Crucial Event Research Articles

Unraveling Macrophage Polarization: Functions, Mechanisms, and “Double-Edged Sword” Roles in Host Antiviral Immune Responses

Numerous viruses that propagate through the respiratory tract may be initially engulfed by macrophages (Mφs) within the alveoli, where they complete their first replication cycle and subsequently infect the adjacent epithelial cells. This process can lead to significant pathological damage to tissues and organs, leading to various diseases. As essential components in host antiviral immune systems, Mφs can be polarized into pro-inflammatory M1 Mφs or anti-inflammatory M2 Mφs, a process involving multiple signaling pathways and molecular mechanisms that yield diverse phenotypic and functional features in response to various stimuli. In general, when infected by a virus, M1 macrophages secrete pro-inflammatory cytokines to play an antiviral role, while M2 macrophages play an anti-inflammatory role to promote the replication of the virus. However, recent studies have shown that some viruses may exhibit the opposite trend. Viruses have evolved various strategies to disrupt Mφ polarization for efficient replication and transmission. Notably, various factors, such as mechanical softness, the altered pH value of the endolysosomal system, and the homeostasis between M1/M2 Mφs populations, contribute to crucial events in the viral replication cycle. Here, we summarize the regulation of Mφ polarization, virus-induced alterations in Mφ polarization, and the antiviral mechanisms associated with these changes. Collectively, this review provides insights into recent advances regarding Mφ polarization in host antiviral immune responses, which will contribute to the development of precise prevention strategies as well as management approaches to disease incidence and transmission.

Zygotic activin a is dispensable for the mouse preimplantation embryo development and for the derivation and pluripotency of embryonic stem cells†.

In this work, we aimed to determine the role of activin A during crucial events of mouse embryogenesis and distinguish the function of the protein of zygotic origin and the one secreted by the maternal reproductive tract. To this end, we recorded the progression of development and phenotype of Inhba knockout embryos and compared them with the heterozygotes and wild-type embryos using time-lapse imaging and detection of lineage-specific markers. We revealed that the zygotic activin A deficiency does not impair the course and rate of development of embryos to the blastocyst stage. Inhba knockout embryos form functional epiblast, as evidenced by their ability to give rise to embryonic stem cells. Our study is the first to show that derivation, maintenance in culture, and pluripotency of embryo-derived embryonic stem cells are exogenous and endogenous activin A-independent. However, the implantation competence of activin A-deficient embryos may be compromised as indicated in the outgrowth assay.

Unveiling the Heart's Hidden Enemy: Dynamic Insights into Polystyrene Nanoplastic-Induced Cardiotoxicity Based on Cardiac Organoid-on-a-Chip.

Exposure to micro- and nanoplastics (MNPs) has been implicated in potential cardiotoxicity. However, in vitro models based on cardiomyocyte cell lines lack crucial cardiac characteristics, while interspecies differences in animal models compromise the reliability of the conclusions. In addition, current research has predominantly focused on single-time point exposures to MNPs, neglecting comparative analyses of cardiac injury across early and late stages. Moreover, there remains a large gap in understanding the susceptibility to MNPs under pathological conditions. To address these limitations, this study integrated cardiac organoids (COs) and organ-on-a-chip (OoC) technology to develop the cardiac organoid-on-a-chip (COoC), which was validated for cardiotoxicity evaluation through multiple dimensions. Based on COoC, we conducted a dynamic observation of the cardiac damage caused by short- and long-term exposure to polystyrene nanoplastics (PS-NPs). Oxidative stress, inflammation, disruption of calcium ion homeostasis, and mitochondrial dysfunction were confirmed as the potential mechanisms of PS-NP-induced cardiotoxicity and the crucial events in the early stages, while cardiac fibrosis emerged as a prominent feature in late stages. Notably, low-dose exposure exacerbated myocardial infarction symptoms under pathological states, despite no significant cardiotoxicity shown in healthy models. In conclusion, these findings further deepened our understanding of PS-NP-induced cardiotoxic effects and introduced a promising in vitro platform for assessing cardiotoxicity.

Nicorandil activates lkb1-ampk signaling pathway to ameliorate cardiac remodeling after myocardial ischemia/reperfusion injury by upregulating mt2

Abstract Background Cardiomyocyte apoptosis is a crucial event underlying the development of cardiac abnormalities and dysfunction after myocardial ischemia reperfusion (MI/R) injury. A better understanding of the cell signaling pathways involved in cardiac remodeling may support the development of new therapeutic strategies for the treatment of heart failure (HF) after MI/R. Nicorandil, an ATP-sensitive potassium channel opener, could improve mitochondrial damage and reduce oxidative stress，which reduce cardiomyocyte apoptosis. Metallothionein (Mt), reactive oxygen species (ROS) scavenger, which can reduce oxidative stress, also attenuated MI/R-induced autophagy and cell apoptosis. Except as a potassium channel opener, nicorandil may play a cardioprotective role by regulating metallothionein, and its specific mechanism remains to be elucidated. Objective To clarify the protective effect of nicorandil in myocardial ischemia/reperfusion injury, and elucidate the specific mechanism which nicorandil regulate the expression of metallothiosin to reduce myocardial ischemia/reperfusion injury, so as to provide new drug targets or new measures for clinical prevention and treatment of MI/R. Methods A cardiac MI/R injury model was constructed by the ligation of the left anterior descending coronary artery to investigate the underlying molecular mechanisms. The apoptosis of myocardial tissue cells was detected by TUNEL staining. The ultrastructural changes of myocardial tissue were observed by transmission electron microscopy. The expressions of Mt family, mitochondrial dynamics and Glucose metabolism-associated genes were measured by Western blotting and qPCR. The content of ATP was determined by ELISA in heart tissue. AutodockVina was used to evaluate binding energy and interaction patterns between drug candidates and their targets. The protein-protein interaction model was predicted by ZDOCK software. Results Treatment with nicorandil mitigated left ventricular enlargement, improved cardiac dysfunction,reduced myocardial infarcation area and decreased cardiomyocyte apoptosis after I/R. Nicorandil up-regulated the expression of Mt2 and decreased the expressions of Drp-1,p-Drp-1(ser616), while enhanced the expression of Mfn1/2,GLUT4,HK II and MPC II in myocardium. Knockdown of Mt2 decreased the effects of nicorandil on apoptosis and mitochondrial dysfunction after I/R. Mechanistically, nicorandil significantly upregulated the expression of Mt2, which could bound to LKB1 and cause phosphorylation of LKB1, resulting in AMPK-dependent activation. Conclusions Nicorandil significantly upregulated the expression of Mt2, which interacted with LKB1 to promote LKB1 protein phosphorylation, resulting in AMPK-dependent activation and subsequently alleviating I/R-induced mitochondrial dysfunction and energy metabolism disorder, and thereby reducing cardiomyocyte apoptosis, eventually improving I/ R-induced cardiac remodeling and dysfunction.

FOS-Mediated PLCB1 Induces Radioresistance and Weakens the Antitumor Effects of CD8+ T Cells in Triple-Negative Breast Cancer.

Radioresistance and immune evasion are interactive and crucial events leading to treatment failure and progression of human malignancies. This research studies the role of phospholipase C beta 1 (PLCB1) in these events in triple-negative breast cancer (TNBC) and the regulatory mechanism. PLCB1 was bioinformatically predicted as a dysregulated gene potentially linked to radioresistance in TNBC. Parental TNBC cell lines were exposed to fractionated radiation for 6 weeks. PLCB1 expression was decreased in the first 2 weeks but gradually increased from Week 3. PLCB1 knockdown increased the radiosensitivity of the cells, as manifested by a decreased half-inhibitory dose of irradiation, reduced cell proliferation, apoptosis resistance, mobility, and tumorigenesis in mice. The FOS transcription factor promoted PLCB1 transcription and activated the PI3K/AKT signaling. Knockdown of FOS similarly reduced radioresistance and T cells-mediated immune evasion. However, the radiosensitivity of TNBC cells and the antitumor effects of CD8+ T cells could be affected by a PI3K/AKT activator or by the PLCB1 upregulation. The PLCB1 or FOS knockdown also suppressed radioresistance and tumorigenesis of the TNBC cells in mice. In conclusion, FOS-mediated PLCB1 induces radioresistance and weakens the antitumor effects of CD8+ T cells in TNBC by activating the PI3K/AKT signaling pathway.

Mitochondria and Alcohol-Associated Liver Disease: Pathogenic Role and Target for Therapy.

Alcohol-associated liver disease (ALD) is one of the leading causes of chronic liver disease and a major cause of liver-related death. ALD is a multifactorial disease triggered by the oxidative metabolism of alcohol which leads to the activation of multiple factors that promote the progression from steatosis to more advanced stages like alcohol-associated steatohepatitis (AH) that culminate in alcohol-associated cirrhosis and hepatocellular carcinoma. Poor understanding of the complex heterogeneous pathology of ALD has limited drug development for this disease. Alterations in mitochondrial performance are considered a crucial event in paving the progression of ALD due to the crucial role of mitochondria in energy production, intermediate metabolism, calcium homeostasis, and cell fate decisions. Therefore, understanding the role of mitochondria in eliciting steatosis and progression toward AH may open the door to new opportunities for treatment. In this review, we will cover the physiological function of mitochondria, its contribution to ALD in experimental models and human disease, and explore whether targeting mitochondria may represent a game changer in the treatment of ALD.

KINOME-WIDE SYNTHETIC LETHAL SCREEN IDENTIfiES PANK4 AS A MODULATOR OF TEMOZOLOMIDE RESISTANCE IN GLIOBLASTOMA

Abstract AIMS Temozolomide (TMZ) represents the cornerstone of glioblastoma (GBM) therapy. However, acquisition of resistance limits its therapeutic potential. The human kinome is an undisputable source of druggable targets, still, current knowledge remains confined to a limited fraction of it, with a multitude of under-investigated proteins yet to be characterised. We aimed to uncover synthetic lethal partners of TMZ in GBM that could enhance the effect of TMZ, thus improving TMZ therapy response. METHOD A kinome-wide RNAi screen was performed in a TMZ-resistant GBM cell model. A panel of several TMZ-resistant and patient-derived GBM cell lines was implemented for in vitro validation of our findings through several phenotypic assays. In vivo TMZ-resistant GBM xenografts and immunohistochemical (IHC) analysis of IDH- wildtype GBM specimens were employed to assess the clinical relevance of our findings. Tandem Mass Tag (TMT)-based quantitative proteomic studies were undertaken to elucidate the underlying mechanisms. RESULTS Following a kinome-wide RNAi screen, pantothenate kinase 4 (PANK4) was uncovered as a modulator of TMZ resistance in GBM. Validation of PANK4 across various TMZ-resistant GBM cell models, patient-derived GBM cell lines, tissue samples, as well as in vivo studies, corroborated the potential translational significance of these findings. Moreover, PANK4 expression is induced during TMZ treatment, and its expression is associated with a worse clinical outcome. A Tandem Mass Tag (TMT)-based quantitative proteomic approach revealed that PANK4 abrogation leads to a significant downregulation of numerous proteins with central roles in cellular detoxification and cellular response to oxidative stress. Mechanistically, as cells undergo genotoxic stress during TMZ exposure, PANK4 depletion represents a crucial event that can lead to accumulation of intracellular reactive oxygen species (ROS) and subsequent cell death. CONCLUSION Our study provides novel insights into chemoresistance in GBM and unveils a previously unreported role for PANK4 in mediating therapeutic resistance to TMZ in GBM.

Genome-Wide Profiling of H3K27ac Identifies TDO2 as a Pivotal Therapeutic Target in Metabolic Associated Steatohepatitis Liver Disease.

H3K27ac has been widely recognized as a representative epigenetic marker of active enhancer, while its regulatory mechanisms in pathogenesis of metabolic dysfunction-associated steatotic liver disease (MASLD) remain elusive. Here, a genome-wide comparative study on H3K27ac activities and transcriptome profiling in high fat diet (HFD)-induced MASLD model is performed. A significantly enhanced H3K27ac density with abundant alterations of regulatory transcriptome is observed in MASLD rats. Based on integrative analysis of ChIP-Seq and RNA-Seq, TDO2 is identified as a critical contributor for abnormal lipid accumulation, transcriptionally activated by YY1-promoted H3K27ac. Furthermore, TDO2 depletion effectively protects against hepatic steatosis. In terms of mechanisms, TDO2 activates NF-κB pathway to promote macrophages M1 polarization, representing a crucial event in MASLD progression. A bovine serum albumin nanoparticle is fabricated to provide sustained release of Allopurinol (NPs-Allo) for TDO2 inhibition, possessing excellent biocompatibility and desired targeting capacity. Venous injection of NPs-Allo robustly alleviates HFD-induced metabolic disorders. This study reveals the pivotal role of TDO2 and its underlying mechanisms in pathogenesis of MASLD epigenetically and genetically. Targeting H3K27ac-TDO2-NF-κB axis may provide new insights into the pathogenesis of abnormal lipid accumulation and pave the way for developing novel strategies for MASLD prevention and treatment.

In vitro obtainment of stem-like cells from gubernaculum testis biopsies of cryptorchid pediatric patients

Testicular descent is a crucial event in male sexual development, and alterations in this process during gestation can lead to reduced fertility in adulthood. Cryptorchidism, i.e., failure of one or both testicles to descend into the scrotum, is one of the most common birth defects and represents a principal cause of infertility in adulthood. Therefore, identifying effective approaches for preserving fertility in childhood is of primary importance. In this context, the key role played by the gubernaculum testis during the placement of the testes in the scrotal bursa emerges. Given its close affinity to testicular tissue and its richness in mesenchymal cells, our prime aim is to characterize this para-testicular tissue to explore its potential ability to differentiate into testicular cells for fertility preservation. The first step of our task is represented by the present study that aimed to obtain in vitro stem-like cells starting from gubernaculum testis biopsies of four pediatric patients affected by cryptorchidism, aiming to differentiate them into testicular functioning cells. Our results show that the obtainment of aggregates with stem features is not dependent on the age of the patients and, therefore, not even on the damage suffered by the testis during its stay in the abdomen. This study opens the possibility of extending this approach to older patients, offering a new potential approach to support their fertility potential.

Using Doppler duplex ultrasound to determine hemodynamic alterations in renal vasculature: Crucial pathophysiological event preceding renal dysfunction in decompensated cirrhosis

BackgroundRenal dysfunction is a watershed event in cirrhosis, often preceded by renal vasoconstriction. However, our reliability on elevated serum creatinine often delays interventions. Measurement of Renal Resistive Index (RI) and Renal Venous Stasis Index (RVSI) by Doppler ultrasound offers insight into renal vasoconstriction. MethodsFifty participants with decompensated cirrhosis with ascites and normal serum creatinine underwent renal Doppler ultrasound for the measurement of RI and RVSI. All patients were compliant with a salt-restricted diet. Individuals aged <18 years, hepatocellular carcinoma, non-cirrhosis-related ascites, pre-existing renal disease, obstructive uropathy, or history of nephrotoxic medication use were excluded. Statistical analyses, including Pearson correlation, regression analysis, and Chi-square/Fisher’s exact tests, were performed to assess the statistical significance between RI, RVSI, and renal parameters. Additionally, the association of RI with the model for end-stage liver disease sodium (MELD-Na) and Child-Turcotte-Pugh (CTP) scores was also assessed. ResultsMajority were males (88%), average CTP score was 11.7, mean MELD-Na score was 20.92, and mean serum creatinine was 1.05 mg/dL. Renal parameters had varying RI values among renal arteries, with the main right and left arteries at 0.615 [standard deviation (SD): 0.089] and 0.638 (SD: 0.083), respectively. RI and RVSI are significantly correlated with serum creatinine. Further, significant correlation between, RI, RVSI values noted with MELD-Na score even when serum creatinine values are normal. ConclusionStrong correlations between serum creatinine, RI, and MELD-Na scores hints at predictive clinical potential. Future research with larger cohorts and extended follow-up is required to gauge clinical utility and its impact on outcomes.

Gut Microbiota Dysbiosis in the Pathogenesis of Metabolic-dysfunction Associated Steatotic Liver Disease (MASLD)

: Metabolic-dysfunction-associated steatotic liver disease (MASLD), previously referred to as nonalcoholic fatty liver disease (NAFLD), affecting approximately 30% of the global population. Projections suggest that MASLD incidence may rise by up to 56% over the next decade. MASLD has become the fastest-growing cause of hepatocellular carcinoma (HCC) in the USA, France, UK, and other regions worldwide. The prevalence of MASLD and MASLD-related liver damage is expected to parallel the increasing rates of obesity and type 2 Diabetes Mellitus (T2DM) globally. The factors contributing to MASLD development and its progression to metabolic-dysfunction- associated steatohepatitis (MASH), fibrosis, cirrhosis, and HCC remain poorly understood. Evidence from cell-based, animal-based, and human-subject studies suggests that insulin resistance, endoplasmic reticulum stress, oxidative stress, impaired autophagy, genetics, epigenetics, reduced immune surveillance, increased gut inflammation, and gut dysbiosis are crucial events in MASLD pathogenesis. In recent years, dysregulation of gut microbiota has emerged as a potential mechanism implicated in MASLD and MASLD-related hepatocarcinogenesis. This review briefly outlines the mechanistic events significant for MASLD pathogenesis. Additionally, it offers insight into dysregulated gut microbiota and its correlation with MASLD and MASLD-related liver damage. Furthermore, it highlights pertinent questions for cell and microbiologists in the MASLD research field. It underscores the necessity for identifying factors leading to gut microbiome dysregulation in MASLD and MASH pathogenesis. Identifying these factors could aid in the development of novel strategies for managing MASLD and MASLD-related liver damage.

S-CDK-regulated bipartite interaction of Mcm10 with MCM is essential for DNA replication.

Mcm10 plays an essential role in the activation of replicative helicase CMG through the cell cycle-regulated interaction with the prototype MCM double hexamer in Saccharomyces cerevisiae. In this study, we reported that Mcm10 is phosphorylated by S-phase cyclin-dependent kinases (S-CDKs) at S66, which enhances Mcm10--MCM association during the S phase. S66A single mutation or even deletion of whole N-terminus (a.a. 1-128) only causes mild growth defects. Nevertheless, S66 becomes indispensable in the absence of the Mcm10 C-terminus ((a.a. 463-571), the major MCM-binding domain. Using a two-degron strategy to efficiently deplete Mcm10, we show that mcm10-S66AΔC has a severe defect in proceeding into the S phase. Notably, both lethality and S-phase deficiency can be rescued by artificially tethering mcm10-S66AΔC to MCM. These findings illustrate how the Mcm10-MCM association is regulated as a crucial event in DNA replication initiation.

DivIVA controls the dynamics of septum splitting and cell elongation in Streptococcus pneumoniae.

Bacterial shape and division rely on the dynamics of cell wall assembly, which involves regulated synthesis and cleavage of the peptidoglycan. In ovococci, these processes are coordinated within an annular mid-cell region with nanometric dimensions. More precisely, the cross-wall synthesized by the divisome is split to generate a lateral wall, whose expansion is insured by the insertion of the so-called peripheral peptidoglycan by the elongasome. Septum cleavage and peripheral peptidoglycan synthesis are, thus, crucial remodeling events for ovococcal cell division and elongation. The structural DivIVA protein has long been known as a major regulator of these processes, but its mode of action remains unknown. Here, we integrate click chemistry-based peptidoglycan labeling, direct stochastic optical reconstruction microscopy, and in silico modeling, as well as epifluorescence and stimulated emission depletion microscopy to investigate the role of DivIVA in Streptococcus pneumoniae cell morphogenesis. Our work reveals two distinct phases of peptidoglycan remodeling during the cell cycle that are differentially controlled by DivIVA. In particular, we show that DivIVA ensures homogeneous septum cleavage and peripheral peptidoglycan synthesis around the division site and their maintenance throughout the cell cycle. Our data additionally suggest that DivIVA impacts the contribution of the elongasome and class A penicillin-binding proteins to cell elongation. We also report the position of DivIVA on either side of the septum, consistent with its known affinity for negatively curved membranes. Finally, we take the opportunity provided by these new observations to propose hypotheses for the mechanism of action of this key morphogenetic protein.IMPORTANCEThis study sheds light on fundamental processes governing bacterial growth and division, using integrated click chemistry, advanced microscopy, and computational modeling approaches. It addresses cell wall synthesis mechanisms in the opportunistic human pathogen Streptococcus pneumoniae, responsible for a range of illnesses (otitis, pneumonia, meningitis, septicemia) and for one million deaths every year worldwide. This bacterium belongs to the morphological group of ovococci, which includes many streptococcal and enterococcal pathogens. In this study, we have dissected the function of DivIVA, which is a structural protein involved in cell division, morphogenesis, and chromosome partitioning in Gram-positive bacteria. This work unveils the role of DivIVA in the orchestration of cell division and elongation along the pneumococcal cell cycle. It not only enhances our understanding of how ovoid bacteria proliferate but also offers the opportunity to consider how DivIVA might serve as a scaffold and sensor for particular membrane regions, thereby participating in various cell cycle processes.

Unraveling the key molecular events of Pinot noir berry ripening under varying crop load

Aligned to exploring the physiological and molecular complexity of grape berry development, there is a need to characterize the influence of the source:sink relationships on the genetic regulation of fruit composition. Crop load, as defined by the amount of fruit produced per unit vegetative growth at dormancy, is a common measure of source:sink relationships used to evaluate vineyard production efficiency. We studied the impact of varying crop load on the transcriptome and metabolome of Pinot noir grape berries by comparing the development and ripening of fruit grown on vines with either 50 % or 75 % of their grape clusters removed immediately following fruit set compared to unthinned vines for three consecutive vintages. A clear impact on the general phenylpropanoid pathway resulting in a redistribution between stilbenes and anthocyanins was revealed under varying crop loads and consistent with the transcriptomic profiles of the corresponding branches. Moreover, we identified genes, such as LBDIa3 and AG2, modulated by crop load around veraison, representing putative transcriptional key triggers of the berry ripening phase responding to differences in the vine source:sink ratio generated by the application of cluster thinning. Genes, specifically EXPA1 and EXPA18, involved in softening and other crucial events of ripening initiation responded to crop load and likely influenced the progression of the ripening process. Beyond the major impacts represented by a shift of the onset and completion of ripening, we were able to highlight more subtle effects of the crop load, related to the rate at which the molecular and metabolic changes occur. This study asserts that grape metabolism and transcriptome are remarkably flexible, and that manipulations such as cluster thinning induce extensive, genome-wide changes in expression during berry development. The insights gained here pave the way to progress towards the construction of robust models depicting the molecular network that characterizes berry development and the impact of crop load on its molecular regulation.

The Proteasome and Cul3-Dependent Protein Ubiquitination Is Required for Gli Protein-Mediated Activation of Gene Expression in the Hedgehog Pathway.

Many cellular processes are regulated by proteasome-mediated protein degradation, including regulation of signaling pathways and gene expression. Among the pathways regulated by the ubiquitin-proteasome system is the Hedgehog pathway and its downstream effectors, the Gli transcription factors. Here we provide evidence that proteasomal activity is necessary for maintaining the activation of the Hedgehog pathway, and this crucial event takes place at the level of Gli proteins. We undertook extensive work to demonstrate the specificity of the observed phenomenon by ruling out the involvement of primary cilium, impaired nuclear import, failed dissociation from Sufu, microtubule stabilization, and stabilization of Gli repressor forms. Moreover, we showed that proteasomal-inhibition-mediated Hedgehog pathway downregulation is not restricted to the NIH-3T3 cell line. We demonstrated, using CRISPR/Ca9 mutagenesis, that neither Gli1, Gli2, nor Gli3 are solely responsible for the Hedgehog pathway downregulation upon proteasome inhibitor treatment, and that Cul3 KO renders the same phenotype. Finally, we report two novel E3 ubiquitin ligases, Btbd9 and Kctd3, known Cul3 interactors, as positive Hedgehog pathway regulators. Our data pave the way for a better understanding of the regulation of gene expression and the Hedgehog signaling pathway.

P09-21 Oligodendrocyte development as a crucial key event for developmental neurotoxicity

P09-21 Oligodendrocyte development as a crucial key event for developmental neurotoxicity

DNA damage induced PARP-1 overactivation confers paclitaxel-induced neuropathic pain by regulating mitochondrial oxidative metabolism.

Poly (ADP-ribose) polymerase (PARP) has been extensively investigated in human cancers. Recent studies verified that current available PARP inhibitors (Olaparib or Veliparib) provided clinical palliation of clinical patients suffering from paclitaxel-induced neuropathic pain (PINP). However, the underlying mechanism of PARP overactivation in the development of PINP remains to be investigated. We reported induction of DNA oxidative damage, PARP-1 overactivation, and subsequent nicotinamide adenine dinucleotide (NAD+) depletion as crucial events in the pathogenesis of PINP. Therefore, we developed an Olaparib PROTAC to achieve the efficient degradation of PARP. Continuous intrathecal injection of Olaparib PROTAC protected against PINP by inhibiting the activity of PARP-1 in rats. PARP-1, but not PARP-2, was shown to be a crucial enzyme in the development of PINP. Specific inhibition of PARP-1 enhanced mitochondrial redox metabolism partly by upregulating the expression and deacetylase activity of sirtuin-3 (SIRT3) in the dorsal root ganglions and spinal cord in the PINP rats. Moreover, an increase in the NAD+ level was found to be a crucial mechanism by which PARP-1 inhibition enhanced SIRT3 activity. The findings provide a novel insight into the mechanism of DNA oxidative damage in the development of PINP and implicate PARP-1 as a possible therapeutic target for clinical PINP treatment.

Panax ginseng extract prevents UVB-induced skin photodamage by modulating VMP1-mediated ER stress

BackgroundThe endoplasmic reticulum (ER) stress is a crucial toxic signaling event triggered by chronic exposure to Ultraviolet B radiation (UVB), which significantly exacerbate photodamage responses in the irradiated skin. Therefore, the identification of agents capable of inhibiting ER stress could serve as a promising therapeutic strategy for addressing the unmet clinical needs in the treatment of UVB-induced photodamage. MethodsA UVB-irradiated mouse model was used and topical administration of Panax ginseng extract was carried out for a duration of 9 weeks. Vitamin E was used as a positive control. After 9 weeks of administration, the skin appearance, epidermal hyperplasia, infiltration of inflammatory cells, apoptosis, and collagen content were measured. The keratinocytes were irradiated with 6 mJ/cm2 UVB to establish an in vitro model. The levels of ER stress and apoptosis were investigated both in vivo and in vitro using qRT-PCR, immunoblotting, and immunofluorescence. ResultsAmong the 14 extracts derived from 13 distinct plant species that were screened, Panax ginseng, Prunus mume, and Camellia japonica showed inhibitory effect on UVB-induced ER stress. Notably, Panax ginseng effectively inhibits collagen degradation and apoptosis in both irradiated keratinocytes and Balb/C mice skin. Furthermore, the silencing of VMP1 significantly impeded the cellular protective effect of Panax ginseng extract on UVB-irradiated keratinocytes, indicating that Panax ginseng exerts its protective effects through targeted promotion of VMP1. ConclusionOur data suggest that Panax ginseng extract possess a therapeutical effect on UVB radiation-induced photodamage by promoting VMP1-mediated inhibition of ER stress.

Memantine attenuates the development of osteoarthritis by blocking NMDA receptor mediated calcium overload and chondrocyte senescence

BackgroundMemantine, which is an FDA-proven drug for the treatment of dementia, exerts its function by blocking the function of NMDA (N-methyl-D-aspartate) receptor, a calcium-permeable ion channel that reduces cytotoxic calcium overload. Chondrocyte senescence is a crucial cellular event that contributes to articular cartilage degeneration during osteoarthritis (OA) development. To date, the effects of memantine and its downstream NMDA receptor on chondrocyte senescence and OA have been rarely reported. MethodsThe protein levels of NMDA receptor and its agonistic ligand, glutamate, were compared between normal and OA chondrocytes. The quantity of intracellular calcium ions and the level of mitochondrial damage were evaluated using specific fluorescent probes and transmission electron microscopy (TEM), respectively. Chondrocyte senescence was evaluated by senescence-associated β-galactosidase (SA-β-Gal) staining and p16INK4a analysis. The function of NMDA receptor in chondrocyte senescence and OA was tested via agonists activation and gene knockdown experiments. The therapeutic effects of memantine on OA were examined both in vitro and in vivo. Additionally, to verify the findings from animal samples, a propensity score-matched cohort study was conducted using data from a United Kingdom primary care database (i.e., IQVIA Medical Research Database [IMRD]) to compare the risk of OA-related joint replacement involved in memantine initiators versus active comparators (i.e., acetylcholinesterase [AchE] initiators) in patients with dementia. ResultsThe protein expression of NMDA receptor and the secretion of glutamate were both significantly increased in OA chondrocytes. NMDA receptor activation was found to stimulate chondrocyte calcium overload, which further led to mitochondrial fragmentation and chondrocyte senescence. Blocking the NMDA receptor with memantine and N-methyl-D-aspartate receptor subunit 1(NR1, the gene encoding NMDA receptor) knockdown resulted in reduced calcium influx, mitochondrial fragmentation, as well as cellular senescence in OA chondrocytes. Intra-articular injection of memantine in OA mice also exhibited protective effects against cartilage degeneration. Moreover, in the 1:5 propensity score-matched cohort study consisting of 6218 patients (n = 1435 in the memantine cohort; n = 4783 in the AchE cohort), the memantine initiator was associated with a lower risk of OA-related joint replacement than AchE initiators (Hazard ratio = 0.56, 95 % confidence interval: 0.34 to 0.99). ConclusionNMDA receptor plays an important role in inflammatory-induced cytotoxic calcium overload in chondrocytes, while memantine can effectively block the NMDA receptor to reduce chondrocyte senescence and retard the development of OA. The translational potential of this articleAs a clinically licensed drug used for the treatment of dementia, memantine has shown promising therapeutic effects on OA. Mechanistically, it functions by blocking NMDA receptor from mediating chondrocyte senescence. The protective effects of memantine against OA were verified not only by in vivo and in vitro experiments but also via a propensity score-matched human cohort study. These findings presented robust evidence for repurposing memantine for the treatment of OA.

To GDP and beyond: The past and future history of the world’s most powerful statistical indicator

Gross domestic product (GDP) is unquestionably one of the most influential statistical indicators in history. It is more than a statistic – it not only measures the global economy but defines it. But from the outset there have been criticisms of GDP. Today there are a growing number of commentators arguing that GDP has outlived its usefulness. Their criticisms can be broadly categorized into three classes. The first are measurement problems within the existing framework arising from changes in the economy and society – most notably globalization and digitalization. The second set of criticisms deal with the limits of the SNA framework itself and are sometimes described by the catchall “Beyond GDP” and center on questions as to whether the SNA can or should measure well-being and sustainability. The third is that the construction of GDP promotes a ‘growth-at-all-costs’ ideology which works against environmental and social reforms. This paper summarizes the origins of the SNA and GDP and some of the crucial events and thinking that helped shape its design. The most important criticisms and challenges that will shape the future development of the SNA are also outlined, in particular: globalization, digitalization, well-being and sustainability. As both well-being and sustainability go well beyond traditional measurements of the economy, the paper discusses whether it is possible to address at least some aspects of these issues within the SNA, either in the ‘core’ sequence of economic accounts, or through a broadened set of accounts. The paper concludes with an overview of the 2025 SNA update and new work beginning at the UN to encourage member states to move beyond GDP.