Objective To investigate the effect of propofol on human renal tubule epithelial cell (HK-2 cells) fibrosis induced by ATP depletion/recovery and the role of transforming growth factor β activated kinase 1 (TAK1) in it.Methods HK-2 cells were seeded in 96-well plates,and randomly divided into 4 groups (n =36 each) using a random number table:control group (group C),ATP depletion/recovery group (group D/R),propofol group (group P),and TAK1 over-expression group (group T).HK-2 cells were exposed to antimycin A for 1 h and then returned to normal culture medium to establish the model of ATP depletion/recovery-induced injury.At 1 h before ATP depletion,the cells were incubated for 1 h in the DMEM liquid culture medium containing propofol with the final concentration of 20 μmol/L in group P,and the cells were incubated for 1 h in the DMEM liquid culture medium containing propofol with the final concentration of 20 μmol/L and TAK1 with the titer of 2× 107 TU/ml in group T,and the other treatments were similar to those previously described in group D/R.At 12 h after ATP recovery,the cell viability was evaluated by methyl thiazolyl tetrazolium assay,and cell apoptosis was detected using TUNEL and scored.The expression of TAK1 was detected using Western blot at 12,24 and 48 h after ATP recovery.The expression of α-smooth muscle actin (αSMA),fibronectin (FN),and collagen protein 1 (COL1) was measured at 48 h after ATP recovery.Results Compared with group C,the cell viability was significantly decreased,the apoptosis score was increased,and the expression of TAK1,COL1,αSMA and FN was up-regulated after ATP recovery in D/R,P and T groups (P＜0.05).Compared with group D/R,the cell viability was significantly increased,the apoptosis score was decreased,and the expression of TAK1,COL1,αSMA and FN was down-regulated after ATP recovery in P and T groups (P＜0.05).Compared with group P,the cell viability was significantly decreased,the apoptosis score was increased,and the expression of TAK1,COL1,αSMA and FN was up-regulated after ATP recovery in group T (P＜ 0.05).Conclusion Propofol can reduce HK-2 cell fibrosis induced by ATP depletion/recovery,and the mechanism may be related to down-regulation of TAK1 expression.

AIM: To probe into the anti-epilepsy action of artificial Calculus Bovis,by observing its effect on the behavioral of the experimental epileptic rats,neuron loss in the hippocampus and hilus,and GAD positive cell alteration in the hippocampus.METHODS: SD rats were divided into three groups: group A(artificial Calculus Bovis treatment group);group B(acute epilepsy group) and group C(control group).A model of acute epilepsy rats was established by PTZ.The rat's behavioral alteration was observed by the Racine' scale.The neurons in the hippocampus and hilus were calculated by Nissl staining.The GAD positive cells were observed by immunohistochemical staining.RESULTS: The latency of the first seizure in group A was longer than that in group B,while the seizure times in group A was less than that in group B.Besides,in group A,both the neuron loss amount in the hippocampus and hilus and the GAD positive cell loss amount in the hippocampus were less than those in group B.CONCLUSION: The artificial Calculus Bovis prolonged the latency of the first seizure time,decreased the frequency of seizure,and prevented the neuron loss and protected the GAD positive cells.

Oral cancer is a common head and neck malignant tumor. Its molecular mechanism of pathogenesis is complex and needs further exploration. Non-coding RNAs account for more than 95% of human transcripts and include microRNAs, lncRNAs, and circRNAs. They are an important entry point for research on molecular mechanism of oral cancer. Non-coding RNAs and protein-coding genes constitute a complex regulatory system involved in the regulation of physiological and pathological processes. This review summarizes articles about oral cancer-related non-coding RNAs and presents valuable information from the perspectives of microRNA, lncRNA, and circRNA.

Non-small cell lung cancer (NSCLC) is the most important histological type of lung cancer. This disease affects a large number of patients, and the prognosis of advanced patients is poor. Although great progress has been achieved for existing treatment methods, challenges still exist. Cancer is a genetic disease, and its occurrence is accompanied by substantial genomic-sequence instability. (GT/CA)_n repeat sequence is a common microsatellite sequence serving as transcriptional function-related regions, DNA-methylation modification sites, and other functional sites. Its polymorphism is closely related to the expression of EGFR, HO-1, and HIF-1α in NSCLC patients. (GT/CA)_n repeat sequence is the breakthrough point to explore the molecular mechanism of NSCLC occurrence and development, develop molecular markers for diagnosis and prognosis and epigenetics research. This paper summarizes the studies on (GT/CA)_n repeat polymorphisms in NSCLC with the aim of providing references for relevant NSCLC research.

Repairing DNA double-strand breaks (DSBs) with homologous chromosomes as templates is the hallmark of meiosis. The critical outcome of meiotic homologous recombination is crossovers, which ensure faithful chromosome segregation and promote genetic diversity of progenies. Crossover patterns are tightly controlled and exhibit three characteristics: obligatory crossover, crossover interference, and crossover homeostasis. Aberrant crossover patterns are the leading cause of infertility, miscarriage, and congenital disease. Crossover recombination occurs in the context of meiotic chromosomes, and it is tightly integrated with and regulated by meiotic chromosome structure both locally and globally. Meiotic chromosomes are organized in a loop-axis architecture. Diverse evidence shows that chromosome axis length determines crossover frequency. Interestingly, short chromosomes show different crossover patterns compared to long chromosomes. A high frequency of human embryos are aneuploid, primarily derived from female meiosis errors. Dramatically increased aneuploidy in older women is the well-known "maternal age effect." However, a high frequency of aneuploidy also occurs in young women, derived from crossover maturation inefficiency in human females. In addition, frequency of human aneuploidy also shows other age-dependent alterations. Here, current advances in the understanding of these issues are reviewed, regulation of crossover patterns by meiotic chromosomes are discussed, and issues that remain to be investigated are suggested.
Cell Division/physiology* ; Chromosome Segregation/physiology* ; Humans ; Meiosis/genetics* ; Recombination, Genetic