RESUMO
As people's living standards improve, the development trend of diabetes has gradually become severe. Diabetes is a chronic inflammatory disease associated with abnormal expression of nuclear factor-kappa B (NF-κB) in patients. NF-κB exists in various tissue cells and participates in the regulation of a variety of genes related to immune function and inflammation. Varieties of factors can activate NF-κB when the body is stimulated by external factors, so as to produce inflammation and other reactions. Previous studies on NF-κB mainly focus on cancer, and the pathological mechanism of the treatment of diabetes by related signaling pathways and the progress of traditional Chinese medicine (TCM) treatment have not been systematically elaborated on. By referring to the relevant literature in China and abroad, it was found that NF-κB is not isolated in the development and progression of diabetes but is associated with signal molecules related to inflammation, oxidative stress, and energy metabolism, and it is involved in mediating inflammation, pancreatic β cell apoptosis, insulin signal transduction, and other physiological functions. Therefore, blocking the transmission of NF-κB signaling pathway is beneficial to the treatment of diabetes. At present, Western medicine for the treatment of diabetes mainly includes oral hypoglycemic drugs and insulin injections, but the adverse reactions are obvious. TCM has been characterized by multi-target, extensive action, and excellent curative effects in the treatment of diabetes. TCM and its compounds with functions of tonifying Qi and promoting blood circulation, regulating qi and eliminating phlegm, clearing heat and detoxifying, and nourishing Yin and moistening dryness can effectively intervene in the abnormal expression of NF-κB signaling pathway in vivo through anti-inflammatory effects. In this paper, the association between NF-κB signaling pathway and diabetes was summarized, and the modern research progress of TCM intervention of NF-κB signaling pathway in the treatment of diabetes in the past five years was reviewed, so as to lay a laboratory foundation for the study of a new pathological mechanism of diabetes based on NF-κB signaling pathway and provide new targets and research direction for the prevention and treatment of diabetes and development of related TCM.
RESUMO
Objective:To investigate the protective effect of interfering peptide TAT-GluA2CT on hippocampal neurons in the Lithium chlorine-Pilocarpine status epilepticus model and the optimal time of administration.Methods:Male SD rats (72 cases) were induced to status epilepticus by using Lithium chlorine-Pilocarpine, while a control group ( n=12) was established.The 72 rats were divided into epilepsy group ( n=12), TAT-sham peptide group ( n=12), TAT-GluA2CT peptide group ( n=48) according to the random number table method, and the TAT-GluA2CT peptide group were further divided into the pre-1 h group ( n=12), the post-2 h group ( n=12), the post-4 h group( n=12), and the post-6 h group ( n=12) according to the administration time of the TAT-GluA2CT peptide.Nissl staining and terminal dUTP nick end labeling (TUNEL) assay were performed on 6 rats each from control group, epilepsy group, TAT-shampeptide group, pre-1 h group, post-2 h group, post-4 h group, and post-6 h group to observe the morphological changes and apoptosis of neurons in the CA1 region of the rat hippocampus.Western blot and co-immunopercipitation test were used to detect the expression of GluA2[second subunit of α-amino-3-hydroxy-5-methyl-4-isoxazole propionic acid (AMPA) recepter] and the coupling of GluA2/transmembrane AMPA receptor regulatory protein (TARP γ-8) complex in control group, epilepsy group, pre-1 h group, post-2 h group, post-4 h group and post-6 h group.The t-test was used to compare the data differences between 2 groups, and one-way ANOVA was adopted to compare the differences between the groups. Results:Compared with the epilepsy group, the number of neurons in each TAT-GluA2CT peptide group increased significantly, and the difference was statistically significant( epilepsy group 20.07±3.51, pre-1 h group 39.40±2.39, post-2 h group 38.43±2.42, post-4 h group 30.30±2.55, and post-6 h group 27.93±3.20, F=235.28, P<0.05). Compared with the epilepsy group, the number of apoptotic cells in each TAT-GluA2CT peptide group was significantly reduced, and the difference was statistically significant(epilepsy group 31.47±3.19, pre-1 h group 7.30±3.45, post-2 h group 9.27±3.81, post-4 h group 12.86±3.08, and post-6 h group 14.43±3.13, F=248.60, P<0.05). Compared with the control group, the expression of hippocampal GluA2 decreased after epilepsy induction, and the difference was statistically significant(control group 21 626.53±2 700.58, epilepsy group 14 578.16±2 917.02, pre-1 h group 13 375.47±3 180.54, post-2 h group 15 244.10±1 390.41, post-4 h group 15 799.16±4 559.49, post-6 h group 15 722.95±1 756.01, F=3.83, P<0.05). No statistical difference was observed in the expression of GluA2 between the TAT-GluA2CT peptide group and the epilepsy group( F=0.45, P=0.77). Compared with the epilepsy group, GluA2/TARPγ-8 complex coupling was decreased in each TAT-GluA2CT peptide group, and the difference was statistically significant(epilepsy group 24 509.80±3 718.54, pre-1 h group 12 055.18±5 847.11, post-2 h group 9 630.51±5 805.17, post-4 h group 12 749.35±7 108.45, post-6 h group 11 092.98±7 330.08, F=10.68, P<0.05). Compared with the epilepsy group, the incubation period of seizures in the pre-1 h group was prolonged and the seizure rating was decreased, with statistically significant differences[epilepsy group (18.58±3.99) min, pre-1 h group (103.25±9.21) min, t=29.23, P<0.05]. Conclusions:TAT-GluA2CT peptide can attenuate the neuronal damage in hippocampus of epileptic rats.The neuroprotective effect of TAT-GluA2CT peptide was most obvious at 1 h before or 2 h after administration of Pilocarpine.
RESUMO
Epilepsy occurs as a result of episodic abnormal synchronous discharges in cerebral neuronal networks.It is characterized by an imbalance between excitatory and inhibitory neurotransmission.Although various non-conventional mechanisms are implicated in epileptic synchronization, glutamate excitatory neurons play an essential role.AMPA receptors mediate fast synaptic excitation within and between brain regions relevant to epilepsy, and play a role in epileptogenesis and in seizure-induced brain damage.However, direct modulation of AMPA receptors may have undesirable consequences, given its wide expression within the central nervous system and critical roles on brain circuitry development.Hippocampal CA1 region, as the main site of epilepsy, selectively regulates the high expression of AMPA receptor GluA2 subunit and transmembrane AMPA receptor regulatory protein family(TARPs)γ-8 subtype and its complex GluA2/TARPγ-8, whether it can produce anti-epileptic and avoid adverse reactions.