Neural protection by naturopathic compounds—an example of tetramethylpyrazine from retina to brain

Given the advantages of being stable in the ambient environment, being permeable to the blood–brain and/or blood–eye barriers and being convenient for administration, naturopathic compounds have growingly become promising therapeutic candidates for neural protection. Extracted from one of the most common Chinese herbal medicines, tetramethylpyrazine (TMP), also designated as ligustrazine, has been suggested to be neuroprotective in the central nervous system as well as the peripheral nerve network. Although the detailed molecular mechanisms of its efficacy for neural protection are understood limitedly, accumulating evidence suggests that antioxidative stress, antagonism for calcium, and suppression of pro-inflammatory factors contribute significantly to its neuroprotection. In animal studies, systemic administration of TMP (subcutaneous injection, 50 mg/kg) significantly blocked neuronal degeneration in hippocampus as well as the other vulnerable regions in brains of Sprague–Dawley rats following kainate-induced prolonged seizures. Results from us and others also demonstrated potent neuroprotective efficacy of TMP for retinal cells and robust benefits for brain in Alzheimer’s disease or other brain injury. These results suggest a promising prospect for TMP to be used as a treatment of specific neurodegenerative diseases. Given the assessment of the distribution, metabolism, excretion, and toxicity information that is already available on most neuroprotective naturopathic compounds such as TMP, it would not take much preclinical data to justify bringing such therapeutic compounds to clinical trials in humans

Cytological and Biochemical Effects of St. John’s Wort Supplement (A Complex Mixture of St. John’s Wort, Rosemary and Spirulina) on Somatic and Germ Cells of Swiss Albino Mice

Commercially available St. John’s wort supplement (SJWS) composed of an herbal mixture of St. John’s Wort (SJW), Rosemary (RM) and Spirulina (SP) is used as a dietary supplement for the treatment of psychiatric disorders. Although the minor ingredients, (RM and SP) are proven antioxidants, their quantity is quite insignificant as compared to the SJW, which is the major ingredient. Most of the toxic effects of SJWS are attributed to the main constituents of SJW which differ due to the influence of light (hypericin) and variations in temperature above freezing point (hyperforin). However, there are no reports on toxicity of SJWS maintained at room temperature in pharmacies and supermarkets. In view of the folkloric importance, immense (prescribed or unprescribed) use and a paucity of literature on SJWS, it was found worthwhile to (1) determine the genotoxic effects of SJWS in somatic and germ cells of mice and (2) investigate the role of biochemical changes, as a possible mechanism. The protocol included the oral treatment of mice with different doses (380, 760 and 1520 mg/kg/day) of SJWS for 7 days. The following experiments were conducted: (i) cytological studies on micronucleus test, (ii) cytogenetic analysis for meiotic chromosomes, (iii) cytological analysis of spermatozoa abnormalities, (iv) quantification of proteins and nucleic acids in hepatic and testicular cells and (v) estimation of malondialdehyde (MDA) and nonprotein sulfhydryl (NP-SH) in hepatic and testicular cells. The treatment increased the frequency of micronuclei in polychromatic erythrocytes (PCE) in the femora. It caused aberrations in chromosomes of testes and induced spermatozoa abnormalities. These changes might be attributed to the epigenetic mechanisms as revealed by an increase in concentrations of MDA and depletion of nucleic acids and NP-SH levels in both hepatic and testicular cells observed in the present study. Since, the samples of SJWS used were not drawn from extremities of light and temperature; the observed effect might not be related to the main constituents of SJW. However, these changes might be ascribed to the combined effect of terpenes, tannins, quercetin and flavonoids present in SJW

Neurovascular Protective Effect of FeTPPs in N-Methyl-d-Aspartate Model : Similarities to Diabetes

We have previously shown a causal role of peroxynitrite in mediating retinal ganglion cell (RGC) death in diabetic and neurotoxicity models. In the present study, the role of peroxynitrite in altering the antioxidant and antiapoptotic thioredoxin (Trx) system will be investigated as well as the subsequent effects on glial activation and capillary degeneration. Excitotoxicity of the retina was induced by intravitreal injection of N-methyl-d-aspartate (NMDA) in rats, which also received the peroxynitrite decomposition catalyst FeTPPs. RGC loss was assessed by terminal deoxynucleotidyl transferase-mediated dUTP nick-end labeling and GC count. Glial activation and nitrotyrosine were assessed by immunohistochemistry. Acellular capillaries and pericytes were counted in retinal trypsin digest. NMDA-induced peroxynitrite formation caused RGC loss, which was associated with enhanced expression of Trx and its endogenous inhibitor thioredoxin interacting protein. The results also showed enhanced thioredoxin interacting protein/Trx binding and disruption of the Trx/apoptosis signal-regulating kinase 1 “inhibitory complex,” leading to release of apoptosis signal-regulating kinase 1 and activation of the apoptotic pathway, as evidenced by p38 MAPK and poly-ADP-ribose polymerase activation. Furthermore, NMDA caused glial activation and compromised retinal vasculature, as indicated by acellular-capillary formation and pericyte loss. Treatment with FeTPPs blocked these effects. In conclusion, NMDA-induced retinal neuro/vascular injury is mediated by peroxynitrite-altered Trx antioxidant defense, which in turn activates the apoptosis signal-regulating kinase-1 apoptotic pathway. In addition to acute RGC death, an NMDA model can be a useful tool to study glial activation and capillary degeneration in retinal neurodegenerative disorders, including diabetic retinopathy

Negative regulation of multifunctional Ca2+/calmodulin-dependent protein kinases: physiological and pharmacological significance of protein phosphatases

Multifunctional Ca2+/calmodulin-dependent protein kinases (CaMKs) play pivotal roles in intracellular Ca2+ signaling pathways. There is growing evidence that CaMKs are involved in the pathogenic mechanisms underlying various human diseases. In this review, we begin by briefly summarizing our knowledge of the involvement of CaMKs in the pathogenesis of various diseases suggested to be caused by the dysfunction/dysregulation or aberrant expression of CaMKs. It is widely known that the activities of CaMKs are strictly regulated by protein phosphorylation/dephosphorylation of specific phosphorylation sites. Since phosphorylation status is balanced by protein kinases and protein phosphatases, the mechanism of dephosphorylation/deactivation of CaMKs, corresponding to their ‘switching off', is extremely important, as is the mechanism of phosphorylation/activation corresponding to their ‘switching on'. Therefore, we focus on the regulation of multifunctional CaMKs by protein phosphatases. We summarize the current understanding of negative regulation of CaMKs by protein phosphatases. We also discuss the biochemical properties and physiological significance of a protein phosphatase that we designated as Ca2+/calmodulin-dependent protein kinase phosphatase (CaMKP), and those of its homologue CaMKP-N. Pharmacological applications of CaMKP inhibitors are also discussed. These compounds may be useful not only for exploring the physiological functions of CaMKP/CaMKP-N, but also as novel chemotherapies for various diseases