Phenotypic Conversion Research Articles

Inhibition of STAT3 phosphorylation attenuates perioperative neurocognitive disorders in mice with D-galactose-induced aging by regulating pro-inflammatory reactive astrocytes.

Perioperative Neurocognitive Disorders (PND) are associated withanesthesia and surgery, especially in the elderly. Astrocyte activation in old mice correlates with PND development. These cells can switch to a pro-inflammatory or an anti-inflammatory phenotype, regulated by the STAT3 pathway. It remains unclear whether STAT3 can alleviate PND symptoms in elderly mice by modulating the transitions between these astrocyte phenotypes. Senescence was induced in eight-week-old male C57BL/6J mice with D-galactose, followed by tibial fracture surgery under anesthesia to model PND. On the third postoperative day, cognitive function was assessed using fear conditioning, synaptic plasticity using Golgi/ electrophysiology, and astrocyte phenotype /STAT3/pSTAT3(phosphorylated STAT3) using Western blot/immunofluorescence. The content of neurotrophic factors, including brain-derived neurotrophic factor (BDNF) and glial cell line-derived neurotrophic factor (GDNF), was also measured. Primary astrocytes were stimulated with the conditioned medium referred to as ACM to induce pro-inflammatory reactive astrocytes. Stattic, an inhibitor of STAT3 phosphorylation, was used to investigate its effects on astrocyte phenotypic transformation and hippocampus-dependent learning and memory in aging mice, both in vitro and in vivo. On the third postoperative day, pSTAT3 levels and pro-inflammatory astrocytes increased in the hippocampal CA1 region, with no change in total STAT3 or anti-inflammatory astrocytes, accompanied by a decrease in GDNF and BDNF.ACM treatment of primary astrocytes promoted pro-inflammatory phenotype conversion, which was inhibited by stattic without affecting anti-inflammatory phenotype. Intraperitoneal injection of stattic in mice reduced the accumulation of pro-inflammatory astrocytes, increased the levels of BDNF and GDNF, enhanced synaptic plasticity, and improved hippocampus-dependent learning and memory functions in anesthesia-induced senescent mice, without altering anti-inflammatory astrocytes. Inhibiting STAT3 phosphorylation may improve synaptic plasticity in the CA1 region of the hippocampus by modulating pro-inflammatory astrocytes, thereby alleviating perioperative neurocognitive dysfunction in D-galactose-induced aging mice.

Astrocyte-conditional knockout of MOB2 inhibits the phenotypic conversion of reactive astrocytes from A1 to A2 following spinal cord injury in mice.

After spinal cord injury (SCI), reactive astrocytes in the injured area are triggered after spinal cord injury (SCI) and to polarize into A1 astrocytes with a proinflammatory phenotype or A2 astrocytes with an anti-inflammatory phenotype. Monopolar spindle binder 2 (MOB2) induces astrocyte stellation, maintains cell homeostasis, and promotes neurite outgrowth; however, its role in the phenotypic transformation of reactive astrocytes remains unclear. Here, we confirmed for the first time that MOB2 is associated with A1/A2 phenotypic switching in reactive astrocytes following SCI in mice. MOB2 modulated A1/A2 transformation in a primary astrocyte reactive cell model. Therefore, we constructed MOB2 conditional knockout mice (MOB2GFAP-CKO) and discovered that conditional knockout of MOB2 inhibited the conversion of reactive astrocytes from A1 to A2 and hindered spinal cord function recovery. Mechanistically, MOB2 increased the activation of PI3K-AKT signaling to promote A1/A2 transformation in vitro, whereas sc79 (an AKT activator) reversed the subtype transformation of reactive astrocytes and improved functional recovery in MOB2GFAP-CKO mice after SCI. Taken together, study provides the first insights into how MOB2 acts as a novel regulator to promote the conversion this of the reactive astrocyte phenotype from A1 to A2, showing great potential for the treatment of SCI.

Ipsilateral Breast Carcinoma Recurrence: True Recurrence or New Primary? A Clinicopathologic and Molecular Study.

Determining whether an ipsilateral breast carcinoma recurrence is a true recurrence or a new primary remains challenging based solely on clinicopathologic features. Algorithms based on these features have estimated that up to 68% of recurrences might be new primaries. However, few studies have analyzed the clonal relationship between primary and secondary carcinomas to establish the true nature of recurrences. This study analyzed 70 breast carcinomas from 33 patients using immunohistochemistry, FISH, and massive parallel sequencing. We compared 35 primary carcinomas with the associated recurrences, identifying 24 (68.6%) as true recurrences, 7 (20%) as new primaries, and 4 (11%) as undetermined. Twenty-eight primary carcinomas were invasive carcinomas (22 of no special type, 5 invasive lobular, and 1 invasive micropapillary carcinoma), and 7 were in situ (6 ductal and 1 lobular). Time to recurrence was longer for new primaries (median 12.8y) than for true recurrences (median 6.8y). Among the new primary cases, 6 of 7 (85%) patients had undergone mastectomy as their initial treatment. Clinicopathologic classifications of invasive carcinomas overestimated the number of new primaries (41.6% to 68.6%), partially due to phenotype conversion in 14% of true recurrences. Although 41.7% of recurrences showed private mutations or amplifications relevant to tumor progression, such as PIK3CA, PIK3R1, MAP3K1, AKT1, GATA3, CCND1, MDM4, or T P 5 3; a common mutational progression pattern was not identified. Further studies, including larger series, are necessary to evaluate the prognostic significance of the molecular classification of recurrences.

Lonidamine, a Novel Modulator for the BvgAS System of Bordetella Species.

The Gram-negative bacteria Bordetella pertussis, B. parapertussis, and B. bronchiseptica cause respiratory diseases in various mammals. They share the BvgAS two-component system, which regulates the phenotypic conversion between the virulent Bvg+ and avirulent Bvg- phases. In the BvgAS system, the sensor kinase BvgS senses environmental cues and transduces a phosphorelay signal to the response regulator BvgA, which leads to the expression of Bvg+ phase-specific genes, including virulence factor genes. Bacteria grown at 37°C exhibit the Bvg+ phenotype. In contrast, at lower than 26°C or in the presence of modulators, such as MgSO4 and nicotinic acid, the BvgAS system is inactivated, leading bacteria to the avirulent Bvg- phase. Therefore, effective modulators are expected to provide a therapeutic measure for Bordetella infection; however, no such modulators are currently available, and the mechanism by which modulators inactivate the BvgAS system is poorly understood. In the present study, we identified lonidamine as a novel modulator after screening an FDA-approved drug library using bacterial reporter systems with the Bvg+-specific and Bvg--specific promoters. Lonidamine directly bound to the VFT2 domain of BvgS and inactivated the BvgAS system at concentrations as low as 50 nM, which was at least 2000- to 20,000-fold lower than the effective concentrations of known modulators. Lonidamine significantly reduced the adherence of B. pertussis to cultured cells but unexpectedly exacerbated bacterial colonization of the mouse nasal septum. These results provide insights into the structural requirements for BvgAS modulators and the role of Bvg phenotypes in the establishment of infection.

Platelet-Monocyte Aggregate Instigates Inflammation and Vasculopathy in Kawasaki Disease.

Kawasaki disease (KD) is a severe acute febrile illness and systemic vasculitis that causes coronary artery aneurysms in young children.Platelet hyperreactivity and an aberrant immune responseare key indicatorsof KD; however, the mechanism by which hyperactive platelets contribute toinflammation and vasculopathyin KD remainsunclear. A cytokine-mediated positive feedback loop between KD platelets and monocytes is identified. KD platelet-monocyte aggregates(MPAs) are mediated by an initial interaction of P-selectin(cluster of differentiation 62P, CD62p) and its glycoprotein ligand 1 (PSGL-1). This is followed bya coordinated interactionof platelet glycoprotein (GP)Ibαwithmonocyte CD11b.Monocyte-activated platelets initiate transforming growth factor(TGF)β1release, whichresultsinnuclear localization of nuclear factor kappaBin monocytes, therefore, driving the phenotypic conversion of classical monocytes (CD14+CD16-) into proinflammatory monocytes (CD14+CD16+).The platelet-activated monocytesreleaseinterleukin-1 and tissue necrotic factor-α, whichpromote further platelet activation. KD-induced inflammation and vasculopathy are prevented by inhibiting the componentsof this positive feedback loop. Notably, mice deficient in platelet TGFβ1 showless MPA and CD14+CD16+monocytes, along withreduced inflammation and vasculopathy. These findingsreveal thatplatelet-monocyte interactive proteins (CD62p/PSGL-1 and (GP)Ibα/CD11b) and cytokine mediators (platelet TGFβ1) are potential biomarkers and therapeutic targetsfor KD vasculopathy.

Colchicine reduces neointima formation and VSMC phenotype transition by modulating SRF-MYOCD activation and autophagy.

Vascular smooth muscle cell (VSMC) phenotype transformation significantly contributes to vascular intimal hyperplasia. However, effective preventive and therapeutic measures are lacking. Colchicine, a binary alkaloid derived from Colchicum autumnale, is traditionally used for treating inflammatory diseases. Its role in neointima formation is not fully understood. Here, we investigated the role of colchicine in vascular intimal hyperplasia. We found that colchicine significantly reduced vascular intimal hyperplasia in an animal model at 7, 14, and 28 days post carotid artery ligation and increased the number of contractile-phenotype VSMCs (SMA-positive cells) in the neointimal areas. In vitro experiments demonstrated that colchicine facilitated the transition of VSMCs from a proliferative phenotype to a contractile phenotype. Additionally, colchicine attenuated PDGF-BB-induced phenotypic conversion and upregulated the expression of serum response factor (SRF) and myocardin (MYOCD). Further molecular mechanistic studies revealed that colchicine inhibited the expression of forkhead box protein O3A (FOXO3A) to increase the activation of the SRF‒MYOCD complex. FOXO3A can bind to MSX1/2, thereby inhibiting the expression of SRF-MYOCD and contractile genes. Moreover, colchicine maintains vascular homeostasis and stabilizes the contractile phenotype by affecting the expression of autophagy-related genes (LC3II, p62, and Beclin-1) induced by FOXO3A. Additionally, colchicine inhibited monocyte/macrophage infiltration and inflammatory cytokine expression. In summary, this study suggests that colchicine inhibits vascular intimal hyperplasia by modulating FOXO3A-mediated SRF-MYOCD activation and autophagy, providing new insights for future therapeutic approaches targeting occlusive vascular diseases.

Chronic inflammation and vascular cell plasticity in atherosclerosis.

Vascular smooth muscle cells, endothelial cells and macrophages undergo phenotypic conversions throughout atherosclerosis progression, both as a consequence of chronic inflammation and as subsequent drivers of it. The inflammatory hypothesis of atherosclerosis has been catapulted to the forefront of cardiovascular research as clinical trials have shown that anti-inflammatory therapy reduces adverse cardiovascular events. However, no current therapies have been specifically designed to target the phenotype of plaque cells. Fate mapping has revealed that plaque cells convert to detrimental and beneficial cell phenotypes during atherosclerosis, with cumulative evidence highlighting that vascular cell plasticity is intimately linked with plaque inflammation, ultimately impacting lesion stability. Here we review vascular cell plasticity during atherosclerosis in the context of the chronic inflammatory plaque microenvironment. We highlight the need to better understand how plaque cells behave during therapeutic intervention. We then propose modulating plaque cell phenotype as an unexplored therapeutic paradigm in the clinical setting.

MAIT cell plasticity enables functional adaptation that drives antibacterial immune protection.

Mucosal-associated invariant T (MAIT) cells are known for their rapid effector functions and antibacterial immune protection. Here, we define the plasticity of interferon-γ (IFN-γ)-producing MAIT1 and interleukin-17A (IL-17A)-producing MAIT17 cell subsets in vivo. Whereas T-bet+ MAIT1 cells remained stable in all experimental settings, after adoptive transfer or acute Legionella or Francisella infection, RORγt+ MAIT17 cells could undergo phenotypic and functional conversion into both RORγt+T-bet+ MAIT1/17 and RORγt-T-bet+ MAIT1 cells. This plasticity ensured that MAIT17 cells played a dominant role in generating antibacterial MAIT1 responses in mucosal tissues. Single-cell transcriptomics revealed that MAIT17-derived MAIT1 cells were distinct from canonical MAIT1 cells yet could migrate out of mucosal tissues to contribute to the global MAIT1 pool in subsequent systemic infections. Human IL-17A-secreting MAIT cells also showed similar functional plasticity. Our findings have broad implications for understanding the role of MAIT cells in combatting infections and their potential utility in MAIT cell-targeted vaccines.

Epigenetic regulation of vascular smooth muscle cell phenotypes in atherosclerosis.

Vascular smooth muscle cells (VSMCs) in adult arteries maintain substantial phenotypic plasticity, which allows for the reversible cell state changes that enable vascular remodelling and homeostasis. In atherosclerosis, VSMCs dedifferentiate in response to lipid accumulation and inflammation, resulting in loss of their characteristic contractile state. Recent studies showed that individual, pre-existing VSMCs expand clonally and can acquire many different phenotypes in atherosclerotic lesions. The changes in gene expression underlying this phenotypic diversity are mediated by epigenetic modifications which affect transcription factor access and thereby gene expression dynamics. Additionally, epigenetic mechanisms can maintain cellular memory, potentially facilitating reversion to the contractile state. While technological advances have provided some insight, a comprehensive understanding of how VSMC phenotypes are governed in disease remains elusive. Here we review current literature in light of novel insight from studies at single-cell resolution. We also discuss how lessons from epigenetic studies of cellular regulation in other fields could help in translating the potential of targeting VSMC phenotype conversion into novel therapies in cardiovascular disease.

Curcumin Nicotinate Activates AMPK to Inhibit Aerobic Glycolysis in Vascular Endothelial Cells to Prevent Restenosis

Abnormal proliferation of vascular smooth muscle cells (VSMCs) participates in restenosis after percutaneous coronary intervention (PCI). Curcumin, as the main active ingredient of turmeric, has been proven to inhibit the abnormal proliferation of VSMCs. This study intends to identify the mechanism whereby curcumin nicotinate (CurTn) protects against vascular restenosis. The expression of PTEN and PFKFB3 in VSMCs was detected by immunofluorescence and Western blot. Glycolysis in VSMCs was evaluated by detecting ECAR expression and MTT assays, whilst the Tandem Mass Tag (TMT)-based Liquid Chromatography with tandem mass spectrometry (LC-MS/MS) determined expression of AMPK/PTEN/PFKFB3 in glycolysis. After treatment with CurTn, intracellular citrate and acetyl-CoA levels, and expression of triglyceride content were measured. PFKFB3 and PTEN was up-regulated in the carotid artery specimen. Overexpression of PTEN induced abnormal proliferation of VSMCs and promoted the phenotype conversion of VSMCs when increasing PFKFB3 expression. Additionally, while overexpression of AMPK did not up-regulate PFKFB3 expression, silencing of AMPK prevented the increase in PFKFB3 expression induced by PTEN. Treatment with CurTn enhanced glycolysis and increased the expression level of citrate, acetyl-CoA, and triglycerides. Importantly, PTEN overexpression increased PFKFB3 KD and PFK158 expression and alleviated CurTn-induced increase in triglyceride content. CurTn effectively delays the process of vascular restenosis through AMPK/PTEN/PFKFB3 pathway to inhibit aerobic glycolysis and VSMC proliferation.

A Snapshot of Early Transcriptional Changes Accompanying the Pro-Neural Phenotype Switch by NGN2, ASCL1, SOX2, and MSI1 in Human Fibroblasts: An RNA-Seq Study.

Direct pro-neural reprogramming is a conversion of differentiated somatic cells to neural cells without an intermediate pluripotency stage. It is usually achieved via ectopic expression (EE) of certain transcription factors (TFs) or other reprogramming factors (RFs). Determining the transcriptional changes (TCs) caused by particular RFs in a given cell line enables an informed approach to reprogramming initiation. Here, we characterized TCs in the human fibroblast cell line LF1 on the 5th day after EE of the single well-known pro-neural RFs NGN2, ASCL1, SOX2, and MSI1. As assessed by expression analysis of the bona fide neuronal markers nestin and beta-III tubulin, all four RFs initiated pro-neuronal phenotype conversion; analysis by RNA-seq revealed striking differences in the resulting TCs, although some pathways were overlapping. ASCL1 and SOX2 were not sufficient to induce significant pro-neural phenotype switches using our EE system. NGN2 induced TCs indicative of cell phenotype changes towards neural crest cells, neural stem cells, mature neurons, as well as radial glia, astrocytes, and oligodendrocyte precursors and their mature forms. MSI1 mainly induced a switch towards early stem-like cells, such as radial glia.

Abstract 4120375: Penetrance and Phenotype Conversion Rate of Genetic Hypertrophic Cardiomyopathy in an Academic Biobank

Introduction: Hypertrophic cardiomyopathy (HCM) is an autosomal dominant condition with incomplete penetrance and variable expressivity. Given the increasing prevalence of sequencing and current guidelines on secondary finding disclosure, HCM P/LP alleles are increasingly being returned to patients who undergo genetic testing for other reasons. Whether individuals carrying P/LP HCM variants discovered in a genome-first context have progressive endophenotypes indicative of HCM remains poorly understood. Methods: To evaluate the penetrance and phenotype conversion rate of adults with P/LP HCM variants, we leveraged the Massachusetts General Brigham Biobank (MGBB), which consists of 36,417 participants with genotyping array and clinical data. Primary images of the earliest and latest TTE studies were reviewed for measurements of the posterior wall (PW), interventricular septum (IVS), and left ventricular morphology. Phenotype-positive (P+) status was defined by a PW or IVS thickness of at least 13 mm. Results: P/LP HCM variants were identified in 42 (0.1%) individuals with mean (SD) age 50.0 (16.6) years and 21 (50%) female sex. The most common HCM variants were in MYBPC3 (44%) and MYH7 (40%), followed by TNNI3(7%), MYL3 (7%), and TNNT2 (2%). Among the 42 genotype-positive (G+) individuals in MGBB, 17 (40%) had pre-existing HCM diagnoses prior to genomic return of results (gRoR). In contrast, 25 (60%) G+ individuals lacked a prior HCM diagnosis, among whom gRoR prompted TTE studies in 13 patients, revealing evidence of HCM in 9 individuals. Among the 42 G+ patients, 25 (58%) patients had completed at least two TTE studies, with a median [IQR] of 6 [3-9] TTE studies per patient, across a span of 10 [7-15] years follow-up. At the time of first TTE, 16 (64%) patients were P+ while 9 (36%) were P-. No G+, P- individuals converted to P+ over 10 years follow-up, nor was there any significant change in IVS or PW thickness. In contrast, individuals who were P+ at the initial TTE exhibited thickening PW (25% increase, CI 97.5% of 6 to 44) and IVS (26% increase, CI 97.5% of 4 to 49) over 8 years follow-up. Conclusion: In a genome-first approach, we identified 42 individuals in the MGBB with a P/LP HCM variant, among whom 60% lacked a prior clinical diagnosis of HCM. Targeted phenotyping revealed that nearly half of this newly identified group were P+. Over a median of 10 years follow-up, we observed a 0% phenotype conversion rate among G+, P- adult carriers of HCM variants.

Ligustrazine alleviates the progression of coronary artery calcification by inhibiting caspase-3/GSDME mediated pyroptosis.

Coronary artery calcification (CAC) is an early marker for atherosclerosis and is mainly induced by the osteoblast-like phenotype conversion of vascular smooth muscle cells (VSMCs). Recent reports indicate that NOD-like receptor protein 3 (NLRP3)-mediated pyroptosis plays a significant role in the calcification of vascular smooth muscle cells (VSMCs), making it a promising target for treating calcific aortic valve disease (CAC). Ligustrazine, or tetramethylpyrazine (TMP), has been found effective in various cardiovascular and cerebrovascular diseases and is suggested to inhibit NLRP3-mediated pyroptosis. However, the function of TMP in CAC is unknown. Herein, influences of TMP on β-glycerophosphate (β-GP)-stimulated VSMCs and OPG-/- mice were explored. Mouse Aortic Vascular Smooth Muscle (MOVAS-1) cells were stimulated by β-GP with si- caspase-3, si- Gasdermin E (GSDME) or TMP. Increased calcification, reactive oxygen species (ROS) level, Interleukin-1beta (IL-1β) and Interleukin-18 (IL-18) levels, lactate dehydrogenase (LDH) release, enhanced apoptosis, and activated cysteine-aspartic acid protease-3 (caspase-3)/GSDME signaling were observed in β-GP-stimulated MOVAS-1 cells, which was sharply alleviated by si-caspase-3, si-GSDME or TMP. Furthermore, the impact of TMP on the β-GP-induced calcification and injury in MOVAS-1 cells was abolished by raptinal, an activator of caspase-3. Subsequently, OPG-/- mice were dosed with TMP or TMP combined with raptinal. Calcium deposition, increased nodules, elevated IL-1β and IL-18 levels, upregulated CASP3 and actin alpha 2, smooth muscle (ACTA2), and activated caspase-3/GSDME signaling in OPG-/- mice were markedly alleviated by TMP, which were notably reversed by the co-administration of raptinal. Collectively, TMP mitigated CAC by inhibiting caspase-3/GSDME mediated pyroptosis.

Therapeutic Suppression of Atherosclerotic Burden and Vulnerability via Dll4 Inhibition in Plaque Macrophages Using Dual-Targeted Liposomes.

Atherosclerosis, characterized by chronic inflammation within the arterial wall, remains a pivotal concern in cardiovascular health. We developed a dual-targeted liposomal system encapsulating Dll4-targeting siRNA, designed to selectively bind to pro-inflammatory M1 macrophages through surface conjugation with anti-F4/80 and anti-CD68 antibodies. The Dll4-targeting siRNA is then delivered to the macrophages, where it silences Dll4 expression, inhibiting Notch signaling and reducing plaque vulnerability. Emphasizing accuracy in targeting, the system demonstrates effective suppression of Dll4, a key modulator of atherosclerotic progression, and vulnerability via VSMCs phenotypic conversion and senescence. By employing liposomes for siRNA delivery, we observed enhanced stability and specificity of the siRNA. Alongside the therapeutic efficacy, our study also evaluated the safety profile and pharmacokinetics of the dual-targeted liposomal system, revealing favorable outcomes with minimal off-target effects and optimal biodistribution. The integration of RNA interference techniques with advanced nanotechnological methodologies signifies the importance of targeted delivery in this therapeutic approach. Preliminary findings suggest a potential attenuation in plaque development and vulnerability, indicating the therapeutic promise of this approach. This research emphasizes the potential of nanocarrier-mediated precision targeting combined with a reassuring safety and pharmacokinetic profile for advancing atherosclerosis therapeutic strategies.

Clinical phenotype of ARDS based on K-means cluster analysis: A study from the eICU database

PurposeTo explore the characteristics of the clinical phenotype of ARDS based on Machine Learning. MethodsThis is a study on Machine Learning. Screened cases of acute respiratory distress syndrome (ARDS) in the eICU database collected basic information in the cases and clinical data on the Day 1, Day 3, and Day 7 after the diagnosis of ARDS, respectively. Using the Calinski-Harabasz criterion, Gap Statistic, and Silhouette Coefficient, we determine the optimal clustering number k value. By the K-means cluster analysis to derive clinical phenotype, we analyzed the data collected within the first 24 h. We compared it with the survival of cases under the Berlin standard classification, and also examined the phenotypic conversion within the first 24 h, on day 3, and on day 7 after the diagnosis of ARDS. ResultsWe collected 5054 cases and derived three clinical phenotypes using K-means cluster analysis. Phenotype-I is characterized by fewer abnormal laboratory indicators, higher oxygen partial pressure, oxygenation index, APACHE IV score, systolic and diastolic blood pressure, and lower respiratory rate and heart rate. Phenotype-II is characterized by elevated white blood cell count, blood glucose, creatinine, temperature, heart rate, and respiratory rate. Phenotype-III is characterized by elevated age, partial pressure of carbon dioxide, bicarbonate, GCS score, albumin. The differences in ICU length of stay and in-hospital mortality were significantly different between the three phenotypes (P < 0.05), with phenotype I having the lowest in-hospital mortality (10 %) and phenotype II having the highest (31.8 %). To compare the survival analysis of ARDS patients classified by phenotype and those classified according to Berlin criteria. The results showed that the differences in survival between phenotypes were statistically significant (P < 0.05) under phenotypic classification. ConclusionsThe clinical classification of ARDS based on K-means clustering analysis is beneficial for further identifying ARDS patients with different characteristics. Compared to the Berlin standard, the new clinical classification of ARDS provides a clearer display of the survival status of different types of patients, which helps to predict patient prognosis.

Standard chemotherapy impacts on in vitro cellular heterogeneity in spheroids enriched with cancer stem cells (CSCs) derived from triple-negative breast cancer cell line

Triple-negative breast cancer is a heterogeneous disease with high recurrence and mortality, linked to cancer stem cells (CSCs). Our study characterized distinct cell subpopulations and signaling pathways to explore chemoresistance. We observed cellular heterogeneity among and within the cells regarding phenotyping and drug response. In untreated BT-549 cells, we noted plasticity properties in both CD44+/CD24+/CD146+ hybrid cells and CD44-/CD24+/CD146+ epithelial cells, enabling phenotypic conversion into CD44+/CD24-/CD146- epithelial-mesenchymal transition (EMT)-like like breast CSCs (BCSCs). Additionally, non-BCSCs may give rise to ALDH+ epithelial-like BCSCs. Enriched BCSCs demonstrated the potential to differentiation into CD44-/CD24-/CD146- cells and exhibited self-renewal capabilities. Similar phenotypic plasticity was not observed in untreated Hs 578T and HMT-3522 S1 cells. BT-549 cells were more resistant to paclitaxel/PTX than to doxorubicin/DOX, a phenomenon potentially linked to the presence of CD24+ cells prior to treatment. Under the CSCs-enriched spheroids model, BT-549 demonstrated extreme resistance to DOX, likely due to the enrichment of BCSCs CD44+/CD24-/CD146- and the tumor cells CD44-/CD24-/CD146-. Additionally, DOX treatment induced the enrichment of plastic and chemoresistant cells, further exacerbating resistance mechanisms. BT-549 exhibited high heterogeneity, leading to significant alterations in cell subpopulations under BCSCs enrichment, demonstrating increased phenotypic plasticity during EMT. This phenomenon appears to play a major role in DOX resistance, as indicated by the presence of the refractory cells CD44+/CD24-/CD146- BCSCs EMT-like, CD44-/CD24-/CD146- tumor cells, and elevated STAT3 expression. Gene expression data from BT-549 CSCs-enriched spheroids suggests that ferroptosis may be occurring via autophagic regulation triggered by RAB7A, highlighting this gene as a potential therapeutic target.

A Strategy Involving Microporous Microneedles Integrated with CAR-TREM2-Macrophages for Scar Management by Regulating Fibrotic Microenvironment.

Dipeptidyl peptidase 4 (DPP4) positive fibroblasts play a pivotal role in scar development following skin injury. Heterogeneous vascular endothelial cells (ECs) within scarred areas retain the capacity to drive tissue regeneration and repair. Simultaneously, TREM2 macrophages play a crucial role in the progression and resolution of fibrosis by engaging in mutual regulation with ECs. However, effective strategies to inhibit scar formation through multi-factor regulation of the scar microenvironment remain a challenge. Here, CAR-TREM2-macrophages (CAR-TREM2-Ms) capable of targeting DPP4+ fibroblasts and modulating ECs subtype within the scar microenvironment are engineered to effectively prevent scarring. Hydrogel microporous microneedles (mMNs) are employed to deliver CAR-TREM2-Ms, which can effectively alleviate scar. Single-cell transcriptome sequencing (scRNA-seq) analysis reveals that CAR-TREM2-Ms can modify ECs fibrotic phenotype and regulate fibrosis by suppressing the profibrotic gene leucine-rich-alpha-2-glycoprotein 1 (Lrg1). In vitro experiments further demonstrate that CAR-TREM2-Ms improve the scar microenvironment by phagocytosing DPP4+ fibroblasts and suppressing TGFβ secretion. This, in turn, inhibits the phenotypic conversion of LRG1 ECs and provides multifactorial way of alleviating scars. This study uncovers the evidence that mMNs attached to CAR-TREM2-Ms may exert vital influences on skin scarring through the regulation of the skin scar microenvironment, providing a promising approach for treating posttraumatic scarring.

TAK1 Promotes an Immunosuppressive Tumor Microenvironment through Cancer-Associated Fibroblast Phenotypic Conversion in Pancreatic Ductal Adenocarcinoma.

We aim to clarify the precise function of TGFβ1-activated kinase 1 (TAK1) in cancer-associated fibroblasts (CAF) within human pancreatic ductal adenocarcinoma (PDAC) by investigating its role in cytokine-mediated signaling pathways. The expression of TAK1 in pancreatic cancer was confirmed by The Cancer Genome Atlas data and human pancreatic cancer specimens. CAFs from freshly resected PDAC specimens were cultured and used in a three-dimensional model for direct and indirect coculture with PDAC tumors to investigate TAK1 function. Additionally, organoids from [LSL-KrasG12D/+, LSL-Trp53R172H/+, Pdx1-Cre (KPC)] mice were mixed with CAFs and injected subcutaneously into C57BL/6 mice to explore in vivo functional interactions of TAK1. The Cancer Genome Atlas data revealed significant upregulation of TAK1 in PDAC, associating with a positive correlation with the T-cell exhaustion signature. Knockdown of TAK1 in CAFs decreased the inflammatory CAF signature and increased the myofibroblastic CAF signature both in vitro and in vivo. The absence of TAK1 hindered CAF proliferation, blocked several inflammatory factors via multiple pathways associated with immunosuppression, and hindered epithelial-mesenchymal transition and outgrowth in vitro in spheroid cocultures with PDAC cells. Additionally, TAK1 inhibitor restrained tumor growth, increased CD4+ and CD8+ T-cell abundance, and reduced immunosuppressive cells present in vivo. Blocking the TAK1+ CAF phenotype leads to the conversion of protumorigenic CAFs to antitumorigenic CAFs. This highlights TAK1 as a potential therapeutic target, particularly in CAFs, and represents a novel avenue for combined immunotherapy in PDAC.

Oral Piwi-Interacting RNA Delivery Mediated by Green Tea-Derived Exosome-Like Nanovesicles for the Treatment of Aortic Dissection.

Aortic dissection (AD) is a severe cardiovascular disease necessitating active therapeutic strategies for early intervention and prevention. Nucleic acid drugs, known for their potent molecule-targeting therapeutic properties, offer potential for genetic suppression of AD. Piwi-interacting RNAs, a class of small RNAs, hold promise for managing cardiovascular diseases. Limited research on these RNAs and AD exists. This study demonstrates that an antagomir targeting heart-apoptosis-associated piRNA (HAAPIR) effectively regulates vascular remodeling, mitigating AD occurrence and progression through the myocyte enhancer factor 2D (Mef2D) and matrix metallopeptidase 9 (MMP9) pathways. Green tea-derived plant exosome-like nanovesicles (PELNs) are used for oral administration of antagomir. The antagomir-HAAPIR-nanovesicle complex, after purification and optimization, exhibits a high packing rate, while the antagomir is resistant to enzyme digestion. Administered to mice, the complex targets the aortic lesion, reducing AD incidence and improving survival. Moreover, MMP9 and Mef2D expression decrease significantly, inhibiting the phenotypic conversion of human aortic smooth muscle cells. PELNs encapsulate the antagomir-HAAPIR complex, maintaining stability, mediating transport into the bloodstream, and delivering Piwi-interacting RNAs to AD sites. Thus, HAAPIR is a potential target for persistent clinical AD prevention and treatment, and nanovesicle-encapsulated nucleic acids offer a promising cardiovascular disease treatment, providing insights for other therapeutic targets.

Notch signaling suppresses neuroendocrine differentiation and alters the immune microenvironment in advanced prostate cancer.

Notch signaling can have either an oncogenic or tumor suppressive function in cancer depending on the cancer type and cellular context. While Notch can be oncogenic in early prostate cancer, we identified significant downregulation of the Notch pathway during prostate cancer progression from adenocarcinoma to neuroendocrine prostate cancer where it functions as a tumor suppressor. Activation of Notch in neuroendocrine and Rb1/Trp53-deficient prostate cancer models led to phenotypic conversion towards a more indolent non-neuroendocrine state with glandular features and expression of luminal lineage markers. This was accompanied by up-regulation of MHC and type I interferon and immune cell infiltration. Overall, these data support Notch signaling as a suppressor of neuroendocrine differentiation in advanced prostate cancer and provides insights into how Notch signaling influences lineage plasticity and the tumor microenvironment.