Integrative transcriptomics reveals sexually dimorphic microRNA control of the cholinergic/neurokine interface in schizophrenia and bipolar disorder

Lobentanzer, Sebastian; Hanin, Geula; Klein, Jochen; Soreq, Hermona

doi:10.1101/600932

Cited by 4 publications

(5 citation statements)

References 113 publications

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“…Thanks to these studies, an overview of differences in rodents is slowly building up allowing comparisons with evidence from psychiatric patients to be made. These high‐throughput studies include both microarray and RNA‐sequencing approaches. Both types of technologies allow for a genome‐wide profiling of stress responses in the two sexes and the study of these responses in the context of pathways.…”

Section: Chronic Stressmentioning

confidence: 99%

Sex differences: Transcriptional signatures of stress exposure in male and female brains

Brivio

López

Chen

2020

Genes Brain and Behavior

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More than two‐thirds of patients suffering from stress‐related disorders are women but over two‐thirds of suicide completers are men. These are just some examples of the many sex differences in the prevalence and manifestations of stress‐related disorders, such as major depressive disorder, post‐traumatic stress disorder, and anxiety disorders, which have been extensively documented in clinical research. Nonetheless, the molecular origins of this sex dimorphism are still quite obscure. In response to this lack of knowledge, the NIH recently advocated implementing sex as biological variable in the design of preclinical studies across disciplines. As a result, a newly emerging field within psychiatry is trying to elucidate the molecular causes underlying the clinically described sex dimorphism. Several studies in rodents and humans have already identified many stress‐related genes that are regulated by acute and chronic stress in a sex‐specific fashion. Furthermore, current transcriptomic studies have shown that pathways and networks in male and female individuals are not equally affected by stress exposure. In this review, we give an overview of transcriptional studies designed to understand how sex influences stress‐specific transcriptomic changes in rodent models, as well as human psychiatric patients, highlighting the use of different methodological techniques. Understanding which mechanisms are more affected in males, and which in females, may lead to the identification of sex‐specific mechanisms, their selective contribution to stress susceptibility, and their role in the development of stress‐related psychiatric disorders.

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Section: Chronic Stressmentioning

confidence: 99%

Sex differences: Transcriptional signatures of stress exposure in male and female brains

Brivio

López

Chen

2020

Genes Brain and Behavior

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“…To examine the potential activity of tRFs as regulators of gene expression, we chose to focus on the cholinergic system, which tends to be impaired with age (Perry, 1980), and in neurodegenerative diseases such as PD (Bohnen & Albin, 2011). For this purpose, we defined Cholino‐tRFs as tRFs with the potential to target one core cholinergic gene (i.e., one of the enzymes responsible for the synthesis or breakdown of acetylcholine; cholinergic gene list acquired from Lobentanzer et al, 2019) or at least five genes associated with cholinergic activity in a similar manner to microRNAs (Figure 5a; prediction done by sequences complementarity between the tRFs and the targets, see Methods).…”

Section: Resultsmentioning

confidence: 99%

“…Regarding AD, ample evidence reports sncRNAs shedding into the CSF of patients with AD. A number of miRs, such as miR‐222 and the acetylcholinesterase‐targeting miR‐125b (Lobentanzer et al, 2019), have been shown to be DE in the CSF of AD patients (Dangla‐Valls et al, 2017). Finally, DE sncRNAs have also been shown in the CSF of PD patients, where hsa‐mir‐626, for example, has been the main focus—both as a potential biomarker for disease severity and as a potential therapeutic target (Xia et al, 2019).…”

Section: Discussionmentioning

confidence: 99%

“…Targets with prediction score <0.8 were dropped, aiming to keep only the most plausible targets of each tRF. The specific potential of cholinergic targets was assessed based on predicted targeting of 94 genes that have been associated with cholinergic activity in the brain (Lobentanzer et al, 2019). The genes were weighted by their direct influence on the cholinergic system (Table S1; annotations created using Ensembl release 106—Apr 2022 © EMBL‐EBI; Cunningham et al, 2022) and the cholinergic targeting potential of each tRF was set as the sum of the weight of all of its predicted cholinergic targets.…”

Section: Methodsmentioning

confidence: 99%

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Cerebrospinal fluid and blood profiles of transfer RNA fragments show age, sex, and Parkinson's disease‐related changes

Paldor

Madrer

Vaknine

et al. 2022

Journal of Neurochemistry

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Transfer RNA fragments (tRFs) have recently been shown to be an important family of small regulatory RNAs with diverse functions. Recent reports have revealed modified tRF blood levels in a number of nervous system conditions including epilepsy, ischemic stroke, and neurodegenerative diseases, but little is known about tRF levels in the cerebrospinal fluid (CSF). To address this issue, we studied age, sex, and

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“…Although miR-125b and miR-29b are the top-ranked AD biomarkers in several clinical studies [129][130][131], the mechanism of dysregulation in the blood of AD patients is still unclear. In silico analysis reveals that miR-125b regulates the cholinergic neuron functions by targeting Clock [132]. Further, recent evidence shows that miR-125b regulates neuronal cell growth and apoptosis via the regulation of inflammatory factors and oxidative stress, and this regulation may be related to AD pathogenesis [133].…”

Section: Alzheimer's Diseasementioning

confidence: 99%

MicroRNA: A Key Player for the Interplay of Circadian Rhythm Abnormalities, Sleep Disorders and Neurodegenerative Diseases

et al. 2020

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Circadian rhythms are endogenous 24-h oscillators that regulate the sleep/wake cycles and the timing of biological systems to optimize physiology and behavior for the environmental day/night cycles. The systems are basically generated by transcription–translation feedback loops combined with post-transcriptional and post-translational modification. Recently, evidence is emerging that additional non-coding RNA-based mechanisms are also required to maintain proper clock function. MicroRNA is an especially important factor that plays critical roles in regulating circadian rhythm as well as many other physiological functions. Circadian misalignment not only disturbs the sleep/wake cycle and rhythmic physiological activity but also contributes to the development of various diseases, such as sleep disorders and neurodegenerative diseases. The patient with neurodegenerative diseases often experiences profound disruptions in their circadian rhythms and/or sleep/wake cycles. In addition, a growing body of recent evidence implicates sleep disorders as an early symptom of neurodegenerative diseases, and also suggests that abnormalities in the circadian system lead to the onset and expression of neurodegenerative diseases. The genetic mutations which cause the pathogenesis of familial neurodegenerative diseases have been well studied; however, with the exception of Huntington’s disease, the majority of neurodegenerative diseases are sporadic. Interestingly, the dysfunction of microRNA is increasingly recognized as a cause of sporadic neurodegenerative diseases through the deregulated genes related to the pathogenesis of neurodegenerative disease, some of which are the causative genes of familial neurodegenerative diseases. Here we review the interplay of circadian rhythm disruption, sleep disorders and neurodegenerative disease, and its relation to microRNA, a key regulator of cellular processes.

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Integrative transcriptomics reveals sexually dimorphic microRNA control of the cholinergic/neurokine interface in schizophrenia and bipolar disorder

Cited by 4 publications

References 113 publications

Sex differences: Transcriptional signatures of stress exposure in male and female brains

Sex differences: Transcriptional signatures of stress exposure in male and female brains

Cerebrospinal fluid and blood profiles of transfer RNA fragments show age, sex, and Parkinson's disease‐related changes

MicroRNA: A Key Player for the Interplay of Circadian Rhythm Abnormalities, Sleep Disorders and Neurodegenerative Diseases

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