HmBRI-D94N is a light-driven proton pump, which is functioned by a series of conformational changes of the retinal inside the protein under light illumination. Conjugated polymers are potential candidates for biological interfacing because they have structural and transport properties that are intermediate to those of the two extremes: soft biological systems and hard inorganic electronics. In this research, fabrication of dual-gate organic field-effect transistors (DG-OFETs) by integrating HmBRI-D94N with conjugated polymers, i.e. P3HT, PDPPT2, PffBT4T, PNDIT2, respectively, is attempted. Conventional n-doped silicon is chosen as the bottom gate, while light serves as the pseudo top gate to modulate the conformation of HmBRI-D94N locating on top of the polymer charge-transporting layer. As a result, HmBRI-D94N shows a marginal effect on the photosensitivity of n-type material devices. However, the photosensitivity of p-type material devices containing HmBRI-D94N is evident, especially under green-light illumination. It is envisaged that HmBRI-D94N functions as a dielectric layer between light and semiconducting layer. Subsequent to the light absorption, the conformational change of HmBRI-D94N would result in the variation in the interfacial dipole between HmBRI-D94N and a p-type polymer, resulting in the threshold-voltage shift and the apparent photosensitivity. DG-OFETs can thus be realized.