Testicular and sperm DNA damage after treatment with fludarabine for chronic lymphocytic leukaemia

R. Chatterjee1,4, G.A. Haines1, D.M.D. Perera1, A. Goldstone2 and I.D. Morris3

1 Departments of Obstetrics and Gynaecology and 2 Haematology, University College Hospital, London WC1E 6AU, and 3 Division of Physiology, Pharmacology and Toxicology, School of Biological Sciences, University of Manchester, Oxford Road, Manchester M13 9PT, UK


    Abstract
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 Abstract
 Introduction
 Materials and methods
 Results
 Discussion
 References
 
This study investigated whether chemotherapy using fludarabine (FLU) caused testicular damage and if cytotoxicity could be detected as sperm DNA damage in the single cell Comet assay. A patient with chronic lymphocytic leukaemia requesting preservation of fertility was treated with seven monthly cycles of fludarabine (45.8 mg total dose per cycle). Testicular assessments, serum follicle stimulating hormone (FSH), luteinizing hormone (LH), and testosterone measurements, semen analysis and sperm Comet assays were carried out at presentation (pre-FLU therapy), after 1 and 7 months of FLU treatment, and finally at 11 months after completion of chemotherapy. We found that testicular damage occurred within a month, as indicated by reduced testicular volume, oligozoospermia, elevated FSH and LH, and lower testosterone concentrations. Spermatozoa with a large range of DNA damage were detected in the samples from both the control and treated men. DNA damage in the spermatozoa was marked by 7 months of FLU treatment. The high levels of sperm DNA damage seen during and possibly persisting after treatment suggests that caution should be exercised if the ejaculates from these men are used for in-vitro fertility treatment. Further experiments are needed to assess the biological significance of these DNA changes; it may, however, be prudent at present to be cautious when counselling these patients.

Key words: chemotherapy/Comet assay/DNA damage/fertility/spermatozoa


    Introduction
 Top
 Abstract
 Introduction
 Materials and methods
 Results
 Discussion
 References
 
The adverse effects of conventional and high-dose chemotherapy on testicular function is well established (Chatterjee and Goldstone, 1996Go; Meistrich, 1998Go; Howell et al., 1999Go), but little is known about fludarabine (FLU; Schering Health Care Ltd, Burgess Hill, West Sussex, UK), a purine analogue that is commonly used in haematological malignancies (Adkins et al., 1997Go; Byrd et al., 1998Go). Cytotoxic substances used for malignancies lack tissue specificity, and spermatogenesis is often impaired, so preservation of fertility is an important issue, especially for young adults. Each year several thousand children and young persons of the reproductive age group are exposed to cancer chemotherapy and as more of these treatments are effective, there is a growing concern about the long-term consequences of testicular damage on the survivors.

The recent availability of micromanipulation techniques using a single spermatozoon [intracytoplasmic sperm injection (ICSI)] has improved the prospects of child-bearing in patients with severe oligo-asthenozoospermia (Pisarska et al., 1999Go). Sperm selection techniques do not allow assessment of the genetic integrity of the spermatozoon and it is clear that mutations in the paternal genome can be passed on to the children (Martin, 1996Go; Robbins et al., 1997Go). Current practice to preserve fertility for patients undergoing genotoxic chemotherapy is to cryopreserve spermatozoa with a view to using them later for assisted reproduction treatment (Tournaye et al., 1993Go; Lass et al., 1999Go; Pfeifer and Coutifaris, 1999Go).

Although it is well known that chemotherapy can adversely effect sperm production, the genetic consequences arising after fertilization with sperm from a treated man are less clear. Aneuploidy of the X and Y chromosomes has been reported in the children of men treated for cancer (Robbins et al., 1997Go; Monteil et al., 1997Go). The integrity of the DNA in the male genome carried by the spermatozoa is crucial for genetic health, and changes can lead to alterations in the germ line which result in the inheritance of lethal and non-lethal conditions (Perreault, 1998Go). A major limitation of the current assessment of male fertility is that the genetic integrity of the spermatozoa cannot be easily determined. This is particularly important in view of the known effects of chemotherapy in animal models and the view that normal human ejaculates carry a significant proportion of damaged spermatozoa (Sakkas et al., 1999Go)

We have taken the opportunity to see if DNA damage in spermatozoa can be detected in the semen of a patient treated with a chemotherapeutic regime effective for chronic lymphocytic leukaemia (CLL). The patient received FLU, which has not been previously reported to be gonadotoxic and would allow semen collection uncomplicated by reductions in sperm numbers. This case study allowed us to test the hypothesis that FLU causes testicular and sperm DNA damage.


    Materials and methods
 Top
 Abstract
 Introduction
 Materials and methods
 Results
 Discussion
 References
 
Subjects
A 47-year-old patient with CLL requesting preservation of fertility was studied longitudinally for 18 months that included a course of seven monthly treatment cycles of FLU chemotherapy (45.8 mg per cycle and at 11 months after cessation of treatment). The patient had received one course of chlorambucil (2 mg daily for 2 weeks), a known gonadotoxin (Clark et al., 1995Go), 9 months prior to the treatment with FLU, although there was no indication that this had impaired his testis (Table IGo). The patient also received gonadotrophin-releasing hormone (GnRH) therapy in the form of leuproline acetate (Prostap-SR; Wyeth, South Taplow, Berks, UK) 3.75 mg i.m. monthly for 6 months starting 1 month after initiation of chemotherapy during FLU therapy in an attempt to suppress testicular function. Testicular size was assessed and blood and semen samples collected throughout the study period. The four time-points of study were (i) at presentation (pre-FLU therapy), at the end of (ii) the 1st and (iii) the 7th monthly treatment cycle month, and finally (iv) at 11 months after completion of chemotherapy.


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Table I. Sperm and endocrine parameters of patient before and after fludarabine treatment
 
Semen and DNA analyses were also undertaken on samples from a healthy age-matched control subject whose semen sample was cryopreserved at eight time-points at 3-monthly intervals for 2 years.

Collection of samples
Venous blood (20 ml, in EDTA) and semen samples were collected throughout the study period. Plasma was stored at –40°C until assayed. Semen samples were cryopreserved at –70°C and then analysed by the Comet assay as a single batch (see below).

Assessment of testicular function
Testicular assessments included volume by orchidometry and ultrasound. Testicular function was assessed by LH, FSH (Walton et al., 1998Go) and testosterone immunoassays (Nichols Institute, Newport, Saffron Walden, Essex, UK). Semen parameters were measured using routine in-house methods following the WHO protocols (World Health Organization, 1987Go)

Assessment of sperm DNA damage by Comet assay
The comet assay is a widely used technique for measurement of DNA strand breaks in a wide variety of cell types (Olive, 1999Go). More recently this technique has been used to investigate DNA damage in spermatozoa (Aitken et al., 1998Go; Singh and Stephens, 1998Go; Hughes et al., 1999Go) and we have developed the neutral method for double-strand DNA breaks in human spermatozoa (Haines et al., 1998bGo). Sperm cells were cast into miniature agarose gels on microscope slides and lysed in situ to remove DNA associated proteins. The microgels then underwent electrophoresis, which allowed damaged DNA to migrate from the nucleus towards the anode, which could be visualized using fluorescent DNA probes. The length of the tail of DNA extending from the nucleus and the moment (a product of the migration and the percentage of DNA in this tail) were measured by image analysis in >100 sperm cells per time-point, using a fluorescence microscope and Comet Assay II software (Perceptive Instruments, Steeple Bumpstead, Haverhill, Suffolk, UK).


    Results
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 Abstract
 Introduction
 Materials and methods
 Results
 Discussion
 References
 
The hormonal and semen analysis results for the patient receiving the FLU treatment are given in Table IGo. The results suggest that FLU induces testicular damage within a month after the start of therapy, as evident from the reductions in testicular volume, oligozoospermia, elevated FSH and LH, and diminished testosterone concentrations compared to pre-treatment values and the laboratory control. No effect of the chemotherapy, however, was seen on sperm motility or the proportion of abnormal spermatozoa. During chemotherapy, recovery of testicular function took place, so that at the end of the seventh treatment cycle semen parameters, FSH, and LH approached normal values although testosterone remained low. All semen and hormonal values appeared normal 11 months after the end of treatment.

The Comet assay was used as a measure of DNA damage. Spermatozoa assayed from the treated man at the time-points (i)–(iv) gave Comet tail lengths (µm, mean ± SEM) of 54.0 ± 1.5, 50.1 ± 0.6, 67.6 ± 0.5, and 54.0 ± 1.4 respectively. The comet tail moments were 10.0 ± 1.67, 6.7 ± 0.2, 14.8 ± 0.2, and 7.5 ± 0.1 units (n = 100–200 spermatozoa, mean ± SEM). The values at time-point (iii) were clearly elevated. This was in contrast to values obtained for the control subject which ranged randomly with time from 54.2–65.7 µm tail length and 4.9–6.3 units tail moment. The mean ± SD Comet data from the eight 3-monthly samples was 5.64 ± 0.56 units tail moment and 58.70 ± 4.46 µm tail length. Further information on the effect of cytotoxic treatment was obtained by inspection of the distribution of DNA damage in single spermatozoa from the ejaculate (Figure 1Go). The Comet tail length distribution from the eight samples from the control subject was very similar to the pre-treatment pattern from the patient. The distributions from the first and last sample taken from the control man are given in Figure 2Go. In the control sample and the pre-treatment sample from the patient it can be seen that DNA damage was detected in all spermatozoa and that there was a wide distribution in the level of DNA damage. In control samples, there was a clear population with low amounts of DNA damage (i.e. shorter tail lengths). The frequency distribution pattern of sperm Comet lengths was monophasic and skewed to the left with a frequency peak about 45–50 µm. The number of spermatozoa with higher amounts of DNA damage was much greater after 7 months of FLU chemotherapy (Figure 1Go, panel iii) and the distribution was skewed to the right with a peak at 75 µm. The population of spermatozoa containing lower amounts of DNA damage had almost disappeared. Eleven months after the withdrawal of FLU and GnRH therapy, there was a marked reversal towards the control pattern.



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Figure 1. The frequency distribution of DNA damage in spermatozoa measured by Comet tail length. The histograms represent the analysis of 100 spermatozoa from the ejaculate of a man treated for chronic lymphocytic leukaemia (CLL) with FLU. Time-point (i), pre chemotherapy; time-point (ii), 4 weeks after the start of chemotherapy; time-point (iii), 8 weeks after the start of chemotherapy; and time-point (iv), 44 weeks after the end of chemotherapy.

 


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Figure 2. The frequency distribution of DNA damage in spermatozoa measured by Comet tail length. The histograms represent the analysis of 100 spermatozoa from the ejaculate of a man with normal semen characteristics who was not receiving any prescribed medication. The sample collections were separated by 24 months.

 

    Discussion
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 Abstract
 Introduction
 Materials and methods
 Results
 Discussion
 References
 
This is the first report to suggest that FLU, a widely used chemotherapeutic treatment, impairs spermatogenesis and potentially male fertility, a property shared with many other cytotoxic treatments (Chatterjee and Goldstone, 1996Go; Meistrich, 1998Go; Howell et al., 1999Go). However, these changes cannot be conclusively attributed to FLU, as the patient was also receiving GnRH, which produces atrophy of the testes by withdrawal of gonadotrophin support. As there was no evidence of a fall in gonadotrophin secretion in this patient, it strongly suggests that the testicular effects seen were due to FLU. More detailed studies are needed to confirm these changes.

In animal models, cytotoxic treatment of the male is associated with genetic damage in the spermatozoa, which is transferred to the offspring. These mutations vary in severity, being expressed diversely as embryo lethality, developmental abnormalities, or changes in coat colour (Perreault, 1998Go). In contrast, genetic effects of cytotoxic drugs or radiation upon the human male genome, which may be transmitted to the children, have not been conclusively demonstrated, and their occurrence is still controversial (Meistrich, 1993Go).

Surprisingly, DNA damage in spermatozoa obtained from normal human ejaculate has been detected by several methods (Sakkas et al., 1999Go). A major drawback of many of these methods is that spermatozoa and somatic cells in the human ejaculate are heterogeneous, and therefore single-cell analysis would be more informative. The terminal deoxynucleotidyl transferase-mediated dUDP nick-end labelling (TUNEL) technique labels DNA breaks in spermatozoa, and most probably identifies apoptotic DNA strand breaks carried over from meiosis. The numbers of TUNEL-labelled spermatozoa are related to infertility (Sun et al., 1997Go).

Recently, Comet analysis of single cells has been introduced and is extensively used to measure single- and double-strand DNA breaks in somatic cells (Olive, 1999Go). This technique has been applied to spermatozoa, and the method described in the present study allows the detection of double-strand breaks in single spermatozoa (Haines et al., 1998bGo). We have confirmed the observations of others that DNA damage can be detected by Comet in spermatozoa; our data also show that spermatozoa in the normal ejaculate carry a range of DNA damage. In the patient sample we cannot discount the possibility that this may in part be due to the previous treatment with chlorambucil (Clark et al., 1995Go). However, low numbers of spermatozoa containing high amounts of DNA damage were also present in a similar proportion of spermatozoa from the untreated control man. The origin of this damage is not clear and may arise during spermatogenesis or in the male reproductive tract during transport from the testis to the ejaculate (Aitken, 1999Go; Sakkas et al., 1999Go).

In the present study we have shown for the first time by direct measurement that DNA damage in spermatozoa is substantially increased by cytotoxic treatment. A particular concern is whether the DNA damage has been resolved 11 months after the end of treatment. We are not able to conclude from the present data if the DNA damage to spermatozoa arising during chemotherapy is reversible, as there is a wide spectrum of DNA damage in spermatozoa from the normal ejaculate. Recent observations in the mouse, however, show that DNA damage persists in spermatozoa for up to 120 days after a single dose of irradiation (Haines et al., 1998aGo), and as this is longer than one spermatogenic cycle it may be a permanent effect (Morris et al., 1996Go).

Of particular concern to men is the biological significance of fertilization of an oocyte by a spermatozoon carrying high amounts of DNA damage. Spermatozoa carrying significant DNA damage are motile and capable of fertilization (Mikamo et al., 1991Go; Twigg et al., 1998Go; Ahmadi and Ng, 1999Go) but it is not known what the effect of DNA damage in spermatozoa has upon embryo development, pregnancy, or the subsequent health of the children. Chromosomal aneuploidies have been reported in the children of men conceived after treatment with chemotherapy, and it would be premature to rule out more subtle effects. In animals, cytotoxic treatment of males results in high frequencies of abnormalities both in utero and postnatally (Perreault, 1998Go). Recent in-vitro experiments in the mouse have shown that fertilization by spermatozoa with radiation-induced TUNEL DNA damage results in impaired development of the embryos and reduced numbers of live offspring (Ahmadi and Ng, 1999Go).

With the increasing success of multimodal cancer therapy, a significant proportion of men will survive the malignancy. Fertility is therefore a principal concern, and health care providers are increasingly aware of the need to improve the quality of life of cancer patients by maintaining normal reproductive function. In the past, recovery of sperm output has been of major concern and it may remain low or take several years to increase to an acceptable level after discontinuation of cancer therapy (Meistrich, 1998Go). With the advent of assisted reproduction by ICSI it is now possible to offer a good chance of conception in all men with a low sperm output. Given that the sperm selection techniques are based primarily on motility (Nagy et al., 1998Go), there is a significant chance, especially in treated patients, that spermatozoa with high amounts of DNA damage are selected. The consequences of this selection are presently not known; however, as they may theoretically be associated with genetic changes to the child, the technique should be used with caution and the genetic outcome of this technique closely scrutinized.

In conclusion, this case study indicates that FLU induces testicular damage within a month and markedly increases DNA damage carried by spermatozoa by 7 months of treatment. As the numbers of spermatozoa carrying high amounts DNA damage may persist after discontinuation of treatment, the DNA damage may be permanent. This observation is worrying and the possibility of biological effects being transferred to the offspring must be considered and investigated further. Fertility counselling of patients undergoing cytotoxic chemotherapy should take into account these effects and it may be pertinent to reappraise the most appropriate timing of semen collection for fertility treatment.


    Notes
 
4 To whom correspondence should be addressed at: Obstetric Hospital, Reproductive Medicine Unit (OH2), Huntley Street, London WC1E 6AU, UK Back


    References
 Top
 Abstract
 Introduction
 Materials and methods
 Results
 Discussion
 References
 
Adkins, J.C., Peters, D.H. and Markham, A. (1997) Fludarabine—An update of its pharmacology and use in the treatment of haematological malignancies. Drugs, 53, 1005–1037.[ISI][Medline]

Ahmadi, A. and Ng, S.C. (1999) Developmental capacity of damaged spermatozoa. Hum. Reprod., 14, 2279–2285.[Abstract/Free Full Text]

Aitken, R.J. (1999) The Amoroso Lecture – The human spermatozoon – a cell in crisis? J. Reprod. Fertil., 115, 1–7.[Abstract]

Aitken, R.J., Gordon, E., Harkiss, D. et al. (1998) Relative impact of oxidative stress on the functional competence and genomic integrity of human spermatozoa. Biol. Reprod., 59, 1037–1046.[Abstract/Free Full Text]

Byrd, J.C., Rai, K.R., Sausville, E.A. and Grever, M.R. (1998) Old and new therapies in chronic lymphocytic leukemia: Now is the time for a reassessment of therapeutic goals. Semin. Oncol., 25, 65–74.[ISI][Medline]

Chatterjee, R. and Goldstone, A.H. (1996) Gonadal damage and effects on fertility in adult patients with haematological malignancy undergoing stem cell transplantation. Bone Marrow Transplant., 17, 5–11.[ISI][Medline]

Clark, S.T., Radford, J.A., Crowther, D. et al. (1995) Gonadal-function following chemotherapy for Hodgkin's disease – a comparative study of mvpp and a 7-drug hybrid regimen. J. Clin. Oncol., 13, 134–139.[Abstract]

Haines, G.A., Brison, D.R., Hendry, J.H. et al. (1998a) Effects of paternal X-irradiation on development and apoptosis in the preimplantation mouse embryo. Hum. Reprod., 13, 162

Haines, G., Marples, B., Daniel, P. and Morris, I. (1998b) DNA damage in human and mouse spermatozoa after in vitro irradiation assessed by the comet assay. Adv. Exp. Med. Biol., 444, 79–93.[ISI][Medline]

Howell, S.J., Radford, J.A., Ryder, W.D.J. and Shalet, S.M. (1999) Testicular function after cytotoxic chemotherapy: Evidence of Leydig cell insufficiency. J. Clin. Oncol., 17, 1493–1498.[Abstract/Free Full Text]

Hughes, C.M., McKelveymartin, V.J. and Lewis, S.E.M. (1999) Human sperm DNA integrity assessed by the Comet and ELISA assays. Mutagenesis, 14, 71–75.[Abstract/Free Full Text]

Lass, A., Abusheikha, N., Akagbosu, F. and Brinsden, P. (1999) Cancer patients should be offered semen cryopreservation. Br. Med. J., 318, 1556[Free Full Text]

Martin, R.H. (1996) The risk of chromosomal abnormalities following ICSI. Hum. Reprod., 11, 924–925.[ISI][Medline]

Meistrich, M.L. (1993) Potential genetic risks of using semen collected during chemotherapy-response. Hum. Reprod., 8, 982.[ISI][Medline]

Meistrich, M.L. (1998) Hormonal stimulation of the recovery of spermatogenesis following chemo- or radiotherapy—Review article. APMIS, 106, 37–45.[Medline]

Mikamo, K., Kamiguchi, Y. and Tateno, H. (1991) The interspecies in vitro fertilization system to measure human sperm chromosomal damage. Prog. Clin. Biol. Res., 372, 531–542.[Medline]

Monteil, M., Rousseaux, S., Chevret, E. et al. (1997) Increased aneuploid frequency in spermatozoa from a Hodgkin's disease patient after chemotherapy and radiotherapy. Cytogenet. Cell Genet., 76, 134–138.[ISI][Medline]

Morris, I.D., Hoyes, K.P., Taylor, M.F. and Woolveridge, I. (1996) Male reproductive toxicology. A review with special consideration of hazards to men. In Hamamah, S. and Mieusset, R. (eds), Male Gametes: Production and Quality. INSERM, Paris, pp. 135–150.

Nagy, Z.P., Joris, H., Verheyen, G. et al. (1998) Correlation between motility of testicular spermatozoa, testicular histology and the outcome of intracytoplasmic sperm injection. Hum. Reprod., 13, 890–895.[Abstract]

Olive, P.L. (1999) DNA damage and repair in individual cells: applications of the comet assay in radiobiology. Int. J. Radiat. Biol., 75, 395–405.[ISI][Medline]

Perreault, S. (1998) Gamete toxicology: The impact of new technologies. In Korach, K. (ed.), Reproduction and Developmental Toxicology. Marcel Dekker Inc., New York, pp. 635–641.

Pfeifer, S.M. and Coutifaris, C. (1999) Reproductive technologies 1998: Options available for the cancer patient. Med. Pediatr. Oncol., 33, 34–40.[ISI][Medline]

Pisarska, M.D., Casson, P.R., Cisneros, P.L. et al. (1999) Fertilization after standard in vitro fertilization versus intracytoplasmic sperm injection in subfertile males using sibling oocytes. Fertil. Steril., 71, 627–632.[ISI][Medline]

Robbins, W.A., Meistrich, M.L., Moore, D. et al. (1997) Chemotherapy induces transient sex chromosomal and autosomal aneuploidy in human sperm. Nature Genet., 16, 74–78.[ISI][Medline]

Sakkas, D., Mariethoz, E., Manicardi, G. et al. (1999) Origin of DNA damage in ejaculated human spermatozoa. Rev. Reprod., 4, 31–37.[Abstract/Free Full Text]

Singh, N.P. and Stephens, R.E. (1998) X-ray-induced DNA double-strand breaks in human sperm. Mutagenesis, 13, 75–79.[Abstract]

Sun, J.G., Jurisicova, A. and Casper, R.F. (1997) Detection of deoxyribonucleic acid fragmentation in human sperm: Correlation with fertilization in vitro. Biol. Reprod., 56, 602–607.[Abstract]

Tournaye, H., Van Steirteghem, A. and Devroey, P. (1993) Semen cryobanking for men with cancer. Fertil. Steril., 60, 197–198.[ISI][Medline]

Twigg, J.P., Irvine, D.S. and Aitken, R.J. (1998) Oxidative damage to DNA in human spermatozoa does not preclude pronucleus formation at intracytoplasmic sperm injection. Hum. Reprod., 13, 1864–1871.[Abstract]

Walton, S., Cunliffe, W.J., Kaczkes, K. et al. (1998) Clinical, ultrasound and hormonal markers of androgenicity. Br. J. Dermatol., 133, 249–253.

World Health Organization (1987) WHO Laboratory Manual for the Examination of Human Semen and Semen–Cervical Mucus Interactions. The Press Syndicate of the University of Cambridge, Cambridge.

Submitted on May 13, 1999; accepted on December 16, 1999.