Project description:Acute and delayed transcriptomics changes in 3D LUHMES exposed to rotenone

Project description:In current study, hMSCs were grown as 3D aggregates under wave motion to promote EV secretion (3D EVs). mRNA sequencing reveals global transcriptome alterations (e.g., upregulated Wnt, TNF, and Hippo signaling and downregulated cellular senescence) for 3D aggregates.

Project description:Alzheimer’s disease (AD), the leading cause of dementia, affects millions of people worldwide. With no disease-modifying medication currently available, the human toll and economic costs are rising rapidly. Under current standards, a patient is diagnosed with AD when both cognitive decline and pathology (amyloid plaques and neurofibrillary tangles) are present. Remarkably, some individuals who have AD pathology remain cognitively normal. Uncovering factors that lead to “cognitive resilience” to AD is a promising path to create new targets for therapies. However, technical challenges discovering novel human resilience factors limit testing, validation, and nomination of novel drugs for AD. In this study, we use single-nucleus transcriptional profiles of postmortem cortex from human individuals with high AD pathology who were either cognitively normal (resilient) or cognitively impaired (susceptible) at time of death, as well as mouse strains that parallel these differences in cognition with high amyloid load. Our cross-species discovery approach highlights a novel role for excitatory layer 4/5 cortical neurons in promoting cognitive resilience to AD, and nominates several resilience genes that include ATP1A1, GRIA3, KCNMA1, and STXBP1. This putative cell type has been implicated in resilience in previous studies on bulk RNA-seq tissue, but our single-nucleus and cross-species approach identifies particular resilience-associated gene signatures in these cells. These novel resilience candidate genes were tested for replication in orthogonal data sets and confirmed to be correlated with cognitive resilience. Based on these gene signatures, we identified several potential mechanisms of resilience, including regulation of synaptic plasticity, axonal and dendritic development, and neurite vesicle transport along microtubules that are potentially targetable by available therapeutics. Because our discovery of resilience-associated genes in layer 4/5 cortical neurons originates from an integrated human and mouse transcriptomic space from susceptible and resilient individuals, we are positioned to test causality and perform mechanistic, validation, and pre-clinical studies in our human-relevant AD-BXD mouse panel.

Project description:The susceptibility to chronic social isolation (CSIS) is associated with development of major depression (MD). Recent studies relate MD with altered expression of synaptic proteins in specific brain regions, whereby some individuals exposed to the stressors are resistant to the stress. To explore the neurobiological underpinnings and identify candidate biomarkers for MD, a comparative proteomic approach was used to map hippocampal synaptic protein alterations of rats exposed to 6 weeks of CSIS, an animal model of depression. This model generates two stress-response phenotypes, reflecting CSIS-sensitive (depressive-like behaviour) and CSIS-resilience, assessed by sucrose preference test. Our aim was to characterize the synaptoproteome changes representative of potential long-term changes in protein expression underlying susceptibility or resilience to stress.

Project description:Isodyctia sequencing, testing resilience to heat shock

Project description:Adult male Sprague Dawley rats (5 month-old at the beginning of the study) were subcutaneously exposed to 0.5 mg.kg/d rotenone or the corresponding solvent (PEG/DMSO, 1/1) for 28 days. At the end of the experiment, animals were sacrificed by decapitation and brains were rapidly taken out within 30-40 s. Total RNA was prepared from laser-capture microdissected rat substantia nigra pars compacta (Snpc). Changes in transcript abundance within SNpc were analyzed on samples from solvent and rotenone-exposed groups (n = 3 per group) using CodeLink™ Rat Whole Genome bioarrays containing 34,000 transcripts and EST probes (GE Healthcare, Amersham, Saclay, France). Two groups of rats were exposed either to rotenone (CR rats) or to solvents (CS rats) in order to analyse pesticides impact on gene expression.

Project description:Tridimensional cardiac differentiation from hiPSCs has been largely described in the literature. However, the exact impact that 3D culture has throughout the entire process of cardiac differentiation remains poorly defined. We developed a robust and efficient 3D platform for cardiomyocyte differentiation from hiPSCs, based on the temporal modulation of WNT signalling using small molecules. 3D aggregates of hiPSCs were generated by forced aggregation in microwells and subsequently differentiated. In order to determine the differences in gene expression profile due to 3D culture throughout the different stages of cardiac differentiation, we compared transcriptional changes between cells in 3D aggregates and standard 2D monolayer cardiac differentiation. Analysis of these data suggests a faster commitment of hiPSCs toward the cardiac lineage and also higher degree of cardiomyocyte functional maturation after 20 days of culture in the 3D aggregates when compared with the 2D monolayer.

Project description:Human bone marrow mesenchymal stromal cells (MSCs) are conventionally cultured as adherent monolayers on tissue culture plastic. MSCs can also be cultured as 3D cell aggregates (spheroids). Optimised 3D conditions (60,000 MSCs cultured as a spheroid for 5 days) inhibited MSC proliferation and induced cell shrinkage in the absence of cell death. Primary human MSCs isolated from 2 donors were cultured under both monolayer (2D MSCs) and optimised 3D (3D MSCs) conditions. High quality RNA was isolated from all samples, and global gene expression analysis was performed in duplicate (using Agilent SurePrint G3 Human Gene Expression 8x60K v2 Microarrays) to identify gene expression changes in 3D compared to 2D MSC cultures.

Project description:Extracellular vesicles (EVs) contain proteins, enzymes and metabolites that contribute to the therapeutic potential of human mesenchymal stem cells (hMSCs). However, scale-up production of hMSC EVs has become a major challenge. In current study, hMSCs were grown as 3D aggregates under wave motion to promote EV secretion (3D EVs). mRNA sequencing reveals global transcriptome alterations (e.g., upregulated Wnt, TNF, and Hippo signaling and downregulated cellular senescence) for 3D aggregates. Compared to 2D EVs, the quantity of 3D EVs was enhanced significantly with smaller size, higher miR-21 and miR-22 expression, and the altered protein cargo revealed by proteomics. 3D hMSC aggregates promote activation of the endosomal sorting complexes required for transport (ESCRT) pathway and ESCRT-independent pathway. In addition, 3D EVs rejuvenated stem cells expressing cellular senescence and modulated immune response determined by T lymphocyte and macrophage phenotype assays. In summary, this study provides a promising strategy for high-quality EV production from hMSCs with enhanced therapeutic potentials.

Project description:The pesticide rotenone, a neurotoxin that inhibits the mitochondrial complex I, and destabilizes microtubules (MT) has been linked to Parkinson disease (PD) etiology and is often used to model this neurodegenerative disease (ND). Many of the mechanisms of action of rotenone are posited mechanisms of neurodegeneration; however, they are not fully understood. Therefore, the study of rotenone-affected functional pathways is pertinent to the understanding of NDs pathogenesis. This report describes the transcriptome analysis of a neuroblastoma (NB) cell line chronically exposed to marginally toxic and moderately toxic doses of rotenone. The results revealed a complex pleiotropic response to rotenone that impacts a variety of cellular events, including cell cycle, DNA damage response, proliferation, differentiation, senescence and cell death, which could lead to survival or neurodegeneration depending on the dose and time of exposure and cell phenotype. The response encompasses an array of physiological pathways, modulated by transcriptional and epigenetic regulatory networks, likely activated by homeostatic alterations. Pathways that incorporate the contribution of MT destabilization to rotenone toxicity are suggested to explain complex I-independent rotenone-induced alterations of metabolism and redox homeostasis. The postulated mechanisms involve the blockage of mitochondrial voltage-dependent anions channels (VDACs) by tubulin, which coupled with other rotenone-induced organelle dysfunctions may underlie many presumed neurodegeneration mechanisms associated with pathophysiological aspects of various NDs including PD, AD and their variant forms. Thus, further investigation of such pathways may help identify novel therapeutic paths for these NDs.