Role of mitochondria in regulating immune response during bacterial infection

E2F1/CDK5/DRP1 axis mediates microglial mitochondrial division and autophagy in the pathogenesis of cerebral ischemia-reperfusion injury

BACKGROUND

The integrity of brain function is at stake due to cerebral ischemia-reperfusion injury (CIRI), which encompasses mitochondrial dysfunction, autophagy, and neuroinflammation. The role of E2F1 in mediating these processes in microglia during CIRI remains unclear.

METHODS

A CIRI mouse model was utilized for single-cell RNA transcriptome sequencing of brain tissues. The research comprised diverse gene expression, gene ontology (GO), and the enrichment of Kyoto Encyclopedia of Genes and Genomes (KEGG) pathways. Experimental techniques included oxygen-glucose deprivation (OGD/R) cell models, RT-qPCR, Western Blot, ChIP assays, and microglia-neuron co-cultures.

RESULTS

A significant aspect highlighted in the study was the involvement of CDK5 in the induction of mitochondrial abnormalities associated with CIRI. Upregulation of E2F1 and CDK5 in post-CIRI microglia was observed. E2F1 facilitated CDK5 transcription, leading to DRP1 phosphorylation, exacerbating neurotoxic effects. Silencing E2F1 improved neurobehavioral outcomes in CIRI mice.

CONCLUSIONS

Activation of E2F1-mediated CDK5 drives mitochondrial division while inhibiting mitophagy in microglia, triggering inflammation, neuronal apoptosis, and exacerbating CIRI damage. Targeting this pathway could offer novel therapeutic strategies for mitigating CIRI-induced brain injury.

KEY POINTS

Identification of the E2F1/CDK5/DRP1 Axis in CIRI This study reveals that the E2F1 transcription factor upregulates CDK5 expression, which in turn phosphorylates DRP1, promoting excessive mitochondrial fission and inhibiting mitophagy in microglia. This mechanism plays a critical role in cerebral ischemia-reperfusion injury (CIRI). Mitochondrial Dysfunction and Neuroinflammation The activation of DRP1 leads to mitochondrial fragmentation and excessive ROS accumulation, triggering microglial activation and inflammatory responses, exacerbating neuronal apoptosis and brain injury in CIRI. Therapeutic Potential of E2F1 Silencing Knockdown of E2F1 in microglia effectively reduces mitochondrial damage, restores mitophagy, suppresses inflammation, and improves neurological outcomes in a CIRI mouse model, highlighting a promising therapeutic target for ischemic stroke intervention.

Proteomics Reveals the Response Mechanism of Embryonic Bovine Lung Cells to Mycoplasma bovis Infection

Mycoplasma bovis (M. bovis) has caused huge economic losses to the cattle industry. The interaction between M. bovis and host cells is elucidated by screening and identifying the target protein of M. bovis adhesin on the surface of the host cell membrane. However, the response mechanism of embryonic bovine lung (EBL) cells to M. bovis infection is not yet fully understood. Additionally, it is necessary to further explore whether infection with M. bovis induces oxidative stress and mitochondrial damage in EBL cells. In this study, oxidation reaction, mitochondrial membrane potential, mitochondrial structure, and apoptosis ability of EBL cells infected with M. bovis were assessed at different times (12, 24, 48 h post-infection; hpi). Then, the differential proteomic analysis of M. bovis-infected EBL cells at 12 h and 24 h was performed with uninfected cells as the control. The results showed that M. bovis infection reduced the antioxidant capacity of EBL cells, increased ROS levels, and decreased mitochondrial membrane potential. The mitochondrial membrane of EBL cells was damaged, and the ridge arrangement was disordered after infection by transmission electron microscopy. With the increase in infection time, the mitochondrial matrix partially dissolved and spilled. The apoptosis rate of EBL cells increased with the increase in infection time of M. bovis. Furthermore, proteomic analysis identified 268 and 2061 differentially expressed proteins (DEPs) at 12 hpi and 24 hpi, respectively, compared with the uninfected cells. According to GO analysis, these DEPs were involved in the mitosis and negative regulation of cell growth. Additionally, the Kyoto Encyclopedia of Genes and Genomes (KEGG) analysis indicated the following pathways were linked to mitochondrial damage or cell growth regulation, including glycolysis/gluconeogenesis, pentose phosphate pathway, oxidative phosphorylation, AMPK, cGMP-PKG, cAMP, calcium, Wnt, Phospholipase D, apoptosis, MAPK, cell cycle, Ras, PI3K-Akt, mTOR, HIF-1. PPI results indicated that YWHAZ, PIK3CA, HSP90AB1, RAP1A, TXN, RAF1, MAPK1, PKM, PGK1, and GAPDH might be involved in mitochondrial pathway apoptosis induced by M. bovis infection. This study offers helpful data toward understanding the response of mitochondria of EBL cells to M. bovis infection.

Ecotoxicological risk of co-exposure to fosthiazate and microplastics on earthworms (Eisenia fetida): Integrating biochemical and transcriptomic analyses

Fosthiazate (FOS) is a widely used organophosphorus insecticide effective against soil root-knot nematodes. However, its ecotoxicity to non-target soil organisms, particularly in combination with microplastics (MPs), is unclear. This study explores the toxic-effects and molecular mechanisms of co-exposure to FOS and MPs on earthworms (Eisenia fetida) using multilevel toxicity endpoints and transcriptomics. Results showed that both FOS and MPs elevated the intracellular levels of reactive oxygen species (ROS), malondialdehyde (MDA), and 8-hydroxy-2-deoxyguanosine (8-OHdG) in earthworms' cells. The superoxide dismutase (SOD) and catalase (CAT) activities followed a similar trend in all treatments, with changes observed at 14 and 28 days, indicating that co-exposure to FOS and MPs increased DNA oxidative damage. Notably, the co-exposure more significantly inhibited Ca2+-ATPase activity and exacerbated neurotoxicity compared to individual treatments, closely associated with changes in intracellular ROS levels that mediate neuroinhibition and lead to neurotoxicity. KEGG enrichment analysis revealed that MPs and FOS disrupted pathways related to metabolism, immunity, and apoptosis, while co-exposure primarily impaired endocrine and receptor pathways, showing higher toxicity. Our study offers novel insights into the ecotoxicological effects and mechanisms of pesticides and microplastics on earthworms, providing valuable data for evaluating the soil environmental health risks associated with compound pollution.

The MICOS Complex Subunit Mic60 is Hijacked by Intracellular Bacteria to Manipulate Mitochondrial Dynamics and Promote Bacterial Pathogenicity

Host mitochondria undergo fission and fusion, which bacteria often exploit for their infections. In this study, the underlying molecular mechanisms are aimed to clarify through which Listeria monocytogenes (L. monocytogenes), a human bacterial pathogen, manipulates mitochondrial dynamics to enhance its pathogenicity. It is demonstrated that L. monocytogenes triggers transient mitochondrial fission through its virulence factor listeriolysin O (LLO), driven by LLO's interaction with Mic60, a core component of the mitochondrial contact site and the cristae organizing system (MICOS). Specifically, Phe251 within LLO is identify as a crucial residue for binding to Mic60, crucial for LLO-induced mitochondrial fragmentation and bacterial pathogenicity. Importantly, it is that Mic60 affect the formation of F-actin tails recruited by L. monocytogenes, thereby contributing to intracellular bacterial infection. Mic60 plays a critical role in mediating changes in mitochondrial morphology, membrane potential, and reactive oxidative species (ROS) production, and L. monocytogenes infection exacerbates these changes by affecting Mic60 expression. These findings unveil a novel mechanism through which intracellular bacteria exploit host mitochondria, shedding light on the complex interplay between hosts and microbes during infections. This knowledge holds promise for developing innovative strategies to combat bacterial infections.

Insights into membrane interactions and their therapeutic potential

Recent research into membrane interactions has uncovered a diverse range of therapeutic opportunities through the bioengineering of human and non-human macromolecules. Although the majority of this research is focussed on fundamental developments, emerging studies are showcasing promising new technologies to combat conditions such as cancer, Alzheimer's and inflammatory and immune-based disease, utilising the alteration of bacteriophage, adenovirus, bacterial toxins, type 6 secretion systems, annexins, mitochondrial antiviral signalling proteins and bacterial nano-syringes. To advance the field further, each of these opportunities need to be better understood, and the therapeutic models need to be further optimised. Here, we summarise the knowledge and insights into several membrane interactions and detail their current and potential uses therapeutically.

The crosstalk between PTEN-induced kinase 1-mediated mitophagy and the inflammasome in the pathogenesis of alopecia areata

Alopecia areata (AA) is a T-cell-mediated autoimmune disease that causes chronic, relapsing hair loss; however, its precise pathogenesis remains to be elucidated. Recent studies have provided compelling evidence of crosstalk between inflammasomes and mitophagy-a process that contributes to the removal of damaged mitochondria. Our previous studies showed that the NLR family pyrin domain containing 3 (NLRP3) inflammasome is important for eliciting and progressing inflammation in AA. In this study, we detected mitochondrial DNA damage in AA-affected scalp tissues and IFNγ and poly(I:C) treated outer root sheath (ORS) cells. In addition, IFNγ and poly(I:C) treatment increased mitochondrial reactive oxygen species (ROS) levels in ORS cells. Moreover, we showed that mitophagy induction alleviates IFNγ and poly(I:C)-induced NLRP3 inflammasome activation in ORS cells. Lastly, PTEN-induced kinase 1 (PINK1) knockdown increased NLRP3 inflammasome activation, indicating that PINK1-mediated mitophagy plays a critical role in NLRP3 inflammasome activation in ORS cells. This study supports previous studies showing that oxidative stress disrupts immune privilege status and promotes autoimmunity in AA. The results emphasize the significance of crosstalk between mitophagy and inflammasomes in the pathogenesis of AA. Finally, mitophagy factors regulating mitochondrial dysfunction and inhibiting inflammasome activation could be novel therapeutic targets for AA.

Mitochondrial Impairment: A Link for Inflammatory Responses Activation in the Cardiorenal Syndrome Type 4

Cardiorenal syndrome type 4 (CRS type 4) occurs when chronic kidney disease (CKD) leads to cardiovascular damage, resulting in high morbidity and mortality rates. Mitochondria, vital organelles responsible for essential cellular functions, can become dysfunctional in CKD. This dysfunction can trigger inflammatory responses in distant organs by releasing Damage-associated molecular patterns (DAMPs). These DAMPs are recognized by immune receptors within cells, including Toll-like receptors (TLR) like TLR2, TLR4, and TLR9, the nucleotide-binding domain, leucine-rich-containing family pyrin domain-containing-3 (NLRP3) inflammasome, and the cyclic guanosine monophosphate (cGMP)-adenosine monophosphate (AMP) synthase (cGAS)-stimulator of interferon genes (cGAS-STING) pathway. Activation of these immune receptors leads to the increased expression of cytokines and chemokines. Excessive chemokine stimulation results in the recruitment of inflammatory cells into tissues, causing chronic damage. Experimental studies have demonstrated that chemokines are upregulated in the heart during CKD, contributing to CRS type 4. Conversely, chemokine inhibitors have been shown to reduce chronic inflammation and prevent cardiorenal impairment. However, the molecular connection between mitochondrial DAMPs and inflammatory pathways responsible for chemokine overactivation in CRS type 4 has not been explored. In this review, we delve into mechanistic insights and discuss how various mitochondrial DAMPs released by the kidney during CKD can activate TLRs, NLRP3, and cGAS-STING immune pathways in the heart. This activation leads to the upregulation of chemokines, ultimately culminating in the establishment of CRS type 4. Furthermore, we propose using chemokine inhibitors as potential strategies for preventing CRS type 4.