Abstract
AbstractGlucose-6-phosphate dehydrogenase (G6PD) is an important site of metabolic control in the pentose phosphate pathway (PPP) which provides reducing power (NADPH) and pentose phosphates. The former is mainly involved in the detoxification of chemical reactive species; the latter in the regulation of cell proliferation. G6PD deficiency is the most common enzymopathy in the human population, characterized by decreased G6PD activity, mainly in red blood cells, but actually also in nucleated cells. This decreased activity is not due to enzyme synthesis impairment, but rather to reduced enzyme stability, which leads to a shortening of its half-life. Therefore, a major problem is to understand the underlying mechanisms linking G6PD deficiency to oxidative stress and cell proliferation. In order to address this issue, in the present study we utilized, as an experimental model, fibroblasts isolated from pterygium, an ocular proliferative lesion, from G6PD normal and deficient (PFs+ and PFs-, respectively) patients. Our choice was determined by the fact that pterygium is believed to be caused by chronic oxidative stress induced by UV exposure, and that pterygium fibroblasts resemble a tumorigenic phenotype. As controls we utilized fibroblasts isolated from conjunctiva from G6PD normal and deficient patients (NCFs+ and NCFs-, respectively) who had undergone cataract surgery. Growth rate analysis revealed that PFs grow faster than NCFs, but while NCFs- grow more slowly than NCFs+, PFs- and PFs+ grow at the same rate. This was associated with significantly lower G6PD activity in NCFs+ compared to NCFs-, while no significant differences in the G6PD activity of PFs+ and PFs- were noted. This result was supported by the finding that in PFs-, G6PD mRNA levels were significantly higher than in PFs+. Another interesting finding of this study was increased green autofluorescence in both NCFs- and PFs- compared to corresponding positive cells, indicative of pronounced oxidative stress in deficient cells. Finally, abnormal accumulation of neutral lipids, mainly cholesterol esters was observed both in PFs- and PFs+ compared to NCFs- and NCFs+. Though further studies are necessary for better understanding the exact mechanism which links G6PD to oxidative stress and cell proliferation, our data allow to speculate on the role of G6PD on tumorigenesis, and to consider G6PD-deficient subjects at major risk to develop common and dreaded proliferative disorders, such as atherosclerosis and cancer.
Highlights
Glucose-6-phosphate dehydrogenase deficiency (G6PD-) is an X-linked enzymopathy affecting over 400 million people worldwide [1,2] and about 250,000 people in Sardinia, 11% of the population [3]
In an attempt to better understand the biological implications of G6PD deficiency on cell proliferation, in the present study we analyzed the correlation between growth rate, G6PD activity, and lipid metabolism in primary culture of fibroblasts isolated from human normal conjunctiva (NCFs) and pterygium (PFs) of erythrocyte G6PD normal (G6PD+) and deficient (G6PD-) male subjects
NADPH may be produced by the action of (a)NADP-linked malic enzyme, which oxidatively decarboxylates malate to pyruvate; and (b) the mitochondrial enzyme, NADP-linked isocitrate dehydrogenase, there is compelling evidence that G6PD is the principal source of the NADPH utilized in maintaining cellular redox state within the normal range, and in protecting cells from oxidative stress [26]
Summary
Glucose-6-phosphate dehydrogenase deficiency (G6PD-) is an X-linked enzymopathy affecting over 400 million people worldwide [1,2] and about 250,000 people in Sardinia, 11% of the population [3]. Quiescent nucleated cells from subjects with severe decrease in erythrocyte enzyme activity produce lower NADPH levels than cells from erythrocyte-normal G6PD (G6PD+) [6,7], which renders them more vulnerable to reactive oxygen compounds and free radicals. In a previous study we found that the frequency of G6PD deficiency in patients with pterygium was higher than expected: 22% in the pterygium population, compared to 11% in the normal population (unpublished data). For this reason, fibroblasts isolated from this ocular proliferative lesion, seemed to us to be a good experimental model in an attempt to better understand the biological implications of G6PD deficiency on cell proliferation. Since alterations of cholesterol metabolism, mainly cholesterol esters, have been found during the growth of PFs, [18,19,20], iii) cholesterol metabolism was determined in NCFs+, NCFs, PFs+ and PFs-.quiescent and growth stimulated
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