"Furthermore, genetic damage to the spermatozoa of aging males is thought to contribute to the etiology of more complex polygenic conditions such as autism, spontaneous schizophrenia and epilepsy" RJ Aitken
Expert calls for vigilance on IVF technology
By Anna Salleh for ABC Science Online
Posted Sat Jun 14, 2008 10:46am AEST
A 3D ultrasound showing a foetus inside the womb. (Getty Images)
As humans become more dependent on reproductive technologies, an Australian reproductive biologist says we must remain vigilant to avoid the spread of genetic defects.
The warning comes in an editorial by Professor John Aitken, of the University of Newcastle, in the current issue of Expert Review of Obstetrics and Gynecology.
"People shouldn't be too confident that just because the baby looks normal there is no damage there that won't appear later in life," he said.
"People underestimate how much genetic damage they're passing onto the embryos."
Professor Aitkin says one in every 35 babies born in Australia are a result of IVF.
"In some countries it's more like one in 20 and there are models that predict it will be one in 10 before too long," he said.
Professor Aitken says because IVF allows infertile men to reproduce, the more we use it the more it will be needed in the future.
"So we better make sure it's safe because a large proportion of the population will be generated in this way," he said.
Ageing sperm
Professor Aitken says a number of factors are known, or suspected, to cause genetic damage to sperm that do not necessarily cause defects obvious at birth.
For example, Professor Aitken says the sperm of ageing males is thought to contribute to conditions such as autism, schizophrenia and epilepsy.
He says there is strong evidence linking sperm DNA damage to smoking, which can lead to the development of childhood cancers.
Epigenetic changes to sperm DNA that can affect fertility through several generations have also been reported.
For example, several recent papers have shown that infertile men have a dramatically altered DNA methylation profile.
Screening and monitoring
Professor Aitken says genetic problems mean it is important that reproductive clinics do a good job at screening sperm samples for genetic damage.
He is presenting the latest evidence on one screening technique he is developing with biotech company nuGEN at the Australian Research Council's Graeme Clark Research Outcomes Forum in Canberra next week.
But Professor Aitken says long-term monitoring of children born through IVF and other reproductive technologies is also essential, because such techniques can not pick up epigenetic damage.
"There are all kinds of things that can and could still go wrong," he said.
While he says IVF children are being monitored, he is concerned about complacency among clinics who celebrate their ability to produce normal looking babies from sperm with high levels of DNA damage.
IVF defended
Professor Michael Chapman of the Fertility Society of Australia, who also works for IVF Australia, says genetic damage is considered by IVF clinics.
"They're concerns that are shared within the IVF profession," he said.
Professor Chapman says one rare epigenetic disease has shown up in IVF children, at a rate of one in 1,500 versus one in 5,000 in the general population.
But he says Professor Aitken's "provocative" article overstates the problem since in the 20 years that IVF has been around, few long-term problems have arisen, despite thousands of children being monitored.
"I'm sure that if something starts to turn up, it will jump out at us," he said.
Sandra Hill, chief executive officer of ACCESS Australia, a group led by patients seeking IVF treatment, is confident that IVF is well-monitored, and she agrees this should continue.
But she says many of the concerns raised by Professor Aitken also apply to natural conception and she thinks the use of IVF should not be singled out.
She says it could be useful to educate men in general about the concerns raised by Professor Aitken - especially the need for men to have children before they get too old.
Professor Aitken says this may be so, but IVF still presents a unique challenge.
"With IVF you are facilitating the fertilisation of eggs with sperm that would otherwise be unsuccessful," he said.
Professor Aitken also says the rate of birth defects in IVF children are up to twice that of normally-conceived children, although he expects that to improve as techniques improve.
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Professor R. John Aitken ScD, FRSE
Director, ARC Centre of Excellence in Biotechnology and Development,
Professor of Biological Sciences,
School of Environmental and Life Sciences,
University of Newcastle
Callaghan
NSW 2308.
E mail: jaitken@mail.newcastle.edu.au
Tel: (+61 2) 4921 6143
Mobile: 0414 667 878
Fax: (+61 2) 4921 6308
John Aitken is currently Director of ARC Centre of Excellence in Biotechnology and Development and Professor of Biological Sciences at the University of Newcastle, NSW. His research interests focus on the cell biology of male germ cells, particularly the cell biology of human spermatozoa and the mechanisms regulating the formation and recruitment of primordial follicles within the ovary.
Qualifications: BSc (Special Hons) University of London
MSc University of Wales
PhD University of Cambridge
ScD University of Cambridge
Fellow of the Royal Society of Edinburgh
Positions:
1982-1987 Senior Scientist, Medical Research Council Reproductive Biology Unit, University of Edinburgh.
1987-1998 Special Appointment, Professorial Grade, Medical Research Council Reproductive Biology Unit, University of Edinburgh
1992- Honorary Professorship, Department of Obstetrics and Gynaecology, University of Edinburgh
1998- Professor of Biological Sciences, Faculty of Science and IT, University of Newcastle, NSW.
1998 Director of the Centre for Life Sciences, University of Newcastle, NSW.
2003 Director of the ARC Centre of Excellence in Biotechnology and Development
Honours:
1984 Honorary Fellow of the Faculty of Medicine,University of Edinburgh.
1985 Ayerst Lecturer, Pacific Coast Fertility Society,Caesar's Palace, Las Vegas.
1985 Ortho-McMaster Lecturer, McMaster University Medical Centre, Hamilton, Canada.
1985 Convener, Chairman and Editor, WHO symposium on The Zona-free Hamster Oocyte Penetration test in the Diagnosis of Male Infertility, Boston, Massachusetts, USA.
1986 The Walpole Prize, Society for the Study of Fertility, United Kingdom
1987 The Walpole Prize, Society for the Study of Fertility, United Kingdom
1989 1989 University of Catania Prize, Scientific Committee, Faculty of Medicine.
University of Catania, Italy.
1990 The Puvan Memorial Lecture. Opening Address of the 27th Malaysian Congress of Obstetrics and Gynaecology.
1990 The Jennifer Hallum Memorial Lecture. Royal College of Obstetricians and Gynaecologists,
1992 Honorary Professorship, Department of Obstetrics and Gynaecology, Faculty of Medicine, University of Edinburgh.
1994 Opening Address Thaddeus Mann Symposium. Seventh International Congress of Spermatology, Cairns, Australia.
1994 American Fertility Society State-of-the-Art Lecture. Annual Meeting, San Antonio, Texas,
1995 Elected a Fellow of the Royal Society of Edinburgh
1997 Plenary Lecture European Society of Human Reproduction and Embryology Congress 1997. Edinburgh Conference Centre.
1997 The Bruce Stewart Memorial Lecture 1997 American Urology Society Lecture, American Society for Reproductive Medicine, Cincinnati, OH, USA.
1998 The 1998 Amoroso Lecture. The human spermatozoon-a cell in crisis? Society for the Study of Fertility, Annual Meeting, University of Glasgow, UK
1998 Society for Male Reproduction/Urology Prize Paper. 16th World Congress on Fertility and Sterility/54th Annual Meeting of the American Society for Reproductive Medicine, San Francisco
1999 M.J. Edwards Lecture. Australian Birth Defects Society. University of Sydney.
2000 Best Poster Award. Combined meeting of the Society for Free Radical Research on Oxidants, Antioxidants and Nutrition and ComBio 2000. Wellington, New Zealand.
2002 Plenary Lecture, World Congress on Human Reproduction, Montreal, Canada
2003 Lloyd Cox memorial Lecture, University of Adelaide.
2004 The Founders Lecture, Society for the Study of Reproduction, Annual Meeting, Sydney.
Relevant Employment History:
1987-98 Special Appointment -Professorial Level
MRC Reproductive Biology Unit, University of Edinburgh,
1992-present Honorary Professorship, Faculty of Medicine, University of Edinburgh.
1982-1987 Senior Scientist
MRC Reproductive Biology Unit, University of Edinburgh.
1977-1982 Research Scientist Grade 1
MRC Reproductive Biology Unit, University of Edinburgh.
1976-1977 Chargé de Recherche
Faculte de Medicine, Universitie de Bordeaux.
1975-1976 Consultant Scientist
Human Reproduction Programme, World Health Organisation, Geneva.
1973-1975 MRC Post-Doctoral Fellowship
Department of Genetics, University of Edinburgh.
Publications and Presentations:
More than 350 peer review publications and more than 300 presentations at national and international meetings. Examples:
Angell, R.R., Aitken, R.J., Van Look, P.F.A., Lumsden, M.A. & Templeton, A.A. (1983) Chromosome abnormalities in human embryos after in vitro fertilization. Nature, 303, 336-338.
Aitken, R.J. & Clarkson, J.S. (1987) Cellular basis of defective sperm function and its association with the genesis of reactive oxygen species by human spermatozoa. Journal of Reproduction and Fertility, 83, 459-469.
This article was awarded the Walpole Memorial Prize and Lecture by the Society for the Study of Fertility
Henderson, C.J., Hulme, M.J. & Aitken, R.J. (1988) Contraceptive potential of antibodies to the zona pellucida. Journal of Reproduction and Fertility, 8, 325-343.
This article was awarded the Walpole Memorial Prize and Lecture by the Society for the Study of Fertility
Nasr-Esfahani, M, Aitken, R.J. & Johnson, M.H. (1990) The measurement of H2O2 levels in preimplantation embryos from blocking and non-blocking strains of mice. Development, 109, 501-507.
Aitken, R. J., M. Paterson, H. Fisher, D.W. Buckingham & Van Duin, M. (1995) Redox regulation of tyrosine phosphorylation in human spermatozoa is involved in the control of human sperm function. Journal of Cell Science, 108, 2017-2025.
Aitken, R. J., Buckingham, D.W. & Irvine, D.S. (1996) The extragenomic action of progesterone on human spermatozoa: evidence for a ubiquitous response that is rapidly down-regulated. Endocrinology 137, 3999-4009.
Twigg, J., Fulton, N., Gomez, E, Irvine D. S. & Aitken, R. J. (1998) Analysis of the impact of intracellular reactive oxygen species generation on the structural and functional integrity of human spermatozoa: lipid peroxidation, DNA fragmentation and effectiveness of antioxidants. Human Reproduction 13, 1429-1437. Featured as an ‘Outstanding Article’ by the journal
Aitken, R. J., Harkiss, D., Knox, W., Paterson, M. and Irvine, D. S. (1998) A novel signal transduction cascade in capacitating human spermatozoa characterized by a redox-regulated, cAMP-mediated induction of tyrosine phosphorylation. Journal of Cell Science 111, 645-656.
Aitken, R. J. (1999) The human spermatozoon: a cell in crisis? The Amoroso Lecture. Journal of Reproduction and Fertility 115, 1-7.
Aitken, R.J. & Marshall Graves, J. A. (2002) The Y chromosome, oxidative stress and the future of sex. Nature 415, 963.
Ecroyd, H., Asquith, K., Jones, R.C. & Aitken R.J. (2004) The development of signal transduction pathways during epididymal maturation is calcium dependent. Developmental Biology 268, 53-63.
Baker, M.A., Hetherington, L., Ecroyd, H. & Aitken, R.J. (2004) Analysis of the mechanism by which calcium negatively regulates the tyrosine phosphorylation cascade associated with sperm capacitation. Journal of Cell Science 117, 211-222.
Asquith, K. L., Baleato, R. M. McLaughlin, E. A., Nixon B. & Aitken R.J. (2004) Analysis of the mechanisms by which tyrosine phosphorylation regulates sperm-zona recognition in the mouse, a chaperone-mediated event? Journal of Cell Science 117, 3645-3657.
Aitken, R.J., Koopman, P. & Lewis S. E. (2004). Seeds of concern. Nature. 432, 48-52.
Full Text
Expert Review of Obstetrics & Gynecology
May 2008, Vol. 3, No. 3, Pages 267-271
(doi:10.1586/17474108.3.3.267)
Just how safe is assisted reproductive technology for treating male factor infertility?
R John Aitken
Sections: ChooseINTRODUCTIONThe male factorParental ageEnvironmental pollutionErrors of endogenous meta...Electromagnetic radiation...Epigenetic damageIs ART a dangerous form o...References
INTRODUCTION ChooseTop of pageINTRODUCTION The male factorParental ageEnvironmental pollutionErrors of endogenous meta...Electromagnetic radiation...Epigenetic damageIs ART a dangerous form o...References
Assisted reproductive technology (ART) has been responsible for the birth of over 3 million babies since the delivery of Louise Brown in the UK 28 years ago. Currently, one in 80–100 children born in the USA, one in 50 born in Sweden, one in 40 born in Australia and one in 24 born in Denmark are the product of this form of treatment. In 2003, more than 100,000 in vitro fertilization (IVF) cycles were reported from 399 clinics in the USA, resulting in the birth of more than 48,000 babies [1,101]. Worldwide, this figure has now exceeded 200,000 births per annum [2] and is continuing to rise. Indeed, it is a biological certainty that the more ART is used in one generation, the more it will be needed in the next. Given the cost of this form of treatment, and the fact that children born as a consequence of ART stand a 30–40% increased risk of birth defects [3], the current widespread use of assisted conception may constitute the beginnings of a serious public health problem.
The male factor ChooseTop of pageINTRODUCTIONThe male factor Parental ageEnvironmental pollutionErrors of endogenous meta...Electromagnetic radiation...Epigenetic damageIs ART a dangerous form o...References
There is general agreement that the two major reasons for patient referral to assisted conception programs are increased maternal age and male subfertility. The former can be easily reversed by public awareness and a change in social attitudes to family planning. However, the latter is a more intractable problem, as we have little or no understanding about the origins of this pathology. As a result, rational treatment or prevention of male infertility is all but impossible.
The importance of the male factor in human infertility has been highlighted by recent analyses of population trends in Denmark. This population has witnessed a steady decline in fertility rates in recent years, which is being addressed by increasing reliance on ART [4]. At the present time, 21% of young Danish men exhibit semen quality (in terms of sperm count and morphology) that falls below the internationally accepted thresholds of normality set by the WHO [5]. Moreover, it has been suggested that this situation is getting worse with the passage of time and, according to a recent publication [6]:
‘we may now have reached a level where semen quality of a significant segment of men in the population is so poor that it may contribute to the current widespread use of assisted reproduction’.
Although Denmark affords a particularly striking example of secular trends in male reproduction, semen quality in human males is notoriously poor. Indeed, it is a feature of the human condition, with at least one in 20 men in developed countries suffering from some level of infertility [7]. Most men produce sufficient numbers of spermatozoa to fertilize an egg in vivo; however, the gametes they generate have lost their biological potential for fertilization and the support of normal embryonic development. An important characteristic of these defective spermatozoa is a high level of DNA damage, which is, in turn, correlated with poor fertility, high rates of miscarriage and an increased incidence of disease in the offspring, including childhood cancer [8].
The use of such DNA-damaged spermatozoa in ART is thought to be a major contributor to the increased incidence of birth defects and other diseases seen in children conceived in vitro. Specifically, it has been proposed that the DNA damage brought into the fertilized egg by the spermatozoon may increase the mutational load carried by the embryo as a consequence of the aberrant or incomplete repair of this damage in the interval between fertilization and initiation of the first cleavage division [9,10]. Experimental verification of this relationship between DNA damage in the fertilizing sperm and embryo development has recently been secured in an animal model [11]. In these studies, intracytoplasmic sperm injection (ICSI) was performed in mice with fresh or DNA-damaged spermatozoa. Use of the latter was associated with poor preimplantation development and a reduction in the number of live births. Postnatal examination of the progeny revealed that the use of DNA-damaged spermatozoa in ICSI was associated with behavioral defects (increased anxiety, lack of habituation pattern, deficit in short-term spatial memory and age-dependent hypolocomotion in an open field test), the appearance of mesenchyme tumors, premature aging and a shortened lifespan. These results are supported by clinical data [8] and have profound implications for the safety of ICSI, which must frequently involve the use of DNA-damaged spermatozoa [12]. Currently, both the nature of this genetic damage and its origins are a matter of intense investigation. In terms of etiology, the ensuing paragraphs summarize data suggesting that paternal age, environmental toxicants, errors of endogenous metabolism and exposure to electromagnetic radiation are all potential contributors to DNA damage in the male germ line.
Parental age ChooseTop of pageINTRODUCTIONThe male factorParental age Environmental pollutionErrors of endogenous meta...Electromagnetic radiation...Epigenetic damageIs ART a dangerous form o...References
As men age they do not lose their capacity to generate spermatozoa; however, the quality of these gametes deteriorates. This change can be visualized as an age-dependent increase in DNA fragmentation in spermatozoa [13,14]. Paternal age is also widely recognized as a key factor in the etiology of dominant genetic diseases, such as Apert syndrome or achondroplasia [15]. Furthermore, genetic damage to the spermatozoa of aging males is thought to contribute to the etiology of more complex polygenic conditions such as autism, spontaneous schizophrenia and epilepsy [8]. Since older men tend to be married to older women it is significant that as oocytes age in the ovary, they suffer the depletion of several key genes involved in protection against oxidative stress and the maintenance of DNA integrity, including genes with a probable role in DNA repair [16]. Thus, age-related changes to the integrity of DNA in the spermatozoa are compounded by age-related declines in the oocytes’ capacity for DNA stabilization and repair. In combination, these factors could well make a significant contribution to the elevated incidence of birth defects associated with assisted conception therapy. Whichever way you look at it, aging and reproduction are incompatible bedfellows.
Environmental pollution ChooseTop of pageINTRODUCTIONThe male factorParental ageEnvironmental pollution Errors of endogenous meta...Electromagnetic radiation...Epigenetic damageIs ART a dangerous form o...References
An impact of environmental pollutants on DNA integrity in spermatozoa has been known for some time. For example, men who smoke heavily produce spermatozoa suffering from high levels of oxidative DNA damage. This does not necessarily impair the capacity of these cells for fertilization, however, it does impact upon the subsequent ability of the fertilized egg to develop normally. As a result, the children of heavy smokers stand a four- to fivefold increased chance of developing childhood cancer: a fact that is not often appreciated in the antismoking debate [9].
Recently, exposure of mice to particulate air pollution in an urban/industrial location has also been shown to induce high levels of DNA damage in spermatozoa [17]. Analyses of young men exposed to high levels of air pollution as a result of excessive coal combustion during Eastern European winters have substantiated these results in a clinical context [18]. Similarly, toxicological studies have demonstrated elevated levels of DNA damage in human spermatozoa, which are linked to the presence of metabolites of insecticides or persistent organochlorine pollutants in blood or urine [19,20]. Exposure to environmental endocrine disruptors, such as nonylphenol [21], as well as heavy metals [22], have also been demonstrated to induce oxidative DNA damage in human spermatozoa. Further resolution of the kinds of environmental pollutant that might be damaging to human spermatozoa is clearly needed. Elucidation of the significance of enzyme polymorphisms in defining an individual’s susceptibility to toxicant exposure is also required, as exemplified by a recent study demonstrating that men who are homozygous null for glutathione-S-transferase M1 are more likely to respond to air pollution with high levels of DNA damage in their spermatozoa than men possessing this isoform [23].
Errors of endogenous metabolism ChooseTop of pageINTRODUCTIONThe male factorParental ageEnvironmental pollutionErrors of endogenous meta... Electromagnetic radiation...Epigenetic damageIs ART a dangerous form o...References
Induction of DNA fragmentation in human spermatozoa is not solely due to exposure to environmental toxins, it can also result from errors of endogenous metabolism. An extremely important observation in this context is a recent preliminary report indicating that young male patients suffering from diabetes mellitus exhibit high levels of DNA damage in their spermatozoa [24]. These results have been confirmed in animal studies demonstrating that the experimental induction of diabetes in male mice is associated with oxidative stress and a postmeiotic genotoxic effect reflected in high rates of embryonic resorption in mated females [25]. Our laboratory has also demonstrated that endogenously generated estrogens, particularly catechol estrogens, can have a profound effect on DNA integrity in human spermatozoa, as a consequence of their inherent redox cycling activity [26]. Such studies reinforce the generally held view that most endogenously generated DNA damage in human spermatozoa is a consequence of oxidative stress [8,28]. If this is the case, then any ion (lead or cadmium), organic compound (phthalate ester), enzyme (NADPH oxidase), organelle (mitochondria) or cell (neutrophil), capable of generating reactive oxygen species in the vicinity of human spermatozoa is potentially capable of contributing to DNA damage in the male germ line [8–10,22,28]. In addition to oxidative damage, it is possible that in some patient’s sperm DNA is cleaved by the sequential action of topoisomerase IIB and an uncharacterized nuclease in a process analogous to apoptosis in somatic cells [29]. The relative significance of nuclease- and free radical-mediated mechanisms in the cleavage of sperm DNA, is a key issue that awaits resolution.
Electromagnetic radiation ChooseTop of pageINTRODUCTIONThe male factorParental ageEnvironmental pollutionErrors of endogenous meta...Electromagnetic radiation... Epigenetic damageIs ART a dangerous form o...References
Various forms of electromagnetic radiation are also known to have a detrimental effect on DNA integrity in the male germ line. A classic example is heat. The scrotum is designed to maintain the testes and epididymis slightly below core body temperature. It has been known for some time that elevated testicular temperature impairs spematogenesis. However, recent data have also indicated the ability of mild scrotal heat stress (42°C for 30 min) to induce DNA damage in epididymal mouse spermatozoa [30]. Radiofrequency electromagnetic radiation has also been demonstrated to induce DNA damage in epididymal sperm in animal models [31] and there are some reports of mobile phone exposure having a detrimental effect on semen quality in men [32]. Thus, any practice that elevates testicular temperature, such as wearing clothes or a sedentary occupation, or exacerbated exposure to other forms of electromagnetic radiation, such as excessive mobile phone use, are possible contributors to DNA damage in human spermatozoa.
Epigenetic damage ChooseTop of pageINTRODUCTIONThe male factorParental ageEnvironmental pollutionErrors of endogenous meta...Electromagnetic radiation...Epigenetic damage Is ART a dangerous form o...References
In some couples, the damage brought into the oocyte by the fertilizing spermatozoon may be epigenetic rather than genetic. These epigenetic factors are reviewed in an article in this edition of Expert Review of Obstetrics and Gynecology [31] and include: a functional centrosome to regulate cell division in the embryo; an appropriate pattern of chromatin remodeling; an appropriate population of mRNA and miRNA species that are carried into the zygote by the fertilizing spermatozoon and may play a role in the regulation of early embryonic development; and an appropriate pattern of DNA methylation. There are several recent papers indicating that the DNA methylation profile is dramatically altered in the spermatozoa of infertile men and we already know that the incidence of imprinting defects is elevated in children born as a result of ART [31,32]. The importance of epigenetic defects in the male germ line has recently been highlighted by analyses of vinclozolin, a fungicide used in the wine-making industry [33]. Transient embryonic exposure to vinclozolin in utero resulted in the birth of male offspring exhibiting a spermatogenenic defect. This defect was epigenetic in origin and was vertically transmitted through at least four generations.
Is ART a dangerous form of therapy? ChooseTop of pageINTRODUCTIONThe male factorParental ageEnvironmental pollutionErrors of endogenous meta...Electromagnetic radiation...Epigenetic damageIs ART a dangerous form o... References
Given the evidence that both IVF and ICSI are associated with a significant increase in birth defects, should ART be regarded as safe? On one hand, there is no denying that ART, and particularly ICSI, is an effective form of treatment for infertility. After 12 months approximately 90% of couples submitting to this form of therapy walk away with a baby. Furthermore, even though the risk of birth defects is significantly elevated following ART, the incidence is still relatively rare and should decrease as the field moves towards single-embryo transfers, thereby eliminating complications created by multiple births. Moreover, several clinical groups have trumpeted their ability to successfully perform ART in couples where the male partner’s spermatozoa exhibit high levels of DNA damage, without any obvious consequences as far as the health and wellbeing of the offspring are concerned [34]. These and other data tell us that even if DNA-damaged spermatozoa are used for assisted human conception, the risk of generating a visible phenotypic change in the offspring is extremely low.
However, we should also recognize that the absence of a pathological phenotype in the vast majority of children born as a result of ART, does not mean that the genome has not been damaged, or that the damage will not emerge in some future generation, as a result of mechanisms such as haploid insufficiency, the expression of X-linked defects in male offspring or the future creation of double-recessive combinations. It also does not mean that we will not find defects if we look hard enough. The controversial discovery of fertility-threatening Y-chromosome deletions in the offspring of genotypically normal males as a consequence of ART, is an example of a condition that may take 25–30 years to surface even though the mutation was probably created shortly after fertilization [35].
Clearly, we must continue to be vigilant in our long-term monitoring of the health and wellbeing of children produced by ART. Given recent advances in our understanding of epigenetic defects in the spermatozoa of infertile male patients, we should also extend this surveillance to the DNA methylation profiles of children born as a result of assisted conception. It is also incumbent upon embryologists to optimize the quality of the gametes that are used for ART, particularly where ICSI is involved. The development of prophylactic antioxidant therapies [36], improved culture conditions [37], novel gamete selection technologies [38] and noninvasive methods for the assessment of embryo quality [39] will all contribute to the future evolution of ART as a safe, effective means of treating human infertility.
Financial & competing interests disclosure
Aitken is a Consultant for NuSep. The author has no other relevant affiliations or financial involvement with any organization or entity with a financial interest in or financial conflict with the subject matter or materials discussed in the manuscript apart from those disclosed.
No writing assistance was utilized in the production of this manuscript.
References ChooseTop of pageINTRODUCTIONThe male factorParental ageEnvironmental pollutionErrors of endogenous meta...Electromagnetic radiation...Epigenetic damageIs ART a dangerous form o...References <<
Papers of special note have been highlighted as: • of interest •• of considerable interest
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2 Adamson GD, de Mouzon J, Lancaster P, Nygren KG, Sullivan E, Zegers-Hochschild F; International Committee for Monitoring Assisted Reproductive Technology. World collaborative report on in vitro fertilization, 2000. Fertil. Steril. 85, 1586–1622 (2006). [CrossRef] [Medline]
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•• Meta-analysis suggesting a 30–40% increased risk of birth defects associated with assisted reproductive technology (ART).
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• Recent review highlighting the declining fertility rates typical of the Danish population.
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8 Aitken RJ, De Iuliis GN. Origins and consequences of DNA damage in male germ cells. Reprod. Biomed. Online 14, 727–733 (2007)
•• Recent review of the causes and consequences of DNA damage in the male germ line.
[Medline]
9 Aitken RJ, Koopman P, Lewis SE. Seeds of concern. Nature 432, 48–52 (2004).
• Review of potential environmental impacts on DNA damage in the germ line.
[CrossRef] [Medline]
10 Aitken RJ, Krausz C. Oxidative stress, DNA damage and the Y chromosome. Reproduction 122, 497–506 (2001). [CrossRef] [Medline]
11 Fernández-Gonzalez R, Moreira P, Pérez-Crespo M et al. Long-term effects of mouse intracytoplasmic sperm injection with DNA-fragmented sperm on health and behavior of adult offspring. Biol. Reprod. 78(4), 761–72 (2008).
•• Important recent paper providing experimental evidence that the performance of intracytoplasmic sperm injection (ICSI) with DNA-damaged spermatozoa can have long-lasting impacts on the health and wellbeing of the offspring.
[CrossRef] [Medline]
12 Irvine DS, Twigg JP, Gordon EL, Fulton N, Milne PA, Aitken RJ. DNA integrity in human spermatozoa: relationships with semen quality. J. Androl. 21, 33–44 (2000). [Medline]
13 Schmid TE, Eskenazi B, Baumgartner A et al. The effects of male age on sperm DNA damage in healthy non-smokers. Hum. Reprod. 22, 180–187 (2007). [CrossRef] [Medline]
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15 Crow JF. The origins, patterns and implications of human spontaneous mutation. Nat. Rev. Genet. 1, 40–47 (2000). [CrossRef] [Medline]
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17 Yauk C, Polyzos A, Rowan-Carroll A et al. Germ-line mutations, DNA damage, and global hypermethylation in mice exposed to particulate air pollution in an urban/industrial location. Proc. Natl Acad. Sci. USA 105, 605–610 (2008).
•• Important recent paper clearly demonstrating the impact that air pollution has on the epigenetic programming and integrity of sperm DNA.
[CrossRef] [Medline]
18 Rubes J, Selevan SG, Evenson DP et al. Episodic air pollution is associated with increased DNA fragmentation in human sperm without other changes in semen quality. Hum. Reprod. 20, 2776–2783 (2005). [CrossRef] [Medline]
19 Rignell-Hydbom A, Rylander L, Giwercman A et al. Exposure to PCBs and p,p´-DDE and human sperm chromatin integrity. Environ. Health Perspect. 113, 175–179 (2005). [Medline]
20 Meeker JD, Singh NP, Ryan L et al. Urinary levels of insecticide metabolites and DNA damage in human sperm. Hum. Reprod. 19, 2573–2580 (2004). [CrossRef] [Medline]
21 Anderson D, Schmid TE, Baumgartner A, Cemeli-Carratala E, Brinkworth MH, Wood JM. Oestrogenic compounds and oxidative stress (in human sperm and lymphocytes in the COMET assay). Mutat. Res. 544, 173–178 (2003). [CrossRef] [Medline]
22 Xu DX, Shen HM, Zhu QX et al. The associations among semen quality, oxidative DNA damage in human spermatozoa and concentrations of cadmium, lead and selenium in seminal plasma. Mutat. Res. 534, 155–163 (2003). [Medline]
23 Rubes J, Selevan SG, Sram RJ, Evenson DP, Perreault SD. GSTM1 genotype influences the susceptibility of men to sperm DNA damage associated with exposure to air pollution. Mutat. Res. 625, 20–28 (2007). [Medline]
24 Agbaje IM, Rogers DA, McVicar CM et al. Insulin dependant diabetes mellitus: implications for male reproductive function. Hum. Reprod. 22, 1871–1877 (2007).
• Sentinel paper indicating that diabetic patients possess high levels of DNA damage in their spermatozoa.
[CrossRef] [Medline]
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26 Bennetts LE, De Iuliis GN, Nixon B et al. Analysis of the impact of estrogenic compounds on DNA integrity in the male germ line. Mutat. Res. (2007) (In Press).
27 Wang X, Sharma RK, Sikka SC, Thomas AJ Jr, Falcone T, Agarwal A. Oxidative stress is associated with increased apoptosis leading to spermatozoa DNA damage in patients with male factor infertility. Fertil. Steril. 80, 531–535 (2003). [CrossRef] [Medline]
28 Aitken RJ, Baker HW. Seminal leukocytes: passengers, terrorists or good samaritans? Hum. Reprod. 10, 1736–1739 (1995).
•• Discussion of the significance of leukocytic infiltration in the origins of oxidative stress in the male reproductive tract.
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29 Shaman JA, Yamauchi Y, Ward WS. Sperm DNA fragmentation: awakening the sleeping genome. Biochem. Soc. Trans. 35, 626–628 (2007). [CrossRef] [Medline]
30 Banks S, King SA, Irvine DS, Saunders PT. Impact of a mild scrotal heat stress on DNA integrity in murine spermatozoa. Reproduction 129, 505–514 (2005). [CrossRef] [Medline]
31 Carrell DT. Paternal genetic and epigenetic influences on IVF outcome. Expert Rev. Obstet. Gynecol. 3(3), 359–367 (2008). [Abstract]
32 Houshdaran S, Cortessis VK, Siegmund K, Yang A, Laird PW, Sokol RZ. Widespread epigenetic abnormalities suggest a broad DNA methylation erasure defect in abnormal human sperm. PLoS ONE 2, e1289 (2007). [CrossRef]
33 Anway MD, Cupp AS, Uzumcu M, Skinner MK. Epigenetic transgenerational actions of endocrine disruptors and male fertility. Science 308, 1466–1469 (2005). [CrossRef] [Medline]
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35 Feng C, Wang LQ, Dong MY, Huang HF. Assisted reproductive technology may increase clinical mutation detection in male offspring. Fertil. Steril. (2008) (Epub ahead of print).
• Recent publication indicating that the treatment of male infertility patients with ART is associated with the de novo appearance of Y chromosome deletions in the offspring.
36 Greco E, Iacobelli M, Rienzi L, Ubaldi F, Ferrero S, Tesarik J. Reduction of the incidence of sperm DNA fragmentation by oral antioxidant treatment. J. Androl. 26, 349–353 (2005). [CrossRef] [Medline]
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Website 101 Australian Babies. 4102.0. Australian Social Trends. Australian Bureau of Statistics (2007). www.abs.gov.au/AUSSTATS
Affiliations
R John Aitken
Laureate Professor of Biological Sciences, Faculty of Science and IT, University of Newcastle, Callaghan, NSW 2308, Australia. john.aitken@newcastle.edu.au
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