This manuscript presents the Microbial Enzymatic Cycle (MEC) as the core directional engine within the Microbial Integration Architecture Theory (MIAT), reframing physiology as an enzyme-governed ecological architecture rather than a cell- or gene-centered system. MEC integrates three interdependent microbial enzymatic systems—C1 metabolism, the acetate–acetyl-CoA cycle, and the nitrogen–amino acid cycle—into a unified operational framework that precedes and conditions cellular, tissue-level, and system-wide function across biological organisms. Within this model, physiological states emerge as directional outcomes—regenerative or degenerative—determined by microbial redox coherence and enzymatic continuity, rather than isolated molecular activation or genetic instruction. The manuscript further demonstrates how microbial enzymatic outputs converge within the extracellular matrix (ECM) and fascia network, translating biochemical activity into biophysical structure, signal distribution, and systemic coordination. This architectural integration provides mechanistic explanations for phenomena insufficiently addressed by existing SCFA-centric, immune-centric, neurotransmitter-based, or conventional systems biology models. Finally, the concept of biochemical directionality is formalized through the Green (regenerative) and Orange (degenerative) loops, situating emotional and neurophysiological regulation as measurable modulators of microbial redox coherence within the MEC framework. Together, MEC establishes a cross-organism biological principle that redefines physiology as an enzyme-driven, microbially governed architecture, with implications for regenerative biology, ecological physiology, and integrative systems research.
Henny Hendiyani Irjanti 0009-0003-1708-9646 (Sun,) studied this question.