Abstract:
Endocrine disrupting chemicals (EDCs) are ubiquitous natural or synthetic substances,
present in the environment, that possess hormonal activity. EDCs have the ability to
disrupt hormonally dependent processes and potentially elicit adverse health effects in
both animals and humans. Possible adverse effects on fertility and reproductive
parameters following acute and chronic exposure to these chemicals have been
reported in the scientific literature. However, the association between exposure to EDCs
present in a malaria area and impaired male reproductive health remains inconsistent.
In South Africa (SA), malaria remains a public health threat and various programs are in
place in an effort to prevent malaria transmission. EDCs in a malaria endemic area in
the Limpopo Province, SA were identified as: (i) the organochlorine pesticide, 1,1,1-
trichloro-2,2-bis(p-chlorophenyl)ethane (DDT); (ii) the persistent metabolite of DDT, 1,1-
dichloro-2,2-bis(p-chlorophenyl)ethylene (DDE); (iii) the active substance in insecticidetreated
nets (ITNs) and used for indoor residual spraying (IRS), deltamethrin (DM); (iv)
the anti-oxidant used in the preparation of lubricating oil additives, resins, plasticizers
and found in polyvinyl chloride (PVC), para-nonylphenol (p-NP); (v) and phytoestrogens
(coumestrol, genistein, zearalenone), which form part of a normal diet.
The aim of the study was to investigate the effects of in utero-, lactational- and direct
exposure to selected concentrations of previously studied EDCs found in the
environment on male reproductive health using the rat model. The objectives were to (1)
determine the impact of in utero-, lactational- and direct exposure to EDCs on malespecific
endocrine sensitive endpoints (anogenital distance and gonadosomatic index),
male accessory glands (prostate, seminal vesicles), epididymis and liver (2) determine
the effects of EDC exposure on epididymal sperm count and testosterone levels, (3)
assess and compare the testicular histology and spermatogenesis cycle using the
spermatogenesis staging program STAGES and the Johnsen Scoring system, (4) determine the possible relationship between exposure to selected EDCs and the
increase incidence of testicular apoptosis.
We adapted the Organization for Economic Cooperation and Development (OECD) 415
reproductive toxicity protocol to include one control and three experimental groups, a
longer prenatal exposure period, and several additional endpoints. Male Sprague-
Dawley rats were exposed in utero- for 2 weeks, indirectly during lactation for 3 weeks
and directly for 10 weeks to cottonseed oil [control - group 1; n=24]; DDT (35mg/kg)
[group 2; n=11]; DDE (35mg/kg) [group 3; n=27]; and a mixture of DDT (35mg/kg), DM
(0.5mg/kg), p-NP (2.5?g/kg), genistein (2.5?g/kg), coumestrol (2.5?g/kg) and
zearalenone (2.5?g/kg) [group 4; n=15]. Following exposure and at 13 weeks of age,
changes in organ weights, epididymal sperm counts, histological assessments, staging
of the spermatogenic cycle and testicular apoptosis were assessed.
Treatment effects were found for male reproductive tract development as evidenced by
anogenital distance (AGD) in newborns and in liver characteristics. Compared with AGD
in the control group (group 1; 17.54 +/- 0.65mm), AGD was significantly shorter in the
mixture group (group 4; 15.20 +/- 0.16mm; P = 0.005), indicating possible feminization.
In comparison with the control group mean liver mass (group 1; 17.36 +/- 2.16 g), was
significantly higher in all three experimental groups: DDT (group 2; 21.16 +/- 1.29g; P
<0.001), DDE (group 3; 20.65 +/- 5.06g; P = 0.003) and the mixture (group 4; 19.45 +/-
2.00g; P = 0.031). Since enlargement of the liver is a marker of liver toxicity, the
increase in liver mass observed in this study indicates that exposure to these selected
EDCs had a significant effect on the liver of male rats. Lipid droplet formation and
hepatic disorganization were present in the liver of the DDT, DDE and mixture groups
suggesting that the liver may be a primary target. The changes in liver function may
therefore be involved in the reproductive effects observed in this study.
When animals had reached adulthood at the end of the study, the effects of EDC
exposures were found for a number of endpoints. Prostate mass in the control group
(group 1; 0.83 +/-0.24g) was significantly higher in the DDT group (group 2; 1.02 +/- 0.19g; P = 0.018). Prostate mass was not, however, correlated with testosterone levels
which were significantly higher in the DDE and mixture groups. Testicular histology
revealed marked effects in all groups including dilated tubular lumens, detachment of
the seminiferous epithelium, necrosis in the interstitium, disorganization of the
seminiferous epithelium with few germ cells present, reduced seminiferous tubule
diameter with no lumen, absent seminiferous tubules and decreased layers of germ
cells. Although these changes were not seen in all tubules, treatment was associated
with decreased mean seminiferous tubule diameters, decreased epithelial thickness,
and smaller luminal diameters. Application of the Johnsen scoring system showed that
the treatment effects manifested primarily as a Johnsen Score of 9 tubules (a Johnsen
Score of 9 is defined as a seminiferous tubules with many spermatozoa present, but
germinal epithelium disorganization with marked sloughing or obliteration of the lumen).
Specifically, controls had, on average, 19% abnormal tubules, compared 46%, 25% and
56% in the DDT, DDE and mixture groups, respectively. Surprisingly, however, the
lesions in histology did not translate into changes in epididymal sperm counts. This
suggests that spermatogenesis proceeded normally in a proportion of tubules, resulting
in sperm production sufficient to maintain apparently normal epididymal sperm stores.
The results of this study indicate that in utero-, lactational- and direct exposure to
mixture of EDCs found in a malaria area, at the levels used here, has negative impacts
on normal genital development after in utero exposure and on spermatogenesis in
adulthood after combined prenatal, lactational and postnatal exposure. These findings
raise concerns to EDC exposures to mothers living in malaria-areas and the
reproductive health of their male offspring. Significant differences were found in the
endocrine-sensitive endpoints: AGD, testosterone, testicular STAGES and Johnsen
score.
This study shows that in utero-, lactational- and direct exposure to EDCs present in a
malaria-area negatively affects male reproductive parameters in rats. These findings
raise concerns to EDC-exposures to mothers living in malaria-areas and the
reproductive health of their male offspring. Since this reproductive toxicology study constitutes in utero-, lactational and direct lifespan exposure to environmentally relevant
concentrations of EDCs present in a currently malaria-vector control area, these results
might be considered indicative of the effects following similar human exposures. Safer
alternatives should be sought particularly in malaria vector-control programs where
adverse reproductive health effects have been reported following chronic exposure to
these potentially harmful chemicals.