Calibration-aware genomic prediction of paratuberculosis serostatus in indigenous Turkish goats.
Journal:
Scientific reports
Published Date:
Jul 16, 2026
Abstract
Paratuberculosis, caused by Mycobacterium avium subsp. paratuberculosis (MAP), is a chronic, incurable enteritis of ruminants in which late-onset clinical signs preclude timely intervention, making early genomic stratification a key control lever. We investigated the genetic architecture underlying the host antibody response to MAP - measured as anti-MAP ELISA serostatus - using genome-wide SNP data from 474 animals representing seven indigenous Turkish goat breeds sampled across 11 provinces (237 seropositive, 237 seronegative; estimated true seroprevalence 14.1%). Fourteen architecturally diverse machine learning frameworks - encompassing regularized regression, GBLUP, kernel machines, tree ensembles, deep neural networks, and a meta-ensemble - were evaluated under repeated stratified cross-validation using both discriminative and calibration metrics. Mutual information-based preselection served a dual function: reducing computational dimensionality while prioritizing markers with detectable phenotypic association. Six regularized and kernel-based models converged at a statistically indistinguishable discrimination ceiling (mean AUC ≈ 0.982; range 0.002), a convergence pattern consistent with an additive component captured by the available SNP data. Critically, whereas ROC-AUC varied only 1.14-fold across all models, Brier score varied 4.85-fold (0.046-0.223), with tree ensembles exhibiting systematic miscalibration despite competitive discrimination - indicating that predicted probabilities vary substantially across model architectures and cannot be reduced to discrimination metrics alone when informing breeding or biosecurity decisions. Post-hoc offset recalibration across realistic field seroprevalence conditions preserved tier-level performance rankings across the tested prevalence scenarios. These findings indicate that genome-wide SNP variation encodes sufficient signal to support accurate and calibrated classification of anti-MAP ELISA serostatus in indigenous goat populations, and provide a calibration-aware framework potentially extensible to other complex disease traits in livestock.
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