Cortico-striatal projections are critical components of forebrain circuitry that regulate motivated behaviors. To enable the study of the human cortico-striatal pathway and how its dysfunction leads to neuropsychiatric disease, we developed a method to convert human pluripotent stem cells into region-specific brain organoids that resemble the developing human striatum and include electrically active medium spiny neurons. We then assembled these organoids with cerebral cortical organoids in three-dimensional cultures to form cortico-striatal assembloids. Using viral tracing and functional assays in intact or sliced assembloids, we show that cortical neurons send axonal projections into striatal organoids and form synaptic connections. Medium spiny neurons mature electrophysiologically following assembly and display calcium activity after optogenetic stimulation of cortical neurons. Moreover, we derive cortico-striatal assembloids from patients with a neurodevelopmental disorder caused by a deletion on chromosome 22q13.3 and capture disease-associated defects in calcium activity, showing that this approach will allow investigation of the development and functional assembly of cortico-striatal connectivity using patient-derived cells.
Extremely preterm born individuals at < 28 postconceptional weeks (PCW) are at high risk for encephalopathy of prematurity and life-long neuropsychiatric conditions. Clinical studies and animal models of preterm brain injury suggest that encephalopathy of prematurity is strongly associated with exposure to hypoxia and/or inflammation in the perinatal period. Histologic examination of postmortem brain tissue from children born preterm demonstrates decreased numbers of cortical GABA-ergic interneurons in the cerebral cortex. However, the cellular and molecular mechanisms underlying the decreased numbers of GABA-ergic interneurons in the cerebral cortex of extremely preterm individuals remain unclear. Here, we developed a dual, complementary human cellular model to study hypoxia-induced interneuronopathies using human forebrain assembloids (hFA) derived from human induced pluripotent stem cells (hiPSCs) and ex vivo human prenatal cerebral cortex at mid-gestation. The hFA are generated through the integration of region-specific neural organoids containing either dorsal forebrain (excitatory) glutamatergic neurons or ventral forebrain (inhibitory) GABA-ergic interneurons. We discover a substantial reduction in migration of cortical interneurons during exposure to hypoxic stress in both hFA and ex vivo human prenatal cerebral cortex. Next, we identify that this migration defect is restored by supplementation of hypoxic cell culture media with exogenous adrenomedullin (ADM), a peptide hormone member of the calcitonin gene related peptide (CGRP) family. Lastly, we demonstrate that the rescue is mediated through increased activity of the PKA molecular pathway and increased pCREB-dependent expression of GABA receptors. Overall, these findings provide important insights into the cellular mechanisms possibly contributing to cortical interneuron depletion in preterm infants, and pinpoint novel therapeutic molecular pathways with translational potential for hypoxic encephalopathy of prematurity.
Brain metastasis is a major cause of morbidity and mortality in cancer patients. Here we investigated mechanisms allowing small-cell lung cancer (SCLC) cells to grow in the brain. We show that SCLC cells undergo a cell state transition towards neuronal differentiation during tumor progression and metastasis, and that this neuronal mimicry is critical for SCLC growth in the brain. Mechanistically, SCLC cells re-activate astrocytes, which in turn promote SCLC growth by secreting neuronal pro-survival factors such as SERPINE1. We further identify Reelin, a molecule important in brain development, as a factor secreted by SCLC cells to recruit astrocytes to brain metastases in mice. This recruitment of astrocytes by SCLC was recapitulated in assembloids between SCLC aggregates and human cortical spheroids. Thus, SCLC brain metastases grow by co-opting mechanisms involved in reciprocal neuron-astrocyte interactions during development. Targeting such developmental programs activated in this cancer ecosystem may help treat brain metastases.
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