Modeling glioblastoma invasion using human brain organoids and single-cell transcriptomics

Krieger, Teresa G; Tirier, Stephan M.; Park, Jeongbin; Eisemann, Tanja; Peterziel, Heike; Angel, Peter; Eils, Roland; Conrad, Christian

doi:10.1101/630202

Cited by 12 publications

(27 citation statements)

References 39 publications

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“…Human organoids are also being developed to model glioblastoma, so invasion can be studied and how tumorigenesis relates to the extracellular matrix can be understood ( Silvia and Dai, 2020 ). Tumor cells within organoids extend a network of long microtubes, recapitulating the in vivo behavior of GBM ( Krieger et al, 2020 ). The transcriptional changes implicated in the invasion process are coherent across patient samples, indicating that GBM cells reactively upregulate genes required for their dispersion.…”

Section: Neural Cell Lineages Derived From Ips Cellsmentioning

confidence: 99%

Cell Calcium Imaging as a Reliable Method to Study Neuron–Glial Circuits

2020

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Complex dynamic cellular networks have been studied in physiological and pathological processes under the light of single-cell calcium imaging (SCCI), a method that correlates functional data based on calcium shifts operated by different intracellular and extracellular mechanisms integrated with their cell phenotypes. From the classic synaptic structure to tripartite astrocytic model or the recent quadripartite microglia added ensemble, as well as other physiological tissues, it is possible to follow how cells signal spatiotemporally to cellular patterns. This methodology has been used broadly due to the universal properties of calcium as a second messenger. In general, at least two types of receptor operate through calcium permeation: a fast-acting ionotropic receptor channel and a slow-activating metabotropic receptor, added to exchangers/transporters/pumps and intracellular Ca 2+ release activated by messengers. These prototypes have gained an enormous amount of information in dynamic signaling circuits. SCCI has also been used as a method to associate phenotypic markers during development and stage transitions in progenitors, stem, vascular cells, neuro- and glioblasts, neurons, astrocytes, oligodendrocytes, and microglia that operate through ion channels, transporters, and receptors. Also, cancer cells or inducible cell lines from human organoids characterized by transition stages are currently being used to model diseases or reconfigure healthy cells in terms of the expression of calcium-binding/permeable molecules and shed light on therapy.

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Section: Neural Cell Lineages Derived From Ips Cellsmentioning

confidence: 99%

Cell Calcium Imaging as a Reliable Method to Study Neuron–Glial Circuits

2020

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“…Microfluidic organotypic cultures will not be included in this review. To the best of our knowledge, only six articles have been published on this topic (Nayernia et al, 2013;Ogawa et al, 2018;Bian et al, 2018aBian et al, , 2018bPlummer et al, 2019;Linkous et al, 2019;Krieger et al, 2020). cell culture approach went largely unnoticed and unrecognized-until this publication, it received only 15 citations.…”

Section: Introductionmentioning

confidence: 99%

“…The majority of human stem cell organotypic cultures used to generate GB-3DBrain models are the socalled cerebral organoids (Lancaster et al, 2013), either by using the exact protocol (Bian et al, 2018a;Ogawa et al, 2018) or by adding minor adaptations (Krieger et al, 2020;Linkous et al, 2019). The exception were Nayemia and collaborators, who used a different type of organotypic culture (the neural organoid) (Nayernia et al, 2013), and Plummer and collaborators, who utilized a model called BrainSpheres (Plummer et al, 2019) (Figure 1).…”

Section: Introductionmentioning

confidence: 99%

“…GB cells (directly from biopsies or patient-derived glioma cells) are added into the 3D structures. This primarily utilizes gravity approaches (Linkous et al, 2019;Krieger et al, 2020;Nayernia et al, 2013;Ogawa et al, 2018), allowing GB to attach cells to the surface of the organoid (Table 1). This could initially be viewed as an unfavorable approach, because contact between the GB with microenvironment cells will not be ideal.…”

Section: Introducing Glioblastoma Cells Into 3d Modelsmentioning

confidence: 99%

“…This could initially be viewed as an unfavorable approach, because contact between the GB with microenvironment cells will not be ideal. However, Krieger and collaborators, by using a combination of live stained (or fixed) cerebral organoids embedded in Matrigel, together with clearing tissue technique and confocal imaging, were able to show tumor invasion after only 2 days of culture (Krieger et al, 2020). Tumoral cells added to the surface of the cerebral organoids were able to invade deeply into the tissue, exceeding 100 mm in the majority of organoids, with some cells detected at 300 mm from the organoid surface.…”

Section: Introducing Glioblastoma Cells Into 3d Modelsmentioning

confidence: 99%

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Organotypic Models to Study Human Glioblastoma: Studying the Beast in Its Ecosystem

2020

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Glioblastoma is a very aggressive primary brain tumor in adults, with very low survival rates and no curative treatments. The high failure rate of drug development for this cancer is linked to the high-cost, time-consuming, and inefficient models used to study the disease. Advances in stem cell and in vitro cultures technologies are promising, however, and here we present the advantages and limitations of available organotypic culture models and discuss their possible applications for studying glioblastoma.

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Single‐cell profiling for advancing birth defects research and prevention

Knudsen

Spielmann

Megason

et al. 2021

Birth Defects Research

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Cellular analysis of developmental processes and toxicities has traditionally entailed bulk methods (e.g., transcriptomics) that lack single cell resolution or tissue localization methods (e.g., immunostaining) that allow only a few genes to be monitored in each experiment. Recent technological advances have enabled interrogation of genomic function at the single-cell level, providing new opportunities to unravel developmental pathways and processes with unprecedented resolution. Here, we review emerging technologies of singlecell RNA-sequencing (scRNA-seq) to globally characterize the gene expression sets of different cell types and how different cell types emerge from earlier cell states in development. Cell atlases of experimental embryology and human embryogenesis at single-cell resolution will provide an encyclopedia of genes that define key stages from gastrulation to organogenesis. This technology, combined with computational models to discover key organizational principles, was recognized by Science magazine as the "Breakthrough of the year" for 2018 due to transformative potential on the way we study how human cells mature over a lifetime, how tissues regenerate, and how cells change in diseases (e.g., patient-derived organoids to screen disease-specific targets and design precision therapy). Profiling transcriptomes at the single-cell level can fulfill the need for greater detail in the molecular progression of all cell lineages, from pluripotency to adulthood and how cell-cell signaling pathways control progression at every step. Translational opportunities emerge for elucidating pathogenesis of genetic birth defects with cellular precision and improvements for predictive toxicology of chemical teratogenesis.

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Modeling glioblastoma invasion using human brain organoids and single-cell transcriptomics

Cited by 12 publications

References 39 publications

Cell Calcium Imaging as a Reliable Method to Study Neuron–Glial Circuits

Cell Calcium Imaging as a Reliable Method to Study Neuron–Glial Circuits

Organotypic Models to Study Human Glioblastoma: Studying the Beast in Its Ecosystem

Single‐cell profiling for advancing birth defects research and prevention

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