Impaired generation of mature neurons due to extended expression of Tlx by repressing Sox2 transcriptional activity.

As a master regulator of the dynamic process of adult neurogenesis, timely expression and regulation of the orphan nuclear receptor Tailless (Tlx) is essential. However, there is no study yet to directly investigate the essential role of precise spatiotemporal expressed Tlx. Here, we generated a conditional gain of Tlx expression transgenic mouse model, which allowed the extended Tlx expression in neural stem cells (NSCs) and their progeny by mating with a TlxCreERT2 mouse line. We demonstrate that extended expression of Tlx induced the impaired generation of mature neurons in adult subventricular zone and subgranular zone. Furthermore, we elucidated for the first time that this mutation decreased the endogenous expression of Sox2 by directly binding to its promoter. Restoration experiments further confirmed that Sox2 partially rescued these neuron maturation defects. Together, these findings not only highlight the importance of shutting-off Tlx on time in controlling NSC behavior, but also provide insights for further understanding adult neurogenesis and developing treatment strategies for neurological disorders.

Tragus Nerve Stimulation Suppresses Post-Infarction Ventricular Arrhythmia by Modulating Autonomic Activity and Heterogeneities of Cardiac Receptor Distribution.

BACKGROUND Imbalanced cardiac autonomic control and cardiac receptors redistribution contribute to the arrhythmogenic substrate under the myocardial infarction (MI) condition. Stimulating the auricular branch of vagus nerve (AB-VNS) has been proven to reduce post-infarction ventricular arrhythmia (VAs), but its potential mechanisms were largely unknown. This study aimed to investigate whether long-term intermittent low-intensity AB-VNS could produce a protective effect on modulating autonomic activities and abnormal redistribution of autonomic nerve efferent receptors in a MI canine model. MATERIAL AND METHODS Twelve healthy beagle dogs underwent ligation of the left anterior descending coronary artery to establish a MI model and were randomized into 2 groups: an AB-VNS group, (AB-VNS for 4 weeks) and a control group (sham stimulation for 4 weeks). Dynamic electrocardiogram recording, neural recording, catecholamine concentration, and histological studies were conducted subsequently. RESULTS Compared to the control group, the AB-VNS group had significantly suppressed post-infarction VAs, reduced low frequency (LF) power and increased high frequency (HF) power. In the AB-VNS group, with the progression of reduced cardiac sympathetic activities and augmented cardiac parasympathetic activities, the catecholamine concentration in heart tissue declined in the peripheral infarction area and right ventricle (RV); tyrosine hydroxylase (TH)-positive neurons decreased in the inferior cardiac sympathetic nerve, and choline acetyltransferase (ChAT)-positive neurons increased in the cervical vagus nerve. Expression of TrkA and P75NGFR were reduced in the peripheral MI (peri-MI) and non-MI area with AB-VNS. The mRNA expression of adrenergic and nicotinic receptors (ß1-AR, ß3-AR, and CHRNA7) significantly declined in the peri-MI and non-MI area of the AB-VNS group. CONCLUSIONS Chronic intermittent low-intensity AB-VNS effectively suppressed post-infarction VAs by potentially rebalancing extracardiac intrathoracic autonomic activities, reducing excessive cardiac sympathetic denervation, and attenuating the heterogeneities of cardiac efferent nerve receptors distribution.

The aOECs Facilitate the Neuronal Differentiation of Neural Stem Cells in the Inflammatory Microenvironment Through Up-Regulation of Bioactive Factors and Activation of Wnt3/ß-Catenin Pathway.

The therapeutic application of neural stem cells (NSCs) in the central nerve system (CNS) injury is a promising strategy for combating irreversible neuronal loss. However, a variety of obvious inflammatory responses following nerve injury rapidly create an unfavorable microenvironment for survival and neuronal differentiation of NSCs in lesion area, limiting the efficacy of NSC-based therapy for CNS injury. It remained unknown how to effectively increase the neuronal differentiation efficiency of NSCs through transplantation. Here, we demonstrated that curcumin (CCM)-activated olfactory ensheathing cells (aOECs) effectively promoted neuronal differentiation of NSCs in the activated microglial inflammatory condition, and co-transplantation of aOECs and NSCs improved neurological recovery of rats after spinal cord injury (SCI), as evidenced by higher expression levels of neuronal markers and lower expression levels of glial markers in the differentiated cells, greater number of Tuj-1-positive cells as well as higher Basso, Beattie, and Bresnahan (BBB) locomotor scale, compared to the corresponding controls. Pathologically, hematoxylin and eosin (HE) staining and immunostaining also showed that aOECs remarkably enhanced the in vivo neuronal differentiation of NSCs and migration, and nerve repair. Further analysis revealed that the underlying mechanisms of aOECs potentiating the neuronal conversion of NSCs under inflammatory environment were tightly associated with up-regulation of anti-inflammatory cytokines and neurotrophic factors in OECs, and importantly, the activation of Wnt3/ß-catenin pathway was likely involved in the mechanisms underlying the observed cellular events. Therefore, this study provides a promising strategy for SCI repair by co-transplantation of aOECs and NSCs.