An In Silico Study on Withania somnifera Bioactives and Curcumin Analogs as Potential Inducers of Smoothened (Smo) Receptor of Sonic Hedgehog (SHH) Pathway to Promote Oligodendrogenesis.

Demyelinating disorder is a subset of neurodegenerative conditions wherein factors such as aging and/or auto-immune attack cause damage and degradation of myelin sheath which enwraps the neuronal axons. Lowered axonal integrity and sub-par conduction of nerve impulses due to impaired action potentials make neurodegeneration imminent as the neurons do not have mitotic ability to replenish their numbers. Oligodendrocytes (OLs) myelinate the axonal segments of neurons and perform neuronal maintenance. Neuroregenerative stem cell therapy exploits this property for remyelination by targeting OL replenishment using in vitro stem cell differentiation protocols for inducing OL lineage cells. But some shortcomings of such protocols are over-reliance on synthetic inducers, lengthy differentiation process, low differentiation efficiency besides being financially expensive. This in silico study sought to identify herbal substitutes of currently available OL-lineage-specific synthetic inducers from a virtual library of curcumin analogs and Withania somnifera bioactives. Smoothened (Smo) receptor belonging to the canonical sonic hedgehog (SHH) signaling pathway promotes in vivo differentiation of OLs as well as their subsequent lineage progression to myelinating OLs. Therefore, we performed pharmacokinetics prediction for the bioactives followed by their molecular docking and molecular dynamics simulation with Smo. From a pool of 1289 curcumin analogs and 80 Withania somnifera-derived bioactives, the best docked ligands were identified as the compounds with PubChem IDs 68815167 and 25880, respectively. Molecular dynamics simulation of these ligands further concluded the Withania somnifera bioactive 25880 to have the best activity with Smo. This compound may be deemed as a potential lead molecule for an agonistic interaction with and activation of Smo to initialize its downstream signaling cascade for enriching OL differentiation.

Comparative evaluation of divergent concoction of NGF, BDNF, EGF, and FGF growth factor's role in enhancing neuronal differentiation of adipose-derived mesenchymal stem cells.

MSCs (Mesenchymal Stem Cells) can differentiate into various lineages, including neurons and glial cells. In the past few decades, MSCs have been well explored in the context of neuronal differentiation and have been reported to have the immense potential to form distinct kinds of neurons. The distinguishing features of MSCs make them among the most desired cell sources for stem cell therapy. This study involved the trans-differentiation of Adipose-derived human Mesenchymal Stem Cells (ADMSCs) into neurons. The protocol employs a cocktail of chemical inducers in different combinations, including Brain-derived neurotrophic factor (BDNF), epidermal growth factor (EGF), and Nerve growth factor (NGF) Fibroblastic growth factor (FGF), in induction media. Both types have been successfully differentiated into neurons, confirmed by morphological aspects and the presence of neural-specific markers through RT-PCR (Reverse transcription polymerase chain reaction) studies and immunocytochemistry assay. They have shown excellent morphology with long neurites, synaptic connections, and essential neural markers to validate their identity. The results may significantly contribute to cell replacement therapy for neurological disorders.

Inhibition of LINGO1 as a therapeutic target to promote axonal regeneration and repair for neurological disorders.

The Central nervous system is blemished by the high incidence of neurodegenerative diseases, which is known to cause disfiguration of regeneration and repair of axonal growth. Recognition of proteins that act as agents of repressing such repair has become the norm to tackle these abominable conditions. One such protein is LINGO1 that act as a repressor for axonal growth. Being one of the critical causative agents of several neurodegenerative pathways. Consequently, its inhibition may tend to help the outcomes of regenerative technologies aiming to outweigh the symptoms of neurodegenerative diseases. For this objective, LINGO1 was targeted with pharmacophore analogs of Fasudil and Ibuprofen, as they are known to have a deterring effect against the concerned protein. 1-Tosyl-2-(chloromethyl)-2,3-dihydro-1H-indole was found showing the least binding score of - 6.8, with verified ADMET admissibility. The pharmacological activity of the said ligand was estimated with QSAR tool showing favourable electro-steric model. All this was finally collaborated with a molecular dynamics simulation study which exhibited a stable structure compatibility of the ligand with LINGO-1. Further, the efficacy of the compound can be evaluated through experimental studies for inferring its future potential and utilization as an effective means to tackle neuronal regeneration and remyleination. Supplementary Information: The online version contains supplementary material available at 10.1007/s13205-023-03789-4.

Therapeutical growth in oligodendroglial fate induction via transdifferentiation of stem cells for neuroregenerative therapy.

The merits of stem cell therapy and research are undisputed due to their widespread usage in the treatment of neurodegenerative diseases and demyelinating disorders. Cell replacement therapy especially revolves around stem cells and their induction into different cell lineages both adult and progenitor - belonging to each germ layer, prior to transplantation or disease modeling studies. The nervous system is abundant in glial cells and among these are oligodendrocytes capable of myelinating new-born neurons and remyelination of axons with lost or damaged myelin sheath. But demyelinating diseases generate tremendous deficit between myelin loss and recovery. To compensate for this loss, analyze the defects in remyelination mechanisms as well as to trigger full recovery in such patients mesenchymal stem cells (MSCs) have been induced to transdifferentiate into oligodendrocytes. But such experiments are riddled with problems like prolonged, tenuous and complicated protocols that stretch longer than the time taken for the spread of demyelination-associated after-effects. This review delves into such protocols and the combinations of different molecules and factors that have been recruited to derive bona fide oligodendrocytes from in vitro differentiation of embryonic stem cells (ESCs), induced pluripotent stem cells (iPSCs) and MSCs with special focus on MSC-derived oligodendrocytes.

The cross-talk between mucormycosis, steroids and diabetes mellitus amidst the global contagion of COVID-19.

Mucormycosis is an opportunistic fungal disease that targets individuals having an impaired immune system due to a wide array of risk factors including HIV-AIDS, immunosuppressive therapy, diabetes mellitus, etc. The current explosive outbreak of coronavirus disease 2019 (COVID-19) has become the latest threat to such patients who are already susceptible to secondary infections. Physiological outcomes of COVID-19 end up in a cascade of grave alterations to the immunological profile and irreparable harm to their respiratory passage, heart and kidneys. Corticosteroidal treatment facilitates faster recovery and alleviates the adverse pathological effects of the severe acute respiratory syndrome coronavirus 2 (SARS-CoV-2). But clinical reports lend this approach a darker perspective especially if these patients have pre-existing diabetes mellitus. The mucormycotic fungal genera belonging to the order Mucorales not only survive but thrive under the comorbidity of COVID-19 and diabetes, often staying undetected until they have inflicted irreversible damage. Steroidal usage has been noted to be a common thread in the sudden spurt in secondary fungal infections among COVID-19 cases. Once considered a rare occurrence, mucormycosis has now acquired a notoriously lethal status in mainstream medical hierarchy. We set out to investigate whether corticosteroidal therapy against COVID-19 emboldens the development of mucormycosis. We also assess the conditions brought forth by steroidal usage and uncontrolled progression of diabetes in COVID-19 cases and their effect on the susceptibility towards mucormycosis.