Manabu Nishikawa

Mitochondrial generation of reactive oxygen species and its role in aerobic life.

Mitochondria are the major site for the generation of ATP at the expense of molecular oxygen. Significant fractions (approximately 2%) of oxygen are converted to the superoxide radical and its reactive metabolites (ROS) in and around mitochondria. Although ROS have been known to impair a wide variety of biological molecules including lipids, proteins and DNA, thereby causing various diseases, they also play critical roles in the maintenance of aerobic life. Because mitochondria are the major site of free radical generation, they are highly enriched with antioxidants including GSH and enzymes, such as superoxide dismutase (SOD) and glutathione peroxidase, on both sides of their membranes to minimize oxidative stress in and around this organelle. The present work reviews the sites and mechanism of ROS generation by mitochondria, mitochondrial localization of Mn-SOD and Cu,Zn-SOD which has been postulated for a long time to be a cytosolic enzyme. The present work also describes that a cross-talk of molecular oxygen, nitric oxide (NO) and superoxide radicals regulates the circulation, energy metabolism, apoptosis, and functions as a major defense system against pathogens. Pathophysiological significance of ROS generation by mitochondria in the etiology of aging, cancer and degenerative neuronal diseases is also described.

L-Carnitine inhibits cisplatin-induced injury of the kidney and small intestine.

Although cis-diamminedichloroplatinum (II) (cisplatin) is a potent anticancer drug, clinical use of this agent is highly limited predominantly because of its strong side effects on the kidney and gastrointestinal tracts. We found that cisplatin impaired respiratory function and DNA of mitochondria in renal proximal tubules and small intestinal mucosal cells, thereby inducing apoptosis of epithelial cells. Cisplatin-induced mitochondrial dysfunction and DNA (mtDNA) injury, lipid peroxidation, and apoptosis of epithelial cells in the kidney and small intestine were strongly inhibited by L-carnitine. However, carnitine had no appreciable effect on the tumoricidal action of cisplatin against cancer cells inoculated in the peritoneal cavity. These results indicate that L-carnitine may have therapeutic potential for inhibiting the side effects of cisplatin and other anticancer agents in the kidney and small intestine.

L-carnitine inhibits hepatocarcinogenesis via protection of mitochondria.

Hepatocellular carcinoma is usually preceded by chronic inflammation. However, the molecular mechanism in hepatocarcinogenesis is not well known. Recently, we reported that mitochondrial dysfunction plays an important role in hepatocarcinogenesis via the production of free radicals. Furthermore, we proved that L‐carnitine effectively protects mitochondrial function in vivo. Therefore, we investigated whether long‐term administration of L‐carnitine could prevent hepatitis and subsequent hepatocellular carcinoma in Long‐Evans Cinnamon rats that are often analyzed as a model of hepatocarcinogenesis. The results indicated that oxidative stress elicited from abnormally accumulated copper increased the amount of free fatty acids, thereby inducing mitochondrial dysfunction, resulting in cell death and enhanced secondary generation of reactive oxygen species, which were significantly inhibited by carnitine treatment. Finally, the occurrence of placental glutathione S‐transferase‐positive foci as a marker for preneoplastic lesions and hepatocarcinogenesis were significantly inhibited by L‐carnitine. These facts suggest that mitochondrial injury plays an essential role in the development of hepatocarcinogenesis and that the clinical use of carnitine has excellent therapeutic potential in individuals with chronic hepatitis.

Accumulation of mitochondrial DNA mutation with colorectal carcinogenesis in ulcerative colitis

We recently reported that oxidative stress elicited by chronic inflammation increases the mutation of mitochondrial DNA (mtDNA) and possibly correlates with precancerous status. Since severe oxidative stress is elicited in the colorectal mucosa of individuals with ulcerative colitis (UC), the possible occurrence of an mtDNA mutation in the inflammatory colorectal mucosa and colitic cancer was investigated. Colorectal mucosal specimens were obtained from individuals with UC with and without colitic cancer and from control subjects. The frequency of mtDNA mutations was higher in colorectal mucosal specimens from patients with UC than that from control subjects. The levels of 8-hydroxy-2′-deoxyguanosine, a DNA adduct by reactive oxygen species, were significantly higher in UC than in control. Specimens from patients with colitic cancer contained a significantly higher number of mtDNA mutations. The present observations suggest that the injury followed by the regeneration of colorectal mucosal cells associated with chronic inflammation causes accumulation of mtDNA mutations. The increased instability of genes, including those on the mtDNA, is consistent with the high and multicentric incidence of colorectal cancer in individuals with UC. Thus, analysis of mtDNA could provide a new criterion for the therapeutic evaluation, and may be useful for the prediction of risk of carcinogenesis.

Oxygen‐dependent regulation of the respiration and growth of Escherichia coli by nitric oxide

To elucidate the role of nitric oxide (NO) in the metabolisms of enteric bacteria, its effect on the respiration and growth of Escherichia coli was examined. Respiration of E. coli was reversibly inhibited by NO particularly under low oxygen tensions. Growth of E. coli was also inhibited by NO more strongly under low oxygen tension than at its high concentration. Because the intestinal lumen is anaerobic, even a small amount of NO might strongly inhibit the energy metabolism and growth of E. coli and other enteric bacteria in vivo than in air atmospheric conditions in which oxygen tension is unphysiologically high.

L-carnitine inhibits hypoglycemia-induced brain damage in the rat.

Hypoglycemia sometimes occurs in patients with diabetes mellitus who receive excessive doses of insulin. Severe hypoglycemia has been known to induce mitochondrial swelling followed by neuronal death in the brain. Since L-carnitine effectively preserves mitochondrial function in various cells both in vitro and in vivo, we investigated its effects on the neuronal damage induced by hypoglycemic insult in male Wistar rats. Animals were given L-carnitine-containing water (0.1%) for 1 week and then received insulin (20 U/kg, i.p.) to induce hypoglycemia. Although L-carnitine did not affect the mortality of animals that developed hypoglycemic shock, it improved the cognitive function of the survived animals as assessed by the Morris water-maze test. L-carnitine effectively inhibited the increase in oxidized glutathione and mitochondrial dysfunction in the hippocampus and prevented neuronal injury. L-carnitine also inhibited the decrease in mitochondrial membrane potential and the generation of reactive oxygen species in hippocampal neuronal cells cultured in glucose-deprived medium. These results suggest that L-carnitine prevents hypoglycemia-induced neuronal damage in the hippocampus, presumably by preserving mitochondrial functions. Thus, L-carnitine may have therapeutic potential in patients with hypoglycemia induced by insulin overdose.

Correlation between clinical characteristics and mitochondrial D-loop DNA mutations in hepatocellular carcinoma.

BackgroundMitochondrial DNA (mtDNA) mutations are found in many kinds of human cancer. The aim of this study was to evaluate the relationship between mtDNA mutations in the liver and human hepatocarcinogenesis.MethodsDirect sequencing of mtDNA was done in 54 hepatocellular carcinomas (HCCs) and 47 surrounding liver tissue samples, obtained from 54 patients with HCC, and in 5 liver samples without inflammation, obtained from 5 patients with metastatic liver tumors. We also examined p53 mutations in the 54 HCCs to examine the correlation between nuclear DNA mutations and mtDNA mutations.ResultsMutations of mtDNA in the D-loop region were found in both HCC and noncancerous liver tissue. In normal liver without chronic inflammation, no mtDNA mutation was detected. In every case, the number of mtDNA mutations in HCC correlated with that in noncancerous liver tissue. Twelve of 52 mutation sites in the D-loop region of mtDNA were specific for HCC. The mean number of mtDNA mutations was 1.7 in well-differentiated HCC, as compared with 4.5 in moderately differentiated HCC and 4.6 in poorly differentiated HCC. The frequency of mtDNA mutations was thus higher in less differentiated HCC. We detected p53 mutations in 15 (28%) of 54 HCCs. The mean number of mtDNA mutations was 5.3 in HCC with p53 mutations and 3.8 in HCC with wild-type p53 (P = 0.024).ConclusionsA higher frequency of mtDNA mutations was found in less differentiated HCCs, and it is also possible that mtDNA mutations are related to nuclear DNA mutations in HCC. The accumulation of mtDNA mutations is a useful predictor of hepatocarcinogenesis.

Cross talk of nitric oxide, oxygen radicals, and superoxide dismutase regulates the energy metabolism and cell death and determines the fates of aerobic life.

Although oxygen is required for the energy metabolism in aerobic organisms, it generates reactive oxygen and nitrogen species that impair a wide variety of biological molecules, including lipids, proteins, and DNA, thereby causing various diseases. Because mitochondria are the major site of free radical generation, they are highly enriched with enzymes, such as Mn-type superoxide dismutase in matrix, and antioxidants including GSH on both sides of inner membranes, thus minimizing oxidative stress in and around this organelle. We recently showed that a cross talk of nitric oxide and oxygen radicals regulates the circulation, energy metabolism, reproduction, and remodeling of cells during embryonic development, and functions as a major defense system against pathogens. The present work shows that Cu/Zn-type superoxide dismutase, which has been postulated for a long time to be a cytosolic enzyme, also localizes bound to inner membranes of mitochondria, thereby minimizing oxidative stress in and around this organelle, while mitochondrial association decreases markedly with the variant types of the enzyme found in patients with familial amyotrophic lateral sclerosis. We also report that a cross talk of nitric oxide, superoxide, and molecular oxygen cooperatively regulates the fates of pathogens and their hosts and that oxidative stress in and around mitochondria also determines cell death in the development of animals and tissue injury caused by anticancer agents by some carnitine-inhibitable mechanism.

L-carnitine suppresses the onset of neuromuscular degeneration and increases the life span of mice with familial amyotrophic lateral sclerosis.

Amyotrophic lateral sclerosis (ALS) is a fatal disease caused by progressive degeneration of motor neurons in the spinal cord and motor cortex. Although the etiology of ALS remains unknown, a mutation of the gene encoding Cu,Zn-superoxide dismutase (SOD1) has been reported in 20% of familial cases of ALS (FALS). Transgenic mice that overexpress a mutated human SOD1 exhibit a phenotype and pathology similar to those observed in patients with FALS. Mitochondrial abnormality has been reported in patients with ALS and in animal models of FALS. We recently reported that L-carnitine, an essential cofactor for the beta-oxidation of long-chain fatty acids, effectively inhibits various types of mitochondrial injury and apoptosis both in vitro and in vivo. The present study demonstrates that oral administration of L-carnitine prior to disease onset significantly delayed the onset of signs of disease (log-rank P=0.0008), delayed deterioration of motor activity, and extended life span (log-rank P=0.0001) in transgenic mice carrying a human SOD1 gene with a G93A mutation (Tg). More importantly, subcutaneous injection of L-carnitine increased the life span of Tg mice (46% increase in male, 60% increase in female) even when given after the appearance of signs of disease.

Free radical theory of apoptosis and metamorphosis

Abstract Reactive oxygen species (ROS) are the major factors that induce oxidative modification of DNA and gene mutation. ROS can elicit oxidative stress and affect a wide variety of physiological and pathological processes including embryonal development, maturation and aging.