Autophagy Process Research Articles

Protective effects of naringenin against methamphetamine-induced cell death in dopaminergic SH-SY5Y cells

ABSTRACT Background: Methamphetamine is a psychoactive substance that competes with the dopamine transporter, disrupting its flow and storage. This can trigger oxidative stress, finally resulting in neural cell death. Due to the increasing prevalence of methamphetamine use, extensive research has been devoted to finding treatments that ameliorate its detrimental effects. Naringenin, a dietary flavonoid found in citrus fruits, has shown several neuroprotective and pharmacological properties. Objectives: This study was aimed to assess the protective effects of naringenin against methamphetamine-induced dopaminergic cell death. Methods: Before exposure to methamphetamine, human neuroblastomaSH-SY5Y cells were either pretreated or not treated (controls) with naringenin. Cell viability, level of oxidative stress markers, and expression of some genes involved in apoptosis and autophagy processes were then assessed using MTT, ROS, and MMP assays, and qRT-PCR and Western blotting techniques. Results: Naringenin pretreatment significantly enhanced cell viability following methamphetamine exposure (p < .01). It significantly decreased ROS levels (p < .001), preserved mitochondrial membrane potential, and moderated upregulation of apoptotic (CytC, Casp3, and Bax) and autophagic genes (Beclin-1, and LC-3) and down-regulation of Bcl-2 as an anti-apoptotic gene. Similar naringenin-mediated patterns were observed for cytochrome C and caspase 3 proteins. Conclusion: Naringenin administration can be considered for treating the neurotoxic effects of methamphetamine.

MiR-137 regulates autophagy and apoptosis in duodenal ulcer by targeting BNIP3L.

Duodenal ulcer (DU) represents a clinical manifestation and disease state that occurs when the mucosal surface of the duodenum is damaged. The processes of autophagy and apoptosis have been linked to the development of DU, yet the precise roles they play remain unclear. This study aimed to investigate the expression and mechanism of action of microRNAs (miRNA)-137 (miR-137) in DU. Dysregulated miRNAs and targeted genes were identified from the Gene Expression Omnibus database, and the immune cell infiltration levels were analyzed using CIBERSORT. To confirm the targeting of the miRNAs, we conducted dual luciferase reporter assays in vitro. The detection of cell apoptosis was conducted using flow cytometry. Moreover, quantitative reverse transcription polymerase chain reaction, cell counting kit-8, and Western blot were employed to ascertain the levels of autophagy- and apoptosis-related proteins. Bioinformatics analysis identified 5 miRNAs, with miR-137 showing the most pronounced dysregulation. Its target gene, BNIP3L, was subsequently identified. In vitro experiments confirmed that miR-137 targeted BNIP3L. The upregulation of miR-137 expression in HIEC-6 cells resulted in the inhibition of BNIP3L expression, a reduction in autophagy, and an increase in apoptosis. A reduction in the expression of miR-137 would have the opposite effect. miR-137 is upregulated in DU patients and contributes to ulcer progression by inhibiting BNIP3L, reducing autophagy, and promoting apoptosis. Targeting miR-137 could provide a novel therapeutic strategy for DU management.

Uncovering the Significance of JNK/AKT Axis in the Autophagic Regulation of Leishmania major Infection.

The role of autophagy in host induced by infection of parasites of the Leishmania genus remains inadequately understood. Leishmania parasites modulate host macrophages to promote its survival by inducing autophagy response in the host cell. In this study, we conducted an investigation of L. major infection, focusing on host autophagy processes where we reconstructed two mathematical models elucidating autophagy induction and inhibition processes and its impact on parasite survival. Our models presented systems modulatory dynamics of the parasite-mediated host autophagy. Our work highlighted the pivotal role of signaling molecules associated with the immune response which included signaling induced by Toll-like receptor (TLR), specifically through regulation of JNK and AKT. Both molecules emerged as key regulators of host autophagy process, highlighting that JNK/AKT signaling axis may be a potential avenue for innovative therapeutic approaches in targeting leishmaniasis. Also, ATG16L complex was identified as a critical determinant in shaping the course of leishmanial infection through formation of autophagosomes. Through invitro analyses in differentiated human monocyte cell line, we observed an increase in nitric oxide synthase (iNOS) concentration upon autophagy inhibition, while autophagy induction resulted in decreased iNOS concentration. This suggested that autophagy induction favors parasite survival in the host, potentially by providing a nutrient source that may be advantageous for the parasite. Inhibition of host autophagy promoted parasite elimination. Hence, our work proposed an avenue for strategically blocking host autophagy which enumerates a targeted approach for combating leishmaniasis.

Understanding the spleen response of Russian sturgeon (Acipenser gueldenstaedtii) dealing with chronic heat stress and Aeromonas hydrophila challenge

Sturgeon aquaculture has grown in recent years, driven by increasing global demand for its highly valued products. Russian sturgeon (Acipenser gueldenstaedtii), recognised as one of the most valuable species for caviar production, is farmed in several warm-temperate regions. However, the substantial temperature increase due to global warming represents a challenge for developing sturgeon aquaculture. Previously we demonstrated that Russian sturgeon under chronic heat stress (CHS) exhibited a liver metabolic reprogramming to meet energy demands, weakening their innate defences and leading to increased mortality and economic losses. Here, we used RNA-seq technology to analyse regulated genes in the spleen of Russian sturgeons exposed to CHS and challenged with Aeromonas hydrophila. The assembly gave 253,415 unigenes, with 13.7 % having at least one reliable functional annotation. We found that CHS caused mild splenitis and upregulated genes related to protein folding, heat shock response, apoptosis and autophagy while downregulated genes associated with the cell cycle. The cell cycle arrest was maintained upon A. hydrophila challenge in heat-stressed fish, potentially inducing cell senescence. Surprisingly, immunoglobulin heavy and light chains were upregulated in the spleen of stressed sturgeons but not in those maintained at tolerable temperatures; however, no changes in IgM serum levels were observed in any condition. Our findings indicate that long-term exposure to non-tolerable temperatures induced a heat shock response and activated apoptosis and autophagy processes in the spleen. These mechanisms may enable the control of tissue damage and facilitate the recycling of cell components in a condition where the nutrient supply by the liver might be insufficient. Stressed sturgeons challenged with A. hydrophila maintain these mechanisms, which could culminate in cellular senescence.

Induction of Ca2+-dependent autophagy and concurrent lysosomal alkalinization underlies the cytotoxic effects of NNC-55-0396 on glioblastoma cells.

Diverse agents targeting (macro)autophagy, a critical metabolic stress response in cancer cells, have been proposed for cancer therapy. In previous studies, we showed that NNC-55-0396 (NNC) induces glioblastoma cell death by activating the Unfolded Protein Response (UPR) of ER stress and increasing cytosolic Ca2+ levels. Here, we report that NNC affects both ends of the autophagy process, causing extensive cytoplasmic vacuolation. Our results show that: (1) NNC induces autophagy downstream of UPR and Ca2+ signaling pathways, thus silencing IRE1α/JNK1 or inhibiting Ca2+/IP3R signaling prevents NNC-induced vacuolation. (2) Silencing ATG5 delays cell death, indicating that autophagy induction plays a role in NNC's cytotoxic effects. (3) NNC and other Ca2+-mobilizing agents transcriptionally upregulate p62/SQSTM1, an autophagosome cargo receptor, highlighting a role for this protein in the response to NNC. (4) Studies using tandem fluorescent-tagged LC3 and electron microscopy, however, further reveal that NNC blocks late-stage autophagy that leads to enlarged degradative compartments accumulating ubiquitin-tagged cargoes. (5) Finally, NNC impedes pro-cathepsin-B processing, an effect that is reversed with a weak acid co-treatment, suggesting that lysosomal dysfunction due to increased intraluminal pH is the underlying cause of the autophagy blockade. Together, these findings underscore a multi-level dysregulation of autophagy that contributes to NNC's anti-tumoral effects.

Zinc ions facilitate metabolic bioenergetic recovery post spinal cord injury by activating microglial mitophagy through the STAT3-FOXO3a-SOD2 pathway

Spinal cord injury (SCI) is a devastating condition of the central nervous system (CNS) with high global rates of disability and mortality, and no effective cure currently available. Microglia play a critical role in the progression of SCI, and enhancing their metabolic function may facilitate tissue repair and recovery. Mitochondrial dysfunction is a key feature of metabolic impairment, with the regulation of autophagy being essential for maintaining mitochondrial homeostasis and cell survival. The transcription factor Forkhead box O3a (FOXO3a) is integral to cellular metabolism, mitochondrial dysfunction, and oxidative stress responses, yet its role in post-SCI microglial metabolism remains underexplored. In this study, single-cell RNA sequencing reveals the crucial involvement of the FOXO signaling pathway in zinc ion-mediated enhancement of microglial metabolism. Mechanistically, oxidative stress-induced reactive oxygen species (ROS) accumulation exacerbates metabolic dysfunction by promoting excessive mitochondrial fission and impairing mitophagy. Importantly, zinc ions induce the nuclear translocation of FOXO3a, leading to its activation as a transcription factor. This activation enhances mitochondrial autophagy and fusion processes, thereby restoring microglial metabolic capacity. Our findings suggest that the zinc ion regulation of the STAT3-FOXO3a-SOD2 axis is pivotal in modulating mitochondrial gene expression, which governs microglial energy homeostasis and improves the spinal cord microenvironment, potentially enhancing neuronal survival. These insights highlight a promising therapeutic target for SCI.

Targeting the PDE3B-cAMP-autophagy axis prevents liver injury in long-term supercooling liver preservation.

In liver transplantation, donor livers are typically stored in a preservation solution at 4°C for up to 12 hours. However, this short preservation duration can lead to various issues, such as suboptimal donor-recipient matching and limited opportunities for organ sharing. Previous studies have developed a long-term preservation method called supercooling liver preservation (SLP) to address these issues. However, in this study using a rat model, we observed that long-term SLP led to more severe liver damage compared with clinically prevalent traditional static cold storage (SCS) for durations less than 8 hours. To understand the potential mechanism of SLP-induced liver injury, we conducted an integrative metabolomic, transcriptomic, and proteomic analysis. We identified the PDE3B-cAMP-autophagy pathway as a key determinant of SLP-induced liver injury. Specifically, we found that PDE3B was elevated during SLP, which promoted a reduction of cAMP metabolites, triggering an AMPK-dependent autophagy process that led to liver injury in rats. We found that blocking the reduction in cAMP using the PDE3B inhibitor cilostamide inhibited autophagy and substantially ameliorated liver injury during 48-hour SLP in rat livers. Furthermore, we validated the effectiveness of cilostamide treatment in preventing liver injury in pig and human liver 48-hour SLP models. In summary, our results reveal that metabolic reprogramming involving the PDE3B-cAMP-autophagy axis is the key determinant of liver injury in long-term SLP and provide an early therapeutic strategy to prevent liver injury in this setting.

Simultaneous and discriminative visualization of endoplasmic reticulum and lysosomes in apoptosis and autophagy using a single fluorescent probe

The interplay of organelles plays indispensable roles in various biological processes, and their precise interactions contribute to a series of biological functions. Therefore, the exploitation of single probes capable of simultaneously visualizing two organelles is significant yet challenging. In this study, a novel fluorescent probe able to visualize both the endoplasmic reticulum (ER) and lysosomes concurrently was utilized to monitor apoptosis and autophagy. Leveraging the photoinduced electron transfer (PET) mechanisms, the probe (named EL) demonstrated distinct variations in fluorescent intensity within solutions of different pH levels, which enables the differentiation of ER and lysosomes due to their diverse pH values. EL was also effective in monitoring apoptosis with a decrease in fluorescent intensity, and it could visualize the increase of fluorescent intensity in autophagy. Consequently, the discrimination of apoptosis and autophagy processes was achieved. The potential applications of EL in visualizing ER and lysosomes and tracking their dynamic changes during various physiological processes are significant, so this probe would prompt the development of physiology and pathology related to ER and lysosomes.

WHAMM Inhibits Type II Alveolar Epithelial Cell EMT by Mediating Autophagic Degradation of TGF-β1 in Bronchopulmonary Dysplasia.

Bronchopulmonary dysplasia (BPD) is one of the most prevalent complication in preterm infants, primarily characterized by arrested alveolar growth. The involvement of epithelial-mesenchymal transition (EMT) of AECII cells is proposed to have a crucial role in the pathogenesis of BPD; however, the underlying mechanism remains unclear. The present study reveals a significant reduction of WHAMM (WASP homolog associated with actin, membranes, and microtubules) in hyperoxia-induced BPD mice, highlighting its crucial role in suppressing the progression of BPD through the inhibition of EMT in AECIIs. We demonstrated that hyperoxia-induced downregulation of WHAMM leads to the accumulation of TGF-β1 primarily through its mediation of the autophagic degradation pathway. Mechanistically, WHAMM enhanced the autophagosomal localization of TGF-β1 and concurrently promoted the process of autophagy, thereby comprehensively facilitating the autophagic degradation of TGF-β1. These findings reveal the important role of WHAMM in the development of BPD, and the proposed WHAMM/autophagy/TGF-β1/EMT pathway may represent a potential therapeutic strategy for BPD treatment.

Overexpression of autophagy enhancer PACER/RUBCNL in neurons accelerates disease in the SOD1G93A ALS mouse model

Amyotrophic lateral sclerosis (ALS) is a debilitating and fatal paralytic disorder associated with motor neuron death. Mutant superoxide dismutase 1 (SOD1) misfolding and aggregation have been linked to familial ALS, with the accumulation of abnormal wild-type SOD1 species being also observed in postmortem tissue of sporadic ALS cases. Both wild-type and mutated SOD1 are reported to contribute to motoneuron cell death. The autophagic pathway has been shown to be dysregulated in ALS. Recent evidence suggests a dual time-dependent role of autophagy in the progression of the disease. PACER, also called RUBCNL (Rubicon-like), is an enhancer of autophagy and has been found diminished in its levels during ALS pathology in mice and humans. Pacer loss of function disturbs the autophagy process and leads to the accumulation of SOD1 aggregates, as well as sensitizes neurons to death. Therefore, here we investigated if constitutive overexpression of PACER in neurons since early development is beneficial in an in vivo model of ALS. We generated a transgenic mouse model overexpressing human PACER in neurons, which then was crossbred with the mutant SOD1G93A ALS mouse model. Unexpectedly, PACER/SOD1G93A double transgenic mice exhibited an earlier disease onset and shorter lifespan than did littermate SOD1G93A mice. The overexpression of PACER in neurons in vivo and in vitro increased the accumulation of SOD1 aggregates, possibly due to impaired autophagy. These results suggest that similar to Pacer loss-of function, Pacer gain-of function is detrimental to autophagy, increases SOD1 aggregation and worsens ALS pathogenesis. In a wider context, our results indicate the requirement to maintain a fine balance of PACER protein levels to sustain proteostasis.

Tetrandrine induces muscle atrophy involving ROS-mediated inhibition of Akt and FoxO3

Tetrandrine (Tet), a well-known drug of calcium channel blocker, has been broadly applied for anti-inflammatory and anti-fibrogenetic therapy. However, due to the functional diversity of ubiquitous calcium channels, potential side-effects may be expected. Our previous report revealed an inhibitory effect of Tet on myogenesis of skeletal muscle. Here, we found that Tet induced protein degradation resulting in the myofibril atrophy. Upon administration with a relative high dose (40 mg/kg) of Tet for 28 days, the mice displayed significantly reduced muscle mass, strength force, and myosin heavy chain (MyHC) protein levels. The MyHC reduction was further detected in C2C12 myotubes after treating with Tet. Interestingly, the expression of Atrogin-1 and Murf-1, the skeletal muscle specific E3 ligases of protein ubiquitin–proteasome system (UPS), was accordingly up-regulated, and the reduced MyHC was significantly mitigated by MG132, a 26S proteasome inhibitor, indicating a key role of UPS in the protein degradation of muscle cells. Further study showed that Tet induced autophagy also participated in the protein degradation. Mechanistically, Tet treatment caused ROS production in myotubes that in turn targeted on FoxO3/AKT signaling, resulting in the activation of UPS and autophagy processes that were involved in the protein degradation. Our study reveals a potential side-effect of Tet on skeletal muscle atrophy, particularly when the drug dose is relatively high.

Treatment of Melanoma Cells with Chloroquine and Everolimus Activates the Apoptosis Process and Alters Lipid Redistribution.

The balance between apoptosis and autophagy plays a key role in cancer biology and treatment strategies. The aim of this study was to assess the effect of the mTOR kinase inhibitor everolimus and chloroquine on the regulation of proliferation, caspase-3 activation, and apoptosis in melanoma cells. We studied the activity of caspase-3 and the levels of caspase-3 and -9 using the Western blot technique. Cellular apoptosis was examined using a DNA fragmentation assay, and changes in the cell nucleus and cytoskeleton were examined using fluorescence microscopy DAPI, OA/IP. We also studied the rearrangement of lipid structures using fluorescent dyes: Nile Red and Nile Blue. A low nanomolar concentration of the mTOR kinase inhibitor everolimus in combination with chloroquine activated the apoptosis process and decreased cell proliferation. These changes were accompanied by an obvious change in cell morphology and rearrangement of lipid structures. Alterations in lipid redistribution accompanying the process of apoptosis and autophagy are among the first to occur in the cell and can be easily monitored in in vitro studies. The combination of mTOR inhibitors and chloroquine represents a promising area of research in cancer therapy. It has the potential to enhance treatment efficacy through complementary mechanisms.

Lack of retinal degeneration in a Dram2 knockout mouse model

Damage-regulated autophagy modulator 2 (DRAM2) is a homologue of the DRAM family protein, which can induce autophagy process. In the retina, DRAM2 is located to the inner segment of photoreceptors, the apical surface of retinal pigment epithelial (RPE) cells, and the lysosome. Pathogenic variants of DRAM2 lead to autosomal recessive Cone-rod dystrophy 21 (CORD21). Cone-rod dystrophy is characterised by primary cone involvement, or sometimes simultaneous cone and rod loss, thus leading to decreased visual acuity, colour vision deficits, photophobia, and decreased sensitivity of the central visual field. However, the mechanisms underlying DRAM2 related retinal diseases remained unclear. To further explore the role of Dram2 in the retina, we generated Dram2 knockout mice (KO) by CRISPR/Cas-9 technology and demonstrated that expression of DRAM2 was abolished in KO retinas. Dram2 ablation failed to manifest any retinal degenerative phenotypes. Dram2 KO did not exhibit visible defect in photo response and the overt structure of the retinas. Immunostaing analysis using antibodies against cone opsins revealed no detectable loss of cone cells. Moreover, no visible change was observed in the expression and localisation of rhodopsin and other membrane disc proteins in Dram2 KO retinas and no gliosis and apoptosis were detected in KO mice. In summary, these data revealed lack of overt retinal degeneration in Dram2 KO model and emphasized the importance of further investigation of the mechanisms underlying Cone-rod dystrophy 21.

Overexpression of TECPR1 improved cognitive function of P301S-tau mice via activation of autophagy in the early and late process.

Autophagy disorders in AD patients and animal models were well known, however, the effect of P301S-tau on autophagy is not clear. Here, we found that autophagy related protein Tectonin Beta-Propeller Repeat-Containing Protein 1 (TECPR1) decreased in the hippocampus of P301S-tau transgenic mice by proteomics, which was proved invivo and invitro, and P301S-tau induced autophagic deficits in early and late process. TECPR1 overexpression attenuated P301S-tau induced autophagy defects via promoting autophagosome generation and autophagosome and lysosomes fusion. We also found that TECPR1 overexpression ameliorated the behavior disorders of P301S-tau mice with promoting tau degradation, improving synaptic plasticity and neuron loss. Lastly, CQ or 3-MA treatment reversed TECPR1 induced improvement effects on autophagic and cognitive disorders, further proved that, TECPR1 activated the early and late process of autophagy to ameliorate the cognition of P301S-tau mice. Our data suggest that TECPR1 is a potential therapy target for AD.

Overexpression of SlATG8f gene enhanced autophagy and pollen protection in tomato under heat stress.

Autophagy is a mechanism for the degradation of cellular components in eukaryotes and plays a critical role in plant responses to abiotic stress. As a core member of the autophagy process, ATG8's role in how plants respond to heat stress remains unclear. To investigate the response of the tomato autophagy core member ATG8f to heat stress, we studied the key gene ATG8f and generated tomato lines overexpressing SlATG8f using the recombinant expression vector pBWA(V)HS. We observed that under heat stress, SlATG8f overexpression (OE) plants exhibited decreased heat tolerance compared to wild-type (WT) plants. Specifically, OE plants showed increased relative electrolyte leakage, reduced soluble solid content, elevated chlorophyll content, and higher autophagosome numbers, with less damage to chloroplasts and mitochondria. Additionally, expression of some ATG8 family genes and heat shock protein-related genes was upregulated. Moreover, SlATG8f overexpressing plants had higher pollen vitality and more intact pollen morphology. These results suggest that while SlATG8f overexpression renders plants more sensitive to heat, it helps mitigate high-temperature damage to tomato pollen by maintaining chloroplast integrity and interacting with heat shock proteins to respond to heat stress.

Autophagy in the nervous system: general principles and specific functions

Autophagy is an intracellular mechanism for the isolation, transport and degradation of macromolecules and organelles. The physiological significance of autophagy lies, firstly, in maintaining the constancy of the intracellular environment through the timely disposal of proteins with a disrupted structure and damaged organelles. Secondly, due to the selective degradation of macromolecules, autophagy supplies the cell with monomers, which are then used by it to synthesize new compounds, which serves to ensure the rearrangement of cellular metabolism in the processes of cell differentiation, ontogenesis and adaptation to environmental challenges. Autophagy is an extremely important mechanism for maintaining normal functioning of postmitotic and differentiated cells, including neurons. Impaired neuronal autophagy leads to the formation of aggregated protein plaques, the accumulation of damaged cellular organelles, defects in the structure of processes and neuronal degeneration, which often accompanies to the progression of some forms of neurodegenerative diseases. In addition, the role of autophagy in synaptic plasticity and memory mechanisms has been established. Since autophagy has a significant impact on cellular metabolism, the study of the regulation and main pathways of this mechanism may be crucial in the elaboration of means and approaches to the treatment and prevention of many pathologies that progress with age. This review describes the basic concepts of the autophagy process, summarizes the key functions of autophagy in cells, and also presents current data on its role in ensuring the normal metabolism and implementation of specific functions of neurons.

Spotlight on Mitochondrial Health: A Trailblazing Fluorescent Tool for Cancer Detection and Surgical Guidance.

Mitochondria play a pivotal role in maintaining normal physiological functions. Mitochondrial autophagy, namely, mitophagy, is a selective catabolic disposal of impaired mitochondria through an autophagic mechanism during episodes of mitochondrial harm. This selective removal, e.g., mitophagy, is essential for mitochondrial quality control and is closely related to the pathogenesis of many diseases. The abnormal buildup of defective mitochondria in vivo was used as a target to prevent the development of cancer. The mitochondrial autophagy process of disease-related cells is usually accompanied by a decrease in polarity and pH, and the fluorescence sensing effects caused by these two factors are usually contradictory. Here, we propose a reinventing strategy to develop a dual-channel and dual-responsive fluorescent probe HDTVB that is capable of tracking mitochondrial autophagy by monitoring fluctuations in mitochondrial pH and polarity. Based on the aggregation-induced emission (AIE) moiety and hemicarpine moiety push-pull system with activated near-infrared (NIR) emission and pH-activatable cyclization reaction, HDTVB was able to differentiate tumors from normal sites via polarity- and acidity-triggered structural changes of the probe in the course of mitochondrial autophagy. HDTVB is expected to be applied to clinical diagnosis and tumor excision guided by fluorescence, offering a new route in physiological and biochemical research.

Single-cell sequencing unveils mitophagy-related prognostic model for triple-negative breast cancer.

Triple-negative breast cancer (TNBC) is an aggressive subtype of breast cancer lacking hormone receptors and HER2 expression, leading to limited treatment options and poor prognosis. Mitophagy, a selective autophagy process targeting damaged mitochondria, plays a complex role in cancer progression, yet its prognostic significance in TNBC is not well understood. This study utilized single-cell RNA sequencing data from the TCGA and GEO databases to identify mitophagy-related genes (MRGs) associated with TNBC. A prognostic model was developed using univariate Cox analysis and LASSO regression. The model was validated across multiple independent cohorts, and correlations between MRG expression, immune infiltration, and drug sensitivity were explored. Nine key MRGs were identified and used to stratify TNBC patients into high-risk and low-risk groups, with the high-risk group showing significantly worse survival outcomes. The model demonstrated strong predictive accuracy across various datasets. Additionally, the study revealed a correlation between higher MRG expression levels and increased immune cell infiltration, as well as potential responsiveness to specific chemotherapeutic agents. The mitophagy-related prognostic model offers a novel method for predicting outcomes in TNBC patients and highlights the role of mitophagy in influencing the tumor microenvironment, with potential applications in personalized treatment strategies.

Regulation of autophagy by Rab27B in colorectal cancer

Autophagy is a cellular recycling process that is associated with tumor growth, anti-tumor immune responses, and therapy resistance in colorectal cancer (CRC). In this report, we identify the small GTPase Rab27B to control the autophagy process in CRC. Depletion of Rab27B showed an abnormal accumulation of autophagy vesicles and increased autophagy markers in CRC cells, indicating autophagy dysregulation. Image analysis indicated that autophagy flux is blocked at the autophagosome/lysosome fusion step when Rab27B is lost. While Rab27B deficient cells are proficient at growth under 2D in vitro conditions, cell growth was significantly impacted in both in vitro 3D growth and in vivo tumorigenesis studies. Together, these results demonstrate a new role of Rab27B in the autophagy trafficking process in CRC and identify Rab27B as a potential therapeutic target for CRC.

New Insights into the Fanconi Anemia Pathogenesis: A Crosstalk Between Inflammation and Oxidative Stress.

Fanconi anemia (FA) represents a rare hereditary disease; it develops due to germline pathogenic variants in any of the 22 currently discovered FANC genes, which interact with the Fanconi anemia/breast cancer-associated (FANC/BRCA) pathway to maintain genome integrity. FA is characterized by a triad of clinical traits, including congenital anomalies, bone marrow failure (BMF) and multiple cancer susceptibility. Due to the complex genetic background and a broad spectrum of FA clinical symptoms, the diagnostic process is complex and requires the use of classical cytogenetic, molecular cytogenetics and strictly molecular methods. Recent findings indicate the interplay of inflammation, oxidative stress, disrupted mitochondrial metabolism, and impaired intracellular signaling in the FA pathogenesis. Additionally, a shift in the balance towards overproduction of proinflammatory cytokines and prooxidant components in FA is associated with advanced myelosuppression and ultimately BMF. Although the mechanism of BMF is very complex and needs further clarification, it appears that mutual interaction between proinflammatory cytokines and redox imbalance causes pancytopenia. In this review, we summarize the available literature regarding the clinical phenotype, genetic background, and diagnostic procedures of FA. We also highlight the current understanding of disrupted autophagy process, proinflammatory state, impaired signaling pathways and oxidative genotoxic stress in FA pathogenesis.