Small ncRNA binding protein, PIWI: A potential molecular bridge between blood brain barrier and neuropathological conditions

Abstract

The blood brain barrier (BBB) is a neuroprotective layer that maintains the homeostasis of central nervous system and provides an appropriate environment for neurons to execute their functions. The fundamental role of the dynamic semi-permeable BBB is selective and stringent transport of molecules from circulating blood and surrounding extracellular matrix across brain. Disruption of BBB has critical implications that can lead to various neuropathological disorders (NPDs) namely multiple sclerosis, Alzheimer’s disease, epilepsy, traumatic brain injuries and neuropsychiatric disorders, etc. Therapeutic management of NPDs is still a daunting challenge in the field of neuromedicine and there is a great need for identifying novel drug targets and biomarkers. Recently, noncoding RNAs (ncRNA) have emerged as promising prognostic markers in NPDs. Piwi interacting RNAs (piRNA), a family of short noncoding RNAs which in association with PIWI-like proteins have shown to regulate neuronal function and memory formation. In addition, piRNAs are differentially expressed in Alzheimer’s brain tissues and studies also revealed the association of denovo mutations in PIWI genes with autism. Moreover, the role of PIWI-like proteins in neuronal long-term potentiation and neurite outgrowth is now evident, confirming their importance in normal physiology of the brain. Notably, we have reported the significance of PIWI-like proteins in the maintenance of Blood Retinal Barrier (BRB) and its potential role in diseases like diabetic retinopathy through modulation of tight junction proteins. Further studies in hydra and cancer cells confirmed the important function of PIWI-like proteins in the organization of tight junctions. Interestingly, we also observed that loss of PIWI-like proteins affected the activity of Ephrin receptors which have an established functional link to tight junction assembly. Collectively, the evidences profoundly support the novel concept that piRNAs/PIWI-like proteins may have a potential role on the governance of BBB by altering the tight junctions through Ephrin effectors, commotion of which could be the preceding event to various NPDs. Here, we propose PIWI-like proteins and associated piRNAs as potential restorative drug targets for combating neuropathological conditions.