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Human neural organoids (NOs) provide a powerful platform for investigating synaptic development and dysfunction during early neurodevelopment. However, methodologies for isolating functional synaptic structures from these models remain limited. Here, we present a differential centrifugation protocol enabling the enrichment of growth cone particles (GCPs) and immature synaptosomes from air‐liquid interface cerebral organoids (ALI‐COs) at distinct developmental stages (Day 90 and 150). Notably, the method avoids density gradients, requires minimal starting material while maintaining reproducibility across human and murine tissues. Quantitative proteomic profiling revealed significant enrichment of growth cone markers (e.g., GAP43) and classical synaptosomal proteins (e.g., PCLO, BSN, SYN1). Transmission electron microscopy (TEM) confirmed the presence of membrane‐enclosed GCPs with fibrous content and mitochondria in Day 90 isolates, and immature synaptosomes containing synaptic vesicles on day 150. Functional viability of both types of synaptic structures was demonstrated through KCl‐induced depolarization, which triggered phosphorylation changes in growth cone proteins (GAP43, MARCKS, MARCKSL1), cytoskeletal regulators (DCLK1, SHTN1, MARK4, MAP1B) and protein kinases (CAMK2G, PRKCE) in Day 90 GCPs, as well as classical synaptic vesicle cycle proteins (SYN1, DNM1, RPH3A) at Day 150. Overall, this study establishes a centrifugation‐based protocol for isolating growth cones and immature synapses from human organoids, capturing key stages of synaptic development and enabling scalable, patient‐compatible models to study synaptic function and dysfunction in neurodevelopmental and neurodegenerative disorders. Synapses are implicated in several neurological disorders and psychiatric diseases. The emergence and wide use of neural organoids provide a new opportunity to study human synapses in healthy and disease settings. Therefore, we developed a simple method for the enrichment of synaptosomes and growth cone particles from forebrain organoids. The method is based on differential centrifugation, works with small tissue amounts, and is highly reproducible. We validated the functionality of the isolated structures using KCl stimulation and phosphoproteomics. The method enables detailed mapping of protein composition and function during growth cone pathfinding, synaptogenesis, and establishment of neural circuits in organoids.

Background: The pathology of Alzheimer’s Disease (AD) is characterized by aggregates of amyloid beta (Aβ) peptides and neurofibrillary tau tangles. Increased blood-brain barrier (BBB) permeability and reduced Aβ clearance, which signal neurovascular dysfunction, have also been proposed as early markers of AD. Despite intense scrutiny, the mechanisms of AD remain elusive and novel treatments that address core symptoms of dementia are limited. New alternative methods (NAMs) aim to develop in-vitro translational models that recapitulate human pathology more accurately than previous models and could contribute to the development of new therapies. Methods: Here, we developed a NAM model of the cortical neurovascular unit (NVU) using brain cells derived from human induced pluripotent stem cells (hiPSCs) from a patient with AD and a healthy individual. Differentiated neurons, astrocytes, pericytes, microglia, and brain-like microvascular endothelial cells were cultured in a microphysiological system to create a brain-chip model to evaluate NVU-related endpoints. Results: Compared to control, AD brain-chips had reduced claudin-5 and ZO-1 expression and increased paracellular permeability. AD brain-chips also had decreased activity of the efflux transporter P-glycoprotein (P-gp), but its expression was unchanged. In AD brain-chips, levels of Aβ42, total tau, and p-tau 181 were decreased in protein lysates from the brain channel, while levels of total tau and p-tau 181 were increased in protein lysates from the vascular channel. Finally, AD brain-chips had increased levels of the proinflammatory markers IL-6 and MCP-1 in effluent from both brain and vascular channels. Conclusion: In this brain-chip model, we showed Aβ-independent NVU dysfunction that was related to neuroinflammation and vascular tau accumulation. This study demonstrates the utility of the brain-chip model to evaluate changes in NVU functions induced by AD-like pathology and highlights donor-specific responses associated with the use of hiPSC-derived models.

Human primordial germ cell-like cells (hPGCLCs) can be specified from human-induced pluripotent stem cells (hiPSCs), offering a valuable model for human germ cell development. However, further maturation steps of hPGCLCs rely on mouse feeders, or co-culture with mouse gonadal somatic cells. Exposure of hPGCLCs to human cellular niche has not been attempted. Here, we co-cultured female hPGCLCs in two distinct niche compartments. In reconstituted fetal ovary (rOv) culture, human fetal germ cells proliferated and initiated meiosis, while hPGCLCs upregulated gonadal germ cell markers such as DDX4. Additionally, hPGCLCs were supported and matured into migratory hPGCLCs in 3D co-culture with amnion-like cells (AMLCs). Compared to rOv, hPGCLCs in PGCLC/AMLC aggregates were less prone to dedifferentiate. In both niches, stem cell factor (SCF) was crucial for the survival of hPGCLCs. Together, this work underscores that a shift in niche is required for the further germ cell development of hPGCLCs. Graphical abstract Highlights•Reconstituted human fetal ovaries (rOvs) support meiosis entry of fetal germ cells•The rOvs support hPGCLCs to upregulate gonadal germ cell markers•hPGCLCs show less dedifferentiation in amnion-like cell aggregates compared to rOvs•SCF is not required for survival of fetal germ cells, but crucial for hPGCLCs Chuva de Sousa Lopes and colleagues used in vitro reconstituted human fetal ovaries (rOvs) as cellular niche to mature human primordial germ cell-like cells (hPGCLCs). hPGCLCs in rOvs matured but were prone to dedifferentiate. By contrast, hPGCLCs cultured with amnion-like cells were maintained without dedifferentiation and acquired migratory fate. In both systems, SCF was crucial for the survival of hPGCLCs.