Effects of Environmental Water Contamination in the Reproductive System of Mice
Paulo Augusto Amador Pereira, Ana Júlia Lichtenfels, Luiz Alberto Amador Pereira, Olaf Malm, Paulo Hilário Nascimento Saldiva, Alfésio Luís Ferreira Braga, Chin An Lin
1Environmental Epidemiology Study Group, Laboratory of Experimental Air Pollution, University of S?o Paulo Faculty of Medical Sciences, S?o Paulo, Brazil; 2Environmental Risk and Exposure Assessment Group, Collective Health Post-Graduation Program, Catholic University of Santos, Santos, Brazil.
1Environmental Epidemiology Study Group, Laboratory of Experimental Air Pollution, University of S?o Paulo Faculty of Medical Sciences, S?o Paulo, Brazil; 2Medical Clinics Department, University of S?o Paulo Faculty of Medical Sciences, S?o Paulo, Brazil..
Environmental Epidemiology Study Group, Laboratory of Experimental Air Pollution, University of S?o Paulo Faculty of Medical Sciences, S?o Paulo, Brazil.
Program of Environmental Biophysics and Biotechnology, Institute of Biophysics Carlos Chagas Filho, Federal University of Rio de Janeiro, Rio de Janeiro, Brazil.
DOI: 10.4236/jep.2013.47A014   PDF    HTML     4,060 Downloads   5,954 Views   Citations

Abstract

This study investigated the effects on the reproductive system of balb-c mice exposed to water collected from different sources near to a deactivated fertilizer waste depositary. Eighty male mice were separated in four groups: Group A (mineral water); Group B (water from the water treatment station); Group C (water from Cubatao city); Group D (water from the waste depositary region). They were exposed to water since they were weaned until they reached sexual maturity, then they were coupled with females in reproductive age and after this mating time they were sacrificed. The evaluated parameters were testicle weight, sperm analysis, pregnancy rate, sex ratio of the offspring and Sertoli cell count. The analysis of the water did not show presence of pollutants in the Group “A” and Group “C” water. Group “B” showed low level of cadmium, 3.58 ± 0.50 μg/L. Group “D” showed the presence of PAH’s and high levels of lead (221 ± 16 μg/L), cadmiun (12.6 ± 1.2 μg/L) and mercury (5.3 ± 1.1 μg/L). The tests of Levene and Kolmogorov-Smirnov were employed to verify the homogeneity of the variances and the tack to the normal curve, respectively. ANOVA was used for parametric tests and Kruskall-Wallis was used for non-parametric tests, while Turkey tests were employed for multiple comparisons. There were no differences between groups in testicle weight, sperm analysis, pregnancy rate and Sertoli cell count. There was a significant reduction in sex-ratio of the offspring in Group B. This alteration cannot be explained by the cadmium levels in Group B water. In the present study we cannot associate the exposition to contaminated water from the waste depositary and reproductive alterations.

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Pereira, P. , Lichtenfels, A. , Pereira, L. , Malm, O. , Saldiva, P. , Braga, A. and Lin, C. (2013) Effects of Environmental Water Contamination in the Reproductive System of Mice. Journal of Environmental Protection, 4, 121-125. doi: 10.4236/jep.2013.47A014.

1. Introduction

Endocrine disruptor chemicals (EDC), also known as xenostrogens, such as fertilizers, pesticides and products from plastic material degradation can lead to estrogenlike effects. Several of these products, such as biphenyl policlorades (PCB) are used since 1930’s, and its chemical inertia makes it be spread out to the biosphere and can be found in several tissues from diverse species. Although some of these substances with known adverse effects have been widely banned, they persist in the environment and consequently in the food chain due to their lipophilic characteristics and their stability. They also have a high resistance to biodegradation (e.g. the half-life of DDT can be more than 50 years) [1]. Human populations throughout the world are exposed daily to low levels of environmental contaminants (pesticide residue, antibiotics, heavy metals, hormones and industrial chemicals) and the consequences of potential interactions of these compounds to human endocrine, reproductive, and immune function remain unknown [2,3]. The possibility of serious consequences such as a decline on the human population’s fertility makes it an important public health issue at the start of 21st century [4].

In the last decades, the endocrine disrupters’ effects in human being and its possible environmental impacts have been focused. Some studies have pointed out the possibility of these agents being implicated with the increase of occurrence in reproductive disturbances such as reduction in spermatogenesis [5,6] and increase of neoplasms in estrogen target organs (breast, ovaries, uterus and prostate) [7,8] both in animals and humans [9]. Other studies suggest organogenesis alteration due to exposition to these agents during the embryogenesis [10-12] and decreased indices of fertility and mating in Wistar female rats exposed to tobacco smoke during pregnancy [13].

Some other studies suggest that the quality and the quantity of human spermatozoa in semen experienced a decline, thus some have stated that the mankind is approaching to a “fertility crisis”, among the factors blamed to be responsible for this possible male fertility decline: heavy metal, agricultural fertilizers and pesticides, major radiation exposure, xenoestrogen environmental contamination, and global warming [14].

Spano et al. [3] suggest that human dietary PCB exposure might have a negative impact on the sperm chromatin integrity of adult males. Comhaire et al. [15] suggest a relation between dioxin and decreased sperm motility.

In addition, some experimental studies have shown association between reproductive alterations and air pollution in experimental animals [16,17], but there is no evidence that by drinking or feeding xenostrogen contaminated water and food, adverse effects on reproductive system could be observed.

This study was developed to assess the concentration of aromatic polycyclic hydrocarbons and toxic metals in samples of water from three sites: sources near to Industrial fertilizer waste depositary, from a popular trade of bottled water and from tap water provided to Cubatão and Santos inhabitants by the mixed economy company responsible for water supply, sewage collection and treatment of 364 municipalities of São Paulo State; and toinvestigate the xenostrogen-like effect and the toxicity of this substances in the male fertility using an experimental animal model.

2. Material and Methods

A total of 80 male Balb-C mice were divided into 4 groups. They were risen up since they were weaned until they reached sexual maturity inthe same facility at the University of São Paulo Faculty of Medicine. They also received the same type of diet. Each group received water on demand from different sources: Group A (20 mice): bottled mineral water of a same brand; Group B (18 mice): water from the collecting station of SABESP (State Water Supplying Agency), in Itutinga River;

Group C (22 mice): tap water collected from the SABESP supplying system in the city of Cubatão; and Group D (20 mice): water from one of the affluent river in the Itutinga-Pilões Nucleus, State Park of Serra do Mar, which passes by the deactivated industrial waste depositary.

In the State Park of Serra do Mar Environmental Preservation located in Ituitinga-Pilões Nucleus, there was an active industrial waste depositary that worked until 1985. In that occasion, CETESB (State Environmental Protection Agency) detected a soil contamination of heavy metals and pesticides, thus, the waste depositary was deactivated since then. Nowadays, the State Park is one of water collecting locals. The collected water passes by a purifying procedure and supplies the city of Cubatão.

Water from different sources was collected weekly and stored safely regarding the temperature. Water samples of the four different sources were analyzed regarding to concentrations of toxic metals and aromatic polycyclic hydrocarbons (APH), two groups of pollutants that have been found in the Cubatão region.

As soon as they reached sexual maturity, male mice coupled with females in reproductive age for a 7 days period. Female mice received standard supplies of water and diet at the University of São Paulo Faculty of Medical. After this mating time the males were anesthetized and sacrificed by exsanguinations. The testicles were collected and weighted to observe if there was any alteration (edema, inflammation, presence of tumor, etc.), then the espermograms were done by counting the concentration of sperm from epididimus, in a Makler chamber. The sex-ratio of the offspring and the ratio of female pregnancies were also analyzed. After birth and evaluation of the offspring, the females were sacrificed.

Statistical Analysis

The descriptive analyses of all variables of the study were done. The quantitative variables were presented in terms of their values of central trend and dispersion. The percentages of pregnancy and percentage of the male sex were also presented. The tests of Levene and Kolmogorov-Smirnov were used to verify the homogeneity of the variances and then verified if it fits a Gaussian curve. For the variable that satisfied both homogeneity and normal curve parametric tests were employed (ANOVAanalyzes of variance), in other situations non-parametric tests were used (Test of Kruskall-Wallis). When differences were observed, the test of multiple comparisons of Tukey was used. To verify the association between two qualitative variables, the Qui-square test was used (SIEGEL). To compare two ratios the testto compare two proportionswas used (SIEGEL). The level of significance was of 5%. Statistical package used was SPSS 14.0 for windows.

3. Results

Table 1 presentstheconcentration of nine aromatic polycyclic hydrocarbonstested in water samples supplied for the mice groups defined in this study.

Water provided to Group D, which came from one of the affluent river in the Itutinga-Pilões Nucleus, State Park of Serra do Mar, and passes by the deactivated industrial waste depositary presented a concentration of APHs more than fivefold the concentration found in the sample of tap water provided bySABESP to Cubatão inhabitants. Also, APHs concentration on the bottled mineral water (Group A) was higher than those observed in samples from SABESP collecting station (Group B) and tap water (Group C). When we look at each APH, the concentration of Piren in sample provided to Group D was more than ten times those observed in the other water samples.

In terms of toxic metals concentrations in water samples, mercury was detected in all water samples and its concentration in the sample from the contaminated area, which was provided to Group D, was almost nine times the concentrations of mercury found in the other water samples (Table 2).

Table 1. Concentrations of aromatic polycyclic hydrocarbons tested in the water samples supplied for the mice group.

Table 2. Toxic metals in water samples provided for the mice groups.

It is important to notice that lead was only detected in the water that came from the contaminated area and cadmium concentration in the sample provided to Group D was almost fourfold the concentration found in the sample provided to Group B, which came from SABESP collecting station.

Table 3 presents the descriptive analysis of both testicles’ weight according to the exposure groups.

Therewereneither intra-group nor inter-group statistical differences on testes weight.

Table 4 presents descriptive analysis of spermogram parameters (concentration and mobility) in the four experimental groups.

There were no statistical differences on concentration and mobility parameters between the four experimental groups.

Table 5 presents the distributions of offsprings according to sex in each experimental group.

Group B presented the smallest proportion of male offspring and it was statistically different from Groups A and C.

Table 6 presents the percentage of pregnancy in each one of the experimental groups.

Conflicts of Interest

The authors declare no conflicts of interest.

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