Examining FKBP5 mRNA expression in human iPSC-derived neural cells

Lieberman, Richard; Kranzler, Henry R.; Levine, Eric S.; Covault, Jonathan

doi:10.1016/j.psychres.2016.11.027

Cited by 21 publications

(34 citation statements)

References 59 publications

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“…Following 12 weeks of neural maturation, iPSC-derived cultures contained dense Beta III-tubulin positive neurites ( Figure 1G), MAP2-positive neurons with pyramidal morphology (Figure 1H-I), and GFAP-positive astrocytes (Figure 1I). These findings are consistent with our prior work demonstrating this protocol efficiently generates mixed neural cell cultures with ~50% TBR1positive glutamate neurons that have the ability to generate trains of action potentials, display spontaneous synaptic activity indicative of synapse formation, and express functional glutamatergic and GABAergic ionotropic receptors, with no difference in the ability of iPSCs from control or AUD donors to generate neural cultures 24,25 .…”

Section: Ipscs Differentiate Into Frontal Cortical-like Neural Culturessupporting

confidence: 91%

“…Following differentiation and plating onto matrigel-coated glass coverslips, neural cells were cultured and matured for 12 weeks prior to experimentation. Our prior work has demonstrated that 8-12 weeks of growth under this protocol generates neural cultures with functional electrophysiological properties as evidenced by mature action potentials, spontaneous synaptic activity, and expression of ligand-gated ionotropic receptors 24,25 . Neural cell markers were examined in differentiated iPSC lines 12 weeks after plating via immunostaining, as we have described.…”

Section: Neural Differentiation and Immunocytochemistrymentioning

confidence: 99%

“…Neural cell markers were examined in differentiated iPSC lines 12 weeks after plating via immunostaining, as we have described. 25 Cells were fixed in 4% paraformaldehyde, permeabilized using 0.2 % triton X-100 (Sigma-Aldrich), and blocked in 5% donkey serum (Jackson ImmunoResearch). The following primary antibodies were diluted in 5% donkey serum and incubated for 24-48 hours at 4° Celsius: mouse anti-beta III-tubulin (1:500, MAB1637, Millipore), mouse anti-GFAP (1:500, MAB360, Millipore), and rabbit anti-MAP2 (1:500, AB5622, Millipore).…”

Section: Neural Differentiation and Immunocytochemistrymentioning

confidence: 99%

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Alcohol-responsive genes identified in human iPSC-derived neural cultures

Jensen

Lieberman

Kranzler

et al. 2018

Preprint

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Alcohol use contributes to numerous diseases and injuries. The nervous system is affected by alcohol in diverse ways, though the molecular mechanisms of these effects are not clearly understood. Using human-induced pluripotent stem cells (iPSCs), we developed a neural cell culture model to identify the mechanisms of alcohol's effects. iPSCs were generated from fibroblasts and differentiated into forebrain neural cells cultures that were treated with 50 mM alcohol or sham conditions (same media lacking alcohol) for 7 days. We analyzed gene expression using total RNA sequencing (RNA-seq) for 34 samples derived from 11 subjects and for 10 samples from 5 subjects in an independent experiment that had intermittent exposure to the same dose of alcohol. We also analyzed genetic effects on gene expression and conducted a weighted correlation network analysis. We found that differentiated neural cell cultures have the capacity to recapitulate gene regulatory effects previously observed in specific primary neural tissues and identified 226 genes that were differentially expressed (FDR< 0.1) after alcohol treatment. The effects on expression included decreases in INSIG1 and LDLR, two genes involved in cholesterol homeostasis. We also identified a module of 58 co-expressed genes that were uniformly decreased following alcohol exposure. The majority of these effects were supported in the independent alcohol exposure experiment. Enrichment analysis linked the alcohol responsive genes to cell cycle, notch signaling, and cholesterol biosynthesis pathways, which are disrupted in several neurological disorders. Our findings suggest that there is convergence between these disorders and the effects of alcohol exposure.

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Section: Ipscs Differentiate Into Frontal Cortical-like Neural Culturessupporting

confidence: 91%

Section: Neural Differentiation and Immunocytochemistrymentioning

confidence: 99%

Section: Neural Differentiation and Immunocytochemistrymentioning

confidence: 99%

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Alcohol-responsive genes identified in human iPSC-derived neural cultures

Jensen

Lieberman

Kranzler

et al. 2018

Preprint

Self Cite

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“…In the human population, there is a wide variation in perception of stressful challenges, and variation in physiological expression of stress. Single nucleotide polymorphisms (SNPs) within the FKBP5 gene locus have been reported to impact stress responsivity, and risk or resilience to psychiatric disorders (Appel et al., 2011; Binder, 2009; Criado‐Marrero et al., 2019; Liebermann et al., 2017; Wilker et al., 2014). Differential expression levels of FKBP5 have preclinically been shown to impact on stress‐coping behavior and the SNP rs1360780 was reported to profoundly influence stress coping, suggesting FKBP5 genotypes as one source of human variation (Ising et al., 2008; Touma et al., 2011).…”

Section: Introductionmentioning

confidence: 99%

FKBP5 polymorphisms induce differential glucocorticoid responsiveness in primary CNS cells – First insights from novel humanized mice

Nold

Richter

Hengerer

et al. 2020

Eur J of Neuroscience

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The brain is a central hub for integration of internal and external conditions and, thus, a regulator of the stress response. Glucocorticoids are the essential communicators of this response. Aberrations in glucocorticoid signaling are a common symptom in patients with psychiatric disorders. The gene FKBP5 encodes a chaperone protein that functionally inhibits glucocorticoid signaling and, thus, contributes to the regulation of stress. In the context of childhood trauma, differential expression of FKBP5 has been found in psychiatric patients compared to controls. These variations in expression levels of FKBP5 were reported to be associated with differences in stress responsiveness in human carriers of the single nucleotide polymorphism (SNP) rs1360780. Understanding the mechanisms underlying FKBP5 polymorphism‐associated glucocorticoid responsiveness in the CNS will lead to a better understanding of stress regulation or associated pathology. To study these mechanisms, two novel humanized mouse lines were generated. The lines carried either the risk (A/T) allele or the resilient (C/G) allele of rs1360780. Primary cells from CNS (astrocytes, microglia, and neurons) were analyzed for their basal expression levels of FKBP5 and their responsiveness to glucocorticoids. Differential expression of FKBP5 was found for these cell types and negatively correlated with the cellular glucocorticoid responsiveness. Astrocytes revealed the strongest transcriptional response, followed by microglia and neurons. Furthermore, the risk allele (A/T) was associated with greater induction of FKBP5 than the resilience allele. Novel FKBP5‐humanized mice display differential glucocorticoid responsiveness due to a single intronic SNP. The vulnerability to stress signaling in the shape of glucocorticoids in the brain correlated with FKBP5 expression levels. The strong responsiveness of astrocytes to glucocorticoids implies astrocytes play a prominent role in the stress response, and in FKBP5‐related differences in glucocorticoid signaling. The novel humanized mouse lines will allow for further study of the role that FKBP5 SNPs have in risk and resilience to stress pathology.

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“…A series of papers has focused on iPSC-derived neurons in relation to alcohol dependence, FKBP5 regulation, and glucocorticoid activation ( 95 – 97 ). These cells express voltage-gated inward and outward currents, fire APs in response to current injection, respond to puff application of glutamate and GABA, and display spontaneous synaptic activity.…”

Section: Electrophysiological Analysis Of Ipsc-derived Neuronsmentioning

confidence: 99%

Uncovering True Cellular Phenotypes: Using Induced Pluripotent Stem Cell-Derived Neurons to Study Early Insults in Neurodevelopmental Disorders

Fink

Levine

2018

Front. Neurol.

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Animal models of neurodevelopmental disorders have provided invaluable insights into the molecular-, cellular-, and circuit-level defects associated with a plethora of genetic disruptions. In many cases, these deficits have been linked to changes in disease-relevant behaviors, but very few of these findings have been translated to treatments for human disease. This may be due to significant species differences and the difficulty in modeling disorders that involve deletion or duplication of multiple genes. The identification of primary underlying pathophysiology in these models is confounded by the accumulation of secondary disease phenotypes in the mature nervous system, as well as potential compensatory mechanisms. The discovery of induced pluripotent stem cell technology now provides a tool to accurately model complex genetic neurogenetic disorders. Using this technique, patient-specific cell lines can be generated and differentiated into specific subtypes of neurons that can be used to identify primary cellular and molecular phenotypes. It is clear that impairments in synaptic structure and function are a common pathophysiology across neurodevelopmental disorders, and electrophysiological analysis at the earliest stages of neuronal development is critical for identifying changes in activity and excitability that can contribute to synaptic dysfunction and identify targets for disease-modifying therapies.

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Examining FKBP5 mRNA expression in human iPSC-derived neural cells

Cited by 21 publications

References 59 publications

Alcohol-responsive genes identified in human iPSC-derived neural cultures

Alcohol-responsive genes identified in human iPSC-derived neural cultures

FKBP5 polymorphisms induce differential glucocorticoid responsiveness in primary CNS cells – First insights from novel humanized mice

Uncovering True Cellular Phenotypes: Using Induced Pluripotent Stem Cell-Derived Neurons to Study Early Insults in Neurodevelopmental Disorders

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