In thrusting and strike-slip situations, when the maximum principal horizontal stress S1 acts nearly normal to a fault (a misoriented fault, such as the San Andreas), pore-fluid pressure>the lithostatic load, Pf>S&ngr;, is required to reactivate movement on that fault. Pf>S&ngr; may be achieved without causing hydraulic tensile fracturing if (1) previously existing cracks have regained cohesive strength by chemical processes, (2) subcritical crack growth has been blunted, and (3) the least principal horizontal stress S3 nearly equals S&ngr;. Where Pf>S&ngr; has been attained within a misaligned fault, increasing the stress difference (S1-S3) at constant Pf>S&ngr; will not lead to shear failure, while a decrease in (S1-S3) can lead to shear failure of that fault. However, where the cohesive strength of material in a broad misaligned fault zone is less than that of the surrounding intact rock, increasing (S1-S3) while Pf>S&ngr; can result in shear failure of fractures at near optimum angles to S1, but confined within this weak fault zone. If this faulting results in the local short-lived attainment of Pf>S&ngr; (cataclastic deformation and frictional heating overcoming dilation) and a simultaneous decrease in (S1-S3), this combination of effects can trigger movement along the main trace of the misaligned fault. When increasing Pf results in hydraulic failure, anisotropy in tensile strength or fracture toughness resulting from foliation within faults allows fractures to propagate along the planes of weakness rather than across the foliation perpendicular to S3.