Short-term exposure to gossypol causes reversible reproductive toxicity and nephrotoxicity in mice / 南方医科大学学报

OBJECTIVE@#To study the toxic effects of short-term exposure to gossypol on the testis and kidney in mice and whether these effects are reversible.@*METHODS@#Twenty 7 to 8-week-old male mice were randomized into blank control group, solvent control group, gossypol treatment group and drug withdrawal group. In the former 3 groups, the mice were subjected to daily intragastric administration of 0.3 mL of purified water, 1% sodium carboxymethylcellulose solution, and 30 mg/mL gossypol solution for 14 days, respectively; In the drug withdrawal group, the mice were treated with gossypol solution in the same manner for 14 days followed by treatment with purified water for another 14 days. After the last administration, the mice were euthanized and tissue samples were collected. The testicular tissue was weighed and observed microscopically with HE and PAS staining; the kidney tissue was stained with HE and examined for mitochondrial ATPase activity.@*RESULTS@#Compared with those in the control group, the mice with gossypol exposure showed reduced testicular seminiferous epithelial cells with rounded seminiferous tubules, enlarged space between the seminiferous tubules, interstitium atrophy of the testis, and incomplete differentiation of the spermatogonia. The gossypol-treated mice also presented with complete, non-elongated spermatids, a large number of cells in the state of round spermatids, and negativity for acrosome PAS reaction; diffuse renal mesangial cell hyperplasia, increased mesangial matrix, and adhesion of the mesangium to the wall of the renal capsule were observed, with significantly shrinkage or even absence of the lumens of the renal capsules and reduced kidney mitochondrial ATPase activity. Compared with the gossypol-treated mice, the mice in the drug withdrawal group showed obvious recovery of morphologies of the testis and the kidney, acrosome PAS reaction and mitochondrial ATPase activity.@*CONCLUSIONS@#Shortterm treatment with gossypol can cause reproductive toxicity and nephrotoxicity in mice, but these toxic effects can be reversed after drug withdrawal.

Prospects for histone deacetylase inhibitors as antidepressants / 药学学报

Depression is a serious mental illness with a high incidence. At present, we do not fully understand the specific pathological mechanisms of depression, and the efficacy of drug treatments is very limited. Recent studies have shown that epigenetic changes that occur in specific brain regions may be a key mechanism by which environmental factors to interact with individuals to influence the risk of depression. Therefore, drugs that target epigenetic regulation may become a new direction for the development of antidepressants. Histone deacetylase inhibitors (HDACi) are a class of compounds that inhibit histone deacetylase activity, which has been reported to be associated with depression; this article addresses the use of HDACi in preclinical studies, and their potential therapeutic role and limitations of use in depression.

Progress in research of N-acetylaspartate in central nervous system / 药学学报

italic>N-Acetylaspartate (NAA) is a highly abundant brain metabolite. Nowadays, as an important marker reflecting the function of nervous system, NAA is widely used in the results analysis of nuclear magnetic resonance spectroscopy (1H MRS). NAA is synthesized in mitochondria of neurons and metabolized in oligodendrocytes. Additionally, NAA may be converted to the dipeptide N-acetylaspartylglutamate (NAAG), and catabolized into NAA and glutamate in astrocytes. NAA is related to a variety of central nervous system diseases, including Canavan disease, multiple sclerosis, depression, schizophrenia and other mental diseases. Therefore, NAA may be a biomarker of these diseases, and its related enzymes may be used as therapeutic targets for drug screening. Here, we combined the current research on the molecular mechanisms of NAA to reveal the process of NAA generation, metabolism and transport in the brain, explain the possible physiological effects of NAA and discuss its relationship with central nervous system diseases, explore the prospect of NAA in disease prediction and diagnosis, as well as the targeted treatment that may become the breakthrough of refractory diseases.