MiR-182-5p: A Novel Biomarker in the Treatment of Depression in CSDS-Induced Mice.

BACKGROUND: Depression is a neuropsychiatric disease with a high disability rate and mainly caused by the chronic stress or genetic factors. There is increasing evidence that microRNAs (miRNAs) play a critical role in the pathogenesis of depression. However, the underlying molecular mechanism for the pathophysiology of depression of miRNA remains entirely unclear so far. METHODS: We first established a chronic social defeat stress (CSDS) mice model of depression, and depression-like behaviors of mice were evaluated by a series of behavioral tests. Next, we detected several abundantly expressive miRNAs suggested in previous reports to be involved in depression and found miR-182-5p was selected as a candidate for analysis in the hippocampus. Then western blotting and immunofluorescence were used together to examine whether adeno-associated virus (AAV)-siR-182-5p treatment alleviated chronic stress-induced decrease in hippocampal Akt/GSK3ß/cAMP-response element binding protein (CREB) signaling pathway and increase in neurogenesis impairment and neuroinflammation. Furthermore, CREB inhibitor was adopted to examine if blockade of Akt/GSK3ß/CREB signaling pathway abolished the antidepressant actions of AAV-siR-182-5p in mice. RESULTS: Knockdown of miR-182-5p alleviated depression-like behaviors and impaired neurogenesis of CSDS-induced mice. Intriguingly, the usage of agomiR-182-5p produced significant increases in immobility times and aggravated neuronal neurogenesis damage of mice. More importantly, it suggested that 666-15 blocked the reversal effects of AAV-siR-182-5p on the CSDS-induced depressive-like behaviors in behavioral testing and neuronal neurogenesis within hippocampus of mice. CONCLUSIONS: These findings indicated that hippocampal miR-182-5p/Akt/GSK3ß/CREB signaling pathway participated in the pathogenesis of depression, and it might give more opportunities for new drug developments based on the miRNA target in the clinic.

Role of Semaphorin 3A in common psychiatric illnesses such as schizophrenia, depression, and anxiety.

With societal development and an ageing population, psychiatric disorders have become a common cause of severe and long-term disability and socioeconomic burdens worldwide. Semaphorin 3A (Sema-3A) is a secreted glycoprotein belonging to the semaphorin family. Sema-3A is well known as an axon guidance factor in the neuronal system and a potent immunoregulator at all stages of the immune response. It is reported to have various biological functions and is involved in many human diseases, including autoimmune diseases, angiocardiopathy, osteoporosis, and tumorigenesis. The signals of sema-3A involved in the pathogenesis of these conditions, are transduced through its cognate receptors and diverse downstream signalling pathways. An increasing number of studies show that sema-3A plays important roles in synaptic and dendritic development, which are closely associated with the pathophysiological mechanisms of psychiatric disorders, including schizophrenia, depression, and autism, suggesting the involvement of sema-3A in the pathogenesis of mental diseases. This indicates that mutations in sema-3A and alterations in its receptors and signalling may compromise neurodevelopment and predispose patients to these disorders. However, the role of sema-3A in psychiatric disorders, particularly in regulating neurodevelopment, remains elusive. In this review, we summarise the recent progress in understanding sema-3A in the pathogenesis of mental diseases and highlight sema-3A as a potential target for the prevention and treatment of these diseases.

miR-204-5p Plays a Critical Role in the Pathogenesis of Depression and Anti-depression Action of Venlafaxine in the Hippocampus of Mice

Background: Background: Venlafaxine has been demonstrated to treat diseases such as social anxiety disorder and depression. Most of antidepressants including venlafaxine have a certain effect, but significant side effects. Therefore, it is necessary for us to research the development of novel antidepressants for effective treatment in practice. MicroRNA-204 (miR-204) is highly expressed in brain tissue, and plays a critical role in the synaptic plasticity of hippocampal neurons in rats. However, the underlying molecular mechanism of miR-204 remains unclear to date, this study aims to offer unique insights into depression and provide a theoretical basis for clinical physicians. Methods: A chronic social defeat stress (CSDS) was initially adopted for establishing a mice model of depression in this research and depression-like behaviors were evaluated by a series of behavioral experiments including the sucrose preference test (SPT), the tail suspension test (TST), the forced swim test (FST) and the social interaction test (SIT). Quantitative real-time reverse transcription PCR (qRT-PCR) was also conducted to test the expression levels of miR-204 and BDNF in the hippocampus of mice. Finally, gene interference of miR-204-5p was further adopted to test whether miR-204-5p played an effective role in the antidepressant effects of venlafaxine in mice. Results: Our data implicated that CSDS significantly increased the miR-204-5p but not miR-204-3p levels in the hippocampus of mice. The treatment of venlafaxine obviously relieved depression- like behaviors of CSDS-induced mice. The usage of venlafaxine abolished the increasing effects on the expression of miR-204-5p but up-regulated the BDNF expression level in CSDS-exposured mice. More importantly, we found that genetic overexpression of miR-204-5p decreased the reverse effects of venlafaxine on depressive-like behaviors and genetic knockdown of hippocampal miR-204-5p relieved the depressive-like behaviors and neurogenesis in CSDS-induced mice. Conclusion: miR-204-5p played an effective role in the antidepressant effects of venlafaxine in CSDS-induced mice.

Genetic Evaluation of Copy Number Variations, Loss of Heterozygosity, and Single-Nucleotide Variant Levels in Human Embryonic Stem Cells With or Without Skewed X Chromosome Inactivation.

Human embryonic stem cells (hESCs) exhibiting skewed X chromosome inactivation (XCI) have been reported. The copy number variations (CNVs), loss of heterozygosity (LOH), or single-nucleotide variant (SNV) events in those epigenetically distinct cells remain unknown, and whether such genetic abnormalities will influence the XCI status of hESCs is unclear. In this study, three hESCs with skewed XCI, three with random XCI, and two male hESC lines at different passages were analyzed for CNVs and LOH levels using a high-resolution genotyping microarray. Whole-exome sequencing was used to investigate the potentially damaging SNVs. On average, 17.6 CNVs and 5.3 cases of LOH were identified in the skewed hESCs, which were similar to the rates observed in random hESCs. Five recurrent CNV regions were uniquely identified in the skewed hESCs, but all of them were considered polymorphisms. With the exception of a nongenic CNV, no additional CNVs were detected on the X chromosome in the skewed hESCs. Although the XCI status in two hESC lines was observed to be changed from random to skewed, no significant CNV difference was identified before and after the XCI change. SNV analysis indicated that normal alleles are maintained for most genes within copy-neutral LOH regions. Three types of expression patterns were observed in heterozygous alleles, and the damaging SNVs in skewed hESCs favored the expression of the wild-type alleles. In conclusion, in the present study, we did not find genetic differences in the CNV and LOH levels between hESCs with and without skewed XCI. Wild-type allele expression in the presence of damaging SNVs on the X chromosome in skewed hESCs might alleviate adverse effects in those hESCs.

Evolutionary conservation of zebrafish linkage group 14 with frequently deleted regions of human chromosome 5 in myeloid malignancies.

Recurring interstitial loss of all or part of the long arm of chromosome 5, del(5q), is a hallmark of myelodysplastic syndrome and acute myeloid leukemia. Although the genes affected by these changes have not been identified, two critically deleted regions (CDRs) are well established. We have identified 76 zebrafish cDNAs orthologous to genes located in these 5q CDRs. Radiation hybrid mapping revealed that 33 of the 76 zebrafish orthologs are clustered in a genomic region on linkage group 14 (LG14). Fifteen others are located on LG21, and two on LG10. Although there are large blocks of conserved syntenies, the gene order between human and zebrafish is extensively inverted and transposed. Thus, intrachromosomal rearrangements and inversions appear to have occurred more frequently than translocations during evolution from a common chordate ancestor. Interestingly, of the 33 orthologs located on LG14, three have duplicates on LG21, suggesting that the duplication event occurred early in the evolution of teleosts. Murine orthologs of human 5q CDR genes are distributed among three chromosomes, 18, 11, and 13. The order of genes within the three syntenic mouse chromosomes appears to be more colinear with the human order, suggesting that translocations occurred more frequently than inversions during mammalian evolution. Our comparative map should enhance understanding of the evolution of the del(5q) chromosomal region. Mutant fish harboring deletions affecting the 5q CDR syntenic region may provide useful animal models for investigating the pathogenesis of myelodysplastic syndrome and acute myeloid leukemia.