Multicellular control of gene networks

TL;DR

This paper proposes that multicellular interaction networks regulate gene expression in bacteria, enabling robust control mechanisms and self-organization through a novel 'daisy chain' model that links multiple stages of cellular communities.

Contribution

It introduces the concept of multicellular daisy chains as a new model for gene regulation and self-organization in bacterial communities, expanding understanding beyond individual cell control.

Findings

Multicellular interactions influence gene network outputs.

Daisy chains enable reliable propagation of community states.

Multicellular self-organization offers new biological control mechanisms.

Abstract

Biological organisms are simple at heart: cells, their basic units, perform a variety of behaviors by expressing proteins from DNA-encoded genes. Gene expression though depends on sets of often-convoluted regulatory interactions known as gene networks, contributing to biology's apparent complexity. Even in Escherichia coli K-12, the pioneering model organism of molecular biology, gene networks are complicated and inconsistent with gene expression data. Recent discoveries of multicellular self-organization in E. coli suggest a new model for gene regulation that may help in many cases: control of gene networks by multicellular interaction networks, i.e. the changing physical and chemical interactions between cells in communities. E. coli's observed dynamics indicate multicellular interactions serve as inputs for key gene networks, thereby producing robust expression of otherwise noisy genes. In turn, multicellular interaction networks are dynamically generated as outputs of gene networks during self-organization. Thus, multicellular self-organization enables uniquely-biological control mechanisms that are not available to individual cells. As further suggested by E. coli self-organization, the gene-network outputs from one multicellular stage can be linked, via multicellular interaction networks, to serve as the gene-network inputs for later stages, thereby creating multicellular daisy chains. Daisy chains are a general model for reliably propagating multicellular communities and, therefore, for predictably determining the gene-network inputs of each cell throughout multicellular self-organization and development. Considerations for several fields are briefly discussed and suggest multicellular daisy chains are a general mechanism for biological organisms to control cell behavior and to be simpler than the sum of their parts.