an inverse dose-dependent correlation between concentration of folate in the physiological range and increased DNA damage such as micronuclei (biomarker of double strand breaks) and nucleoplasmic bridges (biomarker of chromosome fusions and/or breakage–fusion-–bridge cycles)(Reference Beetstra, Thomas, Salisbury, Turner and Fenech94, Reference Crott, Mashiyama, Ames and Fenech96). Nucleoplasmic bridges are expected to originate from dicentric chromosomes caused by telomere end fusions and/or mis-repair of DNA strand breaks and highlight the possibility that folate deficiency may, in some way, cause instability at the telomeric ends of chromosomes. Recent studies in yeast suggest that insufficient synthesis of dTTP from dUMP could result in shortened TL(Reference Toussaint, Dionne and Wellinger97), raising the possibility that excessive uracil incorporation might cause breaks in the telomere sequence, as it does in other regions of the chromosome. Similarly, oxidative stress in mammalian and human cells has also been shown to cause telomere shortening, possibly as a result of the creation of abasic sites via glycosylases (discussed in following Section)(Reference Oikawa and Kawanishi98, Reference von Zglinicki99). Consequently, under low folate conditions the thymidine-rich telomere repeat sequence may be particularly prone to DNA breaks, leading to telomere shortening thus increasing chromosomal instability and DNA damage (Fig. 4).

Fig. 4. Possible models of strand breaks in telomere DNA sequence caused by base excision repair of damaged bases such as uracil (U) and oxidised guanine (G). (A) Folate deficiency causes a high dUMP:dTMP in the cell, resulting in increased U incorporation into DNA instead of thymidine. U bases are then excised by uracil glycosylase, leading to abasic sites and double-strand breaks (DSB) in DNA during the base excision repair process if U is present on complementary DNA strands within twelve bases of each other(Reference Blount, Mack, Wehr, MacGregor, Hiatt, Wang, Wickramasinghe, Everson and Ames93, Reference Dianov, Timchenko, Sinitsina, Kuzminov, Medvedev and Salganik95). In the model shown, this situation may occur after two cell divisions under folate deficiency conditions. (B) Combined effects of oxidative stress and folate deficiency. Oxidative stress causes oxidation of DNA bases such as 8′-hydroxydeoxyguanosine (8′OHdG). Oxidised bases, such as G, are excised by glycosylases, resulting in the formation of an abasic site and DSB in DNA during base excision repair. Under low folate conditions this process may result in a DSB within one cell division cycle if the DNA incorporates U when it already contains oxidised bases(Reference Oikawa and Kawanishi98, Reference von Zglinicki99)., The formation of DSB within the telomere sequence if base excision repair occurs to remove U and G simultaneously on the opposite strands of the telomeric DNA.

Folate and other methyl donors such as vitamin B12, choline and methionine also play a critical role in maintenance methylation of cytosine which, apart from its importance for transcriptional control of gene expression, determines the structural stability of important regions of the chromosomes such as the centromeres and the sub-telomeric DNA. As discussed earlier, there is strong evidence that defects in the DNA methylation process can cause excessive telomere elongation and homologous recombination between telomeres that could lead to telomere end fusions(Reference Gonzalo, Jaco, Fraga, Chen, Li, Esteller and Blasco91). It is therefore possible that deficiency of folate and other methyl donors may also result in telomere instability by causing inadequate maintenance of methylation in the sub-telomeric sequences, which leads to telomere dysfunction. It is also plausible that hypomethylation or hypermethylation of the CpG islands in the promoter of telomerase may cause excessive expression of telomerase or silence the gene respectively in differentiated cells(Reference Renaud, Loukinov, Abdullaev, Guilleret, Bosman, Lobanenkov and Benhattar100).

Nicotinic acid and telomere integrity

Nicotinic acid (niacin) is another dietary micronutrient that is known to play a fundamental role in chromosome integrity and reduction of cancer risk(Reference Hageman and Stierum101, Reference Kirkland102). PARP is a DNA break sensor, a deficiency of which has been shown to cause telomere shortening and chromosome instability(Reference Hande103Reference Malanga and Althaus106). Activation of the PARP molecule occurs upon binding of its two Zn finger domains to single or double DNA strand breaks(Reference Meyer-Ficca, Meyer, Jacobson and Jacobson104). Activation results in automodification by attachment of ADP-ribose moieties sourced from NAD(Reference Hageman and Stierum101, Reference Meyer-Ficca, Meyer, Jacobson and Jacobson104). Long polymers, ⩽200 units and often branching, are added to the PARP molecule as well as to other DNA repair proteins that are recruited to the complex. The complex is dynamic, being rapidly broken down by poly-ADP glycohydrolase, thus freeing up ADP-ribose units. The process of poly(ADP-ribosylation) requires nicotinic acid as a precursor of NAD, which is consumed during this process giving rise to nicotinamide(Reference Meyer-Ficca, Meyer, Jacobson and Jacobson104).

At least seven members have been identified in the PARP family(Reference Meyer-Ficca, Meyer, Jacobson and Jacobson104), three of which have been shown to associate with telomeric protein complexes at various stages of the cell cycle (PARP1, PARP2 and TANK1)(Reference Dantzer, Giraud-Panis and Jaco107Reference O'Connor, Safari, Liu, Qin and Songyang110). TANK1 is a human telomere-specific PARP that is present at multiple subcellular sites including telomeres, mitotic centrosomes, nuclear pore complexes and the Golgi apparatus(Reference Chang, Dynek and Smith109). TANK1 positively regulates TL through its interaction with TRF1(Reference Ye and de Lange111, Reference Cook, Dynek, Chang, Shostak and Smith112). TRF1-interacting nuclear factor exercises a higher level of control by inhibiting the previously mentioned interaction(Reference Ye and de Lange111). Binding of TANK1 to TRF1 occurs via one or more of five discrete binding sites, followed by poly(ADP-ribosylation) of TRF1 resulting in a negative charge, thereby inhibiting its binding to telomeric DNA(Reference Dynek and Smith108). Once released from DNA, TRF1 is ubiquitinated and degraded by proteasomes, directly reducing the level present in the cell(Reference Dynek and Smith108, Reference Chang, Dynek and Smith113). Overexpression of TANK1 in the nucleus of telomerase-positive cells promotes an increase in TL; however, no effect has been observed in telomerase-negative human cells. This finding suggests that the activity of TANK1 involves regulating access of telomerase to the telomeric complex(Reference Cook, Dynek, Chang, Shostak and Smith112). The recent identification of TANK2, a closely-related homologue of TANK1, opens the possibility for a second PARP being involved in telomere maintenance(Reference Cook, Dynek, Chang, Shostak and Smith112).

In addition to regulating TL, another role for TANK1 at telomeres has been identified using a mouse knock-down model in which the absence of TANK1 results in mitotic arrest(Reference Dynek and Smith108). It was found that sister chromatids successfully separate at the centromere and chromosomal regions, but are unable to separate at the telomeres, causing arrest at early anaphase(Reference Dynek and Smith108). A later study has shown that nuclear mitotic apparatus protein is a major acceptor of poly(ADP-ribosylation) by TANK1 and may play a role in the resolution of sister chromatids and the exit from mitosis(Reference Chang, Dynek and Smith109). A defective TANK1 may thus also result in the formation of telomere end fusions and nucleoplasmic bridges at anaphase and therefore cause major chromosomal instability.

Given the pivotal role that PARP molecules play in maintaining chromosome integrity by recruiting repair protein complexes, regulating TL and facilitating separation of sister chromatid telomeres during anaphase, the need for adequate nicotinic acid levels to maintain the poly(ADP-ribosylation) process is likely. One study has investigated the effect of nicotinic acid deficiency on chromosomal instability in rats by using the micronucleus assay. Animals were fed one of three diets: nicotinic acid deficient; nicotinic acid replete; nicotinic acid supplemented in conjunction with the cancer drug etoposide. A 6-fold increase in chromosomal instability was found in the nicotinic acid-deficient group compared with the nicotinic acid-replete group(Reference Spronck and Kirkland114). Supplementation over and above the replete levels was not found to have an additional effect. Similarly, a recent cross-sectional study has shown that micronucleus frequency in human lymphocytes in vivo is directly and inversely correlated with daily intake levels of nicotinic acid(Reference Fenech, Baghurst, Luderer, Turner, Record, Ceppi and Bonassi33). However, a human study conducted in twenty-one healthy smokers supplemented with four different levels of nicotinic acid has shown no protective effect against DNA damage(Reference Hageman, Stierum, van Herwijnen, van der Veer and Kleinjans115). Studies have been conducted into the epigenetic effects of NAD restriction, mainly focusing on its role as a cofactor for sirtuins, histone deacetylase enzymes(Reference Gallo, Smith and Smith116Reference Oommen, Griffin, Sarath and Zempleni118). No studies have been conducted that have specifically addressed the issue of TL and chromosomal instability under nicotinic acid-deficient conditions. The plausibility that niacin or nicotinic acid deficiency may impact on TL needs to be tested.

Oxidative stress and telomere integrity

Reactive oxygen species such as the highly-reactive hydroxyl radical and superoxide radical have been implicated in numerous disease states(Reference Evans, Dizdaroglu and Cooke119). Damage to DNA, lipids and proteins induced by reactive oxygen species may be controlled by antioxidants (such as vitamins C and E) as well as enzymic mechanisms such as superoxide dismutase, catalase and glutathione peroxidise(Reference Evans, Dizdaroglu and Cooke119). In the case of lipids and proteins normal turnover will usually remove most damaged molecules, whilst oxidised DNA bases must be rapidly identified and repaired to avoid the formation of point mutations in DNA during replication, which could lead to pathological phenotypic changes if critical genes are affected. This process occurs by the coordinated recruitment of components of the base excision repair pathway, including glycosylase, endonuclease, polymerase and ligase proteins(Reference Evans, Dizdaroglu and Cooke119). Under certain conditions, such as increased levels of free radicals and/or reduced levels of antioxidants, an imbalance can occur and the capacity for prevention and repair can become overwhelmed.

Both the bases and the ribose components of DNA have been identified as targets for different forms of oxidative damage; however, guanine residues have been shown to be particularly prone, with 8′-hydroxydeoxyguanosine being a common biomarker of oxidative stress(Reference Evans, Dizdaroglu and Cooke119). Given the high incidence of guanine residues in telomeric DNA it can be speculated that telomeres may be particularly sensitive to oxidative damage. Telomere shortening has been observed in cell lines under hyperoxic stress conditions (40% O2 partial pressure), caused by increased telomere attrition from 90 bp per population doubling to 500 bp per population doubling(Reference Von Zglinicki, Saretzki, Döcke and Lotze120). Importantly, this study has also shown that TL following hyperoxic treatment became as short as those of senescent cells (approximately 4 kb) and the mechanism for attrition has been shown to be an accumulation of single-strand breaks(Reference Von Zglinicki, Saretzki, Döcke and Lotze120). In vivo evidence has also been found to support the theory of an increased rate of telomere shortening in conditions of ill-health that are associated with increased oxidative stress(Reference Brouilette, Singh, Thompson, Goodall and Samani64Reference Fitzpatrick, Kronmal, Gardner, Psaty, Jenny, Tracy, Walston, Kimura and Aviv69). In in vitro studies antioxidant treatment has been found to prevent telomere attrition and high expression of superoxide dismutase is also associated with decreased telomere erosion rates and increased cellular lifespan(Reference Serra, von Zglinicki, Lorenz and Saretzki121); however, whether similar effects can be achieved in vivo remains uncertain.

In order to explore the mechanism of oxidative stress on telomere loss a recent study has tested the effects of site-specific 8′-hydroxydeoxyguanosine lesions and the presence of base excision repair intermediates (e.g. abasic sites) within telomeres(Reference Opresko, Fan, Danzy, Wilson and Bohr90). Single 8′-hydroxydeoxyguanosine lesions were found to reduce the percentage of bound TRF1 and TRF2 by ≥50% compared with undamaged telomeric DNA. Even more dramatic effects were observed with multiple 8′-hydroxydeoxyguanosine lesions(Reference Opresko, Fan, Danzy, Wilson and Bohr90). Both abasic sites, as well as modified guanine residues, were found to disrupt binding of TRF1 and TRF2 proteins. Alteration of any of the guanines in the TTAGGG sequence was found to decrease binding; however, alteration of the third guanine shows the strongest effect(Reference Opresko, Fan, Danzy, Wilson and Bohr90). TRF1 and TRF2 proteins have been shown to bind directly to DNA with a high extent of specificity and are critical for the recruitment of other protein components of the telosome(Reference de Lange75). Accordingly, oxidative damage to the telomere sequence may be expected to induce disruption of telomere capping and cause loss of telomere function. Whether oxidative damage to other bases in the telomere sequence also disables TRF1 and TRF2 binding remains to be tested.

Based on these considerations there are several plausible mechanisms involving folate and/or niacin (nicotinic acid) deficiency and/or antioxidant deficiency that could lead to telomere dysfunction, which are summarized together in Fig. 5.

Fig. 5. Possible mechanisms by which deficiency of folate and/or niacin (or nicotinic acid) and/or antioxidants may cause dysfunction of telomeres and consequently chromosomal instability (CIN) as a result of telomere end fusions. 8′OHdG, 8′-hydroxydeoxyguanosine; TANK, tankyrase; TRF, telomere repeat binding factor; ?, plausible but untested mechanisms.

Conclusion

It is evident that micronutrients play an important role in genome maintenance. Given that damage to the genome is the most critical pathological event that can lead to aberrant phenotype and tissue dysfunction, it is essential that more attention is given to the nutritional requirements for genome-health maintenance. As there are now excellent diagnostics for DNA damage, it is feasible to define the optimal nutritional requirements or ‘nutriome’ for individuals using DNA damage biomarkers and to determine whether their dietary choices are beneficial or harmful to their DNA. There are currently no reported investigations that have specifically focused on nutrient deficiencies and telomeric integrity. Determining the optimal micronutrient requirements for telomere maintenance may help to define more precisely the dietary strategies for optimising the genome health status of both differentiated cells and stem cells. Defining optimal culture conditions for genome-health maintenance of stem cells before their use in vivo for therapy is also critically important in preventing the risk of transplanting cells that may be prone to become cancers because of genomic instability acquired in vitro. Given the evidence that has been provided here it is postulated that optimising nutritional and lifestyle requirements for the prevention of chromosomal and telomere aberrations on an individual basis via ‘genome health clinics’(Reference Fenech5) could be one of the most cost-effective strategies for the prevention of developmental and degenerative diseases from now and into the future.

Acknowledgements

We appreciate Nathan O'Callaghan's advice on published papers relating to the association of telomere shortening with obesity and related diseases.

References

1.Ames, BN (2006) Low micronutrient intake may accelerate the degenerative diseases of aging through allocation of scarce micronutrients by triage. Proc Natl Acad Sci USA 103, 1758917594.CrossRefGoogle ScholarPubMed
2.Ames, BN & Wakimoto, P (2002) Are vitamin and mineral deficiencies a major cancer risk? Nat Rev Cancer 2, 694704.CrossRefGoogle ScholarPubMed
3.Ames, BN (2003) The metabolic tune-up: metabolic harmony and disease prevention. J Nutr 133, Suppl. 1, 1544S1548S.CrossRefGoogle ScholarPubMed
4.Fenech, M & Ferguson, LR (editors) (2001) Micronutrients and genomic stability. Mutat Res 475, 1183.Google Scholar
5.Fenech, M (2005) The Genome Health Clinic and Genome Health Nutrigenomics concepts: diagnosis and nutritional treatment of genome and epigenome damage on an individual basis. Mutagenesis 20, 255269.Google Scholar
6.Egger, G, Liang, G, Aparicio, A & Jones, PA (2004) Epigenetics in human disease and prospects for epigenetic therapy. Nature 429, 457463.Google Scholar
7.Fenech, M (2002) Chromosomal biomarkers of genomic instability relevant to cancer. Drug Discov Today 7, 11281137.Google Scholar
8.Rajagopalan, H & Lengauer, C (2004) Aneuploidy and cancer. Nature 432, 338341.Google Scholar
9.Nathanson, KL, Wooster, R, Weber, BL & Nathanson, KN (2001) Breast cancer genetics: what we know and what we need. Nat Med 7, 552556.Google Scholar
10.Thompson, LH & Schild, D (2002) Recombinational DNA repair and human disease. Mutat Res 509, 4978.Google Scholar
11.Trkova, M, Kapras, J, Bobkova, K, Stankova, J & Mejsnarova, B (2000) Increased micronuclei frequencies in couples with reproductive failure. Reprod Toxicol 14, 331335.Google Scholar
12.Fenech, M (2000) The in vitro micronucleus technique. Mutat Res 455, 8195.CrossRefGoogle ScholarPubMed
13.Fenech, M (2007) The cytokinesis-block micronucleus cytome assay. Nat Protoc 2(5), 10841104.CrossRefGoogle ScholarPubMed
14.Narula, A, Kilen, S, Ma, E, Kroeger, J, Goldberg, E & Woodruff, TK (2002) Smad4 overexpression causes germ cell ablation and leydig cell hyperplasia in transgenic mice. Am J Pathol 161, 17231734.Google Scholar
15.Ng, JM, Vrieling, H, Sugasawa, K et al. (2002) Developmental defects and male sterility in mice lacking the ubiquitin-like DNA repair gene mHR23B. Mol Cell Biol 22, 12331245.Google Scholar
16.Hsia, KT, Millar, MR, King, S, Selfridge, J, Redhead, NJ, Melton, DW & Saunders, PT (2003) DNA repair gene Ercc1 is essential for normal spermatogenesis and oogenesis and for functional integrity of germ cell DNA in the mouse. Development 130, 369378.Google Scholar
17.Liu, L, Blasco, M, Trimarchi, J & Keefe, D (2002) An essential role for functional telomeres in mouse germ cells during fertilization and early development. Dev Biol 249, 7484.Google Scholar
18.Vinson, RK & Hales, BF (2002) DNA repair during organogenesis. Mutat Res 509, 7991.Google Scholar
19.Bonassi, S, Hagmar, L, Stromberg, U et al. (2000) Chromosomal aberrations in lymphocytes predict human cancer independently of exposure to carcinogens. Cancer Res 60, 16191625.Google ScholarPubMed
20.Bonassi, S, Znaor, A, Ceppi, M et al. (2007) An increased micronucleus frequency in peripheral blood lymphocytes predicts the risk of cancer in humans. Carcinogenesis 28, 625631.Google Scholar
21.Fenech, M (1998) Chromosomal damage rate, ageing and diet. Ann NY Acad Sci 854, 2336.Google Scholar
22.Bonassi, S, Fenech, M, Lando, C et al. (2001) HUman MicroNucleus Project: International data base comparison for results with the cytokinesis-block micronucleus assay in human lymphocytes: effect of laboratory protocol, scoring criteria and host factors on the frequency of micronuclei. Environ Mol Mutagen 37, 3145.Google Scholar
23.Joenje, H & Patel, JK (2001) The emerging genetic and molecular basis of Fanconi anaemia. Nat Rev Genet 2, 446457.CrossRefGoogle ScholarPubMed
24.Shen, J & Loeb, LA (2001) Unwinding the molecular basis of Werner syndrome. Mech Ageing Dev 122, 921944.Google Scholar
25.Lansdorp, PM (2000) Repair of telomeric DNA prior to replicative senescence. Mech Ageing Dev 118, 2334.Google Scholar
26.Migliore, L, Botto, N, Scarpato, R, Petrozzi, L, Cipriani, G & Bonucelli, U (1999) Preferential occurrence of chromosome 21 segregation in peripheral blood lymphocytes of Alzheimer disease patients. Cytogenet Cell Genet 87, 4146.Google Scholar
27.Migliore, L, Scarpato, R, Coppede, F, Petrozzi, L, Bonucelli, U & Rodilla, V (2001) Chromosome and oxidative damage biomarkers in lymphocytes of Parkinson's disease patients. Int J Hyg Environ Health 204, 6166.CrossRefGoogle ScholarPubMed
28.Thiel, R & Fowkes, SW (2005) Can cognitive deterioration associated with Down syndrome be reduced? Med Hypotheses 64, 524532.Google Scholar
29.Reliene, R & Schiestl, RH (2007) Antioxidants suppress lymphoma and increase longevity in Atm-deficient mice. J Nutr 137, Suppl., 229S232S.CrossRefGoogle ScholarPubMed
30.Beetstra, S, Salisbury, C, Turner, J, Altree, M, McKinnon, R, Suthers, G & Fenech, M (2006) Lymphocytes of BRCA1 and BRCA2 germline mutation carriers, with or without breast cancer, are not abnormally sensitive to the chromosome damaging effect of moderate folate deficiency. Carcinogenesis 27, 517524.Google Scholar
31.Iarmarcovai, G, Bonassi, S, Botta, A, Baan, RA & Orsière, T (2007) Genetic polymorphisms and micronucleus formation: A review of the literature. Mutat Res (Epublication ahead of print version).Google Scholar
32.Fenech, M (2003) Nutritional treatment of genome instability: a paradigm shift in disease prevention and in the setting of recommended dietary allowances. Nutr Res Rev 16, 109122.Google Scholar
33.Fenech, M, Baghurst, P, Luderer, W, Turner, J, Record, S, Ceppi, M & Bonassi, S (2005) Low intake of calcium, folate, nicotinic acid, vitamin E, retinol, β-carotene and high intake of pantothenic acid, biotin and riboflavin are significantly associated with increased genome instability – results from a dietary intake and micronucleus index survey in South Australia. Carcinogenesis 26, 991999.CrossRefGoogle ScholarPubMed
34.Lamprecht, SA & Lipkin, M (2003) Chemoprevention of colon cancer by calcium, vitamin D and folate: molecular mechanisms. Nat Rev Cancer 3, 601614.CrossRefGoogle ScholarPubMed
35.Willett, WC (2001) Diet and cancer: one view at the start of the millennium. Cancer Epidemiol Biomarkers Prev 10, 38.Google Scholar
36.Xu, N, Luo, KQ & Chang, DC (2003) Ca2+ signal blockers can inhibit M/A transition in mammalian cells by interfering with the spindle checkpoint. Biochem Biophys Res Commun 306, 737745.Google Scholar
37.Cagnacci, A, Baldassari, F, Rivolta, G, Arangino, S & Volpe, A (2003) Relation of homocysteine, folate, and vitamin B12 to bone mineral density of postmenopausal women. Bone 33, 956959.CrossRefGoogle ScholarPubMed
38.Sato, Y, Honda, Y, Iwamoto, J, Kanoko, T & Satoh, K (2005) Effect of folate and mecobalamin on hip fractures in patients with stroke: a randomized controlled trial. JAMA 293, 10821088.Google Scholar
39.Macdonald, HM, McGuigan, FE, Fraser, WD, New, SA, Ralston, SH & Reid, DM (2004) Methylenetetrahydrofolate reductase polymorphism interacts with riboflavin intake to influence bone mineral density. Bone 35, 957964.Google Scholar
40.Fenech, M, Noakes, M, Clifton, P & Topping, D (2005) Aleurone flour increases red cell folate and lowers plasma homocyst(e)ine in humans. Br J Nutr 93, 353360.Google Scholar
41.Beetstra, S, Salisbury, C, Turner, J, Altree, M, McKinnon, R, Suthers, G & Fenech, M (2006) Lymphocytes of BRCA1 and BRCA2 germ-line mutation carriers, with or without breast cancer, are not abnormally sensitive to the chromosome damaging effect of moderate folate deficiency. Carcinogenesis 27, 517524.Google Scholar
42.Fenech, M, Aitken, C & Rinaldi, J (1998) Folate, vitamin B12, homocysteine status and DNA damage in young Australian adults. Carcinogenesis 19, 11631171.CrossRefGoogle ScholarPubMed
43.Ames, BN (2004) A role for supplements in optimizing health: the metabolic tune-up. Arch Biochem Biophys 423, 227234.CrossRefGoogle ScholarPubMed
44.Skibola, CF, Smith, MY, Kane, E, Roman, E, Rollinson, S, Cartwright, RA & Morgan, G (1999) Polymorphisms in the methylenetetrahydrofolate reductase gene are associated with susceptibility to acute leukaemia in adults. Proc Natl Acad Sci USA 96, 1281012815.CrossRefGoogle ScholarPubMed
45.Chen, J, Giovannucci, EL & Hunter, DJ (1999) MTHFR polymorphisms, methyl-replete diets and risk of colorectal carcinoma and adenoma among US men and women: an example of gene-environment interactions in colorectal tumorigenesis. J Nutr 129, 560S564S.Google Scholar
46.Fenech, M (2001) The role of folic acid and vitamin B12 in genomic stability of human cells. Mutat Res 475, 5667.Google ScholarPubMed
47.Kimura, M, Umegaki, K, Higuchi, M, Thomas, P & Fenech, M (2004) MTHFR C677T polymorphism, folic acid and riboflavin are important determinants of genome stability in cultured human lymphocytes. J Nutr 134, 4856.Google Scholar
48.Fenech, M, Noakes, M, Clifton, P & Topping, D (1999) Aleurone flour is a rich source of bioavailable folate in humans. J Nutr 129, 11141119.Google Scholar
49.Gisselsson, D & Hoglund, M (2005) Connecting mitotic instability and chromosome aberrations in cancer – can telomeres bridge the gap? Semin Cancer Biol 15, 1323.CrossRefGoogle ScholarPubMed
50.Rodier, F, Kim, SH, Nijjar, T, Yaswen, P & Campisi, J (2005) Cancer and aging: the importance of telomeres in genome maintenance. Int J Biochem Cell Biol 37, 977990.Google Scholar
51.Gilley, D, Tanaka, H & Herbert, BS (2005) Telomere dysfunction in aging and cancer. Int J Biochem Cell Biol 37, 10001013.Google Scholar
52.Blasco, MA (2005) Telomeres and human disease: ageing, cancer and beyond. Nat Rev Genet 6, 611622.CrossRefGoogle ScholarPubMed
53.Mariani, E, Meneghetti, A, Formentini, I, Neri, S, Cattini, L, Ravaglia, G, Forti, P & Facchini, A (2003) Different rates of telomere shortening and telomerase activity reduction in CD8 T and CD16 NK lymphocytes with ageing. Exp Gerontol 38, 653659.CrossRefGoogle ScholarPubMed
54.Callen, E & Surralles, J (2004) Telomere dysfunction in genome instability syndromes. Mutat Res 567, 85104.Google Scholar
55.Hande, MP, Samper, E, Lansdorp, P & Blasco, MA (1999) Telomere length dynamics and chromosomal instability in cells derived from telomerase null mice. J Cell Biol 144, 589601.CrossRefGoogle ScholarPubMed
56.Puzianowska-Kuznicka, M & Kuznicki, J (2005) Genetic alterations in accelerated ageing syndromes. Do they play a role in natural ageing? Int J Biochem Cell Biol 37, 947960.Google Scholar
57.Krtolica, A (2005) Stem cell: balancing aging and cancer. Int J Biochem Cell Biol 37, 935941.Google Scholar
58.Liu, Q, Wang, H, Hu, D, Ding, C & Xu, H (2004) Effects of trace elements on the telomere lengths of hepatocytes L-02 and hepatoma cells SMMC-7721. Biol Trace Elem Res 100, 215227.Google Scholar
59.von Zglinicki, T, Burkle, A & Kirkwood, TB (2001) Stress, DNA damage and ageing – an integrative approach. Exp Gerontol 36, 10491062.Google Scholar
60.Neri, M, Fucic, A, Knudsen, LE, Lando, C, Merlo, F & Bonassi, S (2003) Micronuclei frequency in children exposed to environmental mutagens: a review. Mutat Res 544, 243254.Google Scholar
61.Benassi, B & Fenech, M (2004) Alcohol, genome instability and breast cancer. Asia Pac J Clin Nutr 13, S55.Google Scholar
62.Bonassi, S, Neri, M, Lando, C, Ceppi, M, Lin, YP, Chang, WP, Holland, N, Kirsch-Volders, M, Zeiger, E & Fenech, M (2003) Effect of smoking habit on the frequency of micronuclei in human lymphocytes: results from the Human MicroNucleus project. Mutat Res 543, 155166.Google Scholar
63.Crott, JW & Fenech, M (1999) Effect of vitamin C supplementation on chromosome damage, apoptosis and necrosis ex vivo. Carcinogenesis 20, 10351041.Google Scholar
64.Brouilette, S, Singh, RK, Thompson, JR, Goodall, AH & Samani, NJ (2003) White cell telomere length and risk of premature myocardial infarction. Arterioscler Thromb Vasc Biol 23, 842846.Google Scholar
65.Cawthon, RM, Smith, KR, O'Brien, E, Sivatchenko, A & Kerber, RA (2003) Association between telomere length in blood and mortality in people aged 60 years or older. Lancet 361, 393395.CrossRefGoogle ScholarPubMed
66.Cherkas, LF, Aviv, A, Valdes, AM, Hunkin, JL, Gardner, JP, Surdulescu, GL, Kimura, M & Spector, TD (2006) The effects of social status on biological aging as measured by white-blood-cell telomere length. Aging Cell 5, 361365.Google Scholar
67.Epel, ES, Blackburn, EH, Lin, J, Dhabhar, FS, Adler, NE, Morrow, JD & Cawthon, RM (2004) Accelerated telomere shortening in response to life stress. Proc Natl Acad Sci USA 101, 1731217315.Google Scholar
68.Valdes, AM, Andrew, T, Gardner, JP, Kimura, M, Oelsner, E, Cherkas, LF, Aviv, A & Spector, TD (2005) Obesity, cigarette smoking, and telomere length in women. Lancet 366, 662664.Google Scholar
69.Fitzpatrick, AL, Kronmal, RA, Gardner, JP, Psaty, BM, Jenny, NS, Tracy, RP, Walston, J, Kimura, M & Aviv, A (2007) Leukocyte telomere length and cardiovascular disease in the cardiovascular health study. Am J Epidemiol 165, 1421.CrossRefGoogle ScholarPubMed
70.Blackburn, EH (2005) Telomeres and telomerase: their mechanisms of action and the effects of altering their functions. FEBS Lett 579, 859862.Google Scholar
71.Mayer, S, Brüderlein, S, Perner, S, Waibel, I, Holdenried, A, Ciloglu, N, Hasel, C, Mattfeldt, T, Nielsen, KV & Möller, P (2006) Sex-specific telomere length profiles and age-dependent erosion dynamics of individual chromosome arms in humans. Cytogenet Genome Res 112, 194201.Google Scholar
72.Colgin, L & Reddel, R (2004) Telomere biology: a new player in the end zone. Curr Biol 14, R901R902.Google Scholar
73.Greider, CW (1999) Telomeres do D-loop-T-loop. Cell 97, 419422.CrossRefGoogle ScholarPubMed
74.Baumgartner, BL & Lundblad, V (2005) Telomere identity crisis. Genes Dev 19, 25222525.CrossRefGoogle ScholarPubMed
75.de Lange, T (2005) Shelterin: the protein complex that shapes and safeguards human telomeres. Genes Dev 19, 21002110.Google Scholar
76.van Steensel, B, Smogorzewska, A. & de Lange, T (1998) TRF2 protects human telomeres from end-to-end fusions. Cell 92, 401413.Google Scholar
77.Liu, D, O'Connor, MS, Qin, J & Songyang, Z (2004) Telosome, a mammalian telomere-associated complex formed by multiple telomeric proteins. J Biol Chem 279, 5133851342.Google Scholar
78.Griffith, JK, Bryant, JE, Fordyce, CA, Gilliland, FD, Joste, NE & Moyzis, RK (1999) Reduced telomere DNA content is correlated with genomic instability and metastasis in invasive human breast carcinoma. Breast Cancer Res Treat 54, 5964.Google Scholar
79.Chin, K, de Solorzano, CO, Knowles, D et al. (2004) In situ analyses of genome instability in breast cancer. Nat Genet 36, 984988.Google Scholar
80.Meeker, AK (2006) Telomeres and telomerase in prostatic intraepithelial neoplasia and prostate cancer biology. Urol Oncol 24, 122130.Google Scholar
81.Sieglova, Z, Zilovcová, S, Cermák, J et al. (2004) Dynamics of telomere erosion and its association with genome instability in myelodysplastic syndromes (MDS) and acute myelogenous leukemia arising from MDS: a marker of disease prognosis? Leuk Res 28, 10131021.Google Scholar
82.Engelhardt, M, Wasch, R & Guo, Y (2004) Telomeres and telomerase in normal and leukemic hematopoietic cells. Leuk Res 28, 10011004.Google Scholar
83.Rudolph, KL, Millard, M, Bosenberg, MW & DePinho, RA (2001) Telomere dysfunction and evolution of intestinal carcinoma in mice and humans. Nat Genet 28, 155159.CrossRefGoogle ScholarPubMed
84.Gisselsson, D (2005) Mitotic instability in cancer: is there method in the madness? Cell Cycle 4, 10071010.Google Scholar
85.DePinho, RA & Polyak, K (2004) Cancer chromosomes in crisis. Nat Genet 36, 932934.Google Scholar
86.Bodnar, AG, Ouellette, M, Frolkis, M, Holt, SE, Chiu, CP, Morin, GB, Harley, CB, Shay, JW, Lichtsteiner, S & Wright, WE (1998) Extension of life-span by introduction of telomerase into normal human cells. Science 279, 349352.Google Scholar
87.Reddel, RR (2003) Alternative lengthening of telomeres, telomerase, and cancer. Cancer Lett 194, 155162.Google Scholar
88.Mabruk, MJ & O'Flatharta, C (2005) Telomerase: is it the future diagnostic and prognostic tool in human cancer? Expert Rev Mol Diagn 5, 907916.Google Scholar
89.Askree, SH, Yehuda, T, Smolikov, S, Gurevich, R, Hawk, J, Coker, C, Krauskopf, A, Kupiec, M & McEachern, MJ (2004) A genome-wide screen for Saccharomyces cerevisiae deletion mutants that affect telomere length. Proc Natl Acad Sci USA 101, 95159516.Google Scholar
90.Opresko, PL, Fan, J, Danzy, S, Wilson, DM & Bohr, VA (2005) Oxidative damage in telomeric DNA disrupts recognition by TRF1 and TRF2. Nucleic Acids Res 33, 12301239.CrossRefGoogle ScholarPubMed
91.Gonzalo, S, Jaco, I, Fraga, MF, Chen, T, Li, E, Esteller, M & Blasco, MA (2006) DNA methyltransferases control telomere length and telomere recombination in mammalian cells. Nat Cell Biol 8, 416424.Google Scholar
92.Blasco, MA (2007) The epigenetic regulation of mammalian telomeres. Nat Rev Genet 8, 299309.Google Scholar
93.Blount, BC, Mack, MM, Wehr, CM, MacGregor, JT, Hiatt, RA, Wang, G, Wickramasinghe, SN, Everson, RB & Ames, BN (1997) Folate deficiency causes uracil misincorporation into human DNA and chromosome breakage: implications for cancer and neuronal damage. Proc Natl Acad Sci USA 94, 32903295.Google Scholar
94.Beetstra, S, Thomas, P, Salisbury, C, Turner, J & Fenech, M (2005) Folic acid deficiency increases chromosomal instability, chromosome 21 aneuploidy and sensitivity to radiation-induced micronuclei. Mutat Res 578, 317326.Google Scholar
95.Dianov, GL, Timchenko, TV, Sinitsina, OI, Kuzminov, AV, Medvedev, OA & Salganik, RI (1991) Repair of uracil residues closely spaced on the opposite strands of plasmid DNA results in double-strand break and deletion formation. Mol Gen Genet 225, 448452.Google Scholar
96.Crott, JW, Mashiyama, ST, Ames, BN & Fenech, M (2001) The effect of folic acid deficiency and MTHFR C677T polymorphism on chromosome damage in human lymphocytes in vitro. Cancer Epidemiol Biomarkers Prev 10, 10891096.Google Scholar
97.Toussaint, M, Dionne, I & Wellinger, RJ (2005) Limited TTP supply affects telomere length regulation in a telomerase-independent fashion. Nucleic Acids Res 33, 704713.Google Scholar
98.Oikawa, S & Kawanishi, S (1999) Site-specific DNA damage at GGG sequence by oxidative stress may accelerate telomere shortening. FEBS Lett 453, 365368.Google Scholar
99.von Zglinicki, T (2002) Oxidative stress shortens telomeres. Trends Biochem Sci 27, 339344.Google Scholar
100.Renaud, S, Loukinov, D, Abdullaev, Z, Guilleret, I, Bosman, FT, Lobanenkov, V & Benhattar, J (2007) Dual role of DNA methylation inside and outside of CTCF-binding regions in the transcriptional regulation of the telomerase hTERT gene. Nucleic Acids Res 35, 12451256.Google Scholar
101.Hageman, GJ & Stierum, RH (2001) Niacin, poly(ADP-ribose) polymerase-1 and genomic stability. Mutat Res 475, 4556.Google Scholar
102.Kirkland, JB (2003) Niacin and carcinogenesis. Nutr Cancer 46, 110118.Google Scholar
103.Hande, MP (2004) DNA repair factors and telomere-chromosome integrity in mammalian cells. Cytogenet Genome Res 104, 116122.Google Scholar
104.Meyer-Ficca, ML, Meyer, RG, Jacobson, EL & Jacobson, MK (2005) Poly(ADP-ribose) polymerases: managing genome stability. Int J Biochem Cell Biol 37, 920926.Google Scholar
105.Burkle, A, Brabeck, C, Diefenbach, J & Beneke, S (2005) The emerging role of poly(ADP-ribose) polymerase-1 in longevity. Int J Biochem Cell Biol 37, 10431053.Google Scholar
106.Malanga, M & Althaus, FR (2005) The role of poly(ADP-ribose) in the DNA damage signaling network. Biochem Cell Biol 83, 354364.Google Scholar
107.Dantzer, F, Giraud-Panis, MJ, Jaco, I et al. (2004) Functional interaction between poly(ADP-Ribose) polymerase 2 (PARP-2) and TRF2: PARP activity negatively regulates TRF2. Mol Cell Biol 24, 15951607.Google Scholar
108.Dynek, JN & Smith, S (2004) Resolution of sister telomere association is required for progression through mitosis. Science 304, 97100.Google Scholar
109.Chang, W, Dynek, JN & Smith, S (2005) NuMA is a major acceptor of poly(ADP-ribosyl)ation by tankyrase 1 in mitosis. Biochem J 391, 177184.Google Scholar
110.O'Connor, MS, Safari, A, Liu, D, Qin, J & Songyang, Z (2004) The human Rap1 protein complex and modulation of telomere length. J Biol Chem 279, 2858528591.Google Scholar
111.Ye, JZ & de Lange, T (2004) TIN2 is a tankyrase 1 PARP modulator in the TRF1 telomere length control complex. Nat Genet 36, 618623.Google Scholar
112.Cook, BD, Dynek, JN, Chang, W, Shostak, G & Smith, S (2002) Role for the related poly(ADP-Ribose) polymerases tankyrase 1 and 2 at human telomeres. Mol Cell Biol 22, 332342.Google Scholar
113.Chang, W, Dynek, JN & Smith, S (2003) TRF1 is degraded by ubiquitin-mediated proteolysis after release from telomeres. Genes Dev 17, 13281333.Google Scholar
114.Spronck, JC & Kirkland, JB (2002) Niacin deficiency increases spontaneous and etoposide-induced chromosomal instability in rat bone marrow cells in vivo. Mutat Res 508, 8397.Google Scholar
115.Hageman, GJ, Stierum, RH, van Herwijnen, MH, van der Veer, MS & Kleinjans, JC (1998) Nicotinic acid supplementation: effects on niacin status, cytogenetic damage, and poly(ADP-ribosylation) in lymphocytes of smokers. Nutr Cancer 32, 113120.Google Scholar
116.Gallo, CM, Smith, DL Jr & Smith, JS (2004) Nicotinamide clearance by Pnc1 directly regulates Sir2-mediated silencing and longevity. Mol Cell Biol 24, 13011312.Google Scholar
117.Sauve, AA, Moir, RD, Schramm, VL & Willis, IM (2005) Chemical activation of Sir2-dependent silencing by relief of nicotinamide inhibition. Mol Cell 17, 595601.Google Scholar
118.Oommen, AM, Griffin, JB, Sarath, G & Zempleni, J (2005) Roles for nutrients in epigenetic events. J Nutr Biochem 16, 7477.Google Scholar
119.Evans, ME, Dizdaroglu, M & Cooke, MS (2004) Oxidative DNA damage and disease: induction, repair and significance. Mutat Res 567, 161.Google Scholar
120.Von Zglinicki, T, Saretzki, G, Döcke, W & Lotze, C (1995) Mild hyperoxia shortens telomeres and inhibits proliferation of fibroblasts: A model for senescence? Exp Cell Res 220, 186193.Google Scholar
121.Serra, V, von Zglinicki, T, Lorenz, M & Saretzki, G (2003) Extracellular superoxide dismutase is a major antioxidant in human fibroblasts and slows telomere shortening. J Biol Chem 278, 68246830.Google Scholar
122.Paul, AA & Southgate, DA (1978) McCance and Widdowson's The Composition of Foods, 4th ed. Amsterdam: Elsevier.Google Scholar
Figure 0

Fig. 1. Expression of micronuclei and nucleoplasmic bridges during nuclear division. Micronuclei originate from either (1) lagging whole chromosomes (A) that are unable to engage with the mitotic spindle because of a defect in the spindle or a defect in the centromere–kinetochore complex required to engage with the spindle, or (2) an acentric chromosome fragment originating from a chromosome break (A and B) that lags behind at anaphase because it lacks a centromere–kinetochore complex. Mis-repair of two chromosome breaks may lead to an asymmetrical chromosome rearrangement producing a dicentric (i.e. two centromeres) chromosome and an acentric fragment (B); frequently the centromeres of the dicentric chromosome are pulled to opposite poles of the cell at anaphase resulting in the formation of a nucleoplasmic bridge between the daughter nuclei. Nucleoplasmic bridges are frequently accompanied by a micronucleus originating from the associated acentric chromosome fragment. Nucleoplasmic bridges may also originate from dicentric chromosomes caused by telomere end fusions. As micronuclei and nucleoplasmic bridges are only expressed in cells that have completed nuclear division it is necessary to score these genome instability biomarkers specifically in once-divided cells. This process is readily accomplished by blocking cytokinesis using cytochalasin-B (for a more detailed explanation, see Fenech(7,12,13)).

Figure 1

Fig. 2. Percentage variation in genome damage for the mid-tertile of intake (□) and the highest tertile of intake (■) of vitamin E, calcium, folate, retinol, nicotinic acid, β-carotene, riboflavin, pantothenic acid and biotin relative to the lowest tertile of intake in an Australian cohort of healthy adults. Genome damage rate was measured in peripheral blood lymphocytes using the cytokinesis-block micronucleus assay (for more details, see Fenech et al.(33)). The percentage variations in genome damage were significant: *P<0·006.

Figure 2

Fig. 3. Content of micronutrients associated with reduced DNA damage in selected common foods. The height of each bar for each micronutrient within the separate foods corresponds to the amount of the micronutrient expressed as the percentage of the minimum daily intake associated with a reduced micronucleus frequency index in lymphocytes as determined in the study of Fenech et al.(33). The relative contribution of each of the micronutrients (if present) is indicated by the height of each specifically coloured bar. The nutrient content of the foods was determined using published food content tables(122). (), Calcium; (), folate; (), niacin; (), vitamin E; (), β-carotene; (), retinol.

Figure 3

Fig. 4. Possible models of strand breaks in telomere DNA sequence caused by base excision repair of damaged bases such as uracil (U) and oxidised guanine (G). (A) Folate deficiency causes a high dUMP:dTMP in the cell, resulting in increased U incorporation into DNA instead of thymidine. U bases are then excised by uracil glycosylase, leading to abasic sites and double-strand breaks (DSB) in DNA during the base excision repair process if U is present on complementary DNA strands within twelve bases of each other(93,95). In the model shown, this situation may occur after two cell divisions under folate deficiency conditions. (B) Combined effects of oxidative stress and folate deficiency. Oxidative stress causes oxidation of DNA bases such as 8′-hydroxydeoxyguanosine (8′OHdG). Oxidised bases, such as G, are excised by glycosylases, resulting in the formation of an abasic site and DSB in DNA during base excision repair. Under low folate conditions this process may result in a DSB within one cell division cycle if the DNA incorporates U when it already contains oxidised bases(98,99)., The formation of DSB within the telomere sequence if base excision repair occurs to remove U and G simultaneously on the opposite strands of the telomeric DNA.

Figure 4

Fig. 5. Possible mechanisms by which deficiency of folate and/or niacin (or nicotinic acid) and/or antioxidants may cause dysfunction of telomeres and consequently chromosomal instability (CIN) as a result of telomere end fusions. 8′OHdG, 8′-hydroxydeoxyguanosine; TANK, tankyrase; TRF, telomere repeat binding factor; ?, plausible but untested mechanisms.