Dr. Manuel Schröter / Prof. Andreas Hierlemann

We are inviting applications for a 2-year postdoc position for a project at the intersection of human cellular modeling, large-scale electrophysiology, gene therapy and multi-modal data analysis. The candidate will work at the ETH Department of Biosystems Science and Engineering (BSSE) and closely collaborate with groups at the Roche Institute for Translational Bioengineering (ITB) and Roche Innovation Center (pRED). The preferred starting date is October 2022; the exact starting date can be negotiated. Project background: Human iPSC-derived cellular models are transforming our ability to probe the mechanisms and pathogenic drivers of neurodevelopmental diseases. As it is now possible to generate stem-cell-derived neural cells in a highly reproducible and scalable manner from any healthy/diseased individual, there are realistic prospects for progress in our understanding of the specific pathogenetic mechanisms underlying neurodevelopmental diseases and the development of personalized treatments. Job description: In this project, we will characterize 2D and 3D iPSC-derived human cellular models of Rett and dup15q syndrome using high-throughput large-scale extracellular electrophysiology, patch-clamping and single-cell genomic methods – and attempt phenotype rescues using pharmacological and gene-therapeutic interventions. The Postdoc will lead activities in a highly interdisciplinary project that aims at gaining mechanistic insights into neurodevelopmental disorders using a comprehensive multi-modal description of human iPSC-derived human cellular models in healthy and diseased states. The main activities and responsibilities will include: - generation and maintenance of in vitro human cellular models. - electrophysiological and optical functional characterization as well as analysis of the acquired data. - treatment interventions using pharmacological and genetic approaches. - guidance and supervision of practical work of other team members (PhD students).

Integration of 3D human stem cell models derived from post-mortem tissue and statistical genomics to guide schizophrenia therapeutic development

Schizophrenia is a neuropsychiatric disorder characterized by positive symptoms (such as hallucinations and delusions), negative symptoms (such as avolition and withdrawal) and cognitive dysfunction1. Schizophrenia is highly heritable, and genetic studies are playing a pivotal role in identifying potential biomarkers and causal disease mechanisms with the hope of informing new treatments. Genome-wide association studies (GWAS) identified nearly 270 loci with a high statistical association with schizophrenia risk; however each locus confers only a small increase in risk therefore it is difficult to translate these findings into understanding disease biology that can lead to treatments. Induced pluripotent stem cell (iPSC) models are a tractable system to translate genetic findings and interrogate mechanisms of pathogenesis. Mounting research with patient-derived iPSCs has proposed several neurodevelopmental pathways altered in SCZ, such as neural progenitor cell (NPC) proliferation, imbalanced differentiation of excitatory and inhibitory cortical neurons. However, it is unclear what exactly these iPS models recapitulate, how potential perturbations of early brain development translates into illness in adults and how iPS models that represent fetal stages can be utilized to further drug development efforts to treat adult illness. I will present the largest transcriptome analysis of post-mortem caudate nucleus in schizophrenia where we discovered that decreased presynaptic DRD2 autoregulation is the causal dopamine risk factor for schizophrenia (Benjamin et al, Nature Neuroscience 2022 https://doi.org/10.1038/s41593-022-01182-7). We developed stem cell models from a subset of the postmortem cohort to better understand the molecular underpinnings of human psychiatric disorders (Sawada et al, Stem Cell Research 2020). We established a method for the differentiation of iPS cells into ventral forebrain organoids and performed single cell RNAseq and cellular phenotyping. To our knowledge, this is the first study to evaluate iPSC models of SZ from the same individuals with postmortem tissue. Our study establishes that striatal neurons in the patients with SCZ carry abnormalities that originated during early brain development. Differentiation of inhibitory neurons is accelerated whereas excitatory neuronal development is delayed, implicating an excitation and inhibition (E-I) imbalance during early brain development in SCZ. We found a significant overlap of genes upregulated in the inhibitory neurons in SCZ organoids with upregulated genes in postmortem caudate tissues from patients with SCZ compared with control individuals, including the donors of our iPS cell cohort. Altogether, we demonstrate that ventral forebrain organoids derived from postmortem tissue of individuals with schizophrenia recapitulate perturbed striatal gene expression dynamics of the donors’ brains (Sawada et al, biorxiv 2022 https://doi.org/10.1101/2022.05.26.493589).

Reversing autism-related phenotypes in human brain organoids

Synaptic alterations in the striatum drive ASD-related behaviors in mice

Stem cell approaches to understand acquired and genetic epilepsies

The Hsieh lab focuses on the mechanisms that promote neural stem cell self-renewal and differentiation in embryonic and adult brain. Using mouse models, video-EEG monitoring, viral techniques, and imaging/electrophysiological approaches, we elucidated many of the key transcriptional/epigenetic regulators of adult neurogenesis and showed aberrant new neuron integration in adult rodent hippocampus contribute to circuit disruption and seizure development. Building on this work, I will present our recent studies describing how GABA-mediated Ca2+ activity regulates the production of aberrant adult-born granule cells. In a new direction of my laboratory, we are using human induced pluripotent stem cells and brain organoid models as approaches to understand brain development and disease. Mutations in one gene, Aristaless-related homeobox (ARX), are of considerable interest since they are known to cause a common spectrum of neurodevelopmental disorders including epilepsy, autism, and intellectual disability. We have generated cortical and subpallial organoids from patients with poly-alanine expansion mutations in ARX. To understand the nature of ARX mutations in the organoid system, we are currently performing cellular, molecular, and physiological analyses. I will present these data to gain a comprehensive picture of the effect of ARX mutations in brain development. Since we do not understand how human brain development is affected by ARX mutations that contribute to epilepsy, we believe these studies will allow us to understand the mechanism of pathogenesis of ARX mutations, which has the potential to impact the diagnosis and care of patients.

Modeling human neurodevelopment and evolution using brain organoids

Brain Organoids and Next-Generation Assembloid Models to Study Human Development and Disease

Rethinking neuroconstructivism through brain organoids at single cell resolution

A “breathing” brain model: Metabolic measurements in whole-brain organoids

FENS Forum 2024

Characterization of a new human co-culture model of endothelial cells, pericytes, and brain organoids in a microfluidic device

FENS Forum 2024

Characterization of ventral forebrain organoids derived from human induced pluripotent stem cells

FENS Forum 2024

Comprehensive functional profiling of human brain organoids

FENS Forum 2024

Elevated synaptic pruning in microglia across patient-derived brain organoids

FENS Forum 2024

High-throughput neural connectivity mapping in human brain organoids

FENS Forum 2024

Human microglia cells in Alzheimer disease-derived brain organoids: Can it be a good model?

FENS Forum 2024

An innovative approach for conducting 3D electrophysiological recordings within intact brain organoids

FENS Forum 2024

Investigating the development of the GABAergic system using human brain organoids

FENS Forum 2024

Microstructural characterization of brain organoids

FENS Forum 2024

Modelling MSA disease through the generation of brain organoids

FENS Forum 2024

Modelling regional specification in brain organoids using a novel mesofluidic device

FENS Forum 2024

Studying glioblastoma invasion in brain organoids

FENS Forum 2024

Toward a comprehensive in vitro model of the human visual system: Three-dimensional assembloids integrating retinal and brain organoids

FENS Forum 2024