Takuji Shirasawa

Carnosic acid, a catechol-type electrophilic compound, protects neurons both in vitro and in vivo through activation of the Keap1/ Nrf2 pathway via S-alkylation of targeted cysteines on Keap1

Electrophilic compounds are a newly recognized class of redox‐active neuroprotective compounds with electron deficient, electrophilic carbon centers that react with specific cysteine residues on targeted proteins via thiol (S‐)alkylation. Although plants produce a variety of physiologically active electrophilic compounds, the detailed mechanism of action of these compounds remains unknown. Catechol ring‐containing compounds have attracted attention because they become electrophilic quinones upon oxidation, although they are not themselves electrophilic. In this study, we focused on the neuroprotective effects of one such compound, carnosic acid (CA), found in the herb rosemary obtained from Rosmarinus officinalis. We found that CA activates the Keap1/Nrf2 transcriptional pathway by binding to specific Keap1 cysteine residues, thus protecting neurons from oxidative stress and excitotoxicity. In cerebrocortical cultures, CA‐biotin accumulates in non‐neuronal cells at low concentrations and in neurons at higher concentrations. We present evidence that both the neuronal and non‐neuronal distribution of CA may contribute to its neuroprotective effect. Furthermore, CA translocates into the brain, increases the level of reduced glutathione in vivo, and protects the brain against middle cerebral artery ischemia/reperfusion, suggesting that CA may represent a new type of neuroprotective electrophilic compound.

Inhibition of autophagy in the heart induces age-related cardiomyopathy.

Constitutive autophagy is important for control of the quality of proteins and organelles to maintain cell function. Damaged proteins and organelles accumulate in aged organs. We have previously reported that cardiac-specific Atg5 (autophagy-related gene 5)-deficient mice, in which the gene was floxed out early in embryogenesis, were born normally, and showed normal cardiac function and structure up to 10 weeks old. In the present study, to determine the longer-term consequences of Atg5-deficiency in the heart, we monitored cardiac-specific Atg5-deficient mice for further 12 months. First, we examined the age-associated changes of autophagy in the wild-type mouse heart. The level of autophagy, as indicated by decreased LC3-II (microtubule-associated protein 1 light chain 3-II) levels, in the hearts of 6-, 14- or 26-month-old mice was lower than that of 10-week-old mice. Next, we investigated the cardiac function and life-span in cardiac-specific Atg5-deficient mice. The Atg5-deficient mice began to die after the age of 6 months. Atg5-deficient mice exhibited a significant increase in left ventricular dimension and decrease in fractional shortening of the left ventricle at the age of 10 months, compared to control mice, while they showed similar chamber size and contractile function at the age of 3 months. Ultrastructural analysis revealed a disorganized sarcomere structure and collapsed mitochondria in 3- and 10-month-old Atg5-deficient mice, with decreased mitochondrial respiratory functions. These results suggest that continuous constitutive autophagy has a crucial role in maintaining cardiac structure and function.

Cytoplasmic superoxide causes bone fragility owing to low‐turnover osteoporosis and impaired collagen cross‐linking

The aging process correlates with the accumulation of cellular and tissue damage caused by oxidative stress. Although previous studies have suggested that oxidative stress plays a pathologic role in the development of bone fragility, little direct evidence has been found. In order to investigate the pathologic significance of oxidative stress in bones, we analyzed the bone tissue of mice deficient in cytoplasmic copper/zinc superoxide dismutase (CuZn‐SOD, encoded by the Sod1 gene; Sod1−/−). In this study, we showed for the first time that in vivo cytoplasmic superoxide caused a distinct weakness in bone stiffness and decreased BMD, aging‐like changes in collagen cross‐linking, and transcriptional alterations in the genes associated with osteogenesis. We also showed that the surface areas of osteoblasts and osteoclasts were decreased significantly in the lumbar vertebrae of Sod1−/− mice, indicating the occurrence of low‐turnover osteopenia. In vitro experiments demonstrated that intracellular oxidative stress induced cell death and reduced the proliferation in primary osteoblasts but not in osteoclasts, indicating that impaired osteoblast viability caused the decrease in osteoblast number and suppressed RANKL/M‐CSF osteoclastogenic signaling in bone. Furthermore, treatment with an antioxidant, vitamin C, effectively improved bone fragility and osteoblastic survival. These results imply that intracellular redox imbalance caused by SOD1 deficiency plays a pivotal role in the development and progression of bone fragility both in vivo and in vitro. We herein present a valuable model for investigating the effects of oxidative stress on bone fragility in order to develop suitable therapeutic interventions.

Carnosic acid protects neuronal HT22 Cells through activation of the antioxidant-responsive element in free carboxylic acid- and catechol hydroxyl moieties-dependent manners.

In a previous study, we found that carnosic acid (CA) protected cortical neurons by activating the Keap1/Nrf2 pathway, which activation was initiated by S-alkylation of the critical cysteine thiol of the Keap1 protein by the electrophilicquinone-type of CA [T. Satoh, K. Kosaka, K. Itoh, A. Kobayashi, M. Yamamoto, Y. Shimojo, C. Kitajima, J. Cui, J. Kamins, S. Okamoto, T. Shirasawa, S.A. Lipton, Carnosic acid, a catechol-type electrophilic compound, protects neurons both in vitro and in vivo through activation of the Keap1/Nrf2 pathway via S-alkylation of targeted cysteines on Keap1. J Neurochem., in press]. In the present study, we used HT22 cells, a neuronal cell line, to test CA derivatives that might be more suitable for in vivo use, as an electrophile like CA might react with other molecules prior to reaching its intended target. CA and carnosol protected the HT22 cells against oxidative glutamate toxicity. CA activated the transcriptional antioxidant-responsive element of phase-2 genes including hemeoxygenase-1, NADPH-dependent quinone oxidoreductase, and gamma-glutamyl cysteine ligase, all of which provide neuroprotection by regulating cellular redox. This finding was confirmed by the result that CA significantly increased the level of glutathione. We synthesized a series of its analogues in which CA was esterified at its catechol hydroxyl moieties to prevent the oxidation from the catechol to quinone form or esterified at those moieties and its carbonic acid to stop the conversion from CA to carnosol. In both cases, the conversion and oxidation cannot occur until the alkyl groups are removed by an intracellular esterase. Thus, the most potent active form as the activator of the Keap1/Nrf2 pathway, the quinone-type CA, will be produced inside the cells. However, neither chemical modulation potentiated the neuroprotective effects, possibly because of increased lipophilicity. These results suggest that the neuroprotective effects of CA critically require both free carboxylic acid and catechol hydroxyl moieties. Thus, the hydrophilicity of CA might be a critical feature for its neuroprotective effects.

Protective effects of astaxanthin on 6-hydroxydopamine-induced apoptosis in human neuroblastoma SH-SY5Y cells

Parkinson’s disease (PD) is a neurodegenerative disorder characterized by selective loss of dopaminergic neurons in the substantia nigra pars compacta. Although understanding of the pathogenesis of PD remains incomplete, increasing evidence from human and animal studies has suggested that oxidative stress is an important mediator in its pathogenesis. Astaxanthin (Asx), a potent antioxidant, has been thought to provide health benefits by decreasing the risk of oxidative stress‐related diseases. This study examined the protective effects of Asx on 6‐hydroxydopamine (6‐OHDA)‐induced apoptosis in the human neuroblastoma cell line SH‐SY5Y. Pre‐treatment of SH‐SY5Y cells with Asx suppressed 6‐OHDA‐induced apoptosis in a dose‐dependent manner. In addition, Asx strikingly inhibited 6‐OHDA‐induced mitochondrial dysfunctions, including lowered membrane potential and the cleavage of caspase 9, caspase 3, and poly(ADP‐ribose) polymerase. In western blot analysis, 6‐OHDA activated p38 MAPK, c‐jun NH2‐terminal kinase 1/2, and extracellular signal‐regulated kinase 1/2, while Asx blocked the phosphorylation of p38 MAPK but not c‐jun NH2‐terminal kinase 1/2 and extracellular signal‐regulated kinase 1/2. Pharmacological approaches showed that the activation of p38 MAPK has a critical role in 6‐OHDA‐induced mitochondrial dysfunctions and apoptosis. Furthermore, Asx markedly abolished 6‐OHDA‐induced reactive oxygen species generation, which resulted in the blockade of p38 MAPK activation and apoptosis induced by 6‐OHDA treatment. Taken together, the present results indicated that the protective effects of Asx on apoptosis in SH‐SY5Y cells may be, at least in part, attributable to the its potent antioxidative ability.

Oxidative stress in skeletal muscle causes severe disturbance of exercise activity without muscle atrophy.

The increase in reactive oxygen species (ROS) levels that occurs during intense exercise has been proposed to be one of the major causes of muscle fatigue. In addition, the accumulation of cellular damage due to ROS is widely regarded to be one of the factors triggering age-related pathological conditions in skeletal muscle. To investigate the pathological significance of oxidative stress in skeletal muscle, we generated skeletal muscle-specific manganese superoxide dismutase-deficient (muscle-Sod2(-/-)) mice. The mutant mice showed severe disturbances in exercise activity, but no atrophic changes in their skeletal muscles. In histological and histochemical analyses, the mutant mice showed centralized nuclei in their muscle fibers and selective loss of enzymatic activity in mitochondrial respiratory chain complexes. In addition, the mutant mice displayed increased oxidative damage and reduced ATP content in their muscle tissue. Furthermore, a single administration of the antioxidant EUK-8 significantly improved exercise activity and increased the cellular ATP level in skeletal muscle. These results imply that the superoxide anions generated in mitochondria play a pivotal role in the progression of exercise intolerance.

Retinal dysfunction and progressive retinal cell death in SOD1-deficient mice.

The superoxide dismutase (SOD) family is a major antioxidant system, and deficiency of Cu,Zn-superoxide dismutase (SOD1) in mice leads to many different phenotypes that resemble accelerated aging. The purpose of this study was to examine the morphology and physiology of the sensory retina in Sod1(-/-) mice. The amplitudes of the a- and b-waves of electroretinograms elicited by stimuli of different intensity were reduced in senescent Sod1(-/-) mice, and this reduction in amplitude was more pronounced with increasing age. Retinal morphometric analyses showed a reduced number of nuclei in both the inner nuclear cell layer and outer nuclear cell layer. Electron microscopy revealed swollen cells and degenerated mitochondria in the inner nuclear cell and outer nuclear cell layer of senescent Sod1(-/-) mice indicating necrotic cell death. Terminal deoxynucleotidyl transferase-mediated dUTP nick end labeling revealed no significant differences in the number of apoptotic cells between Sod1(-/-) and wild-type mice, and activated caspase-3 could not be detected in the retina of Sod1(-/-) mice. In addition to the age-related macular degeneration-like phenotypes previously reported, Sod1(-/-) mice also present progressive retinal degeneration. Our results indicate that Sod1(-/-) mice may be a good model system in which to study the mechanism of reactive oxygen species-mediated retinal degeneration.

Role of Nrf2 and p62/ZIP in the neurite outgrowth by carnosic acid in PC12h cells.

Neurotrophins such as NGF promote neuronal survival and differentiation via the cell surface TrkA neurotrophin receptor. Compounds with neurotrophic actions that are low in molecular weight and can permeate the blood-brain barrier are promising therapeutic agents against neurodegenerative diseases such as Alzheimers disease. Carnosic acid (CA), an electrophilic compound in rosemary, activates antioxidant responsive element (ARE)-mediated transcription via activation of Nrf2. In the present study, we discovered that CA strongly promotes neurite outgrowth of PC12h cells. NGF as well as CA activated Nrf2, whereas CA and NGF-mediated neuronal differentiation was suppressed by Nrf2 knockdown. On the other hand, CA activated TrkA-downstream kinase Erk1/2 independently of Nrf2. CA-induced p62/ZIP expression in an Nrf2-dependent manner, while the CA-induced neural differentiation was suppressed by p62/ZIP knockdown. Furthermore, CA-induced ARE activation was attenuated both by p62/ZIP knockdown and a Trk signal inhibitor. These results suggest that the CA induction of p62/ZIP by Nrf2 enhances TrkA signaling which subsequently potentiates Nrf2 pathway. This is the first demonstration that activation of the Nrf2-p62/ZIP pathway by a low-molecular natural electrophilic compound plays important roles in TrkA-mediated neural differentiation and may represent the common molecular mechanism for neurotrophic activities of electrophilic compounds.

Identification of Physiological and Toxic Conformations in Aβ42 Aggregates

Aggregation of the 42‐residue amyloid β‐protein (Aβ42) plays a crucial role in the pathogenesis of Alzheimers disease (AD). Despite numerous structural studies on Aβ aggregates, the relationship between tertiary structure and toxicity remains unclear. Our proline scanning and solid‐state NMR studies suggested that aggregates both of wild‐type Aβ42 and of E22K‐Aβ42 (one of the mutants related to cerebral amyloid angiopathy) contain two conformers: a major one with a turn at positions 25 and 26, and a minor one with a turn at positions 22 and 23. To identify the toxic conformer, the derivative Aβ42‐lactam(22K–23E), in which the side chains at positions 22 and 23 were covalently linked, was synthesized as a minor conformer surrogate, along with Aβ42‐lactam(25K–26E) as a major conformer surrogate. The Aβ42‐lactam(22K–23E) showed stronger aggregation, neurotoxicity, radical generation, and oligomerization than wild‐type Aβ42, whereas in Aβ42‐lactam(25K–26E) were weak. The transition from the physiological conformation with a turn at positions 25 and 26 to the toxic conformation with a turn at positions 22 and 23 might be a key event in the pathogenesis of AD.

Copper/Zinc Superoxide Dismutase Insufficiency Impairs Progesterone Secretion and Fertility in Female Mice

ABSTRACT Copper/zinc superoxide dismutase (CuZn-SOD, SOD1) is one of the major antioxidant enzymes, and is localized in the cytoplasm to scavenge superoxide. To investigate the physiological role of SOD1 in the ovaries, we analyzed the fertility of Sod1-deficient female mice. To evaluate their hormonal metabolism, we measured pituitary and ovarian hormone levels in the plasma of the mutant mice. Plasma follicle-stimulating hormone, luteinizing hormone, and estradiol were not altered in the mutant compared to the wild-type females, while the plasma progesterone level was significantly reduced in the mutant females. Furthermore, the mutant mice showed decreased progesterone secretion under the condition of superovulation. In a histochemical analysis, we observed a remarkable reduction in the corpus luteum area in the mutant ovaries without atrophic changes. The mutant mice also displayed enhanced superoxide generation in the region surrounding the corpora lutea, which was associated with increased apoptotic cells and suppressed vasculature. These results suggested that SOD1 deficiency dysregulated luteal formation because of increased superoxide generation in the ovary. In vitro fertilization experiments showed no abnormal fertilization of Sod1-deficient oocytes. In addition, when Sod1-deficient embryos were transferred into the oviducts of wild-type females, mutant embryos developed at a normal rate, indicating that SOD1 deficiency in embryos did not cause miscarriage in the uterus of wild-type females. These results indicated that increased intracellular ROS impaired luteal formation and progesterone production in the mutant females, thus suggesting that SOD1 plays a crucial role in both the luteal function and the maintenance of fertility in female mice.