From Snapshots to Structure: A Novel Method for Reconstructing Directed Microbial Interaction Networks from Compositional Data

Microbial communities are shaped by complex ecological interactions that govern their structure, stability, and function. However, inferring these interactions from 16S rRNA gene sequencing data remains challenging due to data compositionality, limited temporal resolution, and the inability of traditional correlation-based methods to capture directionality or mechanistic influence. Microbial communities dynamically restructure in response to environmental and internal pressures, yet the ecological mechanisms guiding these transitions remain elusive. Here, we present a novel network inference framework that reconstructs directed, signed, and weighted microbial interaction networks from cross-sectional compositional data, without relying on predefined dynamic models or time-series sampling. By estimating asymmetric slopes and applying a perturbation-informed inference strategy, the method infers ecological interaction polarity and strength while accounting for compositional constraints. Applied to a synthetic gut microbiome dataset, the framework revealed taxon-specific trajectories, directional ecological dependencies, and hierarchically organized interaction networks. Persistent Directed Acyclic Graph (DAG) motifs identified keystone initiators, while other taxa emerged as resilient, high-connectivity hubs. A quadrant-based network visualization was introduced to enhance interpretability by distinguishing ecological influencers from responders based on interaction flow. The inferred networks demonstrated strong alignment between interaction polarity and abundance trends, revealing a robust ecological principle polarity-driven succession whereby the net balance of cooperative and antagonistic interactions predicts species abundance trajectories and community dynamics. This mechanistic insight advances microbial ecology by enabling predictive interpretations from cross-sectional datasets and broadening the theoretical understanding of microbial interaction networks. The approach supports scalable, hypothesis-driven analysis of microbial communities across environments and holds particular promise for guiding microbiome engineering, synthetic consortia design, and the retrospective analysis of public microbiome repositories.