Microbial rhodopsins are photoreceptive membrane proteins that transport various ions using light energy. While they are widely used in optogenetics to optically control neuronal activity， rhodopsins that function with longer-wavelength light are highly demanded because of their low phototoxicity and high tissue penetration. Here， we achieve a 40-nm red-shift in the absorption wavelength of a sodium-pump rhodopsin (KR2) by altering dipole moment of residues around the retinal chromophore (KR2 P219T/S254A) without impairing its ion-transport activity. Structural differences in the chromophore of the red-shifted protein from that of the wildtype are observed by Fourier transform infrared spectroscopy. QM/MM models generated with an automated protocol show that the changes in the electrostatic interaction between protein and chromophore induced by the amino-acid replacements， lowered the energy gap between the ground and the first electronically excited state. Based on these insights， a natural sodium pump with red-shifted absorption is identified from Jannaschia seosinensis.