African Health Sciences Makerere University Medical School ISSN: 1680-6905 EISSN: 1729-0503 Vol. 10, Num. 1, 2010, pp. 2-8

African Health Sciences, Vol. 10, No. 1, March, 2010, pp. 2-8

Trace elements and Vitamin E status in Nigerian patients with prostate cancer

*Adaramoye OA ¹, Akinloye O², Olatunji IK³                       

1. Department of Biochemistry, College of Medicine, University of Ibadan, Nigeria.
2. Department of Chemical Pathology, Ladoke Akintola University, Osogbo, Nigeria
3. Cancer Screening Unit, Nuclear Medicine Department, University College Hospital, Ibadan, Nigeria   

* Correspondence author: Dr. O.A. Adaramoye, Drug metabolism and Toxicology Unit, Department of Biochemistry, College of Medicine, University of Ibadan, Nigeria Email: aoadaramoye@yahoo.com Phone: +234-808-8382-846 Fax: +234-2-8103-043

Code Number: hs10002

Abstract

Background: Prostate cancer is the most common type of cancer among men.
Objectives: To investigate the trace elements (Se, Zn, Cu and Cd) and vitamin E status of some Nigerian prostate cancer (PCa) patients relative to their prostate-specific antigen (PSA) values.
Methods: Prostate cancer patients were assigned into groups 1, 2 and 3 with PSA of 5-10 ng/ml, 11-20 ng/ml and > 20 ng/ml, respectively.
Results: The results showed that the levels of whole blood superoxide dismutase (SOD) and serum Se and Zn were significantly lower (p< 0.05) in the PCa patients. Specifically, levels of SOD, Se and Zn decreased by 67%, 30% and 35%; 70%, 52% and 41%; 81%, 58% and 47%, in subjects with PSA of 5-10 ng/ml, 11-20 ng/ml and > 20 ng/ml, respectively. There were no significant differences (p> 0.05) in levels of Cu and Cd. Serum Cu/ Zn ratio were significantly higher in PCa patients. The Cu/ Zn ratios were 1: 1.2: 1.3 for subjects in groups 1, 2 and 3, respectively. Vitamin E levels in PCa patients were significantly lower and followed the order; normal > PSA (5-10) > PSA (11-20) > PSA (> 20).
Conclusions: Deficiency of vitamin E, Zn and Se may be risk factors for development of PCa.

Key words: Lipid peroxidation, Prostate cancer, PSA values, Trace elements, Vitamin E

Introduction

In the United States, prostate cancer is the most commonly diagnosed cancer in men and the second leading cause of cancer deaths. It is estimated that 220,000 cases of PCa may be diagnosed yearly, and this is expected to increase with the expanding geriatric population¹. Despite the extensive clinical and experimental studies over decades, the pathogenesis of Prostate cancer remains unknown. The biochemical and molecular mechanisms responsible for and associated specifically with the development and progression of Prostate cancer are largely unidentified². Coupled with this is the largely ignored role of altered cellular metabolism as an essential factor in Prostate cancer; although transformations of metabolism are implicated in virtually all malignant cells³. The combination of molecular/biochemical relationships is required to identify critical events in Prostate cancer process.

Interest in the essential trace elements as cancer preventative agents was stimulated with the observation that selenium supplementation (200 µg per day) induced a 61% reduction in colorectal cancer in the treatment arm of the Nutritional Prevention of Cancer Trial, a randomized placebo controlled trial for skin cancer prevention⁴. Further epidemiologic evidence for the preventive role of selenium in selenium-poor populations in Linxian, China⁵ showed that combined intervention with selenium, vitamin E, and β-carotene was related to reduced incidence and mortality of gastric cancer and total cancer. Also, vitamin E has been shown to be a promising candidate for Prostate cancer prevention in the α-tocopherol β-carotene cancer prevention study, a controlled smoking trial where α-tocopherol reduced Prostate cancer incidence by 32% and mortality by 41%⁶. The SUpplementation en Vitamines et Mineraux AntioXidants (SUVIMAX) study found a significant reduction in Prostate cancer rates among men receiving a multivitamin containing 30 mg vitamin E, although the protective effect could not be attributed to any specific micronutrient ⁷. In vitro studies have demonstrated that vitamin E can inhibit DNA synthesis ⁸, reduce invasion ⁹, and induce apoptosis ¹⁰ . Only a few studies have evaluated the mechanism of the combination of vitamin E and selenium in PCa ¹¹. Because oxidative stress increases with depletion of trace elements in diseased states as well as androgen exposure in Prostate cancer ¹², a putative risk factor for Prostate cancer therefore is the elevated level of malondialdehyde (an index of oxidative stress). Futhermore, oxidative stress can ameliorate the activities of several selenoenzymes and thereby reduced the preventive efficiency of selenium and zinc as well as their related proteins ¹³. Other trace elements, such as zinc, copper and cadmium are also necessary for the development and progression of Prostate cancer. For example, the total zinc levels in the prostate are ten times higher than those in other soft tissues ¹⁴. Zn is an essential trace element required for normal functions of several enzyme systems such as dehydrogenases, phosphatases, 5α-reductases, carboxypeptidases and carbonic anhydrase ¹⁵. In contrast, the Prostate cancer cells lose their ability to amass Zn and thus the essential roles of Zn are compromised in Prostate cancer cells ¹⁶.

In the present study, the extent of lipid peroxidation, serum concentrations of selenium, zinc, copper, cadmium and vitamin E were determined relative to the PSA values of the subjects.

Subjects

Total of 170 participants were recruited from the Cancer Screening Unit (CSU), University College Hospital (UCH), Ibadan, between 24 and 73 years of age who resided in the South-Western part of Nigeria. 120 participants had PSA in the range of 5.0- 43.8 ng/ml, specifically, they were grouped into low-grade PSA (5-10 ng/ml) (n= 33), medium-grade PSA (11-20 ng/ml) (n=45) and high-grade PSA (> 20 ng/ml) (n= 42). Likewise, 50 apparently normal subjects were recruited as control and had PSA value < 3.0 ng/ml. Exclusion criteria included abstinence from hormonal and/ radiation therapy, use of prescription and non-prescription preparations known to alter PSA (e.g. Saw Palmetto, Finesteride), hormone levels and blood pressure. Those who were eligible were invited and screened during which their blood samples were collected. Written informed consent was obtained from each participant, and the Human Ethical Committee at the Oyo State Ministry of Health, Ibadan, Nigeria, approved the study.

Blood samples were drawn from an antecubital vein of subjects into containers containing EDTA and another portion in plain centrifuge tubes. All sample collection procedures were conducted with a minimal light exposure. The samples in plain centrifuge tubes were allowed to clot, and spun at 3,000 g for 15 minutes in an MSC bench centrifuge to obtain serum which was used for the estimation of total protein, PSA, lipid peroxidation and trace elements (Se, Zn, Cu and Cd). The blood samples in EDTA tubes were spun at 3,000 g for 15 minutes to obtain plasma which was used for the estimation vitamin E, while portion of the whole blood was used for determination of superoxide dismutase level. 

Laboratory and clinical methods

We measured PSA in serum using electrochemiluminesence immunoassays (ECLIAs) from Roche Diagnostics in combination with a Roche/Hitachi MODULAR ANALYTICS device. The sera total protein levels were determined according to the method of Lowry et al.¹⁷ using bovine serum albumin as standard, while the extent of lipid peroxidation was estimated by the method of Buege and Aust¹⁸. The plasma vitamin E levels were estimated according to the method described by Meshali and Nightingale¹⁹. Whole blood superoxide dismutase level was assayed by the method of McCord and Fridovich.²⁰ Standard precautions for trace element determination were taken, samples with signs of hemolysis were discarded. The serum trace elements levels were determined by direct method using atomic absorption spectroscopy (AAS), Shimadzu model AA-580 fitted with a Shimadzu PR-5 graphic printer following the manufacturer's analytical techniques at the International Institute of Tropical Agriculture (IITA), Ibadan, Nigeria. The determination of selenium concentration was done by digesting the serum with a mixture of nitric and perchloric acid. After hydride generation and using a sodium borohydride method, the selenium concentration was determined (AAS Model AA-580). To monitor the reproducibility and accuracy of the analytical techniques, reagent blanks and known samples were interspersed with the test samples.

Statistical analysis

All values were expressed as the mean S.D. (n > 30 in all the groups). Data were analyzed using one-way ANOVA followed by the post-hoc

Duncanmultiple range test for analysis of biochemical data using SPSS version 11 (SPSS Inc Chicago, IIinois). Values were considered statistically significant at p< 0.05.

Results

Table 1 reveals some changes in the levels of total protein, superoxide dismutase, vitamin E and Cu/Zn ratio among prostate cancer patients studied. Plasma vitamin E levels were significantly (p< 0.05) decreased in PCa subjects when compared to normal. Precisely, vitamin E levels were decreased by 30%, 47% and 77% in subjects with PSA (5-10 ng/ml), PSA (11-20 ng/ml) and PSA (>20 ng/ml), respectively.  Furthermore, there were no significant differences (p> 0.05) in the levels of serum total protein in PCa subjects with PSA (5-10 ng/ml) and PSA (11-20 ng/ml) when compared to normal (PSA < 3.0 ng/ml). However, the serum total protein levels were significantly (p< 0.05) reduced in PCa subjects with PSA > 20 ng/ml. There was a positive correlation between the mean age of the patients and their PSA values, i.e. PSA values increased with increase in the mean age of the patients. In addition, the ratios of serum Cu/Zn increased with increase in PSA values of the subjects. Concisely, the serum Cu/Zn ratios were 1: 1.2: 1.3 in subjects with PSA (5-10 ng/ml), PSA (11-20 ng/ml) and PSA (> 20 ng/ml), respectively (Table 1). Also, the whole blood superoxide dismutase levels decreased significantly (p<0.05) in PCa patients when compared to normal.

Figure 1 depicts the levels of serum selenium and zinc in PCa subjects. The serum selenium and zinc levels were significantly lower (p< 0.05) in all categories of patients studied. Specifically, the levels of serum selenium decreased by 30%, 52% and 58%, while the levels of serum zinc decreased by 35%, 41% and 47%, in subjects with PSA of 5-10 ng/ml, 11-20 ng/ml and > 20 ng/ml, respectively.

Figure 2 shows the extent of accumulation of lipid peroxidation products in sera of the subjects studied. The levels of serum lipid peroxidation products were significantly (p< 0.05) higher in Prostate cancer patients when compared to normal. Furthermore, the levels of lipid peroxidation products were elevated by 80%, 107% and 98% in subjects with PSA of 5-10 ng/ml, 11-20 ng/ml and >20 ng/ml, respectively.  In Figure 3, there were no significant differences (p>0.05) in the levels of serum copper and cadmium of the subjects with Prostate cancer when compared to normal.

Discussion

We conducted a fairly large study consisting of 120 suspected Prostate cancer subjects, and 50 apparently normal subjects as control. Overall, lower levels of plasma vitamin E, serum selenium and zinc were observed in these subjects. These parameters were inversely associated with the PSA values of the subjects. This inverse association between serum trace elements and PSA values points to a higher risk of Prostate cancer among the subjects.

Selenium has been hypothesized to play a role in preventing cancers²¹. Epidemiologic studies have demonstrated an inverse association between circulating selenium levels and cancers of the prostate, lung and colorectum ²². This observation was confirmed in the present study. In contrast, with respect to skin cancer hypothesis, recent analyses suggest that selenium supplementation actually increases the risk of non-melanoma skin cancer, particularly squamous cell carcinoma, among participants with higher baseline serum selenium levels²³. However, secondary analyses showed reductions in risk of other cancers, especially prostate cancer; after approximately 4.5 years of treatment and 7.5 years of follow-up, prostate cancer incidence among persons receiving selenium supplements was half that experienced by the placebo group²⁴. The mechanisms by which selenium may decrease cancer risk were summarized by Rayman²⁵. The mechanisms include among others the role of selenium in cell cycle arrest, decreasing cells proliferation, inducing apoptosis, facilitating DNA repair by activation of p53, disruption of androgen receptor signaling, and being a key component of selenoenzymes^{26, 27}, which incorporate selenium as selenocysteine, an infrequently occurring amino acid, into their active center²⁸. The unique redox characteristics of selenocysteine confer important antioxidant properties to these selenoenzymes, such as glutathione peroxidases, selenoprotein P, and thioredoxin reductase, which are all expressed in the prostate²⁹. Because of the low levels of selenium in this study, the essential functions of this element will be hindered in the Prostate cancer patients studied. However, selenium supplementation in Prostate cancer patients may be greatly influenced by genetic variation in the antioxidant enzyme, superoxide dismutase (SOD) genes. Chan et al,³⁰ conducted a cross-sectional epidemiologic study of plasma selenium, an SOD2 variant and aggressive prostate cancer in men. They observed an unexpected positive association between plasma selenium and aggressive disease. Also, an SOD2 variant, a substitution of alanine for valine at amino acid 16 in the antioxidant enzyme SOD, was not statistically significantly associated with aggressive disease, although the relative risks (RRs) for one or two alanine alleles were above 1.0. Two patterns emerged in the analysis of the plasma selenium and SOD2: men with low selenium and two alanine alleles had a higher risk of aggressive disease (compared with low selenium and none or one alanine alleles); high selenium seemingly protected men with two alanine alleles; and men with high selenium and none or one alanine allele had a higher risk of aggressive disease (compared with low selenium and none or one alanine allele). In light of these findings, they concluded that the data "indicate caution against broad use of selenium supplementation for men with prostate cancer" and that "complete interpretation of results should depend on assessment of SOD2 genotype in trial participants."

Our interest was to explore interactions of vitamin E and trace elements in Prostate cancer patients since evidence from animal and human studies showed an association between trace elements and antioxidative nutrients in cancers (including α- and β-carotenes and vitamin E)³¹.

In the present study, a significant decrease in plasma vitamin E levels in Prostate cancer patients was observed. The mean level of plasma vitamin E in subjects with PSA (5-10 ng/ml), PSA (11-20 ng/ml) and PSA (> 20 ng/ml) differs significantly from the normal (PSA < 3.0 ng/ml). The results are in agreement with other workers³². Decreasein vitamin E in these patients could be due to the possibility that vitamin E reacts very rapidly with molecular oxygen and free radicals generated during prostate carcinogenesis. This argument was supported by the fact that lipid peroxidation products were significantly higher in the Prostate cancer subjects relative to normal. The role of reactive oxygen species in the etiology of different cancers is well known^,33.

It is therefore suggested that vitamin E acts as a free radical scavenger protecting polyunsaturated fatty acids from peroxidation reactions in the Prostate cancer subjects³².

Many laboratory studies have shown that the loss of a unique capability to retain high levels of zinc is an important factor in the development and progression of malignant prostate cells. In this study, we found that serum zinc levels in the Prostate cancer group were significantly lower than the control. The cancer group showed the lowest zinc level, whereas the control group consisting mostly of subjects with

Conclusion

In the studied subjects, lowered vitamin E, selenium and zinc levels were associated with higher lipid peroxidation and increased risk of Prostate cancer, which seems more prominent in subjects with PSA values > 5.0 ng/ml. The decrease in serum selenium and zinc in the Prostate cancer patients may be indicative of an inter-relationship of these elements and/or their respective metalloenzymes. This study may therefore serves as a basis for recommending supplementation with vitamin E, selenium and zinc in the long-term management of prostate health.

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