Expression Of Connexin Research Articles

Unveiling the native architecture of adult cardiac tissue using the 3D-NaissI method

Accurately imaging adult cardiac tissue in its native state is essential for regenerative medicine and understanding heart disease. Current fluorescence methods encounter challenges with tissue fixation. Here, we introduce the 3D-NaissI (3D-Native Tissue Imaging) method, which enables rapid, cost-effective imaging of fresh cardiac tissue samples in their closest native state, and has been extended to other tissues. We validated the efficacy of 3D-NaissI in preserving cardiac tissue integrity using small biopsies under hypothermic conditions in phosphate-buffered saline, offering unparalleled resolution in confocal microscopy for imaging fluorescent small molecules and antibodies. Compared to conventional histology, 3D-NaissI preserves cardiac tissue architecture and native protein epitopes, facilitating the use of a wide range of commercial antibodies without unmasking strategies. We successfully identified specific cardiac protein expression patterns in cardiomyocytes (CMs) from rodents and humans, including for the first time ACE2 localization in the lateral membrane/T-Tubules and SGTL2 in the sarcoplasmic reticulum. These findings shed light on COVID-19-related cardiac complications and suggest novel explanations for therapeutic benefits of iSGLT2 in HFpEF patients. Additionally, we challenge the notion of "connexin-43 lateralization” in heart pathology, suggesting it may be an artifact of cardiac fixation, as 3D-NaissI clearly revealed native connexin-43 expression at the lateral membrane of healthy CMs. We also discovered previously undocumented periodic ring-like 3D structures formed by pericytes that cover the lateral surfaces of CMs. These structures, positive for laminin-2, delineate a specific spatial architecture of laminin-2 receptors on the CM surface, underscoring the pivotal role of pericytes in CM function. Lastly, 3D-NaissI facilitates the mapping of native human protein expression in fresh cardiac autopsies, offering insights into both pathological and non-pathological contexts. Therefore, 3D-NaissI provides unparalleled insights into native cardiac tissue biology and holds the promise of advancing our understanding of physiology and pathophysiology, surpassing standard histology in both resolution and accuracy.

Expression and function of Connexin 43 and Connexin 37 in the murine zona glomerulosa.

The zona glomerulosa (ZG) synthesizes the mineralocorticoid aldosterone. The primary role of aldosterone is the maintenance of volume and electrolyte homeostasis. Aldosterone synthesis is primarily regulated via tightly controlled oscillations in intracellular calcium levels in response to stimulation. It has previously been shown that calcium oscillations are synchronized through mechanical linkage between adjacent ZG cells. In many other cell types, similar synchronization is rather dependent on gap junctions (GJ). The recent discovery of mutations in CADM1 was linked to impaired GJ function in the ZG. Based on published transcriptomics data, we re-examined the presence and functional impact of GJ in the ZG. We found evidence for the expression of murine connexin 43 and 37 using microarray data, in-situ hybridization and immunohistology. Connexin 43 was also present in human samples. Calcium oscillations in ZG rosettes showed some degree of synchronization as reported previously. Unspecific GJ inhibition only had a small impact on this synchronicity. However, no signs of connections between cytosols could be observed as indicated by the lack of fluorescence recovery after photobleaching. We conclude that, while connexin proteins are expressed in the ZG, functional GJ in the physiological ZG are rare and of little consequence for calcium signaling.

Genetic loss of Uchl1 leads to female infertility by affecting oocyte quality and follicular development.

Ubiquitin C-terminal hydrolase L1 (UCHL1) is a deubiquitinating enzyme specifically highly expressed in the brain and gonads. Inhibition of UCHL1 hydrolase activity impairs oocyte maturation. Uchl1 knockout mice exhibit reproductive dysfunction, but the underlying pathogenesis remains unclear. Uchl1 knockout mice were used to explore the role of UCHL1 in oocyte maturation and follicle development. Oocyte development potential and mitochondrial membrane potential were also assessed to determine UCHL1 function on early embryo development. Transcriptome and proteomic analyses were conducted to elucidate molecular changes associated with Uchl1 knockout. Uchl1-/- mice exhibited ovarian dysfunction and infertility, with decreased serum estrogen, reduced antral follicle number, and diminished oocyte developmental potential compared to wild types. Histological examination revealed compromised follicle development and disrupted granulosa cell function in Uchl1-/- ovaries. In vitro, Uchl1-/- follicles had impaired preantral follicle development and poor FSH response. Loss of UCHL1 not only leads to mitochondrial dysfunction in oocytes, but also negatively affected estrogen biosynthesis with downregulation of steroidogenic acute regulatory protein (STAR) and estrogen receptor alpha (ER-α) in granulosa cells. Additionally, downregulated expression of connexin 37 (CX37), which is known to impair gap junction intercellular communication between oocyte and granulosa cells, transmitted the Uchl1 gene damage from oocyte to granulosa cells, which in turn affected functions of follicles and even the whole ovary. Loss of UCHL1 leads to significant disruptions in follicular development and oocyte quality, resulting in infertility. UCHL1 in oocytes influences not only the quality and quantity of the oocytes themselves, but also the follicles and the ovaries as a whole. This disruption ultimately manifests in symptoms similar to diminished ovarian reserve (DOR).

A functional cardiac patch promotes cardiac repair by modulating the CCR2- cardiac-resident macrophage niche and their cell crosstalk.

C-C chemokine receptor type 2 (CCR2-) cardiac-resident macrophages (CCR2- cRMs) are known to promote cardiac repair after myocardial infarction (MI). However, the substantial depletion and slow recovery of CCR2- cRMs pose significant barriers in cardiac recovery. Here, we construct a functional conductive cardiac patch (CCP) that can provide exogenously elastic conductive microenvironment and induce endogenously reparative microenvironment mediated by CCR2- cRMs for MI repair. This CCP exhibits suitable mechanical properties, conductivity, and high water retention, reminiscent of natural myocardium, which can actively engage in modulating CCR2- cRM renewal and their cell crosstalk. The functional CCP can promote the expression of Connexin43 between CCR2- cRMs and cardiomyocytes (CMs) and regulate paracrine signaling to activate epicardial cell epithelial-to-mesenchymal transition (EMT) toward endothelial cells using rat and Wt1CreERT2 transgenic lineage tracing mice. Overall, this study provides a promising strategy to construct a synergistic reparative microenvironment for MI repair.

Developmental Changes in Gap Junction Expression in Rat Adrenal Medullary Chromaffin Cells

Cell-to-cell communications are desirable for efficient functioning in endocrine cells. Gap junctions and paracrine factors are major mechanisms by which neighboring endocrine cells communicate with each other. The current experiment was undertaken to morphologically examine gap junction expression and developmental changes in rat adrenal medullary chromaffin (AMC) cells. The expression of connexin 43 (Cx43) was conspicuous in the rat adrenal cortex, but not detected immunohistochemically in neonatal or adult AMC cells. Consistent with the morphological findings, the phosphorylated and non-phosphorylated forms of Cx43 were predominantly and faintly detected by immunoblotting in the adrenal cortical and medullary homogenates, respectively. In contrast to Cx43, Cx36-like immunoreactive (IR) material was detected in neonatal AMC cells, a fraction of which were in the process of migration to the center of the adrenal gland, but this was not seen in adult AMC cells. The current results raise the possibility that the mechanism for cell-to-cell communication changes in a developmental manner in rat AMC cells.

Nanogrooved Elastomeric Diaphragm Arrays for Assessment of Cardiomyocytes under Synergistic Effects of Circular Mechanical Stimuli and Electrical Conductivity to Enhance Intercellular Communication.

Cardiovascular diseases remain the leading cause of mortality, necessitating advancements in in vitro cardiac tissue engineering platforms for improved disease modeling, drug screening, and regenerative therapies. The chief challenge to recapitulating the beating behavior of cardiomyocytes is creation of the circular stress profile experienced by hollow organs in the natural heart due to filling pressure and integrated strategies for intercellular communication to promote cell-to-cell connections. We present a platform featuring addressable arrays of nanogrooved polydimethylsiloxane (PDMS) diaphragms for cell alignment and circular mechanical stimulation, with embedded silver nanowires (AgNWs) for electrical cues, so that cardiomyocyte functionality can be assessed under these synergistic influences. Central to our innovation is a two-layer PDMS diaphragm design that electrically isolates the liquid metal (EGaIn) strain sensor in the bottom layer to enable detection and control of mechanical stimulation from conductive portions of embedded AgNWs in the top layer that supports cardiomyocyte culture and communication. In this manner, through localized detection and control of the circular mechanical stimulation, the essential role of multiaxial stretching on cardiomyocyte function is elucidated based on their contractility, sarcomere length, and connexin-43 expression. This in vitro platform can potentially transform cardiac tissue engineering, drug screening, and precision medicine approaches.

Teaching strategies for resolving gastrointestinal function from the perspective of cell biomechanics

Traditional gastrointestinal function teaching focuses on biochemical and physiological regulation, but fails to explore the effects of mechanical forces on gastrointestinal cell behavior and function, resulting in students’ one-sided understanding of gastrointestinal function. This paper proposes a new teaching strategy by combining cell biomechanics with teaching to help students master the gastrointestinal function mechanism more comprehensively. First, the membrane elasticity of gastrointestinal smooth muscle cells is measured. The elastic modulus is calculated by combining the Hertz model and the applied force is controlled to avoid cell membrane damage. Elasticity change data is obtained. Then, a flexible substrate is used to apply stretching and low frequency to simulate the mechanical force of cells during peristalsis and monitor the fluctuation of calcium ion concentration. Then, the distribution of intercellular cadherin is analyzed, and mechanical force is used to accelerate the permeability of gap junctions and the expression of Connexin43 to promote signal transmission. Finally, a teaching experiment based on cell biomechanics is designed, covering cell culture, mechanical stimulation, quantitative analysis and molecular biology verification, to help students understand how mechanical forces affect gastrointestinal cell behavior and function. The results show that before and after the application of the cell biomechanics teaching strategy, the students’ test scores increase by 16%, and the experimental results are good. Applying biomechanical factors into teaching by combining teaching strategies with cell biomechanics has a positive effect on medical education.

CX43-mediated mitochondrial transfer maintains stemness of KG-1a leukemia stem cells through metabolic remodeling

BackgroundAcute myeloid leukemia (AML) is characterized by abundant immature myeloid cells, relapse and refractory due to leukemia stem cells (LSCs). Bone marrow mesenchymal stem/ stromal cells (BMSCs) supported LSCs survival, meanwhile, chemotherapy improved connexin43 (CX43) expression. CX43, as the most intercellular gap junction, facilitated transmit mitochondria from BMSCs into AML. We hypothesized that increased mitochondria transferred from BMSCs supported metabolic remodeling in LSCs to sustain their stemness.MethodsPrimary BMSCs from AML patients were isolated. CX43-BMSCs, overexpressing CX43, were cocultured with KG-1a cells. Fluorescence and confocal microscopy observed mitochondrial transfer. Flow cytometry, EdU assay, and clonogenicity evaluated cell cycle, proliferation, and clonogenic potential. Xenograft mouse models were used to evaluate the tumorigenicity of KG-1a in vivo. Seahorse, RNA-seq, and LC-MS assessed mitochondrial function, transcriptomes, and metabolites post-coculture.ResultsCX43-BMSCs promoted unidirectional mitochondrial transfer, enhancing KG-1a adhesion and proliferation to maintain LSCs stemness in vitro and vivo. RNA-seq revealed coculture with CX43-BMSCs upregulated genes related to adhesion, proliferation, and migration in KG-1a cells. Elevated CX43 expression strengthened BMSCs-KG-1a interaction, facilitating mitochondrial transfer and nucleoside metabolism, fueling KG-1a cells. This enhanced mitochondrial energy metabolism, promoting metabolic reprogramming and clonogenicity.ConclusionCX43-mediated mitochondrial transfer from BMSCs to KG-1a enhances LSCs adhesion, proliferation, clonogenicity, and metabolic reprogramming. CX43 emerges as a potential therapeutic target for AML by sustaining LSCs stemness through metabolic remodeling.

Ferroptosis is involved in the damage of ocular lens under long-term PM2.5 exposure in rat models and humans

Epidemiological studies show a positive association between air pollution and age-related cataracts, but the pathogenic mechanism remains unclear. This study first demonstrates that fine particulate matter (PM2.5) induces ferroptosis in the lens, leading to morphological and functional disorders, through human, animal, and cellular samples. In 3-week PM2.5-exposed rat models (10 µl 1 mg/ml PM2.5 suspension per eye, 4 times a day), we find that many vacuoles form in the lens equatorial region by analysis of haematoxylin and eosin staining after PM2.5 exposure. Using iron and glutathione (GSH) assay kits, we found increased Fe2+ contents and decreased GSH levels in PM2.5-exposed rats’ lenses. Additionally, the lipid peroxide 4-hydroxynonenal (4-HNE) was also found to be elevated with immunoblot, suggesting ferroptosis is involved. Ferroptosis was also observed in human lens epithelial cells treated with 25, 50, and 100 µg/ml PM2.5 suspension for 24 h, accompanied by decreased cell viability and migration. Furthermore, we collect about 60 human lens anterior capsule (HLAC) samples for RNA-seq. The results show that compared to HLACs from areas with PM2.5 concentration ≤30 μg/m³, ferroptosis-related genes expression of those from areas with PM2.5 concentration ≥35 μg/m³ are significantly altered, such as glutathione peroxidase 4 and STEAP family member 3. Also, human lens in areas with high PM2.5 concentrations showed elevated levels of transferrin receptor and 4-HNE with immunoblot, and down-regulated expression of connexin 43 (Cx43) through immunofluorescent. These results demonstrate that ferroptosis plays a key role in PM2.5-induced cataractogenesis.

Direct Interaction Between CD34+ Hematopoietic Stem Cells and Mesenchymal Stem Cells Reciprocally Preserves Stemness.

A specialized microenvironment in the bone marrow, composed of stromal cells including mesenchymal stem cells (MSCs), supports hematopoietic stem cell (HSC) self-renewal, and differentiation bands play an important role in leukemia development and progression. The reciprocal direct interaction between MSCs and CD34+ HSCs under physiological and pathological conditions is yet to be fully characterized. Here, we established a direct co-culture model between MSCs and CD34+ HSCs or MSCs and acute myeloid leukemia cells (THP-1, Molm-13, and primary cells from patients) to study heterocellular communication. Following MSCs-CD34+ HSCs co-culture, the expression of adhesion markers N-Cadherin and connexin 43 increased in both cell types, forming gap junction channels. Moreover, the clonogenic potential of CD34+ HSCs was increased. However, direct contact of acute myeloid leukemia cells with MSCs reduced the expression levels of connexin 43 and N-Cadherin in MSCs. The impairment in gap junction formation may potentially be due to a defect in the acute myeloid leukemia-derived MSCs. Interestingly, CD34+ HSCs and acute myeloid leukemia cell lines attenuated MSC osteoblastic differentiation upon prolonged direct cell-cell contact. In conclusion, under physiological conditions, connexin 43 and N-Cadherin interaction preserves stemness of both CD34+ HSCs and MSCs, a process that is compromised in acute myeloid leukemia, pointing to the possible role of gap junctions in modulating stemness.

Water-Soluble Lynx1 Upregulates Dendritic Spine Density and Stimulates Astrocytic Network and Signaling.

Secreted and membrane-tethered mammalian neuromodulators from the Ly6/uPAR family are involved in regulation of many physiological processes. Some of them are expressed in the CNS in the neurons of different brain regions and target neuronal membrane receptors. Thus, Lynx1 potentiates nicotinic acetylcholine receptors (nAChRs) in the brain, while others like Lypd6 and Lypd6b suppress it. However, the mechanisms underlying the regulation of cognitive processes by these neuromodulators remain unclear. Here, we showed that water-soluble analogue of Lynx1 (ws-Lynx-1) targets α7-nAChRs both in the hippocampal neurons and astrocytes. Incubation of astrocytes with ws-Lynx1 increased expression of connexins 30 and 43; α4, α5, and β4 integrins; and E- and P-cadherins. Ws-Lynx1 reduced secretion of pro-inflammatory adhesion factors ICAM-1, PSGL-1, and VCAM-1 and downregulated secretion of CD44 and NCAM, which inhibit synaptic plasticity. Moreover, increased astrocytic secretion of the dendritic growth activator ALCAM and neurogenesis regulator E-selectin was observed. Incubation of neurons with ws-Lynx1 potentiated α7-nAChRs and upregulated dendritic spine density. Thus, the pro-cognitive activity of ws-Lynx1 observed previously can be explained by stimulation of astrocytic network and signaling together with up-regulation of spinogenesis, potentiation of the α7-nAChRs, and neuronal and synaptic plasticity. For comparison, influence of water-soluble analogues of a set of Ly6/uPAR proteins (SLURP-1, SLURP-2, Lypd6, Lypd6b, and PSCA) on dendritic spine density and diameter was studied. Data obtained give new insights on the role of Ly6/uPAR proteins in the brain and open new prospects for the development of drugs to improve cognitive function.

CSIG-16. A CX43-WNK1-C-MYC SIGNALING AXIS DRIVES GLIOBLASTOMA CANCER STEM CELL SURVIVAL

Abstract Tumors represent a highly dynamic system that relies on coordinated signaling to drive growth and adapt to selective pressures, including those induced by anti-cancer therapies. Given the need for tumors to engage in rapid and coordinated cell-cell communication, mechanisms such as gap junction intracellular communication (GJIC) should be essential. However, the connexin proteins that make up gap junctions have traditionally been considered tumor suppressors based on the frequent loss of GJIC and lower connexin expression in tumor cells compared to non-neoplastic tissue. For this reason, connexin 43 (Cx43) has been proposed to suppress the growth of glioblastoma (GBM), the most common primary malignant brain tumor. However, recent data suggest that this tumor-suppressive effect is context dependent and that connexins can also function in a tumor-promoting role. Using next-generation sequencing techniques, we found Cx43 expressed at high levels in a panel of GBM patient-derived xenograft (PDX) CSCs and that these models rely on Cx43 for their survival and self-renewal. Mechanistically, depletion of Cx43 led to a dramatic loss of c-MYC expression through reduced phosphorylation of its upstream mediator WNK lysine-deficient protein kinase 1 (WNK1). Depletion of WNK1 phenocopied knockdown of Cx43 and reduced MYC protein and mRNA as well as tumor growth in vivo. Together, this work defines a novel signaling axis downstream of gap junction protein expression that promotes tumor growth and cancer stem cell phenotypes in GBM. Due to the difficulty in targeting both Cx43 and MYC, the identification of intermediate targetable signaling nodes may lead to improved therapies for patients with GBM.

Glioma-Astrocyte connexin43 confers temozolomide resistance through activation of the E2F1/ERCC1 axis.

Glioma is the most prevalent and lethal tumor of the central nervous system. Routine treatment with Temozolomide (TMZ) would unfortunately result in inevitable recurrence and therapy resistance, severely limiting therapeutic efficacy. Tumor associated astrocytes (TAAs) are key components of the tumor microenvironment and increasing evidence has demonstrated that aberrant expression of Connexin43 (Cx43) was closely associated with glioma progression and TMZ resistance. However, the specific role of Cx43 in mediating TMZ resistance through glioma and astrocyte interactions has not been fully explored. The expression and prognostic value of Cx43 were evaluated in tumor samples and clinical databases. ShRNA-medicated knockdown and Gfap-Cre Cx43flox/flox gene mouse were used to assessed the role and functional significance of Cx43 in vitro and in vivo. Moreover, we performed mass spectrometry analysis, chromatin immunoprecipitation, and other biochemical assays to define the molecular mechanisms by which Cx43 promotes TMZ resistance. We confirmed that upregulation of Cx43 expression between TAAs and glioma cells contributed to TMZ resistance and tumor recurrence. Genetic knockdown or pharmacological inhibition of Cx43 enhanced TMZ-induced cytotoxicity. Mechanistically, elevated Cx43 expression induced β-catenin accumulation at the cell surface of glioma cells, suppressing TCF/LEF transcription, This led to impaired miR-205-5p expression and subsequent activation of E2F1/ERCC1 axis, which eventually led to chemoresistance. Our study reveals a novel regulatory mechanism in which the Cx43/miR-205-5p/E2F1/ERCC1 axis contributes to TMZ resistance in glioma. These findings further highlight the potential of targeting Cx43 as a therapeutic strategy in glioma.

Nppb contributes to Sepsis-Induced myocardial injury by regulating Senescence-Related genes

BackgroundSepsis, a systemic inflammatory condition, is a leading cause of mortality due to cardiovascular injury. Sepsis and cellular senescence are closely related, yet the specific mechanisms are still unclear. This study aims to identify a novel therapeutic target for mitigating sepsis-induced myocardial injury. MethodsWe initially assessed serum inflammatory markers and myocardial injury indicators in septic mice. This involved observing inflammatory cell infiltration in ventricular muscle tissue, assessing cardiac function, and recording electrocardiograms. We examined the expression of connexin 40 (Cx40) and connexin 43 (Cx43) and analyzed mitochondrial structures in ventricular tissues. A conditional heart-specific Nppb knockout mouse model was then developed in mice to evaluate these changes. Ventricular tissues were analyzed via mRNA sequencing to identify differentially expressed genes (DEGs), which were cross-referenced with senescence-related genes to identify key hub genes. The expression and distribution of hub genes were subsequently analyzed by single-cell analysis. Finally, the expression of the senescence-related gene CCL2, along with cardiac structure and function, was validated in a conditional heart-specific Nppb knockout sepsis mouse model. ResultsMyocardial injury severity positively correlated with serum brain natriuretic peptide (BNP) in septic mice. Conditional heart-specific Nppb knockout improved myocardial injury outcomes in mice with sepsis. The DEGs identified in the conditional heart-specific Nppb knockout model overlapped with senescence-related genes, identifying seven upregulated genes associated with inflammation, cardiac contraction and apoptotic pathways. Single-cell analysis confirmed high CCL2 levels and an increased macrophage presence correlating with sepsis progression. Conditional heart-specific Nppb knockout reduced CCL2 levels, which were associated with improved cardiac structure and function. ConclusionThis study confirms that conditional heart-specific Nppb knockout reduces CCL2 expression, thereby ameliorating myocardial injury in septic mice. Targeting Nppb to regulate the senescence-related gene CCL2 may represent an effective strategy for treating myocardial injury in septic patients.

Macrophages enhance sodium channel expression in cardiomyocytes

Cardiac macrophages facilitate electrical conduction through the atrioventricular-node (AV) in mice. A possible role for cardiomyocyte-macrophage coupling on the effect of antiarrhythmic therapy has not been investigated yet. Holter monitoring was conducted in LysMCrexCsf1rLsL−DTR mice (MMDTR) under baseline conditions and after an elctrophysiological stress test by flecainide. In vivo effects were recapitulated in vitro by patch-clamp experiments. The underlying mechanism was characterized by expression and localization analysis of connexin43 (Cx43) and voltage-gated-sodium-channel-5 (Nav1.5). ECG monitoring in MMDTR mice did not show any significant conduction abnormalities but a significantly attenuated flecainide-induced extension of RR- and PP-intervals. Patch-clamp analysis revealed that the application of flecainide to neonatal rat ventricular cardiomyocytes (CMs) changed their resting-membrane-potential (RMP) to more negative potentials and decreased action-potential-duration (APD50). Coupling of macrophages to CMs significantly enhances the effects of flecainide, with a further reduction of the RMP and APD50, mediated by an upregulation of Cx43 and Nav1.5 surface expression. Macrophage depletion in mice does not correlate with cardiac electric conduction delay. Cardiac macrophages amplify the effects of flecainide on electrophysiological properties of cardiomyocytes in vivo and in vitro. Mechanistically, formation of macrophage-cardiomyocyte cell–cell-contacts via Cx43 facilitates the recruitment of Nav1.5 to the cell membrane increasing flecainide effects.

Morphological, electrophysiological, and molecular alterations in foetal noncompacted cardiomyopathy induced by disruption of ROCK signalling.

Left ventricular noncompaction cardiomyopathy is associated with heart failure, arrhythmia, and sudden cardiac death. The developmental mechanism underpinning noncompaction in the adult heart is still not fully understood, with lack of trabeculae compaction, hypertrabeculation, and loss of proliferation cited as possible causes. To study this, we utilised a mouse model of aberrant Rho kinase (ROCK) signalling in cardiomyocytes, which led to a noncompaction phenotype during embryogenesis, and monitored how this progressed after birth and into adulthood. The cause of the early noncompaction at E15.5 was attributed to a decrease in proliferation in the developing ventricular wall. By E18.5, the phenotype became patchy, with regions of noncompaction interspersed with thick compacted areas of ventricular wall. To study how this altered myoarchitecture of the heart influenced impulse propagation in the developing and adult heart, we used histology with immunohistochemistry for gap junction protein expression, optical mapping, and electrocardiography. At the prenatal stages, a clear reduction in left ventricular wall thickness, accompanied by abnormal conduction of the ectopically paced beat in that area, was observed in mutant hearts. This correlated with increased expression of connexin-40 and connexin-43 in noncompacted trabeculae. In postnatal stages, left ventricular noncompaction was resolved, but the right ventricular wall remained structurally abnormal through to adulthood with cardiomyocyte hypertrophy and retention of myocardial crypts. Thus, this is a novel model of self-correcting embryonic hypertrabeculation cardiomyopathy, but it highlights that remodelling potential differs between the left and right ventricles. We conclude that disruption of ROCK signalling induces both morphological and electrophysiological changes that evolve over time, highlighting the link between myocyte proliferation and noncompaction phenotypes and electrophysiological differentiation.

Se-Methylselenocysteine Ameliorates DEHP-Induced Ferroptosis in Testicular Sertoli Cells via the Nrf2/GPX4 Axis.

Di (2-ethylhexyl) phthalate (DEHP) is an important plasticizer in industrial production, and its toxic effects on testes are widely recognized. Se-methylselenocysteine (SMC) is a major selenium compound found in selenium-rich plants, which possesses unique biological properties such as antioxidants. However, the effect of SMC on DEHP-induced testicular injury and the specific mechanism remains unknown. In this study, 50 mice were randomly divided into 5 groups and were given corn oil (Control), DEHP, low-dose SMC (L-SMC), moderate-dose SMC (M-SMC), or high-dose SMC (H-SMC). The sperm quality of the mice in each group was determined, and HE staining and transmission electron microscopy (TEM) were applied to observe testicular morphology, and testicular tissues were collected for the subsequent molecular biological analyses. The TM4 cell line was applied in vitro for mechanism validation. Our results showed that DEHP could lead to decreased sperm quality and blood-testis barrier damage in mice, which could be alleviated by SMC. Mitochondrial damage accompanied by accumulation of total iron content, MDA, and 4-HNE, as well as downregulation of antioxidants SOD, GSH, and GSH-Px were observed after DEHP treatment, which exhibited a typical ferroptosis feature. In vitro experiments confirmed that SMC promoted upregulation of GPX4 in TM4 cells and was able to alleviate DEHP metabolite MEHP-induced ferroptosis and promote the expression of cell junction key proteins ZO-1, Occludin, and Connexin 43, which could be inhibited by the GPX4 inhibitor RSL3 or the Nrf2 inhibitor ML385. Overall, the above results suggest that SMC ameliorates the DEHP-induced ferroptosis in testicular Sertoli cells, protects the blood-testis barrier, and prevents sperm aberrations via the Nrf2/GPX4 axis.

Calmodulin kinase II inhibition suppresses atrioventricular conduction by regulating intracellular Ca2+ homeostasis

BackgroundCa2+/calmodulin-dependent protein kinase II (CaMKII) inhibition decelerates atrioventricular node (AVN) conduction, providing a potential treatment of tachycardia. However, the effectiveness of CaMKII inhibition on tachycardia and its underlying mechanism remains unclear. ObjectiveWe aimed to assess the effectiveness of CaMKII inhibition in reducing ventricular rates during atrial fibrillation and to elucidate the underlying mechanism in affecting AVN electrophysiology. MethodsCardiac CaMKII inhibition (AC3-I) mice were used. Transesophageal atrial pacing was performed to evaluate AVN conduction function and to induce atrial fibrillation. Patch-clamp techniques were employed to record action potentials and ionic currents in AVN cells. Intracellular Ca2+ transients and sarcomere length measurements were obtained with the IonOptix system. Masson trichrome stain was used to evaluate fibrosis in the AVN region. Western blotting and immunofluorescence techniques were employed to detect connexin expression and localization. ResultsCaMKII inhibition decreased the ventricular rate during atrial fibrillation and isoproterenol-induced tachycardia. Esophageal electrocardiogram results from AC3-I mice showed longer AVN conduction than in wild-type mice. AN- and N-type AVN cells from AC3-I mice exhibited slower action potential frequencies and diastolic depolarization rates than those of wild-type mice. The study revealed that CaMKII inhibition reduced AVN cell sarcoplasmic reticulum (SR) Ca2+ content, Ca2+ release rate from the SR during diastole, Ca2+ transient amplitude, and SR Ca2+ uptake rate. In addition, CaMKII inhibition prolonged the sarcomere diastole duration and enhanced the sensitivity of sarcomeres to Ca2+. ConclusionCaMKII inhibition effectively decreases the ventricular rate during atrial fibrillation and tachycardia by slowing down AVN conduction through suppressing Ca2+ overload in AVN cells.

Reactive astrocytes generated from human iPSC are pro-inflammatory and display altered metabolism

Astrocytes are the most abundant type of glial cell in the central nervous system and they play pivotal roles in both normal health and disease. Their dysfunction is detrimental to many brain related pathologies. Under pathological conditions, such as Alzheimer's disease, astrocytes adopt an activated reactive phenotype which can contribute to disease progression. A prominent risk factor for many neurodegenerative diseases is neuroinflammation which is the purview of glial cells, such as astrocytes and microglia. Human in vitro models have the potential to reveal relevant disease specific mechanisms, through the study of individual cell types such as astrocytes or the addition of specific factors, such as those secreted by microglia. The aim of this study was to generate human cortical astrocytes, in order to assess their protein and gene expression, examine their reactivity profile in response to exposure to the microglial secreted factors IL-1α, TNFα and C1q and assess their functionality in terms of calcium signalling and metabolism. The successfully differentiated and stimulated reactive astrocytes display increased IL-6, RANTES and GM-CSF secretion, and increased expression of genes associated with reactivity including, IL-6, ICAM1, LCN2, C3 and SERPINA3. Functional assessment of these reactive astrocytes showed a delayed and sustained calcium response to ATP and a concomitant decrease in the expression of connexin–43. Furthermore, it was demonstrated these astrocytes had an increased glycolytic capacity with no effect on oxidative phosphorylation. These findings not only increase our understanding of astrocyte reactivity but also provides a functional platform for drug discovery.

CYLD Alterations Are Associated With Metastasis and Poor Prognosis in Human Papilloma Virus-Positive Head and Neck Cancer.

Human papilloma virus (HPV)-associated head and neck squamous cell carcinoma (HNSCC) is an emerging epidemic and a subset of HPV-positive patients experience aggressive disease with metastases. The CYLD gene is frequently altered in HPV-positive HNSCC, but the role of these alterations in disease progression is poorly understood. We identified 11 HPV-positive HNSCC patients with CYLD alterations and assessed their clinical course. We also characterized a unique, HPV-positive, metastatic, HNSCC patient-derived xenograft (PDX). All 11 patients developed metastasis with reduced overall survival when compared with metastatic HPV-positive patients with wild-type CYLD. The metastatic PDX harbored a CYLD mutation (S371*) and exhibited reduced expression of connexin 43, a potentially antimetastatic protein. We also investigated the functional impact of the S371* mutation, as well as 2 CYLD mutations from our 11-patient cohort. Our findings indicate that alterations in CYLD in HPV-positive HNSCC are associated with metastasis and poor prognosis.