Sperm DNA can be damaged due to a multitude of different noxae, which include disease, and occupational and environmental factors. Depending on the magnitude of the damage, such lesions may be repaired by the oocyte or the embryo. If this is not possible, a permanent damage can be manifested leading to mutations of the male genome. In cases where the oocyte or the embryo does not counter these damages to the male genome in terms of repair or an early abortion, sperm DNA damage and fragmentation can be a cause of numerous diseases including childhood cancer.
AgarwalAAllamaneniSSR. The effect of sperm DNA damage on assisted reproduction outcomes. A review. Minerva Ginecol2004; 56:235–45.
2.
AgarwalADeepinderFSharmaRKRangaGLiJ. Effect of cell phone usage on semen analysis in men attending infertility clinic: an observational study. Fertil Steril2008; 89:124–8.
3.
AgarwalADesaiNRMakkerKVargheseAMouradiRSabaneghESharmaR. Effects of radiofrequency electromagnetic waves (RF-EMW) from cellular phones on human ejaculated semen: an in vitro pilot study. Fertil Steril2009; 92:1318–25.
4.
AgarwalASaidTM. Oxidative stress, DNA damage and apoptosis in male infertility: a clinical approach. BJU Int2005; 95:503–7.
5.
AgarwalASalehRA. Role of oxidants in male infertility: rational, significance and treatment. Urol Clin N Am2002; 29:817–27.
6.
AgarwalA. Semen banking in patients with cancer: 20-year experience. Int J Androl2000; 23Suppl 2:16–9.
7.
AhmadiANgSC. Developmental capacity of damaged spermatozoa. Hum Reprod1999; 14:2279–85.
8.
AitkenRJBuckinghamDWBrindleJGomezEBakerHWIrvineDS. Analysis of sperm movement in relation to the oxidative stress created by leukocytes in washed sperm preparations and seminal plasma. Hum Reprod1995b; 10:2061–71.
9.
AitkenRJClarksonJSFishelS. Generation of reactive oxygen species, lipid peroxidation, and human sperm function. Biol Reprod1989; 40:183–97.
10.
AitkenRJDe IuliisGNMcLachlanRI. Biological and clinical significance of DNA damage in the male germ line. Int J Androl2009; 32:46–56.
11.
AitkenRJFisherHMFultonNGomezEKnoxWLewisBIrvineS. Reactive oxygen species generation by human spermatozoa is induced by exogenous NADPH and inhibited by the flavoprotein inhibitors diphenylene iodonium and quinacrine. Mol Reprod Dev1997; 47:468–82.
12.
AitkenRJGordonEHarkissDTwiggJPMilnePJenningsZIrvineDS. Relative impact of oxidative stress on the functional competence and genomic integrity of human spermatozoa. Biol Reprod1998; 59:1037–46.
13.
AitkenRJKrauszC. Oxidative stress, DNA damage and the Y chromosome. Reproduction2001; 122:497–506.
14.
AitkenRJPatersonMFisherHBuckinghamDWvan DuinM. Redox regulation of tyrosine phosphorylation in human spermatozoa and its role in the control of human sperm function. J Cell Sci1995a; 108:2017–25.
15.
AitkenRJSawyerD. The human spermatozoon – not waving but drowning. Adv Exp Med Biol2003; 518:85–98.
16.
AlvarezJGLewisS. Sperm chromatin structure assay parameters measured after density gradient centrifugation are not predictive of the outcome of ART. Hum Reprod2008; 23:1235–6.
17.
AlvarezJGSharmaRKOlleroMSalehRALopezMCThomasAJEvensonDPAgarwalA. Increased DNA damage in sperm from leukocytospermic semen samples as determined by the sperm chromatin structure assay. Fertil Steril2002; 78:319–29.
18.
AmannRP. Can the fertility potential of a seminal sample be predicted accurately?J Androl1989; 10:89–98.
19.
AndersonKNisenblatVNormanR. Lifestyle factors in people seeking infertility treatment — A review. Aust N Z J Obstet Gynaecol2010; 50:8–20.
20.
AndersonSBankierATBarrellBGde BruijnMHCoulsonARDrouinJEperonICNierlichDPRoeBASangerFSchreierPHSmithAJStadenRYoungIG. Sequence and organisation of the human mitochondrial genome. Nature1981; 290:457–65.
21.
AnseriniPChiodiSSpinelliSCostaMConteNCopelloFBacigalupoA. Semen analysis following allogeneic bone marrow transplantation. Additional data for evidence-based counselling. Bone Marrow Transplant2002; 30:447–51.
22.
AokiVWCarrellDT. Human protamines and the developing spermatid: their structure, function, expression and relationship with male infertility. Asian J Androl2003; 5:315–24.
23.
AokiVWLiuLCarrellDT. Identification and evaluation of a novel sperm protamine abnormality in a population of infertile males. Hum Reprod2005; 20:1298–306.
24.
AzizNSalehRASharmaRKLewis-JonesIEsfandiariNThomasAJJr.AgarwalA. Novel association between sperm reactive oxygen species production, sperm morphological defects, and the sperm deformity index. Fertil Steril2004; 81:349–54.
25.
BalhornR. A model for the structure of chromatin in mammalian sperm. J Cell Biol1982; 93:298–305.
26.
BanksSKingSAIrvineDSSaundersPT. Impact of a mild scrotal heat stress on DNA integrity in murine spermatozoa. Reproduction2005; 129:505–14.
27.
BartoovBBerkovitzAEltesFKogosowskiAMenezoYBarakY. Real-time fine morphology of motile human sperm cells is associated with IVF-ICSI outcome. J Androl2002; 23:1–8.
28.
BartoovBBerkovitzAEltesFKogosovskyAYagodaALedermanHArtziSGrossMBarakY. Pregnancy rates are higher with intracytoplasmic morphologically selected sperm injection than with conventional intracytoplasmic injection. Fertil Steril2003; 80:1413–9.
29.
BarrattCLAitkenRJBjörndahlLCarrellDTde BoerPKvistULewisSEPerreaultSDPerryMJRamosLRobaireBWardSZiniA. Sperm DNA: organization, protection and vulnerability: from basic science to clinical applications–a position report. Hum Reprod2010; 25:824–38.
30.
BellverJMeseguerMMurielLGarcia-HerreroSBarretoMAGardaALRemohiJPellicerAGarridoN. Y chromosome microdeletions, sperm DNA fragmentation and sperm oxidative stress as causes of recurrent spontaneous abortion of unknown etiology. Hum Reprod2010; 25:1713–21.
31.
BianQXuLCWangSLXiaYKTanLFChenJFSongLChangHCWangXR. Study on the relation between occupational fenvalerate exposure and spermatozoa DNA damage of pesticide factory workers. Occup Environ Med2004; 61:999–1005.
32.
BianchiPGManicardiGCBizzaroDBianchiUSakkasD. Effect of deoxyribonucleic acid protamination on fluorochrome staining and in situ nick-translation of murine and human mature spermatozoa. Biol Reprod1993; 49:1083–8.
33.
BizzaroDManicardiGBianchiPGSakkasD. Sperm decondensation during fertilization in the mouse: presence of DNase I hypersensitive sites in situ and a putative role for topoisomerase II. Zygote2000; 8:197–202.
34.
Blanco-RodriguezJMartinez-GarciaC. Apoptosis is physiologically restricted to a specialized cytoplasmic compartment in rat spermatids. Biol Reprod1999; 61:1541–7.
35.
Blanco-RodriguezJ. A matter of death and life: the significance of germ cell death during spermatogenesis. Int J Androl1998; 21:236–48.
36.
BoitrelleFFerfouriFPetitJMSegretainDTourainCBergereMBaillyMVialardFAlbertMSelvaJ. Large human sperm vacuoles observed in motile spermatozoa under high magnification: nuclear thumbprints linked to failure of chromatin condensation. Hum Reprod2011; 26:1650–8.
37.
BondeJPStorgaardL. How work-place conditions, environmental toxicants and lifestyle affect male reproductive function. Int J Androl2002; 25:262–8.
38.
BondeJP. Semen quality in welders exposed to radiant heat. Br J Ind Med1992; 49:5–10.
39.
BrackenMBEskenaziBSachseKMcSharryJEHellenbrandKLeo-SummersL. Association of cocaine use with sperm concentration, motility, and morphology. Fertil Steril1990; 53:315–22.
40.
BraunRE. Every sperm is sacred–or is it?Nat Genet1998; 18:202–4.
41.
BrinkworthMH. Paternal transmission of genetic damage: findings in animals and humans. Int J Androl2000; 23:123–35.
42.
BuchJPKolonTFMaulikNKreutzerDLDasDK. Cytokines stimulate lipid membrane peroxidation of human sperm. Fertil Steril1994; 62:186–8.
43.
CarrellDTLiuL. Altered protamine 2 expression is uncommon in donors of known fertility, but common among men with poor fertilizing capacity, and may reflect other abnormalities of spermiogenesis. J Androl2001; 22:604–10.
44.
CastroFOHernandezOUliverCSolanoRMilanesCAguilarAPerezAde ArmasRHerreraLde la FuenteJ. Introduction of foreign DNA into the spermatozoa of farm animals. Theriogenology1990; 34:1099–110.
45.
CentolaGMKellerJWHenzlerMRubinP. Effect of low-dose testicular irradiation on sperm count and fertility in patients with testicular seminoma. J Androl1994; 15:608–13.
46.
ChanceBSiesHBoverisH. Hydroperoxide metabolism in mammalian organs. Physiol Rev1979; 59:527–605.
47.
ChanceBWilliamsGR. The respiratory chain and oxidative phosphorylation. Adv Enzymol Biochem1956; 17:65–134.
48.
ChangFWSunGHChengYYChenICChienHHWuGJ. Effects of varicocele upon the expression of apoptosis-related proteins. Andrologia2010; 42:225–30.
49.
ChatterjeeRHainesGAPereraDMDGoldstoneAMorrisID. Testicular and sperm DNA damage after treatment with fludarabine for chronic lymphocytic leukaemia. Hum Reprod2000; 15:762–6.
50.
ChenJLLongoFJ. Expression and localization of DNA topoisomerase II during rat spermatogenesis. Mol Reprod Dev1996; 45:61–71.
51.
ComhaireFHMahmoudAMDepuydtCEZalataAAChristopheAB. Mechanisms and effects of male genital tract infection on sperm quality and fertilizing potential: the andrologist's viewpoint. Hum Reprod Update1999; 5:393–8.
52.
CookeMSEvansMDDizdarogluMLunecJ. Oxidative DNA damage: mechanisms, mutation, and disease. FASEB J2003; 17:1195–214.
53.
CroteauDLBohrVA. Repair of oxidative damage to nuclear and mitochondrial DNA in mammalian cells. J Biol Chem1997; 272:25409–12.
54.
CroteauDLStierumRHBohrVA. Mitochondrial DNA repair pathways. Mutat Res1999; 434:137–48.
55.
CuiJHolmesEHGreeneTGLiuPK. Oxidative DNA damage precedes DNA fragmentation after experimental stroke in rat brain. FASEB J2000; 14:955–67.
56.
CurtisKMSavitzDAArbuckleTE. Effects of cigarette smoking, caffeine consumption, and alcohol intake on fecundability. Am J Epidemiol1997; 146:32–41.
57.
De IuliisGNNeweyRJKingBVAitkenRJ. Mobile phone radiation induces reactive oxygen species production and DNA damage in human spermatozoa in vitro. PLoS One2009; 4:e6446.
58.
De IuliisGNWingateJKKoppersAJMcLaughlinEAAitkenRJ. Definitive evidence for the nonmitochondrial production of superoxide anion by human spermatozoa. J Clin Endocrinol Metab2006; 91:1968–75.
59.
de LamirandeEGagnonC. Capacitation-associated production of superoxide anion by human spermatozoa. Free Radic Biol Med1995; 18:487–95.
60.
de LamirandeEGagnonC. Human sperm hyperactivation and capacitation as parts of an oxidative process. Free Radical Biol Med1993; 14:157–66.
61.
DerijckAvan der HeijdenGGieleMPhilippensMde BoerP. DNA double-strand break repair in parental chromatin of mouse zygotes, the first cell cycle as an origin of de novo mutation. Hum Mol Genet2008; 17:1922–37.
62.
De RosaMZarrilliSPaesanoLCarboneUBoggiaBPetrettaMMaistoACimminoFPucaGColaoALombardiG. Traffic pollutants affect fertility in men. Hum Reprod2003; 18:1055–61.
63.
DesaiNRKesariKKAgarwalA. Pathophysiology of cell phone radiation: oxidative stress and carcinogenesis with focus on male reproductive system. Reprod Biol Endocrinol2009; 7:114.
64.
DiemerTHuwePLudwigMHauckEWWeidnerW. Urogenital infection and sperm motility. Andrologia2003a; 35:283–7.
65.
DiemerTHuwePLudwigMSchroeder-PrintzenIMichelmannHWSchieferHGWeidnerW. Influence of autogenous leucocytes and Escherichia coli on sperm motility parameters in vitro. Andrologia2003b; 35:100–5.
66.
DiMauroSDavidzonG. Mitochondrial DNA and disease. Ann Med2005; 37:222–32.
67.
DuranEHMorshediMTaylorSOehningerS. Sperm DNA quality predicts intrauterine insemination outcome: a prospective cohort study. Hum Reprod2002; 17:3122–8.
68.
Eggert-KruseWKieferIBeckCDemirakcaTStrowitzkiT. Role for tumor necrosis factor alpha (TNF-alpha) and interleukin 1-beta (IL-1beta) determination in seminal plasma during infertility investigation. Fertil Steril2007; 87:810–23.
69.
EguchiJKojiTNomataKYoshiiAShinMKanetakeH. Fas-Fas ligand system as a possible mediator of spermatogenic cell apoptosis in human maturation-arrested testes. Hum Cell2002; 15:61–8.
70.
El-DomyatiMMAl-DinABBarakatMTEl-FakahanyHMXuJSakkasD. Deoxyribonucleic acid repair and apoptosis in testicular germ cells of aging fertile men: the role of the poly(adenosine diphosphate-ribosyl)ation pathway. Fertil Steril2009; 91 (Suppl 5): 2221–9.
71.
ErogulOOztasEYildirimIKirTAydurEKomesliGIrkilataHCIrmakMKPekerAF. Effects of electromagnetic radiation from a cellular phone on human sperm motility: an in vitro study. Arch Med Res2006; 37:840–3.
72.
FabricantJDLegatorMSAdamsPM. Post-meiotic cell mediation of behavior in progeny of male rats treated with cyclophosphamide. Mutat Res1983; 119:185–190.
73.
FejesIZavaczkiZSzöllosiJKoloszarSDaruJKovacsLPalA. Is there a relationship between cell phone use and semen quality?Arch Androl2005; 51:385–93.
74.
FensterLKatzDFWyrobekAJPieperCRempelDMOmanDSwanSH. Effects of psychological stress on human semen quality. J Androl1997; 18:194–202.
75.
Figa-TalamancaICiniCVarricchioGCDonderoFGandiniLLenziALombardoFAngelucciLDi GreziaRPatacchioliFR. Effects of prolonged autovehicle driving on male reproduction function: a study among taxi drivers. Am J Ind Med1996; 30:750–8.
76.
FolgeroTBertheussenKLindalSTorbergsenTOianP. Mitochondrial disease and reduced sperm motility. Hum Reprod1993; 8:1863–8.
77.
FraczekMSzumala-KakolAJedrzejczakPKamienicznaMKurpiszM. Bacteria trigger oxygen radical release and sperm lipid peroxidation in in vitro model of semen inflammation. Fertil Steril2007; 88 (4 Suppl): 1076–85.
78.
FragaCGMotchnikPAShigenagaMKHelbockHJJacobRAAmesBN. Ascorbic acid protects against endogenous oxidative DNA damage in human sperm. Proc Natl Acad Sci USA1991; 88:11003–6.
79.
FragaCGMotchnikPAWyrobekAJRempelDMAmesBN. Smoking and low antioxidant levels increase oxidative damage to sperm DNA. Mutat Res1996; 351:199–203.
80.
FrancoJGJrMauriALPetersenCGMassaroFCSilvaLFFelipeVCavagnaMPontesABaruffiRLOliveiraJBVagniniLD. Large nuclear vacuoles are indicative of abnormal chromatin packaging in human spermatozoa. Int J Androl2011; Apr 28. doi: 10.1111/j.1365-2605.2011.01154.x. [Epub ahead of print]
GandiniLLombardoFPaoliDCarusoFEleuteriPLeterGCiriminnaRCulassoFDonderoFLenziASpanoM. Full-term pregnancies achieved with ICSI despite high levels of sperm chromatin damage. Hum Reprod2004; 19:1409–17.
83.
GarridoNMeseguerMSimonCPellicerARemohiJ. Pro-oxidative and anti-oxidative imbalance in human semen and its relation with male fertility. Asian J Androl2004; 6:59–65.
84.
GatewoodJMCookGRBalhornRSchmidCWBradburyEM. Isolation of four core histones from human sperm chromatin representing a minor subset of somatic histones. J Biol Chem1990; 265:20662–6.
85.
GenerosoWMCattanachBMalashenkoAM. Mutagenicity of selected chemicals in mammals; the heritable translocation test. In: de SerresFJShelbyMD (eds.). Comparative Chemical Mutagenesis. New York, Plenum Press; 1981: 681–707.
86.
GinsburgESYanushpolskyEHJacksonKV. In vitro fertilization for cancer patients and survivors. Fertil Steril2001; 75:705–10.
GoldsteinMEidJF. Elevation of intratesticular and scrotal skin surface temperature in men with varicocele. J Urol1989; 142:743–5.
89.
GomezEBuckinghamDBrindleJLanzafameFIrvineDSAitkenRJ. Development of an image analysis system to monitor the retention of residual cytoplasm by human spermatozoa: correlation with biochemical markers of the cytoplasmic space, oxidative stress and sperm function. J Androl1996; 17:276–87.
90.
GorczycaWTraganosFJesionowskaHDarzynkiewiczZ. Presence of DNA strand breaks and increased sensitivity of DNA in situ to denaturation in abnormal human sperm cells: analogy to apoptosis of somatic cells. Exp Cell Res1993; 207:202–5.
91.
HaidlGBaduraBSchillWB. Function of human epididymal spermatozoa. J Androl1994; 15Suppl: 23S–27S.
92.
HalliwellB. The antioxidant paradox. Lancet2000; 355:1179–80.
93.
AmannRPHammerstedtRH. In vitro evaluation of sperm quality: an opinion. J Androl1993; 14:397–406.
94.
HammoudAOGibsonMPetersonCMMeikleAWCarrellDT. Impact of male obesity on infertility: a critical review of the current literature. Fertil Steril2008; 90:897–904.
95.
HanawaltPC. Transcription-coupled repair and human disease. Science1994; 266:1957–8.
96.
HarroukWCodringtonAVinsonRRobaireBHalesBF. Paternal exposure to cyclophosphamide induces DNA damage and alters the expression of DNA repair genes in the rat preimplantation embryo. Mutat Res2000; 461:229–41.
97.
HauserRMeekerJDSinghNPSilvaMJRyanLDutySCalafatAM. DNA damage in human sperm is related to urinary levels of phthalate monoester and oxidative metabolites. Hum Reprod2007; 22:688–95.
98.
HeerdtBGHoustonMAAnthonyGMAugenlichtLH. Mitochondrial membrane potential (delta psi(mt)) in the coordination of p53-independent proliferation and apoptosis pathways in human colonic carcinoma cells. Cancer Res1998; 58:2869–75.
99.
HendinBNKolettisPNSharmaRKThomasAJJr.AgarwalA. Varicocele is associated with elevated spermatozoal reactive oxygen species production and diminished seminal plasma antioxidant capacity. J Urol1999; 161:1831–4.
100.
HenkelRBastiaanHSSchüllerSHoppeIStarkerWMenkveldR. Leukocytes and intrinsic ROS production may be factors compromising sperm chromatin condensation status. Andrologia2010a; 42:69–75.
101.
HenkelRFransmanWHiplerUCWiegandCSchreiberGMenkveldRWeitzFFisherD (2011); Typha capensis (Rohrb.) N. E. Br. (bulrush) extract scavenges free radicals, inhibits collagenase activity and affects human sperm motility and mitochondrial membrane potential in vitro: a pilot study. Andrologia 2011 Jul 6. doi: 10.1111/j.1439-0272.2011.01179.x. [Epub ahead of print]
102.
HenkelRHajimohammadMStalfTHoogendijkCMehnertCMenkveldRGipsHSchillW-BKrugerTF. Influence of deoxyribonucleic acid damage on fertilization and pregnancy. Fertil Steril2004; 81:965–72.
103.
HenkelRHoogendijkCFBouicPJDKrugerTF. TUNEL assay and SCSA determine different aspects of sperm DNA damage. Andrologia2010b; 42:305–13.
104.
HenkelRKierspelEHajimohammadMStalfTHoogendijkCMehnertCMenkveldRSchillW-BKrugerTF. DNA fragmentation of spermatozoa and ART. Reprod Biomed Online2003; 7:477–84.
105.
HenkelRKierspelEStalfTMehnertCMenkveldRTinnebergHRSchillWBKrugerTF. Effect of reactive oxygen species produced by spermatozoa and leukocytes on sperm functions in non-leukocytospermic patients. Fertil Steril2005a; 83:635–42.
106.
HenkelRLudwigMSchuppeHCDiemerTSchillWBWeidnerW. Chronic pelvic pain syndrome/chronic prostatitis affect the acrosome reaction in human spermatozoa. World J Urol2006; 24:39–44.
107.
HenkelRMaaßGBödekerR-HScheibelhutCStalfTMehnertCSchuppeHCJungASchillW-B. Sperm function and assisted reproduction technology. Reprod Med Biol2005b; 4:7–30.
108.
HenkelRMaaßGJungAHaidlGSchillWBSchuppeHC. Age-related changes in seminal polymorphonuclear elastase in men with asymptomatic inflammation of the genital tract. Asian J Androl2007; 9:299–304.
109.
HenkelRSchillW-B. Sperm separation in patients with urogenital infections. Andrologia1998; 30 (Suppl. 1): 91–7.
110.
HenkelR. Detection of DNA damage in sperm. In: KrugerTFOehningerS, (eds.); Male Infertility — Diagnosis and Treatment; 2007; Informa UK Ltd., Oxon, UK; pp. 225–38.
111.
HiranoT. The ABCs of SMC proteins: two-armed ATPases for chromosome condensation, cohesion, and repair. Genes Dev2002; 16:399–414.
112.
HostELindenbergSSmidt-JensenS. DNA strand breaks in human spermatozoa: Correlation with fertilization in vitro in oligozoospermic men and in men with unexplained infertility. Acta Obstet Gynecol Scand2000; 79:189–93.
113.
HowellSJShaletSM. Testicular function following chemotherapy. Hum Reprod Update2001; 7:363–9.
114.
HoyesKPLordBIMcCannCHendryJHMorrisID. Transgenerational effects of procenception paternal contamination with (55) Fe. Rad Res2001; 156:488–94.
115.
HuangCLiJZhengRCuiK. Hydrogen peroxide-induced apoptosis in human hepatoma cells is mediated by CD95(APO-1/Fas) receptor/ligand system and may involve activation of wild-type p53. Mol Biol Rep2000; 27:1–11.
116.
HuckinsC. The morphology and kinetics of spermatogonial degeneration in normal adult rats: an analysis using a simplified classification of the germinal epithelium. Anat Rec1978; 190:905–26.
117.
HullMGGlazenerCMKellyNJConwayDIFosterPAHintonRACoulsonCLambertPAWattEMDesaiKM. Population study of causes, treatment, and outcome of infertility. Br Med J (Clin Res Ed)1985; 291:1693–7.
118.
In't VeldPBrandenburgHVerhoeffADhontMLosF. Sex chromosomal abnormalities and intracytoplasmic sperm injection. Lancet1995; 346:773.
119.
IwasakiAGagnonC. Formation of reactive oxygen species in spermatozoa of infertile patients. Fertil Steril1992; 57:409–16.
120.
JacobABarkerHGoodmanAHolmesJ. Recovery of spermatogenesis following bone marrow transplantation. Bone Marrow Transplant1998; 22:277–9.
121.
JiBTShuXOLinetMSZhengWWacholderSGaoYTYingDMJinF. Paternal cigarette smoking and the risk of childhood cancer among offspring of non-smoking mothers. J Natl Canc Inst1997; 89:238–44.
122.
JohnsonCCSpitzMR. Childhood nervous system tumors: an assessment of risk associated with paternal occupations involving use, repair, or manufacture of electrical and electronic equipment. Int J Epidemiol1989; 18:756–762.
123.
KasaiTOgawaKMizunoKNagaiSUchidaYOhtaSFujieMSuzukiKHirataSHoshiK. Relationship between sperm mitochondrial membrane potential, sperm motility, and fertility potential. Asian J Androl2002; 4:97–103.
124.
KeatingJGrundyCEFiveyPSElliottMRobinsonJ. Investigation of the association between the presence of cytoplasmic residues on the human sperm midpiece and defective sperm function. J Reprod Fertil1997; 110:71–7.
125.
Klonoff-CohenH. Female and male lifestyle habits and IVF: what is known and unknown. Hum Reprod Update2005; 11:179–203.
126.
KocakIYeniseyCDündarMOkyayPSerterM. Relationship between seminal plasma interleukin-6 and tumor necrosis factor alpha levels with semen parameters in fertile and infertile men. Urol Res2002; 30:263–7.
127.
KodamaHYamaguchiRFukudaJKasaiHTanakaT. Increased oxidative deoxyribonucleic acid damage in the spermatozoa of infertile male patients. Fertil Steril1997; 68:519–24.
128.
KöhnFMErdmannIOedaTel MullaKFSchieferHGSchillWB. Influence of urogenital infections on sperm functions. Andrologia1998; 30Suppl 1: 73–80.
129.
KoppersAJDe IuliisGNFinnieJMMcLaughlinEAAitkenRJ. Significance of mitochondrial reactive oxygen species in the generation of oxidative stress in spermatozoa. J Clin Endocrinol Metab2008; 93:3199–207.
130.
KoppersAJGargMLAitkenRJ. Stimulation of mitochondrial reactive oxygen species production by unesterified, unsaturated fatty acids in defective human spermatozoa. Free Radic Biol Med2010; 48:112–9.
131.
KoppersAJMitchellLAWangPLinMAitkenRJ. Phosphoinositide-3-kinase signaling pathway involvement in a truncated apoptotic cascade associated with motility loss and oxidative DNA damage in human spermatozoa. Biochem J2011; 436:687–8.
132.
KortHIMasseyJBElsnerCWMitchell-LeefDShapiroDBWittMARoudebushWE. Impact of body mass index values on sperm quantity and quality. J Androl2006; 27:450–2.
133.
KowaltowskiAJVercesiAE. Mitochondrial damage induced by conditions of oxidative stress. Free Radic Biol Med1999; 26:463–71.
134.
KrawetzSADixonGH. Sequence similarities of the protamine genes: implications for regulation and evolution. J Mol Evol1988; 27:291–7.
135.
KurinczukJJBowerC. Birth defects in infants conceived by intracytoplasmic sperm injection: an alternative interpretation. BMJ1997; 315:1260–5.
136.
LachaudCTesarikJCanadasMLMendozaC. Apoptosis and necrosis in human ejaculated spermatozoa. Hum Reprod2004; 19:607–10.
137.
LavitranoMFrenchDZaniMFratiLSpadaforaC. The interaction between exogenous DNA and sperm cells. Mol Reprod Dev1992; 31:161–9.
138.
LavitranoMMaioneBForteEFrancoliniMSperandioSTestiRSpadaforaC. The interaction of sperm cells with exogenous DNA: a role of CD4 and major histocompatibility complex class II molecules. Exp Cell Res1997; 233:56–62.
139.
LeeJRichburgJHYounkinSCBoekelheideK. The Fas system is a key regulator of germ cell apoptosis in the testis. Endocrinology1997; 138:2081–8.
140.
LestiennePReynierPChretienMFPenisson-BesnierIMalthieryYRohmerV. Oligoasthenospermia associated with multiple mitochondrial DNA rearrangements. Mol Hum Reprod1997; 3:811–4.
141.
LewisSE. Is sperm evaluation useful in predicting human fertility?Reproduction2007; 134:31–40.
142.
LewisSEMO'ConnellMStevensonMThompson-CreeLMcClureN. An algorithm to predict pregnancy in assisted reproduction. Hum Reprod2004; 19:1385–94.
143.
LewisSEMSterlingESLYoungISThompsonW. Comparison of individual antioxidants of sperm and seminal plasma in fertile and infertile men. Fertil Steril1997; 67:142–7.
144.
LoftSKold-JensenTHjollundNHGiwercmanAGyllemborgJErnstEOlsenJScheikeTEnghusen PoulsenHBondeJP. Oxidative DNA damage in human sperm influences time to pregnancy. Hum Reprod2003; 18:1265–72.
145.
LopesSSunJGJurisicovaAMerianoJCasperRF. Sperm deoxyribonucleic acid fragmentation is increased in poor-quality semen samples and correlates with failed fertilization in intracytoplasmic sperm injection. Fertil Steril1998; 69:528–32.
146.
LordBI. Transgenerational susceptibility to leukaemia induction resulting from preconception, paternal irradiation. Int J Rad Biol1999; 75:801–10.
147.
LowengartRAPetersJMCiconiCBuckleyJBernsteinLPreston-MartinSRappaportE. Childhood leukemia and parent's occupational and home exposures. J Natl Cancer Inst1987; 79:39–46.
148.
LuczajWSkrzydlewskaE. DNA damage caused by lipid peroxidation products. Cell Mol Biol Lett2003; 8:391–413.
149.
MaioneBPittoggiCAcheneLLorenziniRSpadaforaC. Activation of endogenous nucleases in mature sperm cells upon interaction with exogenous DNA. DNA Cell Biol1997; 16:1087–97.
150.
MarchettiCObertGDeffosezAFormstecherPMarchettiP. Study of mitochondrial membrane potential, reactive oxygen species, DNA fragmentation and cell viability by flow cytometry in human sperm. Hum Reprod2002; 17:1257–65.
151.
MarconLBoissonneaultG. Transient DNA strand breaks during mouse and human spermiogenesis new insights in stage specificity and link to chromatin remodeling. Biol Reprod2004; 70:910–8.
152.
McPhersonSMLongoFJ. Localization of DNAse I-hypersensitive regions during rat spermatogenesis: stage dependent patterns and unique sensitivity of elongating spermatids. Mol Reprod Dev1992; 31:268–79.
153.
McPhersonSMLongoFJ. Nicking of rat spermatid and spermatozoa DNA: possible involvement of DNA topoisomerase II. Dev Biol1993; 158:122–30.
154.
McVicarCMMcClureNWilliamsonKDalzellLHLewisSE. Incidence of Fas positivity and deoxyribonucleic acid double-stranded breaks in human ejaculated sperm. Fertil Steril2004; 81 (Suppl 1): 767–74.
155.
MeekerJDBarrDBHauserR. Human semen quality and sperm DNA damage in relation to urinary metabolites of pyrethroid insecticides. Hum Reprod2008; 23:1932–40.
156.
MeistrichML. Effects of chemotherapy and radiotherapy on spermatogenesis. Eur Urol1993; 23:136–42.
157.
MendiolaJTorres-CanteroAMAgarwalA. Lifestyle factors and male infertility: an evidence-based review. Arch Med Sci2009; 5, 1A: S3–S12.
158.
MeseguerMSantisoRGarridoNGarcia-HerreroSRemohiJFernandezJL. Effect of sperm DNA fragmentation on pregnancy outcome depends on oocyte quality. Fertil Steril2011; 95:124–8.
159.
MieussetRBujanL. Testicular heating and its possible contributions to male infertility: a review. Int J Androl1995; 18:169–84.
160.
MiglioreLNaccaratiAZanelloAScarpatoRBramantiLMarianiM. Assessment of sperm DNA integrity in workers exposed to styrene. Hum Reprod2002; 17:2912–8.
161.
MongaMRobertsJA. Spermagglutination by bacteria: Receptor-specific interactions. J Androl1994; 15:151–6.
162.
MorrisIDIlottSDixonLBrisonDR. The spectrum of DNA damage in human sperm assessed by single cell gel electrophoresis (Comet assay) and its relationship to fertilization and embryo development. Hum Reprod2002; 17:990–8.
163.
MorrisID. Sperm DNA damage and cancer treatment. Int J Androl2002; 25:255–61.
164.
Morse-GaudioMRisleyMS. Topoisomerase II expression and VM-26 induction of DNA breaks during spermatogenesis in Xenopus laevis. J Cell Sci1994; 107:2887–98.
165.
NakadaKSatoAYoshidaKMoritaTTanakaHInoueSYonekawaHHayashiJ. Mitochondria-related male infertility. Proc Natl Acad Sci USA2006; 103:15148–53.
166.
Nasr-EsfahaniMHRazaviSMozdaraniHMardaniMAzvagiH. Relationship between protamine deficiency with fertilization rate and incidence of sperm premature chromosomal condensation post-ICSI. Andrologia2004; 36:95–100.
167.
NieschlagEBehreHM. Andrology. Male reproductive health and dysfunction.; 2nd edition, Springer, Berlin Heidelberg New York, 2000.
168.
OliveiraJBMassaroFCMauriALPetersenCGNicolettiAPBaruffiRLFrancoJGJr. Motile sperm organelle morphology examination is stricter than Tygerberg criteria. Reprod Biomed Online2009; 18:320–6.
169.
OrthJMGunsalusGLLampertiAA. Evidence from Sertoli cell-depleted rats indicates that spermatid number in adults depends on numbers of Sertoli cells produced during perinatal development. Endocrinology1988; 122:787–94.
170.
OzawaT. Oxidative damage and fragmentation of mitochondrial DNA in cellular apoptosis. Biosc Rep1997; 17:237–50.
171.
PaaschUGrunewaldSKratzschJGlanderHJ. Obesity and age affect male fertility potential. Fertil Steril2010; 94:2898–901.
172.
PadronOFBrackettNLSharmaRKLynneCMThomasAJJr.AgarwalA. Seminal reactive oxygen species and sperm motility and morphology in men with spinal cord injury. Fertil Steril1997; 67:1115–20.
173.
PasqualottoFFSharmaRKNelsonDRThomasAJAgarwalA. Relationship between oxidative stress, semen characteristics, and clinical diagnosis in men undergoing infertility investigation. Fertil Steril2000; 73:459–64.
174.
PaulCMurrayAASpearsNSaundersPT. A single, mild, transient scrotal heat stress causes DNA damage, subfertility and impairs formation of blastocysts in mice. Reproduction2008; 136:73–84.
175.
Perez-CrespoMMoreiraPPintadoBGutierrez-AdanA. Factors from damaged sperm affect its DNA integrity and its ability to promote embryo implantation in mice. J Androl2008; 29:47–54.
PocciaD. Remodeling of nucleoproteins during gametogenesis, fertilization and early development. Int Rev Cytol1986; 105:1–65.
178.
PrintCGLovelandKL. Germ cell suicide: new insights into apoptosis during spermatogenesis. BioEssays2000; 22:423–30.
179.
QiuJHalesBFRobaireB. Damage to rat spermatozoal DNA after chronic cyclophosphamide exposure. Biol Reprod1995; 53:1465–73.
180.
Quillet-MaryAJaffrezouJPMansatVBordierCNavalJLaurentG. Implication of mitochondrial hydrogen peroxide generation in ceramide-induced apoptosis. J Biol Chem1997; 272:21388–95.
181.
RamosLvan der HeijdenGWDerijckABerdenJHKremerJAMvan der VlagJde BoerP. Incomplete nuclear transformation of human spermatozoa in oligo-astheno-teratozoospermia: characterization by indirect immune-fluorescence of chromatin and thiol status. Hum Reprod2008; 23:259–70.
182.
ReichenbergAGrossRWeiserMBresnahanMSilvermanJHarlapSRabinowitzJShulmanCMalaspinaDLubinGKnoblerHYDavidsonMSusserE. Advancing paternal age and autism. Arch Gen Psychiatry2006; 63:1026–32.
183.
RodriguezIOdyCArakiKGarciaIVassalliP. An early and massive wave of germinal cell apoptosis is required for the development of functional spermatogenesis. EMBO J1997; 16:2262–70.
184.
RomeoCIentileRSantoroGImpellizzeriPTuriacoNImpalaPCifalaSCutroneoGTrimarchiFGentileC. Nitric oxide production is increased in the spermatic veins of adolescents with left idiophatic varicocele. J Pediatr Surg2001; 36:389–93.
185.
RossatoMLa SalaGBBalasiniMTariccoFGaleazziCFerlinAForestaC. Sperm treatment with extracellular ATP increases fertilization rates in in-vitro fertilization for male factor infertility. Hum Reprod1999; 14:694–7.
186.
RowePJComhaireFHHargreaveTBMahmoudAMA. WHO manual for the standardized investigation, diagnosis and management of the infertile male. Cambridge University Press, Cambridge, 2000.
187.
RubesJSelevanSGSramRJEvensonDPPerreaultSD. GSTM1 genotype influences the susceptibility of men to sperm DNA damage associated with exposure to air pollution. Mutat Res2007; 625:20–8.
188.
RussellLDPetersonRN. Determination of the elongate spermatid-Sertoli cell ratio in various mammals. J Reprod Fertil1984; 70:635–41.
189.
SakkasDMariethozEManicardiGBizzaroDBianchiPGBianchiU. Origin of DNA damage in ejaculated human spermatozoa. Rev Reprod1999a; 4:31–7.
190.
SakkasDMariethozESt. JohnJC. Abnormal sperm parameters in humans are indicative of an abortive apoptotic mechanism linked to the Fas-mediated pathway. Exp Cell Res1999b; 251:350–5.
191.
SakkasDMoffattOManicardiGCMariethozETarozziNBizzaroD. Nature of DNA damage in ejaculated human spermatozoa and the possible involvement of apoptosis. Biol Reprod2002; 66:1061–7.
192.
SalehRAAgarwalAKandiraliESharmaRKThomasAJJrNadaEAEvensonDPAlvarezJG. Leukocytospermia is associated with increased reactive oxygen species production by human spermatozoa. Fertil Steril2002; 78:1215–24.
Sanocka-MaciejewskaDCiupinskaMKurpiszM. Bacterial infection and semen quality. J Reprod Immunol2005; 67:51–6.
195.
SaowarosWPanyimS. The formation of disulfide bonds in human protamines during sperm maturation. Experientia1979; 35:191–192.
196.
Schulze-OsthoffKBakkerACVanhaesebroeckBBeyaertRJacobWAFiersW. Cytotoxic activity of tumor necrosis factor is mediated by early damage of mitochondrial functions. Evidence for the involvement of mitochondrial radical generation. J Biol Chem1992; 267:5317–23.
197.
SchwartzmanRACidlowskiJA. Apoptosis: the biochemistry and molecular biology of programmed cell death. Endocr Rev1993; 14:133–51.
198.
SeliEGardnerDKSchoolcraftWBMoffattOSakkasD. Extent of nuclear DNA damage in ejaculated spermatozoa impacts on blastocyst development after in vitro fertilization. Fertil Steril2004; 82:378–83.
199.
SepaniakSForgesTGerardHFoliguetBBeneMCMonnier-BarbarinoP. The influence of cigarette smoking on human sperm quality and DNA fragmentation. Toxicology2006; 223:54–60.
200.
ShaletSMTsatsoulisAWhiteheadEReadG. Vulnerability of the human Leydig cell to radiation damage is dependent upon age. J Endocrinol1989; 120:161–5.
201.
ShamsiMBImamSNDadaR. Sperm DNA integrity assays: diagnostic and prognostic challenges and implications in management of infertility. J Assist Reprod Genet2011. Sep 9. [Epub ahead of print]
202.
SharmaRKAgarwalA. Role of reactive oxygen species in male infertility. Urology1996; 48:835–50.
203.
ShefiSTaraporePEWalshTJCroughanMTurekPJ. Wet heat exposure: a potentially reversible cause of low semen quality in infertile men. Int Braz J Urol2007; 33:50–7.
204.
ShenHOngC. Detection of oxidative DNA damage in human sperm and its association with sperm function and male infertility. Free Radic Biol Med2000; 28:529–36.
205.
ShenHMChiaSEOngCN. Evaluation of oxidative DNA damage in human sperm and its association with male infertility. J Androl1999; 20:718–23.
206.
SheynkinYJungMYooPSchulsingerDKomaroffE. Increase in scrotal temperature in laptop computer users. Hum Reprod2005; 20:452–5.
207.
ShiraishiKTakiharaHMatsuyamaH. Elevated scrotal temperature, but not varicocele grade, reflects testicular oxidative stressmediated apoptosis. World J Urol2010; 28:359–64.
SikkaSC. Relative impact of oxidative stress on male reproductive function. Curr Med Chem2001; 8:851–62.
210.
SimonLLuttonDMcManusJLewisSE. Sperm DNA damage measured by the alkaline Comet assay as an independent predictor of male infertility and in vitro fertilization success. Fertil Steril2011; 95:652–7.
211.
SinghNPMullerCHBergerRE. Effects of age on DNA double-strand breaks and apoptosis in human sperm. Fertil Steril2003; 80:1420–30.
212.
SiposARasmussenFHarrisonGTyneliusPLewisGLeonDAGunnellD. Paternal age and schizophrenia: a population based cohort study. BMJ2004; 329:1070.
213.
SkoogSJRobertsKPGoldsteinMPryorJL. The adolescent varicocele: what's new with an old problem in young patients?Pediatrics1997; 100:112–21.
214.
SmitMDohleGRHopWCJWildhagenMFWeberRFARomijnJC. Clinical correlates of the biological variation of sperm DNA fragmentation in infertile men attending an andrology outpatient clinic. Int J Androl2007; 30:48–55.
215.
SongGSSeoJT. Changes in the scrotal temperature of subjects in a sedentary posture over a heated floor. Int J Androl2006; 29:446–57.
216.
StahlOBoydHAGiwercmanALindholmMJensenAKjaerSKAndersonHCavallin-StahlERylanderL. Risk of birth abnormalities in the offspring of men with a history of cancer: a cohort study using Danish and Swedish national registries. J Natl Cancer Inst2011; 103:398–406.
217.
StahlOEberhardJJepsonKSpanoMCwikielMCavallin-StahlEGiwercmanA. Sperm DNA integrity in testicular cancer patients. Hum Reprod2006; 21:3199–205.
218.
Steliarova-FoucherEStillerCKaatschPBerrinoFCoeberghJWLacourBParkinM. Geographical patterns and time trends of cancer incidence and survival among children and adolescents in Europe since the 1970s (the ACCIS project): an epidemiological study. Lancet2004; 364:2097–105.
219.
SunJGJurisicovaACasperRF. Detection of deoxyribonucleic acid fragmentation in human sperm: correlation with fertilization in vitro. Biol Reprod1997; 56:602–7.
220.
TesarikJGrecoEMendozaC. Late, but not early, paternal effect on human embryo development is related to sperm DNA fragmentation. Hum Reprod2004; 19:611–5.
221.
ThomsonABCampbellAJIrvineDSAndersonRAKelnarCJHWallaceWHB. Semen quality and spermatozoal DNA integrity in survivors of childhood cancer: a case-control study. The Lancet2002; 360:361–7.
222.
ThonneauPBujanLMultignerLMieussetR. Occupational heat exposure and male fertility: a review. Hum Reprod1998; 13:2122–5.
223.
TorregrosaNDominguez-FandosDCamejoMIShirleyCRMeistrichMLBallescaJLOlivaR. Protamine 2 precursors, protamine 1/protamine 2 ratio, DNA integrity and other sperm parameters in infertile patients. Hum Reprod2006; 21:2084–9.
224.
TrottmannMBeckerAJStadlerTStraubJSoljanikISchlenkerBStiefCG. Semen quality in men with malignant diseases before and after therapy and the role of cryopreservation. Eur Urol2007; 52:355–67.
225.
TwiggJPIrvineDSAitkenRJ. Oxidative damage to DNA in human spermatozoa does not preclude pronucleus formation at intracytoplasmic sperm injection. Hum Reprod1998; 13:1864–71.
226.
VagniniLBaruffiRLMauriALPetersenCGMassaroFCPontesAOliveiraJBFrancoJGJr. The effects of male age on sperm DNA damage in an infertile population. Reprod Biomed Online2007; 15:514–9.
227.
van CasterenNJvan der LindenGHHakvoort-CammelFGHählenKDohleGRvan den Heuvel-EibrinkMM. Effect of childhood cancer treatment on fertility markers in adult male long-term survivors. Pediatr Blood Cancer2009; 52:108–12.
228.
VestergaardMMorkAMadsenKMOlsenJ. Paternal age and epilepsy in the offspring. Eur J Epidemiol2005; 20:1003–5.
229.
VineMF. Smoking and male reproduction: a review. Int J Androl1996; 19:323–37.
230.
WallaceWHAndersonRAIrvineDS. Fertility preservation for young patients with cancer: who is at risk and what can be offered?Lancet Oncol2005; 6:209–18.
231.
WangXSharmaRKGuptaAGeorgeVThomasAJFalconeTAgarwalA. Alterations in mitochondria membrane potential and oxidative stress in infertile men: a prospective observational study. Fertil Steril2003b; 80Suppl 2:844–50.
232.
WangXSharmaRKSikkaSCThomasAJFalconeTAgarwalA. Oxidative stress is associated with increased apoptosis leading to spermatozoa DNA damage in patients with male factor infertility. Fertil Steril2003a; 80:531–5.
233.
WardWSCoffeyDS. DNA packaging and organization in mammalian spermatozoa: comparison with somatic cells. Biol Reprod1991; 44:569–74.
234.
WdowiakAWdowiakLWiktorH. Evaluation of the effect of using mobile phones on male fertility. Ann Agric Environ Med2007; 14:169–72.
235.
WeidnerWKrauseWLudwigM. Relevance of male accessory gland infection for subsequent fertility with special focus on prostatitis. Hum Reprod Update1999; 5:421–32.
236.
WengSLTaylorSLMorshediMSchuffnerADuranEHBeebeSOehningerS. Caspase activity and apoptotic markers in ejaculated human sperm. Mol Hum Reprod2002; 8:984–91.
237.
WildSRoglicGGreenASicreeRKingH. Global prevalence of diabetes: estimates for the year 2000 and projections for 2030. Diabetes Care2004; 27:1047–53.
238.
WilkinsJRHundleyVD. Paternal occupational exposure to electromagnetic fields and neuroblastoma in offspring. Am J Epidemiol1990; 131:995–1008.
239.
WilkinsJRKoutrasRA. Paternal occupation and brain cancer in offspring: a mortality-based case-control study. Am J Ind Med1988; 14:299–318.
240.
WittKLBishopJB. Mutagenicity of anticancer drugs in mammalian germ cells. Mutat Res1996; 355:209–34.
241.
WolffH. The biologic significance of white blood cells in semen. Fertil Steril1995; 63:1143–57.
242.
XuDXShenHMZhuQXChuaLWangQNChiaSEOngCN. The associations among semen quality, oxidative DNA damage in human spermatozoa and concentrations of cadmium, lead and selenium in seminal plasma. Mutat Res2003; 534:155–63.
243.
XuDXShenHMZhuQXChuaLWangQNChiaSEOngCN. The associations among semen quality, oxidative DNA damage in human spermatozoa and concentrations of cadmium, lead and selenium in seminal plasma. Mutat Res2003; 534:155–63.
244.
ZhaoMShirleyCRHayashiSMarconLMohapatraBSuganumaRBehringerRRBoissonneaultGYanagimachiRMeistrichML. Transition nuclear proteins are required for normal chromatin condensation and functional sperm development. Genesis2004; 38:200–13.
245.
ZiniABomanJMBelzileECiampiA. Sperm DNA damage is associated with an increased risk of pregnancy loss after IVF and ICSI: systematic review and meta-analysis. Hum Reprod2008; 23:2663–8.
246.
ZiniAJamalWCowanLAl-HathalN. Is sperm dna damage associated with IVF embryo quality? A systematic review. J Assist Reprod Genet2011 Feb 16. [Epub ahead of print]
247.
ZiniAKamalKPhangDWillisJJarviK. Biologic variability of sperm DNA denaturation in infertile men. Urology2001; 58:258–61.
248.
ZornBAugerJVelikonjaVKolbezenMMeden-VrtovecH. Psychological factors in male partners of infertile couples: relationship with semen quality and early miscarriage. Int J Androl2008; 31:557–64.