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Biochem. J. (1996) 313 (17–29)
(Printed in Great Britain)
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Review
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Damage to DNA by reactive oxygen and
nitrogen species: role in inflammatory disease and progression to cancer
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Helen WISEMAN* and Barry HALLIWELL†
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*Department of Nutrition and
Dietetics, King's College London, Campden Hill Road, London W8 7AH, and
†Pharmacology Group, King's College London, Manresa Road, London SW3
6LX, U.K.
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Abbreviations used: ROS, reactive oxygen
species; RNS, reactive nitrogen species; O2 -,
superoxide radical; OH, hydroxyl
radical; RO2, peroxyl
radical; RO, alkoxyl radical; O3,
ozone; ONOO-, peroxynitrite; 1O2, singlet
oxygen; NO, nitric oxide radical; NO2,
nitrogen dioxide radical; GC-MS, gas chromatography/MS; 8-OHG,
8-hydroxyguanine; 8-OHdG, 8-hydroxydeoxyguanosine; PARP, poly(ADP-ribose)
polymerase; AP, apurinic/ apyrimidinic; XP, xeroderma pigmentosum; SOD,
superoxide dismutase; MnSOD, manganese-containing SOD; IBD, inflammatory
bowel disease; PMA, phorbol 12-myristate 13-acetate; iNOS, inducible form of
nitric oxide synthase; 5-ASA, 5-aminosalicylic acid.
INTRODUCTION
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It is increasingly proposed that reactive
oxygen species (ROS) and reactive nitrogen species (RNS) play a key role in
human cancer development [1–6], especially as evidence
is growing that antioxidants may prevent or delay the onset of some types of
cancer (reviewed in [7,8]). ROS
is a collective term often used by biologists to include oxygen radicals [superoxide
(O2-), hydroxyl
(OH), peroxyl (RO2)
and alkoxyl (RO)] and certain
non-radicals that are either oxidizing agents and/or are easily converted
into radicals, such as HOCl, ozone (O3), peroxynitrite (ONOO-),
singlet oxygen (1O2) and H2O2.
RNS is a similar collective term that includes nitric oxide radical (NO),
ONOO-, nitrogen dioxide radical (NO2),
other oxides of nitrogen and products arising when NO
reacts with O2-,
RO and RO2.
'Reactive' is not always an appropriate term; H2O2, NO
and O2- react
quickly with very few molecules, whereas OH
reacts quickly with almost anything. RO2,
RO, HOCl, NO2,
ONOO- and O3 have intermediate reactivities. ROS and
RNS have been shown to possess many characteristics of carcinogens [4]
(Figure 1). Mutagenesis by ROS/RNS could contribute to the initiation of
cancer, in addition to being important in the promotion and progression
phases. For example, ROS/RNS can have the following effects.
(1) Cause structural alterations in DNA,
e.g. base pair mutations, rearrangements, deletions, insertions and sequence
amplification. OH is especially
damaging, but 1O2, RO2,
RO, HNO2, O3,
ONOO- and the decomposition products of ONOO- are also
effective [9–13]. ROS can produce gross chromosomal
alterations in addition to point mutations and thus could be involved in the
inactivation or loss of the second wild-type allele of a mutated
proto-oncogene or tumour-suppressor gene that can occur during tumour
promotion and progression, allowing expression of the mutated phenotype [4].
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(2) Affect cytoplasmic and nuclear signal
transduction pathways [14,15].
For example, H2O2 (which crosses cell and organelle
membranes easily) can lead to displacement of the inhibitory subunit from
the cytoplasmic transcription factor nuclear factor kB,
allowing the activated factor to migrate to the nucleus [14].
Nitration of tyrosine residues by ONOO- may block phosphorylation.
(3) Modulate the activity of the proteins
and genes that respond to stress and which act to regulate the genes that
are related to cell proliferation, differentiation and apoptosis [4,14–17].
For example, H2O2 can stimulate transcription of c-jun
[18] and can activate mitogen-activated protein kinase
in NIH 313 cells [19].
CHEMISTRY OF DNA DAMAGE
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The endogenous reactions that are likely
to contribute to ongoing DNA damage are oxidation, methylation, depurination
and deamination [1,2]. Nitric
oxide or, more likely, reactive products derived from it, such as NO2,
ONOO-, N2O3 and HNO2, are
mutagenic agents, with the potential to produce nitration, nitrosation and
deamination reactions on DNA bases [3,6].
Methylation of cytosines in DNA is important for the regulation of gene
expression, and normal methylation patterns can be altered during
carcinogenesis [20]. Conversion of guanine to
8-hydroxyguanine (2), a frequent result of ROS attack [9,10,21],
has been found to alter the enzyme-catalysed methylation of adjacent
cytosines [20], thus providing a link between
oxidative DNA damage and altered methylation patterns.
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The chemistry of DNA damage by several ROS
has been well characterized in vitro [9,11–13,21],
although more information is needed about the changes produced by RO2,
RO, O3, ONOO- and
several of the RNS. Different ROS affect DNA in different ways, e.g. O2-
and H2O2 do not react with DNA bases at all [9,10].
OH generates a multiplicity of products
from all four DNA bases and this pattern appears to be a diagnostic
'fingerprint' of OH attack [10].
By contrast 1O2 selectively attacks guanine [13,22].
The most commonly produced base lesion, and the one most often measured as
an index of oxidative DNA damage, is 8-hydroxyguanine (8-OHG). It is
sometimes measured as the nucleoside, 8-hydroxydeoxyguanosine (8-OHdG) [2,23].
These assay methods have been reviewed in detail [9,10,23,24].
2 shows the structures of the products of ROS attack on DNA.
Damage to DNA by ROS/RNS appears to occur
naturally, in that low steady-state levels of base damage products have been
detected in nuclear DNA from human cells and tissues [2,23–26].
The pattern of damage to the purine and pyrimidine bases (2) suggests that
at least some of the damage occurs by OH
attack, suggesting that OH is formed in
the nucleus in vivo [24].
MITOCHONDRIAL DNA DAMAGE
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ROS/RNS can also damage mitochondrial DNA,
and such damage has been suggested to be important in several human diseases
and in the aging process [27,28].
The free-radical theory of aging postulates that aging is caused by
free-radical reactions and that life expectancy can be increased by
nutritious low calorific diets supplemented by free-radical inhibitors [27].
Indeed, it has been claimed that mechanisms of aging and life span
shortening by enhanced calorific intake are associated with increased
oxidative damage resulting from associated changes in mitochondrial ROS
production [29].
Mitochondria are often said to be the most
important intracellular source of ROS, but it is hard to be sure of this [30].
However, it seems very likely that the mitochondrial electron transport
chain generates ROS in vivo [31,32]
and that mitochondrial DNA is damaged by them. Indeed, oxidative DNA base
damage (measured as 8-OHdG) has been detected in mitochondrial DNA at
steady-state levels several-fold higher than in nuclear DNA [26,28,33].
Which ROS or RNS are responsible has not yet been elucidated. This apparent
increased net oxidative damage in mitochondrial DNA compared with nuclear
DNA could be because of the proximity of mitochondrial DNA to ROS generated
during electron transport, the lack of histone proteins to protect the DNA
against attack, or inefficient repair, so that base damage accumulates to
higher levels. Intermediate radicals formed during lipid peroxidation, as
well as end-products of peroxidation (1), can also attack DNA [34]
and have been suggested to damage mitochondrial DNA, which is in close
proximity to the mitochondrial inner membrane [35].
Oxidative damage by all the above
mechanisms could contribute to the deletions and mutations in mitochondrial
DNA that accumulate with age at a higher rate than in nuclear DNA [36].
Damage to mitochondrial DNA could play a role in neurodegenerative diseases:
mitochondrial deletions and increased steady-state mitochondrial oxidative
DNA damage (measured as elevations in 8-OHdG) have been reported in
Alzheimer's disease [37]. Increased mitochondrial DNA
damage in tissue from atherosclerotic hearts has also been reported [38].
SOURCES OF OH
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The pattern of damage to DNA bases in
nuclear DNA suggests that OH attack
occurs in vivo (no data are available as yet on whether the same is
true for mitochondrial DNA). How could OH
be formed to attack DNA in the nucleus and mitochondria? If OH
is attacking DNA, it must be produced very close to the DNA since it is so
reactive that it cannot diffuse from its site of formation [11,30].
Background radiation may be one source [11], but
radiation-generated OH is formed over
the whole cell and only a small fraction would be likely to hit DNA [39].
Other sources of OH include reaction of
O2- with HOCl [40] and reaction
of nitric oxide radical (NO) with O2-.
NO reacts very quickly with O2-
to give ONOO- [41] and with RO2
and RO to give organic peroxynitrites,
which appear much more stable than ONOO- [42].
ONOO- itself is probably directly damaging to DNA bases (e.g. by
deamination and nitration of guanine residues) and, at physiological pH, it
decomposes into a range of toxic products, including species identical with
(or closely resembling) NO2,
OH and NO2+ [43–45].
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By far the greatest interest has been,
however, in Fenton chemistry as a source of OH
[30,46]. The question of whether
transition metal ions that can convert H2O2 into OH
(e.g. iron and copper ions) really are in close proximity to DNA in vivo
is clearly a critical one. Although iron and copper appear to be present in
the nucleus [10,46] and may
easily be released from non-haem iron proteins in mitochondria (perhaps as a
result of attack by ROS [47]), it remains to be
established how they could reach the DNA. Iron and copper ions are normally
carefully sequestered by the body, into proteins such as ferritin,
transferrin, caeruloplasmin and metallothionein [48].
DNA is a powerful chelating agent for transition metal ions, however, and
oxidative stress may cause the release of intracellular iron and/or copper
ions into forms that could then bind to DNA [10]. Thus
O2- releases some
iron from ferritin [49], H2O2
can release iron from haem proteins [50] and ONOO-
releases copper from caeruloplasmin [51].
DNA-associated copper ions in cells might
also react with phenolic compounds to produce ROS and electrophilic phenolic
intermediates [52–54]. This interaction could cause a
range of DNA lesions including base modifications, strand breaks and phenol
adducts to the DNA bases, all of which might contribute to the
carcinogenicity of certain phenolic compounds. Phenolic compounds that cause
DNA damage in the presence of copper ions include 2-hydroxyoestradiol,
2-methoxyoestradiol, diethylstilboestrol, butylated hydroxytoluene,
butylated hydroxyanisole, L-DOPA,
dopamine, ferulic acid and caffeic acid [52–54].
However, phenols have complex pro- and anti-oxidant effects in vitro,
depending on the assay system used, and it is often hard to predict their
net effect in vivo [55]. For example, many
synthetic and dietary polyphenols (including quercetin, catechin, gallic
acid ester and caffeic acid ester) can protect mammalian and bacterial cells
from the cytotoxicity induced by peroxides such as H2O2
[56].
DNA REPAIR
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DNA damage can be repaired by the action
of a series of enzymes (reviewed in [57]). However,
DNA from human cells and tissues contains low levels of DNA base damage
products [2,24,25,58–61],
suggesting that these enzymes do not achieve complete removal of modified
bases, perhaps because they operate at close to maximum capacity in vivo.
In agreement with this, the steady-state levels of one or more base damage
products have been observed to increase in a number of chronic inflammatory
diseases accompanied by increased ROS/RNS production, including hepatitis [62]
and rheumatoid arthritis [58]. They are also increased
in DNA isolated from cancerous tumour biopsies of human lung, colon, kidney,
breast, liver and bladder (e.g. see [59–62]) and from
benign prostatic hyperplasia tissues [63]. Of course,
a rise in DNA base damage products could be due either to increased
oxidative damage and/or to decreased repair activity; the increased damage
to DNA in inflammation is presumably due to increased ROS/RNS production,
often by the activation of phagocytes [10,17].
DNA glycosylases exist for the repair of
several DNA base lesions, including oxidized, methylated and deaminated
bases. A repair system for the abasic [apurinic/apyrimidinic (AP)] sites
produced by spontaneous depurination also exists. Areas of current interest
include the role of poly(ADP-ribose) polymerase (PARP) in the rejoining of
DNA strand breaks, including those induced by ROS [64,65],
and the fact that repair of oxidative DNA damage is defective in xeroderma
pigmentosum (XP) cells [65,66].
Human XP is a genetic disorder with an autosomal recessive mode of
inheritance, and there are seven genetic complementation groups (A–G) [67].
The defective gene products in these groups are involved in nucleotide
excision repair, particularly in damage recognition and incision processes.
Thus the XPA protein recognizes and binds to damaged DNA, whereas XPB and
XPD are involved in DNA unwinding to facilitate the removal of the faulty
base [67]. Normal repair can be restored by mixing two
XP cell extracts derived from different complementation groups [65].
The XPG protein is an endonuclease that plays a direct role in making one of
the incisions required to excise a damaged base [67].
It seems likely that the products of RNS- and ROS-induced damage may
accumulate in XP cells; this could contribute to the neurological
deterioration and increased occurrence of cancer observed in XP patients [65,66],
an illustration of the importance of DNA repair processes. Defective DNA
repair is also responsible for one of the most common cancers, hereditary
non-polyposis colon cancer [67].
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DNA damage by ROS/RNS can cause multiple
lesions, including single and double strand breaks, AP sites and modified
pyrimidines and purines. Repair of these lesions occurs primarily by base
excision repair, although nucleotide excision repair may also be involved.
Recognition of 'spontaneous' [hydrolysis of the base–sugar (glycosylic)
bond] and ROS/RNS-generated AP sites may be carried out by various AP
endonucleases with different specificities, and this can be used to
differentiate between different types of AP site [68].
DNA repair enzymes have usually been
purified by assaying their ability to act upon a single specific base
lesion. However, recent studies using gas chromatography/MS (GC-MS) have
investigated the ability of enzymes to repair DNA containing a wide range of
lesions, and have shown that they can sometimes have a broader specificity
than expected. For example, Escherichia coli endonuclease III can
excise several thymine- and cytosine-derived lesions, e.g.
5-hydroxy-2´-deoxycytidine, from DNA [57,69,70].
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MEASUREMENT OF
OXIDATIVE DNA DAMAGE
In principle, there are two types of
measurement of oxidative DNA damage. Steady-state damage is measured when
DNA isolated from human cells and tissues is analysed: it is the balance
between damage and repair. It is worth mentioning that the measurement of
baseline levels of modified DNA bases, although very important, does not
provide information as to whether this damage is in active genes or in
quiescent DNA. It does, however, seem likely that 'exposed' DNA could be
more sensitive to damage by ROS/RNS than that packaged into condensed
chromatin.
It is also useful to have an index of
total DNA damage (i.e. that which has occurred but has been repaired) and
this has been attempted in humans by analysis of urine. Several base damage
products are excreted in urine [2,71–73]
but the one most exploited is 8-OHdG because it can be assayed using HPLC
with electrochemical detection [2,23].
8-OHG is sometimes measured, but the 8-OHG content of urine is affected by
the diet (cooking foods oxidizes their DNA and proteins, just as it oxidizes
their lipids) and it can also arise by oxidative damage to RNA. By contrast,
the 8-OHdG content of urine is thought not to be affected by the diet since
nucleosides are not absorbed from the gut. However, some or all of the
8-OHdG measured in urine may come not from DNA, but from the deoxyGTP
precursor pool [74]. An enzyme is believed to
hydrolyse dGTP containing oxidized guanine to prevent its incorporation into
DNA [74,75]. The activity of
this enzyme may vary between different human cells, perhaps contributing to
an explanation of variable mutation rates in different tissues exposed to
oxidative stress [76]. However, if some or all of the
8-OHdG in urine comes from oxidized dGTP, it follows that we urgently need
better markers of total body oxidative DNA damage.
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8-OHG and 8-OHdG are the products most
frequently measured in isolated DNA as an indicator of oxidative DNA damage.
The former can be released from DNA by acid hydrolysis, whereas enzymic
hydrolysis liberates 8-OHdG. The methods commonly used for their analysis
also raise some questions. Measurement of 8-OHdG by HPLC with
electrochemical detection is a highly sensitive method [23].
One alternative is GC-MS with selected ion monitoring, which can measure a
wide spectrum of modified (methylated, oxidized, deaminated, etc.) DNA bases
[9,10,71].
Both methods are sufficiently sensitive to measure steady-state levels of
oxidative base damage in human cells and tissues, but more comparisons of
these methods are needed. HPLC can underestimate the amount of 8-OHdG in DNA
if the enzymic hydrolysis is not completely efficient; the efficiency of the
exonucleases and endonucleases used to hydrolyse the DNA may be diminished
by oxidative modification of the bases [24,77].
By contrast, GC-MS might overestimate base damage products if they are
generated artifactually during derivatization procedures [78].
Dizdaroglu (e.g. [79]) has used stable isotope
dilution MS to quantify DNA damage.
Many additional methods have been
described, e.g. GC-MS has been used to analyse thymine glycol residues [80],
uracil [81] and malondialdehyde–guanine adducts [82].
Analysis of uracil in DNA by GC-MS following its removal by uracil DNA
glycosylase has been used to demonstrate that inhibition of folic acid
metabolism induces uracil accumulation in DNA [81]. We
have used HPLC after acid hydrolysis of DNA to measure several base damage
products, including 8-OHG [83]. HPLC coupled to
32P post-labelling has been used to measure 8-OHdG adducts in the
peripheral blood of human subjects exposed to ionizing radiation [84].
Indeed, 32P post-labelling has been used to measure several DNA
adducts [85,86].
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Different approaches to measuring
oxidative base damage have been reported [87,88].
One of these [87] utilizes the ability of endonuclease
III to make breaks in DNA at sites of base damage; the breaks are then
measured by single-cell gel electrophoresis. For example, normal human
lymphocytes in vitro were found to contain several hundred
endonuclease III-sensitive sites per cell. By contrast, no endonuclease
III-sensitive sites were found in HeLa cells, perhaps reflecting less
oxidative damage and/or more efficient repair processes in these cells as
compared with lymphocytes.
A rigorous comparison and standardization
of these various methods is clearly needed (discussed in [24]).
Another problem to be considered is the possibility that DNA is oxidatively
damaged during its isolation, particularly if phenol-based methods are used
[89]. However, the rigorous control of isolation
procedures and avoidance of phenol (e.g. by isolation of chromatin for GC-MS
analysis [90]) in many laboratories does not decrease
oxidative DNA base damage to zero [24,58,59,87,91],
strongly supporting the view that there is a low steady-state DNA damage
level in vivo. Indeed, the fact that an extensive system of repair
enzymes exists (see above) supports this view.
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HOW COULD DNA DAMAGE
BY ROS/RNS CAUSE MUTATION AND CANCER?
ROS/RNS can cause DNA base changes,
strand breaks, damage to tumour-suppressor genes and enhanced expression
of proto-oncogenes [4,17], and
oxidative stress has been shown to induce malignant transformation of
cells in culture [92,93].
However, the development of human cancer depends on many other factors,
including the extent of DNA damage (excessive DNA damage can cause cell
suicide by activation of PARP; see below), antioxidant defences, DNA
repair systems, the efficiency of removal of oxidized nucleosides (e.g.
oxo-dGTP) before they are incorporated into DNA, and the cytotoxic effects
of ROS in large amounts (a dead cell will not lead to cancer) as well as
their growth-promoting effects in small amounts [15,94].
For example, the proliferative responses of Syrian hamster embryo
fibroblasts to O2-
have been found to depend on tumour-suppressor gene function, and low
levels of O2-
can enhance cell growth [95]. Persistent excessive
oxidative DNA damage may transmit signals to other cellular components
(including the tumour-suppressor protein p53) and may trigger apoptosis.
In addition, DNA damage (including ROS/RNS-induced DNA strand breaks) can
result in p53 accumulation in the nucleus, which may arrest cell growth at
the G1/S border in an attempt to allow repair of DNA lesions
before replication. Roles for ROS in apoptosis are frequently suggested
(although fiercely contested, e.g. see [96]); the
anti-apoptotic gene bcl-2 decreases the overall cellular production
of ROS [16] and ROS can trigger apoptosis [16,97,98].
This does not mean that ROS are essential mediators of apoptosis, of
course. The bcl-2 gene is the prototype of a family of genes that
inhibit apoptosis and was originally cloned from the t(14;18)
translocation breakpoint found in follicular B-cell lymphomas.
Unfortunately, the bcl-2 gene is also an oncogene and the oncogenic
properties of the bcl-2 protein could relate to its ability to
prevent 'useful' apoptotic cell death. The bcl-2 protein has a
C-terminal membrane anchor and is localized to the nuclear, endoplasmic
reticulum and mitochondrial outer membranes; it may protect cells by
inhibiting ROS-induced lipid peroxidation [16,98,99].
Reasoning from first principles, this could be a direct antioxidant effect
of bcl-2, and/or it could occur if bcl-2 up-regulates
endogenous antioxidant defences. Thus, while a high cellular antioxidant
capacity tends to protect DNA from oxidative damage and related
mutagenesis, antioxidant activity may also (ironically) protect
'initiated' cells from ROS-mediated killing. Down-regulation of the
bcl-2 gene by the p53 tumour-suppressor protein in human breast cancer
cells has been reported [100]. However, bcl-2
can rescue cells from apoptosis caused by non-oxidative events, so it does
not simply act by antioxidant mechanisms [96,98,99].
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Which of the multiple different types of
chemical alteration in DNA caused by ROS/RNS are relevant to cancer
development? Recent studies have attempted to identify mutations that are
caused by ROS/RNS damage to DNA, with the aim of ascertaining their
association (if any) with cancer [4].
Damage to DNA by ROS, as measured in a
single-stranded DNA, E.coli-based, forward mutation assay, was found
to induce a wide spectrum of mutations, which depended not only on the ROS
used but also on the DNA replication apparatus that encountered the lesion [5].
The most frequent mutations found in this system were C to T transitions.
However, mutations arising from C to T transitions are not diagnostic for
mutagenesis by ROS because they can be caused by DNA polymerase errors and
by DNA damage arising from the action of other genotoxic agents [5].
Incubation of DNA with ROS-generating systems such as FeSO4/O2
or CuCl2/H2O2 resulted in the formation of
mainly C to T, G to T and G to C substitutions in the iron system; and C to
T and G to T substitutions and CC to TT tandem double transitions in the
copper ion system [101]. Each of these mutation
patterns was clustered in 'hot spots' that are characteristic for each
system; some of this effect might relate to different binding of the two
metal ions to DNA, so that ROS are directed to particular DNA base sequences
[5]. For example, copper ions bind preferentially to
GC-rich sequences [102].
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There are several different pathways
leading from initial DNA base damage by ROS/RNS to subsequent mutation (3).
The first (and probably the simplest) is the chemical modification of DNA
bases causing a change in their hydrogen bonding specificity, e.g. 8-OHG,
thymine glycol and 2-hydroxyadenine [101,103,104].
In addition, 8-hydroxyadenine, ring-opened purines and a number of
pyrimidine fragmentation products can block replication in E. coli
and could thus be mutagenic [105,106].
Singlet-oxygen-induced DNA damage is targeted selectively at guanine
residues [22,107] and the G to T
transversion mutations induced may be generated by an error-prone bypass of
damaged G [108]. Oxidation products of cytosine
(5-hydroxycytosine and 5-hydroxyuracil) exhibit sequence-context-dependent
mispairing in vitro resulting in C to T transitions and C to G
transversions [109]. Although it is not obvious which
modified DNA bases are responsible for the mutations that can be introduced
by DNA polymerases a and b,
it seems likely that the C to T and C to A substitutions observed in the
E. coli system result from the oxidative modification of cytosines [5].
DNA polymerase is known to be sensitive to damage-induced errors at
guanines.
The contribution of oxidative damage to
polymerase-specific 'hot spots', which is a likely major contributor to DNA
polymerase-mediated mutagenesis, is a second possible mechanism. In studies
on the lacZ gene, T to G transversions at positions +70 and +103 were
observed when polymerase was used to copy an undamaged DNA template [110].
A 6–10-fold increase in the frequency of transversions at both sites was
caused by iron-ion-mediated oxidative damage, and an increased frequency of
mutation at position +103 only was produced by copper-ion-dependent damage [110].
The 'background' mutations might also be caused by endogenous oxidative
damage. Perhaps also the sequences used were inherently mutagenic for
polymerase and could thus enhance the miscoding potential of oxidatively
induced adjacent lesions [5].
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A third mechanism is linked to a
conformational change in the DNA template that diminishes the accuracy of
replication by DNA polymerases [110]. Evidence for
this mechanism has been provided by the finding that iron-ion-dependent
damage to M13mp2 double-stranded circular DNA produces a high frequency of
mutants that possess substitutions at positions +95 and +103 on the lacZ
gene. The frequency of this double mutation in the polymerase spectrum is
four orders of magnitude higher than would be expected from two independent
mutational events, and it has been suggested [110]
that oxidative damage to the DNA template alters the pausing pattern for DNA
polymerase at the two sites of mutation by changing the DNA structure. The
frequency of mutation is also greatly increased by exposure of the DNA to
ROS, probably by mechanisms involving rearrangements of the nascent
strand-template. Conformational changes that cause an increase in the
pausing of the DNA polymerase or a decrease in processivity could enhance
such rearrangements. Although direct studies of the effects of base
modifications on DNA conformation are just beginning, it is known that many
oxidized bases are non-planar and could change local DNA structure [5].
Human relevance of
bacterial studies
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Studies of bacterial mutation depend on
the so-called SOS response (which includes DNA repair enzymes) and the
nature of the bacterial DNA replication system. Such studies can only
provide indications about the mutations likely to be caused in human cells
by ROS/RNS. Indeed, studies with mammalian DNA polymerases have shown that
DNA damage by ROS can yield mutations different from those observed in E.
coli [110]. Nevertheless, studies using bacterial
systems have provided useful information, including the suggestion that
tandem CC to TT double substitutions, induced by ROS from many different
sources including iron(II), copper(I) and nickel(II) ions and
g radiation [111,112],
may be specific markers for oxidative DNA damage, at least in cells not
exposed to UV light (which can also induce this mutation [113]).
Nickel(II) is a known human carcinogen which has been shown to increase
oxidative DNA base damage in rats [114] and to induce
the above 'signature mutation' for ROS damage in an E. coli forward
mutation assay [112].
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The p53 tumour-suppressor gene and
the ras family of proto-oncogenes are known to be important
cancer-related genes. It is possible that ROS may be the mutagens involved
in some of the mutations observed in these genes [4,17,115],
e.g. the G to T transversion often found in Ki-ras and H-ras
in non-melanoma skin tumours could be produced by misreplication of the
8-OHdG lesions induced by ROS (although GT tranversions may be generated by
other mutagenic mechanisms). G to T transversions have also been observed in
p53 codons in hepatocellular carcinoma and smoking-related lung
carcinoma, and again they might arise by the actions of ROS. In colorectal
cancer ROS may yet again be involved, as around 95% of the mutations at
p53 hot spot codons in these tumours are C to T and G to A transitions,
and these base-pair changes are often produced by the deamination of
5-methylcytosine, which is enhanced by ROS and RNS [4].
Indirect mutagenicity
by ROS/RNS: damage to proteins and lipids
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ROS/RNS-induced mutations could arise not
only from DNA damage, but also from protein damage. Protein damage is a
major consequence of excess ROS generation in vivo [116]
and damage to DNA polymerases could alter their fidelity. It has been
suggested that an alteration in the conformation of DNA polymerase could
explain the frequency of close-proximity double mutations that occur
secondarily to a wide range of genetic stresses [5,117].
Several RNS, e.g. ONOO- and NO2,
can attack proteins, nitrating aromatic amino acid residues and possibly
affecting their ability to participate in signal transduction mechanisms [43,44,118].
Oxidative protein damage could also affect the activity of DNA repair
enzymes.
Another possible mutagenic effect of ROS
involves their attack on lipids, to initiate lipid peroxidation (2).
Peroxides can decompose to a range of mutagenic carbonyl products [34].
For example, 4-hydroxynonenal is genotoxic to lymphocytes and hepatocytes
and also disrupts gap-junction communications in cultured endothelial cells
[119]. In a study on a baby hamster kidney cell line
(BHK-21/C13) and its polyoma-virus-transformed malignant counterpart
(BHK-21/PyY cells) the level of lipid peroxidation (as measured by HPLC of
malondialdehyde) was higher in transformed cells than in non-transformed
cells, suggesting that the level of lipid peroxidation is increased in the
malignant state [120]. By contrast, earlier work
claimed that susceptibility to lipid peroxidation is decreased in malignant
hepatoma cells (e.g. Novikoff and Yoshida ascites hepatoma cells) (reviewed
in [34]) and this was found to be directly related to
their extent of dedifferentiation [121]. It is of
related interest that regenerating rat liver shows increased steady-state
levels of 8-OHdG in nuclear DNA [122] and that
partially hepatectomized rats show increased urinary excretion of thymine
glycols [123].
Return To Top
These findings illustrate the well-known
observation that cell transformation alters cell responsiveness to oxidative
stress. Changes in antioxidant defence enzymes such as superoxide dismutase
(SOD) have been widely described in cancerous cells, although the most
consistent reports seem to be of falls in Mn-containing SOD (MnSOD) (the
mitochondrial enzyme) activity [124]. This change may
be significant in relation to the malignant phenotype, since
radiation-induced neoplastic transformation in mouse C3H 10T1/2 cells (a
cell line susceptible to transformation by ROS [93])
was decreased by transfection of the cells with a gene encoding human MnSOD
[125]. Similar results have been reported in human
melanoma cells [126] and a mouse fibrosarcoma cell
line [127].
'Slippery' DNA
Return To Top
Another area worthy of consideration in
the ROS/RNS context is that of misalignment mutagenesis ('slippery DNA').
The human genome contains many sequences in which 1–6-nucleotide motifs are
tandemly repeated a number of times. The contraction and expansion of these
'microsatellites' is associated with cancer (e.g. mono-, di- and
tri-nucleotide repeats are unstable in colon cancer cells and this
instability has been linked to a gene on chromosome 2) and several genetic
diseases, including myotonic dystrophy and Huntington's disease [128].
The gain or loss of repetitive DNA sequences may be caused by errors that
result from strand slippage during DNA replication remaining uncorrected
because of defective post-replication heteroduplex repair [129].
The instability of these repeats is associated with DNA polymerases slipping
during replication, and some types of colorectal cancer may reflect
mutations in genes involved in DNA mismatch repair [129].
Theoretically, ROS/RNS should be capable of accelerating such changes [129].
PARP
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The nuclear enzyme PARP modifies proteins
(including itself; automodification) by the attachment of poly(ADP-ribose)
polymers. PARP is involved in base excision repair but not in nucleotide
excision repair, which requires the formation of a multiprotein repair
complex before DNA incision that may prevent the binding of PARP to DNA
breaks [64,65]. The repair of
DNA single strand breaks induced by the antibiotic bleomycin [65]
is totally dependent on the activation of PARP, and the repair of modified
bases generated by alkylating agents is also promoted by PARP activation. In
base excision repair, damaged bases are eliminated by DNA glycosylases,
breaks are then induced at the AP sites by AP endonuclease and this is
followed by the excision of deoxyribose phosphate, DNA synthesis and finally
ligation. The process of DNA break rejoining initiated by AP endonuclease is
aided by PARP, which may have a structural role in chromatin conformation
and may provide temporary protection for the DNA breaks during the initial
stage of the recombination and repair processes. Excess activation of PARP
can kill cells by depleting NAD+ and preventing energy production
[130], and this may be one mechanism by which cells
with excess DNA damage are eliminated (see above).
ROLE OF INFLAMMATION
IN INCREASED DNA DAMAGE, MUTATION AND CANCER
The cumulative risk of cancer increases
with approximately the fourth power of age [2]. This
is true for both short-lived species such as mice, where about 30% have
cancer by the end of their 2–3-year life span, and in long-lived species
such as humans, where approx. 30% have cancer by age 85. Much cancer can
thus be considered as a degenerative disease of old age and it is frequently
suggested that this is related to the effects of continuous damage over a
life span by ROS and RNS [1,2].
For example, prostate cancer is most prevalent among elderly males and has
been suggested to be associated with endogenous cellular processes, in
particular ROS generation [5].
Inflammation can accelerate the
development of cancer [3,131].
Many sources of inflammation are effective, including that caused by viral,
bacterial and parasitic infections. In colon cancer, predisposing sources of
chronic inflammation include ulcerative colitis and infection with the
parasite Schistosoma japonicum [28,62,92].
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However, the link between cancer and
inflammation is by no means a simple one. One chronic inflammatory disease
in which patients suffer oxidative stress is rheumatoid arthritis. There is
increased damage by ROS [132,133]
(and probably also by RNS [134]) to lipids, proteins
and DNA. Rheumatoid arthritis patients also show increased urinary excretion
of 8-OHdG [135]. Increased DNA damage, and increased
susceptibility to killing by H2O2, have also been
reported in lymphocytes from patients with autoimmune diseases: lymphocyte
DNA from patients with rheumatoid arthritis, systemic lupus erythematosus,
vasculitis and Behcet's disease contained significantly more 8-OHdG than
that from healthy controls [58].
Return To Top
Despite all this, there is no clear
evidence that rheumatoid arthritis patients develop cancers at an increased
rate, certainly not at the most intense site of oxidative stress, the
inflamed joint. Perhaps this is linked to the nature of the cells of the
synovium. Synovium seems to be a hostile environment for neoplastic cells [136],
although one might argue that the excessive synovial cell proliferation in
rheumatoid arthritis patients might be related to the growth-promoting
properties of ROS.
Return To Top
Despite the apparent anomaly of rheumatoid
arthritis, there is considerable evidence that ROS/RNS are somehow involved
in UA-1the link between chronic inflammation and cancer [3,28,62,92,131].
A notable activity of tumour promoters is their ability to recruit
inflammatory cells and to stimulate them to generate ROS/RNS. Indeed, there
is a strong relationship between the capacity of tumour promoters to
stimulate inflammatory cells to release ROS/RNS and their capacity to
promote tumours [131,137,138].
Genetic damage and neoplastic transformation have been demonstrated in cells
co-cultured in vitro with activated phagocytes [92].
The genotoxic effects observed in these cells include the formation of DNA
strand breaks [138], sister chromatid exchange [139]
and mutations [140]. The DNA base modifications
observed in cells co-cultured with phorbol 12-myristate 13-acetate (PMA)-activated
inflammatory cells were characteristic of attack by OH
[141]. Presumably phagocyte products such as H2O2
penetrated to the nucleus and were converted into OH
by reaction with localized transition metal ions.
Return To Top
Tumour promotion can be inhibited in
animal models by the use of agents that can inhibit the phagocyte
respiratory burst, including certain antioxidants, as well as steroids and
retinoids [131,137]. Increased
levels of oxidatively modified DNA bases (thymidine glycol,
5-hydroxymethyl-2´-deoxyuridine and 8-OHdG [142]) have
been induced in the skin of mice by topical PMA exposure. 8-OHdG has also
been identified in the epidermis of nude mice exposed to near-UV [143].
The production of ROS in vivo following the application of phorbol
esters to mouse skin requires two applications; each triggers a separate
biochemical event, priming and activation [144]. Both
of these events can be triggered by tumour-promoting phorbol esters but not
by non-promoting ones. Priming events include the recruitment of
inflammatory cells: PMA recruits neutrophils and activates them to produce
ROS/RNS. The inhibitor of phorbol ester tumour promotion, retinoic acid,
inhibits activation but not priming and similar results are found for
several phenolic antioxidants [142,144].
This suggests that retinoic acid, usually considered to inhibit promotion by
altering gene expression in transformed cells, might act additionally to
exert indirect antioxidant effects under certain circumstances, at least
when applied topically to mouse epidermis. Similarly, 13-cis-retinoic
acid inhibits X-ray-induced skin cancer in XP patients (see above), where it
has been proposed to exert antioxidant effects [145].
Return To Top
Inflammatory cells may also increase DNA
damage by activating pro-carcinogens to DNA-damaging species, e.g.
neutrophils can activate aromatic amines, aflatoxins, oestrogens, phenols
and polycyclic aromatic hydrocarbons by ROS-dependent mechanisms [131,146].
RNS can generate carcinogenic nitrosamines [3,147,148],
e.g. nitrosation of morpholine has been reported in immunostimulated rats [149].
Some examples
Schistosomiasis
The schistosomiasis model has been used to
study the interrelationship between inflammation, oxidative DNA damage,
chromosomal instability and dysregulated cell proliferation [131].
Infection with Schistosoma haematobium produces chronic bladder
inflammation and is associated with increased cancer at this site. Indeed,
infected individuals show elevated levels of genetic damage in their
bladders, as measured by the exfoliated cell micronucleus test [131,150],
and micronucleus frequency is decreased by treatments that kill the
parasite. It is possible that clones of cells in these patients develop an
inherited altered ability to repair oxidative DNA damage and thus an
increased sensitivity to the ROS/RNS produced by activated inflammatory
cells. Alterations in chromosome 11 are common in bladder cancer [151]
and loci on this chromosome may be involved in controlling the level of
chromosomal breakage caused by oxidative DNA damage.
Return To Top
This sensitivity to oxidative stress is
apparently not due to a difference in single-strand DNA breakage or repair [152].
In addition, an abnormally high frequency of chromatid breaks and gaps has
been reported when human tumours (of many different tissue origins and/or
histopathology) are X-irradiated during the G2 phase of the cell
cycle; insertion of a normal chromosome 11 decreased radiation-induced
damage, possibly by restoration of a defective repair process (see [153]).
Bladder carcinoma cells have been shown to be sensitive to micronucleus
induction by tumour-promoter-activated neutrophils and protection is
possible via the insertion of a normal chromosome 11 [131].
Again, this is thought to restore the defective DNA repair process [131].
It is of related interest that infection with the pro-inflammatory bacterium
Helicobacter pylori appears to be an important risk factor for
stomach ulcers, gastritis and possibly stomach cancer [154].
Lung cancer
Return To Top
Lung cancer is a frequent cause of death,
and most cases are linked to smoking. Cessation of smoking leads to a rapid
decrease in the risk of lung cancer, suggesting that a series of
smoking-related events is required for cancer development. Cigarette smoke
is rich in carcinogens such as nitrosamines, acrolein and carcinogenic
hydrocarbons, but ROS/RNS may also contribute to cancer development, since
smoke is rich in ROS and oxides of nitrogen [118,155].
Higher levels of oxidative DNA base damage have been reported in lung cancer
tissue compared with surrounding normal tissue [156]
and in cells exposed to cigarette smoke [157].
Additionally, a 4–10-fold elevation of urinary 8-OHdG excretion has been
found in smokers [72,73].
Exposure to asbestos is a major risk
factor for mesothelioma; asbestos-induced chronic inflammation and resulting
DNA damage may contribute [158–160]. Crocidolite (one
of the most carcinogenic types of asbestos) induces release of ROS from
neutrophils and macrophages, and increased 8-OHdG levels in the DNA of a
human promyelocytic leukaemia cell line (HL60) [159].
Furthermore, exposure of rat pleural mesothelial cells to crocidolite and
chrysotile fibres resulted in DNA damage and cell toxicity that was partly
due to ROS [160].
Liver cancer
Return To Top
In both Asia and Africa, hepatocellular
carcinoma is a major cause of mortality. Primary hepatoma in these countries
is often associated with chronic infection with hepatitis viruses B or C [161],
or ingestion of aflatoxin [162]. In primary
hepatocellular carcinoma, aflatoxin exposure often results in mutations
involving codon 249 of the p53 gene [163].
Indeed, aflatoxin frequently produces G to T transversions, and this is the
predominant substitution at codon 249 in p53 found in aflatoxin-associated
tumours. This transversion can also be produced by oxidative damage [115].
Chronic hepatitis [164] is associated with the
presence of inflammatory cells, presumably generating ROS and RNS. Indeed,
increased levels of 8-OHdG have been detected in DNA from livers with
chronic hepatitis [62,165].
Inflammatory bowel disease
(IBD)
Return To Top
IBD is the general name given to a series
of chronic inflammatory diseases of the gastrointestinal tract, including
ulcerative colitis and Crohn's disease. ROS are formed in excess in IBD and
are likely to play an important role not only in the pathogenesis of IBD [166,167]
but also in the increased risk of cancer seen in certain IBDs. An elevated
production of ROS has been shown using colorectal biopsy specimens [168].
Further evidence consistent with damage by ROS is provided by the increase
in lipid peroxides in rectal biopsy specimens from patients with active
ulcerative colitis, and the reports of low levels of GSH, SOD and
glutathione peroxidase in patients with active IBD [166,169,170].
The main sources of ROS in the gut are probably phagocytes, which accumulate
in the mucosa of patients with IBD and generate ROS (and presumably RNS)
upon activation. A marked increase in the activity of the inducible form of
nitric oxide synthase (iNOS) in the inflamed colonic mucosa from patients
with ulcerative colitis has been reported [171,172].
By contrast, there was no increase in iNOS activity in the inflamed colonic
mucosa from patients with active Crohn's disease, even though the extent of
inflammation was similar [171]. In addition,
nitrotyrosine (a putative chemical marker for the formation of ONOO-
[43,173]) has been detected by
an immunohistochemical stain in an animal model of chronic gut inflammation
and found to co-localize with NOS [174]. This suggests
that both NO and O2-
are formed in vivo, and undergo reaction to give ONOO-.
Furthermore, intracolonic instillation of ONOO- is
pro-inflammatory in a rat colitis model [175].
Another important ROS in IBD may be HOCl.
HOCl, produced by the enzyme myeloperoxidase from activated neutrophils, may
attack membrane proteins directly (e.g. by oxidizing -SH groups, destroying
methionine and chlorinating aromatic amino acid residues), or indirectly by
the formation of chloramines. Both HOCl and chloramines can stimulate
colonic secretion [176]. A role for ROS has also been
described in the stimulation of colonic mucosal proliferation by bile salts
[94]. It has been proposed that some of the drugs
effective in the treatment of IBD may act by scavenging HOCl and other ROS [167,177].
Return To Top
What is the evidence for increased
oxidative DNA damage in IBD? DNA from colon biopsies from patients with
ulcerative colitis had significantly increased levels of 8-OHG,
2-hydroxyadenine, 8-hydroxyadenine and 2,6-diamino-5-formamidopyrimidine as
measured by GC-MS/selected ion monitoring (H. Wiseman, M. Dizdaroglu and B.
Halliwell, unpublished work). These lesions, suggestive of OH
attack, could signify increased DNA damage and/or decreased repair. The
constitutive and ROS-induced activity of PARP has been shown to be decreased
in patients with IBD and colon cancer [178].
Breast cancer
Return To Top
Oxidative DNA damage may be involved in
the development of breast cancer. Increased steady-state levels of DNA base
damage, with a pattern characteristic of OH
attack, have been reported in DNA from invasive ductal carcinoma [60,179].
One study found a 9-fold increase in 8-OHG, 8-hydroxyadenine and
2,6-diamino-4-hydroxy-5-formamidopyrimidine in DNA from invasive ductal
carcinoma compared with control tissue [60,179].
Whether this is due to decreased DNA repair and/or increased oxidative DNA
damage is uncertain. DNA damage by ROS is also implicated in inflammatory
breast disease [180], where malignant progression can
occur.
PROSPECTS FOR DIETARY
AND DRUG ANTIOXIDANT INTERVENTION IN THE PREVENTION OF OXIDATIVE DNA
DAMAGE AND HUMAN DISEASE
Dietary antioxidants
Cells have multiple antioxidant defences
to protect themselves against ROS. These protective mechanisms are not
present in excess; if they were, oxidative damage would not occur and repair
mechanisms would not be required. Instead, oxidative damage occurs
continuously in the human body (Table 1). Fortunately, enzymic and some
other (e.g. metallothionein, caeruloplasmin and haptoglobin) antioxidant
defences are often inducible in response to oxidative damage [30].
Return To Top
We also obtain several antioxidants from
the diet. Indeed, the consumption of fruit, grains and vegetables, which are
the main sources of these antioxidants, is of importance in protecting
against oxidative damage and resulting disease [7,8,181–184].
Intake of fresh fruit and vegetables appears to be inversely correlated with
cancer of the stomach, pancreas, oral cavity and oesophagus, and to a lesser
extent of the breast, cervix, rectum and lung [183,184],
and emphasis has been placed on the protective role of ascorbate. Indeed,
there is evidence that ascorbate can react with, and/or inhibit the
formation of, carcinogenic N-nitroso compounds such as N-nitrosamines
[185,186]. Vitamin C
supplementation has been reported to decrease mucosal DNA damage, as
measured by a 32P post-labelling assay, in 28 of 43 patients
attending a gastric follow-up clinic [187]. In
patients with normal gastric mucosa, treatment with vitamin C resulted in an
elevation of intragastric ascorbate in all cases, whereas in patients with
chronic atrophic gastritis the effect was variable [187].
These data support epidemiological evidence suggesting that vitamin C may
exert a protective effect against the development of gastric cancer. Very
low vitamin C intakes have been associated with elevated levels of 8-OHdG in
sperm DNA [188]. However, ascorbate supplementation
did not affect tumour development in chemically induced bladder, mammary or
colon cancers in rodents (reviewed in [7]). Therefore
the extent of the benefits of ascorbate in human cancer prevention remain to
be ascertained.
Table 1 Evidence
for ROS/RNS-mediated damage in vivo
| Target of damage |
Evidence |
| DNA |
Urinary excretion of damaged DNA bases; low
baseline levels of damaged DNA bases in DNA isolated from human cells |
| Lipid |
Lipid peroxidation in atherosclerotic lesions;
presence of peroxidation end-products in plasma and urine |
| Uric acid |
Damaged by ROS to form products (including
allantoin) found in human body fluids; levels increase during oxidative
stress |
| Protein |
Protein carbonyls and o-tyrosine formed
from ROS attack and nitrosothiols/nitro-aromatics from RNS attack; low
levels of some of these products can be detected in human tissues and
body fluids and may increase during oxidative stress |
Return To Top
A sufficient level of dietary antioxidants
has been suggested to be achievable by the intake of a minimum of three
servings of vegetables and two of fruit per day. Furthermore, dietary
supplementation of this daily intake of fruit and vegetables with moderate
amounts of the relatively inexpensive and non-toxic vitamins ascorbate and
a-tocopherol may also be desirable in some
population groups, such as smokers [8,181,183,184,189].
In addition to antioxidants, fruit and vegetables contain many vital
micronutrients that may be protective. These include folic acid, which is
required for the synthesis of DNA precursors, and niacin, which is required
for the NAD+ used by PARP. Many carotenoids, including
b-carotene, can be metabolized to vitamin A
(retinol), and the antioxidant activity of carotenoids is thought to be
particularly directed against 1O2 [190–193].
Return To Top
However, it would be naive in the extreme
to assume that the protective effects of fruits and vegetables are related
only to their antioxidant content; among the many other potentially
protective substances present are anti-angiogenesis factors, inducers of
carcinogen-removing enzymes, fibre and phytates [194].
Diets rich in fruits and vegetables are often low in fat, which could
contribute to their anti-cancer effect [195]. Such
diets are also often low in iron; high body iron levels are
(controversially) associated with increased risk of cancer [196–199].
Furthermore, in a prospective study of the intake of vitamins C, E and A and
the risk of breast cancer, it was found that large intakes of vitamins C or
E were not protective to women [200]. There is an
urgent need to investigate to what extent dietary changes can decrease
steady-state and total-body oxidative DNA damage in humans (which relates to
the methodological questions discussed earlier) and, if so, what is the
optimal intake of, for example, fruit, vegetables or antioxidant
supplements. The rapid development of accurate assays for measuring
oxidative damage to DNA, lipids and proteins in the human body should help
to make this possible (reviewed in [181]).
Drug antioxidants
Return To Top
Several drugs in current clinical use may
exert some antioxidant effects in vivo [201].
Tamoxifen, which is widely used in the treatment of breast cancer and is
being investigated as a prophylactic treatment for this disease, may exert
antioxidant effects additional to its anti-oestrogenic properties [202].
Thus it has been reported to suppress H2O2 production
by human neutrophils [203–205]. The tamoxifen
metabolite 4-hydroxytamoxifen is a more powerful inhibitor of lipid
peroxidation than tamoxifen in lipoproteins [206] and
in the nuclear membrane [207].
Another drug that may act as a
free-radical scavenger in vivo is sulphasalazine and its metabolites,
used in the treatment of IBD. Sulphasalazine is converted by colonic
bacteria into 5-aminosalicylic acid (5-ASA), which has a number of
antioxidant properties. It is an excellent scavenger of several ROS,
especially HOCl [177,208,209].
The finding, in IBD patients treated with sulphasalazine, of 5-ASA-derived
products identical to those formed when this compound reacts with OH
in vitro, suggests that ROS scavenging by 5-ASA is a significant
mechanism of action in vivo [210,211].
CONCLUSION AND FUTURE
PROSPECTS
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We need oxygen in order to survive, but
the constant assault on our DNA by ROS/RNS may lead to cancer development [1,2].
Even phagocyte ROS/RNS production, useful in the short term as a defence
against infection, may harm us in the long term, and certainly harms
patients with chronic inflammatory diseases.
Understanding the mechanisms by which
these chemical changes relate to alterations in gene expression and the
development of cancer, and how they can be affected by drug treatment and/or
dietary changes, requires a combination of expertise in molecular biology
and analytical biochemistry. As an example we have little information on how
oxidative base modification affects the PCR. Thus amplification of oxidized
DNA (e.g. ancient DNA [212]) may produce misleading
results.
Correlations of structural chemistry and
analytical methodology with changes in gene expression should lead to
valuable new concepts and, hopefully, novel ways of preventing cancer.
We are grateful to the Cancer Research
Campaign, the Medical Research Council and MAFF for research support.
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