Short Peptoid Evolved from the Key Hydrophobic Stretch of Amyloid-ß42 Peptide Serves as a Potent Therapeutic Lead of Alzheimer's Disease.

Amyloid-ß 42(Aß42), an enzymatically cleaved (1-42 amino acid long) toxic peptide remnant, has long been reported to play the key role in Alzheimer's disease (AD). Aß42 also plays the key role in the onset of other AD-related factors including hyperphosphorylation of tau protein that forms intracellular neurofibrillary tangles, imbalances in the function of the neurotransmitter acetylcholine, and even generation of reactive oxygen species (ROS), disrupting the cytoskeleton and homeostasis of the cell. To address these issues, researchers have tried to construct several strategies to target multiple aspects of the disease but failed to produce any clinically successful therapeutic molecules. In this article, we report a new peptoid called RA-1 that was designed and constructed from the hydrophobic stretch of the Aß42 peptide, 16KLVFFA21. This hydrophobic stretch is primarily responsible for the Aß42 peptide aggregation. Experimental study showed that the RA-1 peptoid is stable under proteolytic conditions, can stabilize the microtubule, and can inhibit the formation of toxic Aß42 aggregates by attenuating hydrophobic interactions between Aß42 monomers. Furthermore, results from various intracellular assays showed that RA-1 inhibits Aß42 fibril formation caused by the imbalance in AchE activity, reduces the production of cytotoxic reactive oxygen species (ROS), and promotes neurite outgrowth even in the toxic environment. Remarkably, we have also demonstrated that our peptoid has significant ability to improve the cognitive ability and memory impairment in in vivo rats exposed to AlCl3 and d-galactose (d-gal) dementia model. These findings are also validated with histological studies. Overall, our newly developed peptoid emerges as a multimodal potent therapeutic lead molecule against AD.

Targeting Chondroitin Sulfate Proteoglycans: An Emerging Therapeutic Strategy to Treat CNS Injury.

Chondroitin sulfate proteoglycans (CSPGs) are the most abundant components of glial scar formed after severe traumatic brain injury as well as spinal cord injury and play a crucial inhibitory role in axonal regeneration by selective contraction of filopodia of the growth cone of sprouting neurites. Healing of central nervous system (CNS) injury requires degradation of the glycosamine glycan backbone of CSPGs in order to reduce the inhibitory effect of the CSPG layer. The key focus of this Viewpoint is to address a few important regenerative approaches useful for overcoming the inhibitory barrier caused by chondroitin sulfate proteoglycans.

Three-Dimensional Microfluidic Platform with Neural Organoids: Model System for Unraveling Synapses.

Unraveling the large number of various signals in the brain under the influence of physical and chemical cues that govern the formation of individual neurons, axons, dendrites, and their functional synapses during the development of neural network is a challenging task. To understand this task, microfluidic devices equipped with microchannels for reconstitution of cell/tissue-culture environments have been studied. Microfluidic devices are emerging as powerful tools in neurobiology, since they are capable of controlling and manipulating the microenvironment of the brain in a precise manner. They can enhance the physiological relevance of three-dimensional (3D) cell culture by allowing spatial control over fluids in micrometer-sized channels. Recent technological advancement in designing microfluidic platforms for studying neural communication, disease progression, and detection of neurotransmitters enhance our fundamental knowledge and understanding. However, more such advanced and innovative interventions are required. This Viewpoint focuses on highlighting a few of them with future scope of further advancement in this field.