This work systematically extends the full apparatus of meta-operational mathematics to the domain of genetic operations, establishing a new discipline: Gene Meta-Operational Mathematics. We define a hierarchical framework: Level 0 (elements of a base space of genetic states), Level 1 (genetic operations such as transcription, translation, replication, reverse transcription, methylation, demethylation, phosphorylation, dephosphorylation, splicing, CRISPR/Cas9, and their inverses), Level 2 (meta-operations acting on genetic operations), and higher levels. Ten axioms are formulated and shown to be relatively consistent and independent. The space GenOp(G) of smooth genetic operations is equipped with a bornology and proved to be bornologically complete. The category of meta-operations carries an endomorphism operad structure, which is further endowed with a Hopf operad structure; primitives in the operator Hopf algebra are classified as constant coefficient differential operators, while function Hopf algebra primitives are all continuous linear maps. Bornological convergence is introduced to handle infinite cascades of genetic feedback loops, with explicit criteria for convergence and collapse. We apply the framework to noncommutative gene geometry, constructing a spectral triple and proving stability under bornological limits. The path integral is reinterpreted as a trace on the operad, linking to topological quantum field theory and providing a rigorous description of epigenetic state evolution. All classical genetic operations and their inverses are shown to belong to the meta-operational universe, generated by exactly eight fundamental meta-operations (composition, pointwise addition, pointwise multiplication, differentiation, reflection, identity, constant-one, and transcription). We further study non-idempotent dynamics, weighted parameterized families, and collapse phenomena, establishing quantitative laws for collapse times. Categorical duality and superdomain extensions are integrated to capture fermionic degrees of freedom such as methylation switches. Numerical algorithms and error estimates are provided for synthetic biology applications. All open problems from earlier versions have been resolved and are now theorems; no open problems remain.
shifa liu (Wed,) studied this question.