Dysregulation Of Pathways Research Articles

Race and Sex Differences in Placental Lipid Metabolism are Associated with Spontaneous Early Preterm Birth.

Placental dysfunction is implicated in the pathogenesis of spontaneous preterm birth (SPTB). We investigated race (self-identified maternal race) and fetal sex differences in the placental metabolome and transcriptome associated with early SPTB (< 32weeks). Long-chain polyunsaturated fatty acids, acylcarnitines, acylglycerols, plasmalogens, and lysophospholipids were remarkably different between SPTB and Term placentas. These alterations were much more profound in Black than White SPTB placentas. Mode of delivery and BMI had no effect on these differences. The lipid metabolic pathways disrupted in early SPTB placentas also exhibited fetal sex differences, particularly between Black male and Black female placentas. Expression of genes involved in multiple lipid metabolism regulating pathways (e.g. PI3K/AKT signaling and phospholipase activity), especially eicosanoid synthesis and secretion, were significantly altered in early SPTB placentas. The race- and sex-specific changes in lipid metabolites and gene expression were consistent with inflammation in SPTB placentas, which was further supported by dysregulation of various inflammation and immune response pathways. These findings reveal race and fetal sex differences in lipid metabolism and inflammation in SPTB placentas and suggest greater dysfunction and inflammation in Black compared to White SPTB placentas, which may explain mechanisms underlying early SPTB and the risk of SPTB in different populations.

Dysregulation of N-terminal acetylation causes cardiac arrhythmia and cardiomyopathy

N-terminal acetyltransferases including NAA10 catalyze N-terminal acetylation, an evolutionarily conserved co- and post-translational modification. However, little is known about the role of N-terminal acetylation in cardiac homeostasis. To gain insight into cardiac-dependent NAA10 function, we studied a previously unidentified NAA10 variant p.(Arg4Ser) segregating with QT-prolongation, cardiomyopathy, and developmental delay in a large kindred. Here, we show that the NAA10R4S variant reduced enzymatic activity, decreased NAA10-NAA15 complex formation, and destabilized the enzymatic complex N-terminal acetyltransferase A. In NAA10R4S/Y-induced pluripotent stem-cell-derived cardiomyocytes (iPSC-CMs), dysregulation of the late sodium and slow delayed rectifier potassium currents caused severe repolarization abnormalities, consistent with clinical QT prolongation. Engineered heart tissues generated from NAA10R4S/Y-iPSC-CMs had significantly decreased contractile force and sarcomeric disorganization, consistent with the pedigree’s cardiomyopathic phenotype. Proteomic studies revealed dysregulation of metabolic pathways and cardiac structural proteins. We identified small molecule and genetic therapies that normalized the phenotype of NAA10R4S/Y-iPSC-CMs. Our study defines the roles of N-terminal acetylation in cardiac regulation and delineates mechanisms underlying QT prolongation, arrhythmia, and cardiomyopathy caused by NAA10 dysfunction.

Transcriptome-guided GLP-1 receptor therapy rescues metabolic and behavioral disruptions in a Bardet-Biedl Syndrome mouse model.

Bardet-Biedl Syndrome (BBS), a ciliopathy characterized by obesity, hyperphagia, and learning deficits, arises from mutations in BBS genes. More exacerbated symptoms occur with mutations in genes encoding the BBSome, a complex regulating primary cilia function. We investigated the mechanisms underlying BBS-induced obesity using a novel BBS5 knockout (BBS5-/-) mouse model. BBS5-/- mice displayed hyperphagia, learning deficits, glucose/insulin intolerance, and disrupted metabolic hormones, phenocopying human BBS. They displayed an unique immunophenotype in white adipose tissue with increased proinflammatory macrophages and dysfunctional regulatory T cells, suggesting a distinct mechanism for adiposity compared to typical obesity models. Additionally, BBS5-/- mice exhibited pancreatic islet hyperplasia but failed to normalize blood glucose, suggesting defective insulin action. Hypothalamic transcriptomics revealed dysregulated endocrine signaling pathways with functional analyses confirming defects in insulin, leptin, and cholecystokinin (CCK) signalling, while preserving glucagon-like peptide-1 receptor (GLP-1R) responsiveness. Notably, treatment with a GLP-1R agonist effectively alleviated hyperphagia, body weight gain, improved glucose tolerance, and circulating metabolic hormones in BBS5-/- mice. This study establishes BBS5-/- mice as a valuable translational model of BBS to understand the pathogenesis and develop novel treatments. Our findings highlight the therapeutic potential of GLP-1R agonists for managing BBS-associated metabolic dysregulation, warranting further investigation for clinical application.

Circumventing glioblastoma resistance to temozolomide through optimal drug combinations designed by systems pharmacology and machine learning.

Glioblastoma (GBM), the most frequent and aggressive brain tumour in adults, is associated with a dismal prognostic despite intensive treatment involving surgery, radiotherapy and temozolomide (TMZ)-based chemotherapy. The initial or acquired resistance of GBM to TMZ appeals for precision medicine approaches to the design of novel efficient combination pharmacotherapies. Such investigation needs to account for the overexpression of the O6-methylguanine-DNA methyl-transferase (MGMT) repair enzyme which is responsible for TMZ resistance in patients. A comprehensive approach combining quantitative systems pharmacology (QSP) models and machine learning (ML) was undertaken to design TMZ-based drug combinations circumventing the initial resistance to the alkylating agent. A QSP model representing TMZ cellular pharmacokinetics-pharmacodynamics and dysregulated pathways in GBM was developed and validated using multi-type time- and dose-resolved datasets, available in control or MGMT-overexpressing cells. In silico drug screening and subsequent experimental validation identified a strategy to re-sensitise TMZ-resistant cells consisting in combining TMZ with inhibitors of the base excision repair and of homologous recombination. Using ML, functional signatures of response to such optimal multi-agent therapy were derived to assist decision-making in patients. We successfully demonstrated the relevance of combined QSP and ML to design efficient drug combinations re-sensitising glioblastoma cells initially resistant to TMZ. The developed framework may further serve to identify personalised therapies and administration schedules by extending it to account for additional patient-specific altered pathways and whole-body features.

Blood Transcriptome Profiling Highlights the Role of Intestinal Bacterial Translocation in Severe COVID-19

COVID-19 has caused millions of deaths globally; however, the characterization of molecular biomarkers of severe disease remains of great scientific importance. The aim of this study was to capture the transcriptional differences of the whole blood gene expression between COVID-19 patients with mild and severe disease, using Next Generation Sequencing technologies, on admission and after 7 days. The genes which were differentially expressed in severe compared to mild patients were used for Gene Ontology (GO) enrichment analysis. Gene expression data were used to estimate the cell abundance of 22 immune cell types via digital cytometry. GO terms related to the response to molecules of bacterial origin, such as intestine-derived lipopolysaccharide (LPS), were enriched, among other dysregulated pathways, which are well described as paramount mechanisms of severe manifestations of COVID-19. The neutrophil population increased in patients with severe disease, whereas the monocyte, CD8+ T cell, and activated Natural Killer (NK) cell populations were depleted. These cell population dynamics are also indicative of severe COVID-19 and intestinal bacterial translocation. This study elucidates the molecular basis of severe COVID-19 and highlights intestinal bacterial translocation as a potential driver of severe disease.

Characterization of POP mixture redistribution and identification of their molecular signature in xenografted fat mice.

Characterization of POP mixture redistribution and identification of their molecular signature in xenografted fat mice.

Systems biology approach delineates critical pathways associated with papillary thyroid cancer: a multi-omics data analysis

BackgroundPapillary thyroid cancer (PTC) is the most prevalent follicular cell-derived subtype of thyroid cancer. A systems biology approach to PTC can elucidate the mechanism by which molecular components work and interact with one another to decipher a panoramic view of the pathophysiology.MethodologyPTC associated genes and transcriptomic data were retrieved from DisGeNET and Gene Expression Omnibus database respectively. Published proteomic and metabolomic datasets in PTC from EMBL-EBI were used. Gene Ontology and pathway analyses were performed with SNPs, differentially expressed genes (DEGs), proteins, and metabolites linked to PTC. The effect of a nucleotide substitution on a protein's function was investigated. Additionally, significant transcription factors (TFs) and kinases were identified. An integrated strategy was used to analyse the multi-omics data to determine the key deregulated pathways in PTC carcinogenesis.ResultsPathways linked to carbohydrate, protein, and lipid metabolism, along with the immune response, signaling, apoptosis, gene expression, epithelial–mesenchymal transition (EMT), and disease onset, were identified as significant for the clinical and functional aspects of PTC. Glyoxylate and dicarboxylate metabolism and citrate cycle were the most common pathways among the PTC omics datasets. Commonality analysis deciphered five TFs and fifty-seven kinases crucial for PTC genesis and progression. Core deregulated pathways, TFs, and kinases modulate critical biological processes like proliferation, angiogenesis, immune infiltration, invasion, autophagy, EMT, and metastasis in PTC.ConclusionIdentified dysregulated pathways, TFs and kinases are critical in PTC and may help in systems level understanding and device specific experiments, biomarkers, and drug targets for better management of PTC.

AhR Activation at the Air-Blood Barrier Alters Systemic microRNA Release After Inhalation of Particulate Matter Containing Environmentally Persistent Free Radicals.

Particulate matter containing environmentally persistent free radicals (EPFRs) is formed when organic pollutants are incompletely burned and adsorb to the surface of particles containing redox-active metals. Our prior studies showed that in mice, EPFR inhalation impaired vascular relaxation in a dose- and endothelium-dependent manner. We also observed that activation of the aryl hydrocarbon receptor (AhR) in the alveolar type-II (AT-II) cells that form the air-blood interface stimulates the release of systemic factors that promote endothelial dysfunction in vessels peripheral to the lung. AhR is a recognized regulator of microRNA (miRNA) biogenesis, and miRNA control diverse signaling pathways. We thus hypothesized that systemic EPFR-induced vascular endothelial dysfunction is initiated via AhR activation in AT-II cells, resulting in a systemic release of miRNA. Using a combustion reactor, we generated EPFR of two free radical concentrations-EPFRlo (1016-17 radicals/g particles) and EPFR (1018-19 radicals/g)-and exposed mice by inhalation. EFPR inhalation resulted in changes in a distinct array of miRNA in the plasma, and these miRNAs are linked to multiple systemic effects, including cardiovascular diseases and dysregulation of cellular and molecular pathways associated with cardiovascular dysfunction. We identified 17 miRNA in plasma that were altered dependent upon both AhR activation in AT-II cells and ~ 280ug/m3 EPFR exposure. Using Ingenuity Pathway Analysis, we found that 5 of these miRNAs have roles in modulating endothelin-1 and endothelial nitric oxide signaling, known regulators of endothelial function. Furthermore, EPFR exposure reduced the expression of lung adherens and gap junction proteins in control mice but not AT-II-AhR deficient mice, and reductions in barrier function may facilitate miRNA release from the lungs. In summary, our findings support that miRNA may be systemic mediators promoting endothelial dysfunction mediated via EPFR-induced AhR activation at the air-blood interface.

Deep sequencing reveals distinct microRNA-mRNA signatures that differentiate pancreatic neuroendocrine tumor from non-diseased pancreas tissue

BackgroundOnly a limited number of biomarkers guide personalized management of pancreatic neuroendocrine tumors (PanNETs). Transcriptome profiling of microRNA (miRs) and mRNA has shown value in segregating PanNETs and identifying patients more likely to respond to treatment. Because miRs are key regulators of mRNA expression, we sought to integrate expression data from both RNA species into miR-mRNA interaction networks to advance our understanding of PanNET biology.MethodsWe used deep miR/mRNA sequencing on six low-grade/high-risk, well-differentiated PanNETs compared with seven non-diseased tissues to identify differentially expressed miRs/mRNAs. Then we crossed a list of differentially expressed mRNAs with a list of in silico predicted mRNA targets of the most and least abundant miRs to generate high probability miR-mRNA interaction networks.ResultsGene ontology and pathway analyses revealed several miR-mRNA pairs implicated in cellular processes and pathways suggesting perturbed neuroendocrine function (miR-7 and Reg family genes), cell adhesion (miR-216 family and NLGN1, NCAM1, and CNTN1; miR-670 and the claudins, CLDN1 and CLDN2), and metabolic processes (miR-670 and BCAT1/MPST; miR-129 and CTH).ConclusionThese novel miR-mRNA interaction networks identified dysregulated pathways not observed when assessing mRNA alone and provide a foundation for further investigation of their utility as diagnostic and predictive biomarkers.

A trans-Translation Inhibitor is Potentiated by Zinc and Kills Mycobacterium tuberculosis and Nontuberculous Mycobacteria.

Mycobacterium tuberculosis poses a serious challenge for human health, and new antibiotics with novel targets are needed. Here we demonstrate that an acylaminooxadiazole, MBX-4132, specifically inhibits the trans-translation ribosome rescue pathway to kill M. tuberculosis. Our data demonstrate that MBX-4132 is bactericidal against multiple pathogenic mycobacterial species and kills M. tuberculosis in macrophages. We also show that acylaminooxadiazole activity is antagonized by iron but is potentiated by zinc. Our transcriptomic data reveal dysregulation of multiple metal homeostasis pathways after exposure to MBX-4132. Furthermore, we see differential expression of genes related to zinc sensing and efflux when trans-translation is inhibited. Taken together, these data suggest that there is a link between disturbing intracellular metal levels and acylaminooxadiazole-mediated inhibition of trans-translation. These findings provide an important proof-of-concept that trans-translation is a promising antitubercular drug target.

Interplay of Ferroptosis, Cuproptosis, Autophagy and Pyroptosis in Male Infertility: Molecular Crossroads and Therapeutic Opportunities

Male infertility is intricately linked to dysregulated cell death pathways, including ferroptosis, cuproptosis, pyroptosis, and autophagy. Ferroptosis, driven by iron-dependent lipid peroxidation through the Fenton reaction and inactivation of the GPX4/Nrf2/SLC7A11 axis, disrupts spermatogenesis under conditions of oxidative stress, environmental toxin exposure, or metabolic disorders. Similarly, cuproptosis—characterized by mitochondrial dysfunction and disulfide stress due to copper overload—exacerbates germ cell apoptosis via FDX1 activation and NADPH depletion. Pyroptosis, mediated by the NLRP3 inflammasome and gasdermin D, amplifies testicular inflammation and germ cell loss via IL-1β/IL-18 release, particularly in response to environmental insults. Autophagy maintains testicular homeostasis by clearing damaged organelles and proteins; however, its dysregulation impairs sperm maturation and compromises blood–testis barrier integrity. These pathways intersect through shared regulators; reactive oxygen species and mTOR modulate the autophagy–pyroptosis balance, while Nrf2 and FDX1 bridge ferroptosis–cuproptosis crosstalk. Therapeutic interventions targeting these mechanisms have shown promise in preclinical models. However, challenges persist, including the tissue-specific roles of gasdermin isoforms, off-target effects of pharmacological inhibitors, and transgenerational epigenetic impacts of environmental toxins. This review synthesizes current molecular insights into the cell death pathways implicated in male infertility, emphasizing their interplay and translational potential for restoring spermatogenic function.

Molecular mechanism of PANoptosis and programmed cell death in neurological diseases.

Molecular mechanism of PANoptosis and programmed cell death in neurological diseases.

Tet2 loss and enhanced ciliogenesis suppress α-synuclein pathology

There are no approved treatments that slow Parkinson’s disease (PD) progression and therefore it is important to identify novel pathogenic mechanisms that can be targeted. Loss of the epigenetic marker, Tet2 appears to have some beneficial effects in PD models, but the underlying mechanism of action is not well understood. We performed an unbiased transcriptomic analysis of cortical neurons isolated from patients with PD to identify dysregulated pathways and determine their potential contributions to the disease process. We discovered that genes associated with primary cilia, non-synaptic sensory and signaling organelles, are upregulated in both early and late stage PD patients. Enhancing ciliogenesis in primary cortical neurons via sonic hedgehog signaling suppressed the accumulation of α-synuclein pathology in vitro. Interestingly, deletion of Tet2 in mice also enhanced the expression of primary cilia and sonic hedgehog signaling genes and reduced the accumulation of α-synuclein pathology and dopamine neuron degeneration in vivo. Our findings demonstrate the crucial role of TET2 loss in regulating ciliogenesis and potentially affecting the progression of PD pathology.

In silico detection of dysregulated genes and molecular pathways in Alzheimer's disease as basis for food restoring approach.

Forty-eight million people worldwide suffer from dementia, often associated with the growth of the elderly population. There are also concerns about the younger population, where increasing acute and chronic abuse of alcohol and neurotoxic substances may contribute to brain damage and the early onset of dementia. Alzheimer's disease (AD) accounts for 60% of dementia cases and most therapies used so far have been unsuccessful. Genetic, epigenetic and vascular factors contribute to the pathogenesis of AD. Among the epigenetic mechanisms, modulation of microRNA (miRs) plays an important role. To detect genes and pathways involved in AD, we performed an original bioinformatic analysis of published Alzheimer's dysregulated miRs using MIcroRNA ENrichment TURned NETwork (MIENTURNET) followed by Reactome tools. The interrogation of these platforms allowed us to discover common putative genes (by MIENTURNET) targeted by the dysregulated miRs and the pathways in which the set of altered genes are involved (by Reactome tool). Our in silico analysis showed that the β-catenin phosphorylation cascade and Netrin-1 signalling, resulted as the most significant. Lastly, based on the assumption that food bioactive compounds (BC) modulate miRs, which in turn modulate dysregulated genes and pathways associated with AD, a literature search demonstrated that some BC are indeed able to modulate dysregulated pathways and genes. Curcumin, osthole, puerarin, xanthoceraside, sulforaphane, salvianolic acid A, resveratrol and andrographolide lead to upregulation of the Wnt/β-catenin pathway. Choline, methionine, folate and vitamin B6/B12 modulate the upregulation of the Netrin-1 pathway. In conclusion, our in silico analysis of miRs identified dysregulated genes and their associated pathways, paving interesting and new insights for diagnosis and for potential therapeutic interventions.

Single-cell RNA Sequencing Analysis of Sputum Cell Transcriptomes Reveals Pathways and Communication Networks That Contribute to the Pathogenesis of Asthma.

Asthma is driven by complex interactions amongst structural airway cells, cells of the immune system, and the environmental. While sputum cell characterization has been instrumental in studying asthma pathogenesis and refining treatment strategies, the nuances of cellular transcriptomes and intercellular communication in asthmatic sputum remain poorly understood. We employed single-cell RNA sequencing to analyze cells isolated form the sputum from 16 asthma patients and 8 non-asthmatic controls. Cell identities were established using curated marker genes and SingleR annotation. We compared cell-specific gene expression and communication networks between asthmatic and control groups, correlating findings with distinct pathways that were dysregulated in asthma. 37,565 cellular transcriptomes were captured and analyzed. 15 distinct cell populations were identified, including various macrophages, monocytes, dendritic cells, and lymphocytes, along with rare cell types such as mast cells, innate lymphoid cells, bronchial epithelial cells, and eosinophils. Intercellular communication analysis indicated heightened signaling activity in asthma compared to controls, particularly in CD4+ T cells and dendritic cells which exhibited the most significant increases in RNA expression of outgoing signaling molecules. Notably, the ADAM12-SDC4 and CCL22-CCR4 ligand-receptor pathways demonstrated the strongest shifts between asthma and control subjects, particularly between dendritic cells and CD4 lymphocytes. SC RNA seq profiling the asthma cellular transcriptome analysis of sputum highlights both innate and adaptive immune mechanisms that are significantly amplified in asthma. The elevated expression of ADAM12-SCD4 and CCL22-CC4 point to their critical role in asthma pathogenesis, suggesting potential avenues for targeted therapies and improved management of this chronic condition. Evidence Before This Study: Asthma is a chronic inflammatory disease of the airways driven by intricate interactions between airway structural and immune cells. Previous transcriptomic studies have focused on bulk RNA samples from the airway, leaving significant gaps in our understanding of the cellular dynamics that characterize the disease.Added Value of This Study: This study pioneers the use of single-cell RNA sequencing on sputum samples from patients with asthma, revealing a detailed landscape of cell phenotypes and dynamic communication patterns that distinguish asthmatic individuals from those without the disease. Notably, heightened intercellular communication was observed in asthma, particularly between CD4+ T cells and dendritic cells, confirming that there is a robust network of interactions between immune and structural cells. The notable increase of ADAM12-CCR4 communication from dendritic cells to other cell populations further emphasizes the dysregulation present in asthma.Implications of All Available Evidence: Our transcriptomic profiling illuminates distinct and amplified communication pathways involving CD4+ T cells and dendritic cells, aligning with established paradigms of both adaptive and innate immune responses in asthma pathogenesis. The identification of ADAM12 and CCR4 pathway dysregulation adds a critical layer to our understanding of the molecular mechanisms underpinning asthma, paving the way for potential therapeutic targets and personalized treatment strategies. Single cell profiling of the sputum has the capacity to characterize the breadth of cellular phenotypes, their functional status, and the communication in the airway at a level not previously attainable.

A human model to deconvolve genotype-phenotype causations in lung squamous cell carcinoma

Tractable, patient-relevant models are needed to investigate cancer progression and heterogeneity. Here, we report an alternative in vitro model of lung squamous cell carcinoma (LUSC) using primary human bronchial epithelial cells (hBECs) from three healthy donors. The co-operation of ubiquitous alterations (TP53 and CDKN2A loss) and components of commonly deregulated pathways including squamous differentiation (SOX2), PI3K signalling (PTEN) and the oxidative stress response (KEAP1) is investigated by generating hBECs harbouring cumulative alterations. Our analyses confirms that SOX2-overexpression initiates early preinvasive LUSC stages, and co-operation with the oxidative stress response and PI3K pathways to drive more aggressive phenotypes, with expansion of cells expressing LUSC biomarkers and invasive properties. This cooperation is consistent with the classical LUSC subtype. Importantly, we connect pathway dysregulation with gene expression changes associated with cell-intrinsic processes and immunomodulation. Our approach constitutes a powerful system to model LUSC and unravel genotype-phenotype causations of clinical relevance.

Sex and Genotype Affect Mouse Hippocampal Gene Expression in Response to Blast-Induced Traumatic Brain Injury.

Blast-induced traumatic brain injury (bTBI) has been identified as an increasingly prevalent cause of morbidity and mortality in both military and civilian populations over the past few decades. Functional outcomes following bTBI vary widely among individuals, and chronic neurodegenerative effects including cognitive impairments can develop without effective diagnosis and treatment. Genetic predispositions and sex differences may affect gene expression changes in response to bTBI and influence an individual's probability of sustaining long-term damage or exhibiting resilience and tissue repair. Male and female mice from eight genetically diverse and distinct strains (129S1/SvImJ, A/J, C57BL/6J, CAST/EiJ, NOD/ShiLtJ, NZO/HlLtJ, PWK/PhJ, WSB/EiJ) which encompassed 90% of the genetic variability in commercially available laboratory mice were exposed to a single bTBI (180kPa) using a well-established shock tube system. Subacute changes in hippocampal gene expression due to blast exposure were assessed using RNA-seq at 1-month post-injury. We identified patterns of dysregulation in gene ontology terms and canonical pathways related to mitochondrial function, ribosomal structure, synaptic plasticity, protein degradation, and intracellular signaling that varied by sex and/or strain, including significant changes in genes encoding respiratory complex I of the electron transport chain in male WSB/EiJ mice and the glutamatergic synapse across more than half of our groups. This study represents a multi-level examination of how genetic variability may influence response to bTBI and provides a foundation for the identification of potential therapeutic targets that could be modulated to improve the health of Veterans and others with histories of blast exposures.

Long term exposure to multiple environmental stressors induces mitochondrial dynamics imbalance in testis: Insights from metabolomics and transcriptomics.

Long term exposure to multiple environmental stressors induces mitochondrial dynamics imbalance in testis: Insights from metabolomics and transcriptomics.

Lactobacillus paracasei-derived extracellular vesicles reverse molecular and behavioral deficits in mouse models of autism spectrum disorder.

Autism spectrum disorder (ASD) is a heterogeneous group of neurodevelopmental disorders characterized by social communication deficits and repetitive behaviors. Although our current understanding the mechanisms underlying ASD is growing, effective treatment options are still underdevelopment. Extracellular vesicles derived from the probiotic Lactobacillus paracasei (LpEV) have shown neuroprotective effects in both in vitro and in vivo models. Here we investigate whether LpEV can alleviate core symptoms in genetic ASD models that exhibit accumulated developmental deficits. Dopamine receptor D2 (Drd2)-knockout (KO) mice exhibit social behavior deficits and excessive grooming, core symptoms of ASD. LpEV treatment significantly improves these autistic-like behaviors in Drd2-KO mice, suggesting that LpEVs can mitigate the persistent dysregulation of signaling pathways in these mice. RNA sequencing followed by Gene Ontology enrichment analysis of LpEV-treated Drd2-KO mice identifies distinct groups of genes altered in the brain of Drd2-KO mice, which were reversed by LpEV treatment. Notably, a high proportion of these genes overlap significantly with known ASD genes in the SFARI database, strengthening the potential of LpEV to target relevant pathways in ASD. Further investigation identifies oxytocin and oxytocin receptor (Oxtr) as potential therapeutic targets. LpEV treatment significantly improves autistic-like behaviors in Oxtr-KO heterozygous mice, adenylyl cyclase-5 KO mice and Shank3-KO mice, suggesting its therapeutic potential to target ASD through broader mechanisms beyond a single gene pathway. These results highlight the therapeutic potential of LpEV in reversing the accumulated dysregulated signaling pathways leading to ASD symptoms and improving autistic-like behaviors.

Gestational diabetes severity stratification during pregnancy: role of plasma oleic acid as a possible early marker.

Normal pregnancy is characterized by changes in lipid metabolism with significant implications for the health of both mother and offspring. When these changes develop into maternal dyslipidemia, a significant association with adverse pregnancy outcomes has been observed, including the development of gestational diabetes (GD), modulation of the inflammatory response, and excessive fetal growth. In the present study, we performed a lipidomic assessment of patients at GD diagnosis (24-28weeks of gestation) and 12weeks after diagnosis. We found higher levels of esterified oleic acid in plasma at the time of GD diagnosis in women who subsequently required pharmacological therapy to control blood glucose levels compared to those who did not require additional treatment, suggesting that the measurement of plasma oleic acid might be an additional tool for the early identification of patients with a more severe form of gestational diabetes. Moreover, plasma oleic acid levels showed a positive correlation with fetal growth in the context of adequate glycemic control, supporting a metabolic dysregulation of other pathways whose identification could help clinicians to discriminate different cases within the spectrum of severity of the disease. Finally, the correlation between plasma oleic acid and circulating BAFF levels at the time of diagnosis and 12weeks later adds a possible mechanism to support the pro-inflammatory and pro-diabetic state in the metabolic set of GD. Overall, these findings strongly support the role of plasma oleic acid as a possible early marker for GD severity stratification during pregnancy.