arxiv_ml 85% Match Research Paper Computational biologists,Bioinformaticians,Researchers in genomics and cell biology,Medical researchers 4 days ago

Querying functional and structural niches on spatial transcriptomics data

graph-neural-networks › graph-learning

📄 Abstract

Abstract: Cells in multicellular organisms coordinate to form functional and structural niches. With spatial transcriptomics enabling gene expression profiling in spatial contexts, it has been revealed that spatial niches serve as cohesive and recurrent units in physiological and pathological processes. These observations suggest universal tissue organization principles encoded by conserved niche patterns, and call for a query-based niche analytical paradigm beyond current computational tools. In this work, we defined the Niche Query Task, which is to identify similar niches across ST samples given a niche of interest (NOI). We further developed QueST, a specialized method for solving this task. QueST models each niche as a subgraph, uses contrastive learning to learn discriminative niche embeddings, and incorporates adversarial training to mitigate batch effects. In simulations and benchmark datasets, QueST outperformed existing methods repurposed for niche querying, accurately capturing niche structures in heterogeneous environments and demonstrating strong generalizability across diverse sequencing platforms. Applied to tertiary lymphoid structures in renal and lung cancers, QueST revealed functionally distinct niches associated with patient prognosis and uncovered conserved and divergent spatial architectures across cancer types. These results demonstrate that QueST enables systematic, quantitative profiling of spatial niches across samples, providing a powerful tool to dissect spatial tissue architecture in health and disease.

Authors (9)

Mo Chen

Minsheng Hao

Xinquan Liu

Lin Deng

Chen Li

Dongfang Wang

+3 more

Submitted

October 14, 2024

arXiv Category

q-bio.QM

arXiv PDF

Key Contributions

Introduces QueST, a specialized method for the Niche Query Task in spatial transcriptomics. QueST models niches as subgraphs, uses contrastive learning for discriminative embeddings, and incorporates adversarial training to mitigate batch effects, outperforming existing methods for niche querying.

Business Value

Enables deeper understanding of cellular organization and function in health and disease, potentially leading to new diagnostic markers, therapeutic targets, and drug development strategies.

Paper Metadata

Innovation Type

Algorithmic

Deployment Feasibility

Moderate - Requires specialized biological data and computational infrastructure.

Limitations Addressed

Lack of query-based analytical paradigms for cellular niches in spatial transcriptomics. Batch effects that can confound cross-sample comparisons. Limitations of existing computational tools for niche identification.

Performance Gains

QueST outperformed existing methods repurposed for niche querying.

Technical Tags

Spatial TranscriptomicsNiche IdentificationContrastive LearningGraph Representation LearningAdversarial TrainingBatch Effect MitigationSubgraphsDiscriminative EmbeddingsQuery-based AnalysisGene Expression Profiling

Research Topics

Computational BiologyBioinformaticsGraph Neural NetworksMachine Learning for GenomicsSpatial Omics

Methods & Architectures

QueSTContrastive LearningAdversarial TrainingGraph ModelingSubgraph Representation Graph Neural Network (implied)

Applications & Tasks

Biology Medicine Genomics Pathology Identifying similar cellular niches across spatial transcriptomics samplesMitigating batch effects in biological dataQuerying biological structures Developing a query-based paradigm for niche analysisLearning discriminative embeddings for cellular nichesAccurately capturing niche patterns across samples

Datasets & Benchmarks

Datasets

benchmark datasets

Accuracy of niche identificationPerformance against existing methods

Related Fields

BioinformaticsComputational BiologyMachine LearningGraph Neural NetworksGenomics

Keywords

Spatial TranscriptomicsCellular NichesGraph Neural NetworksContrastive LearningAdversarial TrainingBatch EffectsGene ExpressionBioinformaticsComputational BiologySubgraphEmbeddingsQueryingNiche Identification

Academic Context

#Computational Biology#Bioinformatics#Graph Neural Networks#Machine Learning for Genomics#Spatial Omics

Commercial Potential

Potential Products

Software for spatial omics data analysisTools for identifying disease-specific cellular niches

Target Industries

BiotechnologyPharmaceuticalsHealthcareResearch Institutions

Use Case Examples

Identifying tumor microenvironment nichesUnderstanding tissue development and regenerationDiscovering biomarkers for disease diagnosis and prognosis

Competitive Edge

Provides a novel, specialized method (QueST) for the Niche Query Task, outperforming repurposed existing methods by specifically addressing the problem using graph representations, contrastive learning, and adversarial training.

Market Opportunity

Growing market for spatial omics analysis tools.

Revenue Models

Software licensingcloud-based analysis services.

Resource Requirements

Compute Needs

High - Requires significant computational resources for processing large spatial transcriptomics datasets and training GNNs.

Data Requirements

Spatial transcriptomics data.

Deployment Constraints

Requires specialized expertise in bioinformatics and spatial omics data analysis.

Scalability

Scalability depends on the efficiency of the graph representation and learning methods used.

Production Readiness

Maturity Level

Research

Time to Market

2-4 years

Patent Potential

Moderate

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