Serum and Erythrocyte Lipoperoxides and Superoxide Dismutase Levels in Normal Persons and Hypertensive Patients

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Korean J Intern Med. 1986;1(1):113-119

doi : https://doi.org/10.3904/kjim.1986.1.1.113

Yog-Gyun Kim, M.D., Jong-Koo Chae, M.D., Sang-Ho Park, M.D., Choon-Hae Chung, M.D., Soon-Pyo Hong, M.D., Kun-Kook Cho, M.D.

Department of Internal Medicine, College of Medicine, Chosun University

Address reprint requests: Kun-kook Cho, M.D., Department of Internal Medicine in Cho-sun University Hospital, Suhsuck-Dong, Kwangju, Korea

Abstract

To assess the role and responses of lipoperoxide and superoxide dismutase in hypertensive disease, the serum and erythrocyte lipid peroxide and erythrocyte superoxide dismutase levels were measured in 65 normal persons and hypertensive patients.

The results are summerized as follows:

In normal persons, serum and erythrocyte lipoperoxide values showed an increase according to age, but the elevation was not statistically significant.
In normal persons, the erythrocyte superoxide dismutase value did not change according to age.
In hypertensive patients, the serum and erythrocyte lipoperoxide values showed increases of 10.8% and 26% respectively compared to those of the controls.
In hypertensive patients, the erythrocyte superoxide dismutase value showed a decrease of 29.9% compared to that of the controls.

Keywords: Lipoperoxides; Superoxide dismutase; Normal person; Hypertensive patients

INTRODUCTION

Glavid¹⁾ reported that lipoperoxide produced in vivo is related to atherosclerosis. We proposed to examine the relationship between the concentration of serum and tissue lipoperoxide with damage to tissue. Recently, it has been noticed that lipoperoxide induces various disease including atherosclerosis.^2–5)

These lipoperoxides are produced by a chain reaction between superoxide radicals and unsaturated fatty acids. Lipoperoxide inhibits production of prostaglandin l₂ in vascular endothelium and causes cell membrane degeneration in smooth muscle cells by polymerization with protein. It is these actions that are thought to be the mechanism behind the development of atherosclerosis.

We investigated the difference between serum and R.B.C. lipoperoxide and the degree of activation of superoxide dismutase in 38 normal controls who had no evidence of atherosclerosis, either symptomatically or by investigation, and 27 hypertensive patients admitted to the Dept. of Internal Medicine, College of Medicine, Chosun University. We report our experimental results with a review of the literature.

SUBJECTS AND MATERIALS

The study involved 2 groups. The control group consisted of 38 hospital staff who showed no evidence of atherosclerotic disease in the general medical check-up. The experimental group consisted of 27 hypertensive patients admitted to the medical department of the Chosun University Hospital, who had not previously been prescribed any drugs that interact with lipid metabolism (Table 1).

Table 1.

Age and sex distribution

Among chemical reagents, ferricytochrome C, xanthine oxidase, xanthine, thiobarbituric acid (T.B.A) and 1,1,3,3-tetraethoxy propane (T.E.P) were purchased from Sigma Chemical Co., St Louise Missouri, U.S.A. E-Merck made E.D.T.A., ammonium sulphate, potassium chloride, potassium phosphate, phospotungstic acid, ethanol and chloroform. Hayashi made sodium dodecyl sulphate and Ishisu made isobutanol.

METHODS

Collection of blood samples: 3.5ml. of venous blood was taken from all subjects after having been starved for more than 12 hours over-night. The serum was immediately separated by centrifugation.

1) Measurement of lipoperoxide

(A) Serum lipoperoxide: We followed the method of Yagi.^8,9) 50μl of serum was accurately pipetted into centrifuge tubes. 4ml. of 1/12N H₂SO₄ and 0.5ml. of 10% phosphotungstic acid were added and mixed thoroughly. The solutions were left at room temperature for 5 minutes and centrifuged at 10°C for 10 minutes at 4,000 r.p.m.

The supernatant was discarded and the precipitate was washed twice by the above mentioned procedure. To the obtained precipitate, 4ml. of distilled water was added yielding a cloudy solution and 1 ml. of T.B.A. reagent solution (0.67% T.B.A. sol. + acetic acid 0.5/0.5% v/v).

The samples were then boiled for 60 minutes at 95°C. After boiling, the test tubes were cooled under running water. To the extract 0.5ml. of n-butanol was added and was shaken vigorously. The n-butanol layer was separated by centrifugation for 10 minutes at 4,000 r.p.m. and the absorbtion was measured at 532nm. in a Shimadzu dual difference spectrofluorphotometer. Lipoperoxide fluorescence was compared to standard solutions of 4ml. T.E.P. (0.55 Mol/ml.).

LP=0.5×5F×1.00.05×1.050.5=5F×21 (nMol/ml of blood serum)LP = Concentration of lipoperoxideF = Fluorescence of standard solution of T.E.P.f = Fluorescence of sample

(B) R.B.C. lipoperoxide: 3.5ml. of blood samples was centrifuged at 4°C after the serum was removed. The cells deposited were treated as follows: 0.9% of normal saline was added in equal volumes to the sediment. The samples were centrifuged for 15 minutes and supernatant discarded. The sediment was treated 3 times in this way to remove water, and ethanol and chloroform solution added in order to precipitate hemoglobin and obtain R.B.C. cytoplasm. To 0.5ml. of the cytoplasmic solution obtained 0.2ml. of 7% sodium dodecyl sulphate solution was added.

Lipoperoxide in R.B.C. cytoplasm was then estimated by the same method as for serum. Sample concentrations were determined from the standard curve of T.E.P., standard over the range of 1–5 nMol/ml.

2) Measurement of superoxide dismutase in R.B.C.: R.B.C. cytoplasm was obtained by the same process as used in the estimation of cytoplasmic lipoperoxide concentrations. The activity of the cytoplasmic superoxide dismutase was estimated by the following method: Xanthine oxidase will produce superoxide radicals from its substrate xanthine. These superoxide radicals will inhibit the reduction of ferricytochrome C. In the prescence of R.B.C. cytoplasm this inhibition will be reduced by utilization of the superoxide radical by any superoxide dismutase present in the cytoplasm. 2.3ml. of 50 mM phosphate buffer (pH 7.8) and 0.3ml. of 0.5mM xanthine are well mixed in a 3ml. cuvette. This was maintained at 25°C in a water bath and 0.1 ml. of xanthine oxidase soution whose activity produced an increase in the light absorbance at a rate of 0.020/min was added. In a second cuvette, we added cytoplasmic coenzyme and recorded the change in light absorbtion. We designated 1 unit as that activity which resulted in a 50% inhibition of the ferricytochrome C reduction rate of the control.

RESULTS

In the control group, the serum lipoperoxide values were 2.41 ± 0.53 nMol/ml in males and 2.35 ± 0.39nMol/ml in females. There was no significant difference between the sexes (p>0.1). The erythrocytes lipoperoxide value in men and women were 1.80 ±0.55 nMol/ml and 1.71 ± 0.62 nMol/ml respectively and again there was no significant difference between the sexes (p>0.1).

When divided by age, the control serum lipoperoxide values were 2.22 ± 0.43 nMol/ml for the 10–39 age group and 2.68 ± 0.48 nMol/ml for the 40–70 age group, and erythrocyte lipoperoxide values were 1.63 ± 0.67 nMol/ml and 1.77 ± 0.59 nMol/ml for the 10–39 and 40–70 age group respectively. Although the trend shows increasing concentration with age they were not statistically significant (Table 2, Fig. 1, 2). In the hypertensive patient group, the serum lipoperoxide values were 3.25 ± 0.41 nMol/ml in men and 3.36 ± 0.68 nMol/ml women, and erythrocyte lipoperoxide values were 2.10 ± 0.50nMol/ml in men and 2.18 ± 0.51 nmol/ml in women.

Table 2.

Lipoperoxide level of blood in control and hypertension

Fig. 1.

Serum lipoperoxide in control according to age, sex, hours. Figure is graphed as mean±S.D. for each time period.

Fig. 2.

Time course of changes in RBC lipoperoxide in control. Figure is graphed as mean±S.D. for each time period. P value is compared with control group. ^***= p<0.005

These represented an increase in the mean values of the combined sexes of 10.8% in serum and 26% in erythrocyte lipoperoxide values (Table 2, Fig. 3 –6).

Fig. 3.

Serum lipoperoxide in hypertension according to sex, and time.

Fig. 4.

RBC lipoperoxide in hypertension according to sex, and time.

Fig. 5.

Serum lipoperoxide in control and hypertension P value is compared with control group. ^***=p<0.005

Fig. 6.

RBC lipoperoxide level in control and hypertension. P value is compared with control group. ^***=p<0.005

In normal persons superoxide dismutase values were 13.46±1.61 units/ml for the 10–39 age group and 13.24±1.68 units/ml for the 40–70 age group and were not significantly different. But in the hypertensive patients the erythrocyte superoxide dismutase values showed a decrease of 29.9% compared to those of the controls (p<0.005) (Table 3).

Table 3.

Superoxide dismutase activity control and hypertension

There was a correlation between lipoperoxed and superoxide dismutase (r=0.02) but this was not significantly different from the normal control group (p<0.1) (Fig. 7, 8).

Fig. 7.

Carrelation in RBC lipoperoxide and S.O.D. in normal. N = 38 p = >0.1 r=0.02

Fig. 8.

Correlation in RBC lipoperoxide and S.O.D. in hypertension. N = 27 P = >0.1 r=0.04

In normal persons superoxide dismutase values were 13.46 ± 1.61 units/ml for the 10-39 age group and 13.24 + 1.68 units/ml for the 40-70 age group and were not significantly different. But in the hypertensive patients the erythrocyte superoxide dismutase values showed a decrease of 29.9% compared to those of the controls (p<0.005) (Table 3).

There was a correlation between lipoperoxide and superoxide dismutase (r = 0.02) but this was not significantly different from the normal control group (p<0.1) (Fig. 7, 8).

DISCUSSION

It has recently been reported that blood lipoperoxide concentration are related to various diseases including atherosclerosis.^2–5) There are two mechanisms by which lipoperoxide may be increased in different diseases. First, synthesis of large amounts of lipoperoxide from the specific diseased organ is released into the blood and secondly, it may be produced in the blood by auto-oxidation of blood lipids.

Unsaturated fatty acid has been recommended rather than cholesterol rich saturated fatty acid to patients with atheroscerosis and hyperlipidemia. However, Chun et al.^13,14) said that unsaturated fatty acid was a factor in precipitating atherosclerosis due to the production of lipoperoxide from it. Sun Chun et al.^5,7) reported that increased lipoperoxide in blood decreased synthesis of prostaglandin l₂ in vascular endothelial cells with subsequent stimulation of platelet aggregation which increased thromboxane A₂ that damaged vascular endothelium, together with the formation of large quentities of L.D.L.

It was also reported that the protein of endothelial and smooth muscle media cells is denatured by conjugation with lipoperoxide resulting in damage to their cell membranes.

Inhibition of lipoperoxide synthesis and or removal of lipoperoxide present, prevented cell membranes from the toxic effects. Henry et al.^15,16,17) announced that vitamin E, a quinine derivative, phenol, superoxide dismutase, peroxide and catalase were antioxidants that decreased lipoperoxide concentration in blood.

Michelson et al.^18,19) reported that superoxide radicals react with thiol groups and tryptophan in cells with a fatal result in human beings. Petrone et al.²⁰⁾ stated that superoxide radicals produced by neutrophils reacted with a precurssor extracellularly to produce neutrophil chemotactic factor (N.C.F.)

McCord et al.^21,22,23) reported that the harmful effect of the superoxide radicals was lost after it was converted to H₂O₂ by superoxide dismutase and that this enzyme was present in every cell of organs utilizing oxygen, preventing the toxicity caused by the presence of the superoxide radical.

Willis^24,25) reports that some cells utilizing triplet oxygen produce intermediate metabolites such as the superoxide radicals. H₂O₂. singlet oxygen and the hydroxyl radical. The superoxide radical is highly active in performing an important role in the bactericidal process of phagocytes. However, superoxide radicals cause injury to living tissue by promoting lipoperoxide reactions with enzymes and nucleic acid. Hassan ^21,26,27,28). Fridovich^{16,17,29–32)} reports that there are scavenger enzymes such as superoxide dismutase, catalase, and peroxidase to clear the harmful effects of oxygen metabolites from the blood. Originally, superoxide dismutase was extracted from ox R.B.C. and liver tissue as cupriferous, hemocupiein or hepatocuprein by Mann and Keilm.³³⁾

Recently Yagi,^8,9) has reported the significance of measuring lipoperoxide concentrations in the diagnosis of heart disease of measuring lipoperoxide concentrations in the diagnosis of heart disease and geriatric disease, since the development of the T.B.A. fluorescence methods which can now estimate the very small concentrations of lipoperoxide present in the blood. Yoo^{13,14,37,38,39)} suggests that atherosclerosis, myocardial infarction and C.V.A. may be prevented by changing the fatty acid intake which will reduce hyperlipidemia and platelet aggregation.

In this study the hypertensive group had significantly higher (10.8%) lipoperoxide concentration than the controls, 3.31 ± 0.54 and 2.45 ± 0.46 nMol/ml respectively (p<0.005). This result is in accordance with the work of Chun.³⁹⁾

In view of the increased lipoperoxide in serum and a decrease in superoxide dismutase in R.B.C. in the hypertensive patients, superoxide dismutase is considered to be a scavenger for oxygen derivatives. Because many factors affect lipoperoxide and superoxide dismatuase further study is needed on their use in the diagnosis of heart and geriatric disease.

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Group	Age	Sex	No. (%)
Normal	10–39	M	9
F	9
Total	18(27.7)
40–70	M	10
F	10
Total	20(30.7)

Hypertension	40–70	M	11
F	16
Total	27(41.6)

Total average(%)		M	30(46.2)
F	35(53.8)
Total	65(100.0)

Table 2.

Lipoperoxide level of blood in control and hypertension

Group	Age	Sex	No.	Serum lipoperoxide (nMol/ml) mean±S.D.		RBC lipoperoxide (nMol/ml) mean±S.D.
Group	Age	Sex	No.	3hrs	12hrs	3hrs	12hrs
Normal control	10–39	M	9	2.13±0.49	1.95±0.58	1.40±0.55	1.27±0.59
		F	9	2.30±0.39	1.63±0.41	1.85±0.73	1.39±0.45
		total	18	2.22±0.43	1.79±0.51	1.63±0.67	1.33±0.52
	4–70	M	10	268±0.57	1,70±0.48	2.16±0.22	1.54±0.47
		F	10	2.69±0.41	1.85±0.39	13.9±0.60	1.25±0.56
		total	20	2.68±0.48	1.87±0.43	1.77±0.59	1.39±0.52
	Average	M	19	2.41±0.53	1.82±0.53	1.80±0.55	1.41 ±0.53
		F	19	2.49±0.39	1,75±0.40	1.61±0.69	1.32±0.50
		total	38	2.45±0.46	1.83±0.47	1.70±0.62	1.37±0.51
Hypertension	4–70	M	11	3.75±0.40	2.15±0.46	2.10±0.50	1.62±0.48
		F	16	3.36±0.68	2.11±0.40	2.18±0.50	1.62±0.37
		total	17	3.31±0.54^***	2.13±0.42	2.15±0.49^*	1.62±0.41

Values are means ± S.D.

P value is compared with control group.

*=0.01<P<0.05

**= 0.005<p<0.01

***=p<p<0.005

Table 3.

Superoxide dismutase activity control and hypertension

Group	Age	Sex	No.	S.O.D. activity (μml)
	10–39	M	9	13.99±1.51
		F	9	12.84±1.56
		Total	18	13.42±1.61

Normal	40–70	M	10	12.44±1.75
		F	10	14.04±1.21
		Total	20	13.24±1.68

	Total	M	19	13.18±1.78
	Average	F	19	13.47±1.48
	Average	Total	38	13.32±1.62

Hypertension	40–70	M	11	9.03±30
		F	16	9.42±2.13
		Total	27	9.26±1.82^***

Values are means ± S.D.

P value is compared with control group.

***= p<0.005