Neuroprotective potential of Celastrus paniculatus seeds against common neurological ailments: a narrative review

The most common human neurodegenerative diseases like Alzheimer’s disease (AD), Parkinson’s disease (PD), Huntington’s disease (HD) etc. have been recognized to result from a complex interplay between genetic predisposition and defective cellular dynamics such as inappropriate accumulation of unfolded proteins, oxygen free radicals and mitochondrial dysfunction. The treatment strategies available today for these neurodegenerative ailments are only palliative and are incapable of restraining the progression of the disease. Hence, there is an immense requirement for identification of drug candidates with the ability to alleviate neuronal damage along with controlling progression of the disease. From time immemorial mankind has been relying on plants for treating varied types of dreadful diseases. Among the various medicinal plants used for treating various neurological ailments, Celastrus paniculatus (CP) popularly known as Jyotishmati or Malkangni is well known in the Ayurveda system of Indian Traditional Medicine whose seeds and seed oil have been used for centuries in treating epilepsy, dementia, facial paralysis, amnesia, anxiety, sciatica, cognitive dysfunctions etc. This review apart from specifying the phytochemical characteristics and traditional uses of C. paniculatus seeds and seed oil also exemplify the comprehensive data derived from various research reports on their therapeutic potential against some common neurological disorders.

Endoplasmic Reticulum Stress-Associated Neuronal Death and Innate Immune Response in Neurological Diseases

Neuronal death and inflammatory response are two common pathological hallmarks of acute central nervous system injury and chronic degenerative disorders, both of which are closely related to cognitive and motor dysfunction associated with various neurological diseases. Neurological diseases are highly heterogeneous; however, they share a common pathogenesis, that is, the aberrant accumulation of misfolded/unfolded proteins within the endoplasmic reticulum (ER). Fortunately, the cell has intrinsic quality control mechanisms to maintain the proteostasis network, such as chaperone-mediated folding and ER-associated degradation. However, when these control mechanisms fail, misfolded/unfolded proteins accumulate in the ER lumen and contribute to ER stress. ER stress has been implicated in nearly all neurological diseases. ER stress initiates the unfolded protein response to restore proteostasis, and if the damage is irreversible, it elicits intracellular cascades of death and inflammation. With the growing appreciation of a functional association between ER stress and neurological diseases and with the improved understanding of the multiple underlying molecular mechanisms, pharmacological and genetic targeting of ER stress are beginning to emerge as therapeutic approaches for neurological diseases.

Cellular Response to Unfolded Proteins in Depression

Despite many scientific studies on depression, there is no clear conception explaining the causes and mechanisms of depression development. Research conducted in recent years has shown that there is a strong relationship between depression and the endoplasmic reticulum (ER) stress. In order to restore ER homeostasis, the adaptive unfolded protein response (UPR) mechanism is activated. Research suggests that ER stress response pathways are continuously activated in patients with major depressive disorders (MDD). Therefore, it seems that the recommended drugs should reduce ER stress. A search is currently underway for drugs that will be both effective in reducing ER stress and relieving symptoms of depression.

RNA Binding Protein Syncrip Is Required for the Low-Output HSC By Sustaining Proteome Quality

RNA binding proteins (RBPs) have been increasingly recognized as an important class of regulators of normal and malignant hematopoiesis. However, the exact function and underpinning mechanisms of the RBPs that govern hematopoietic stem cells (HSCs) remains poorly characterized. We had previously identified SYNCRIP as a critical RBP that controls leukemia stem cell program in myeloid leukemia. Here, using the novel murine genetic conditional knockout (cKO) model, we delineated the role of SYNCRIP in regulating the low-output HSC. We developed a Syncrip cKO allele and crossed Syncripf/f mice to the interferon (IFN) -a-inducible Mx-1-Cre mice to create Syncripf/f Mx-1-Cre+. We consistently obtained near complete depletion of SYNCRIP 3 weeks after two consecutive Poly(I:C) injections. We observed that SYNCRIP is dispensable for static hematopoiesis and Syncrip KO animals showed equivalent number and frequencies of stem and progenitor cells (Lin-Sca+cKit+ (LSK)- LT-HSC (CD48-CD150+); MPP1 (CD48-CD150-); MPP2 (CD48+CD150+); MPP4 (CD48-CD150-)). However, KO SyncripD/D deficient cells were outcompeted by WT Syncripf/f cells in the transplantation setting (bone marrow (BM) chimerism WT (n=9) 38% ± 7.8% vs. KO (n=9) 2.7% ± 0.8%, p<0.001 at 16 weeks post-transplant) and completely lost their ability to repopulate in secondary recipient animals (WT (n=5) 58% ± 7.4% vs. KO (n=5) 7.2 %± 2.9%, p<0.001 at 16 weeks post-transplant). These data strongly indicate that SYNCRIP is critical for maintenance of long-term self-renewal of HSCs. To decipher the effect of Syncrip deletion on the transcriptomic changes in different cell types upon Syncrip loss, we performed single cell RNA sequencing analysis (scRNA-seq) of sorted LK cells (Lin-cKit+ cells) from KO SyncripD/D (n=3) vs. WT Syncrip f/f (n=3) mice. While there is no significant change in frequencies of stem and progenitor compartments, we found defective trajectory from the HSC that is closely identified as low-output HSC based on previously performed barcoding studies. We observed a strong activation of cellular response to stress and unfolded proteins, in particular the HSF1-dependent pathways upon Syncrip depletion specifically within the HSC population. To further investigate the impacts of SYNCRIP loss in the HSC unfolded protein stress response, we evaluated unfolded proteins in cells using tetraphenylethene maleimide (TMI)-based flow cytometry. The abundance of accessible thiols in unfolded proteins, which is bound by TMI serves as a surrogate measurement for the state of the unfolded proteome. We consistently observed almost 2.5-fold increase in TMI signals specifically in LT-HSC, but not ST-HSCs or MPPs upon SYNCRIP deletion indicating that SYNCRIP is required to maintain high protein quality in HSCs. Similar results were obtained with the epichaperome probe PU-FITC, which consists of HSP90 inhibitor PU-H71 conjugated to FITC. PU-H71 selectively binds to the altered epichaperome, which reflects an accumulation of chaperon networks in an aberrant cellular stress condition. Altogether, these data further confirmed that SYNCRIP depletion tips off the proteostatic balance. To understand the molecular mechanisms underpinning the functional requirement of SYNCRIP in HSPCs, we identified 534 direct mRNA targets of SYNCRIP using hyper-TRIBE method. We performed transcriptomic and proteomic analysis of sorted LT- HSCs and LSKs respectively upon SYNCRIP deletion. We integrated these datasets and found a strong enrichment of SYNCRIP targets in control of cytoskeleton and RHO GTPase related pathways. Using immunofluorescence imaging, we confirmed that SYNCRIP deletion in HSCs resulted in 2-fold reduction in RHO GTPase CDC42 expression coupled with reduced tubulin and a loss of cellular polarity (percentage of tubulin polarized cells 56% WT vs. 40% KO). We also observed that Syncrip deficient HSCs demonstrated reduced expression of lysosomal-associated membrane protein 1 (LAMP-1) and less asymmetric distribution of LAMP1 marked lysosomes during cell division (LAMP1 asymmetric division 25% WT vs. 19% KO). Overexpression of CDC42 restored cell polarity and partly rescued ability of KO SyncripD/D to serially replate. Overall, SYNCRIP is required for maintenance of protein homeostasis and cell polarity of the reserve HSCs. Our study uncovers a new regulatory axis that controls stem cell stress responses to preserve HSC self-renewal. Disclosures No relevant conflicts of interest to declare.

Protein arginylation is regulated during SARS-CoV-2 infection

In 2019, the world witnessed the onset of an unprecedented pandemic. In September 2021, the infection by SARS-CoV-2 had already been responsible for the death of more than 4 million people worldwide. Recently, we and other groups discovered that SARS-CoV-2 infection induces ER-stress and activation of unfolded protein response (UPR) pathway. The degradation of misfolded/unfolded proteins is an essential element of proteostasis and occurs mainly in lysosomes or proteasomes. The N-terminal arginylation of proteins is characterized as an inducer of ubiquitination and proteasomal degradation by the N-end rule pathway. Here we present, for the first time, data on the role of arginylation during SARS-CoV-2 infection. We studied the modulation of protein arginylation in Vero CCL-81 and Calu-3 cells infected after 2h, 6h, 12h, 24h, and 48h. A reanalysis of in vivo and in vitro public omics data combined with immunoblotting was performed to measure the levels of ATE1 and arginylated proteins. This regulation is seen specifically during infections by coronaviruses. We demonstrate that during SARS-CoV-2 infection there is an increase in the expression of the ATE1 enzyme associated with regulated levels of specific arginylated proteins. On the other hand, infected macrophages showed no ATE1 regulation. An important finding revealed that modulation of the N-end rule pathway differs between different types of infected cells. We also confirmed the potential of tannic acid to reduce viral load, and furthermore, to modulate ATE1 levels during infection. In addition, the arginylation inhibitor merbromin (MER) is also capable of both reducing viral load and reducing ATE1 levels. Taken together, these data show the importance of arginylation during the progression of SARS-CoV-2 infection and open the door for future studies that may unravel the role of ATE1 and its inhibitors in pathogen infection.

The Unfolded Protein Response as a Guardian of the Secretory Pathway

The endoplasmic reticulum (ER) is the major site of membrane biogenesis in most eukaryotic cells. As the entry point to the secretory pathway, it handles more than 10,000 different secretory and membrane proteins. The insertion of proteins into the membrane, their folding, and ER exit are affected by the lipid composition of the ER membrane and its collective membrane stiffness. The ER is also a hotspot of lipid biosynthesis including sterols, glycerophospholipids, ceramides and neural storage lipids. The unfolded protein response (UPR) bears an evolutionary conserved, dual sensitivity to both protein-folding imbalances in the ER lumen and aberrant compositions of the ER membrane, referred to as lipid bilayer stress (LBS). Through transcriptional and non-transcriptional mechanisms, the UPR upregulates the protein folding capacity of the ER and balances the production of proteins and lipids to maintain a functional secretory pathway. In this review, we discuss how UPR transducers sense unfolded proteins and LBS with a particular focus on their role as guardians of the secretory pathway.