A Bias-Corrected Weighted Logistic Model for Gene Regulatory Networks: Functional Equivalence with the Product-of-Logistics and Comparison with Weighted-Sum Formulations

Abstract

We introduce a bias-corrected weighted-logistic (bcw) formulation for ODE models of gene regulatory networks. Each gene's regulatory function is a single sigmoid σ(λSi+λbi) of the signed weighted regulator sum Si, with a combinatorial bias bi=-λ-1(2mi-1) depending only on the in-degree mi and the steepness λ. We prove this is the unique single-sigmoid correction recovering the critical-point value 1/2mi of the product-of-logistics model and sharing its canonical equilibrium xi*=κi/(γi 2mi) under self-consistency. The bcw system inherits global C∞ well-posedness, an explicit Lipschitz bound, a positively invariant box, and strictly positive basal output. We derive an exact algebraic identity for the discrepancy fprod-fbcw as a sum over proper non-empty regulator subsets; a slope ratio 2-21-mi at the critical point; a curvature mismatch breaking the symmetry σ''=0 for mi2; a no-go result excluding global equivalence by any state-independent constant; and a mean-field reading of the bias as a zero-order log-sum-exp approximation. At a shared equilibrium the Jacobians satisfy Jbcw=D(Jprod+Γ)-Γ with D=diag(2-21-mi), giving a stability dichotomy. In the contractive regime γi>κiλmi/4 both systems converge globally and exponentially to the shared equilibrium at rate α=i(γi-κiλmi/4). A two-gene self-activating negative-feedback motif illustrates the theory: the bcw form undergoes Hopf bifurcation at 2/3 of the product threshold and sustains limit cycles where the product is linearly stable, with eigenvalue amplification factor D=3/2.