Co-existence atlas of cell types in mouse kidney.

Co-existence atlas of cell types in mouse kidney.

<div><p>Single-cell (SC) sequencing enables detailed characterization of transcriptional heterogeneity but lacks spatial context, while spatial transcriptomics (ST) preserves tissue organization yet is limited by resolution and incomplete gene capture. To bridge these gaps, we developed...

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Bibliographic Details
Main Author: Huamei Li (8815955) (author)
Other Authors: Jingchao Liu (2051245) (author), Guige Wang (22634210) (author), Zhenyu Liu (179092) (author), Meng Cao (105914) (author), Lingyun Sun (255929) (author), Cheng Peng (118834) (author), Yiyao Liu (554854) (author), Liang Ma (37793) (author), Qing Xiong (136442) (author)
Published: 2025
Subjects:
Cell Biology
Molecular Biology
Neuroscience
Biotechnology
Developmental Biology
Cancer
Plant Biology
Environmental Sciences not elsewhere classified
Biological Sciences not elsewhere classified
Information Systems not elsewhere classified
synthetic data demonstrated
reconstructing tissue architectures
minimizing assignment algorithm
method integrates information
improve signal fidelity
effectively delineating fine
10 &# 215
theoretic gene selection
incomplete gene capture
spatial transcriptomic spots
spatial hotspot detection
segments spatial spots
scale spatial patterns
lacks spatial context
handling unmatched datasets
balances transcriptional similarity
xlink "> single
maps single cells
results highlight cell2spatial
cell2spatial incorporates neural
gene complexity
spatial transcriptomics
spatial proximity
spatial organization
spatial coherence
transcriptional heterogeneity
developed cell2spatial
st datasets
visium hd
versatile framework
powerful tool
particular strength
mouse kidney
human thymus
guided clustering
fully matched
enhance scalability
developmental trajectories
computational framework
complex tissues
cellular function
cellular compositions
analytical scope
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Summary:<div><p>Single-cell (SC) sequencing enables detailed characterization of transcriptional heterogeneity but lacks spatial context, while spatial transcriptomics (ST) preserves tissue organization yet is limited by resolution and incomplete gene capture. To bridge these gaps, we developed Cell2Spatial, a computational framework that segments spatial spots at single-cell resolution, even when SC and ST datasets are not fully matched in cell types. The method integrates information-theoretic gene selection, spatially weighted likelihood modeling, and spatial hotspot detection to improve signal fidelity. A corrected saturation model calibrates library size against gene complexity, ensuring accurate cell count estimation in low-resolution ST. To enhance scalability and spatial coherence, Cell2Spatial incorporates neural-network-guided clustering and a cost-minimizing assignment algorithm that balances transcriptional similarity with spatial proximity. Evaluations on synthetic data demonstrated that Cell2Spatial consistently outperforms existing tools in reconstructing tissue architectures and cellular compositions, with particular strength in handling unmatched datasets. Applications to 10× Visium data across mouse brain, human thymus, mouse kidney, and human dorsolateral prefrontal cortex revealed detailed anatomical structures and developmental trajectories. Moreover, for high-resolution platforms including Xenium In Situ, Visium HD, and Slide-seqV2, Cell2Spatial remained robust despite reduced transcript capture, effectively delineating fine-scale spatial patterns in complex tissues. Collectively, these results highlight Cell2Spatial as a versatile framework that expands the analytical scope of ST and provides a powerful tool for uncovering the spatial organization of cellular function and tissue architecture.</p></div>

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