A unique family of three-dimensional (3D) luminescent Sr-II-Re-V metal-organic frameworks (MOFs), {[Sr-II(MeOH)(5)][Re-V(CN)(4)(N)(bpen)(0.5)]center dot MeOH}(n) [1 center dot MeOH; N-3(-) = nitrido ligand, bpen = 1,2-bis(4-pyridyl)ethane, and MeOH = methanol], {[Sr-II(MeOH)(4)][Re-V(CN)(4)(N)(bpee)(0.5)]center dot 2MeOH}(n) [2 center dot MeOH; bpee = 1,2-bis(4-pyridyl) ethylene], and {[Sr-II(bpy)(0.5)(MeOH)(2)][Re-V(CN)(4)(N)(bpy)(0.5)]}(n) (3 center dot MeOH; bpy = 4,4'-bipyridine), is reported. They are obtained by the molecular self-assembly of Sr2+ ions with tetracyanidonitridorhenate(V) metalloligands, [Re-V(CN)(4)(N)](2-), and pyridine-based organic spacers (L = bpen, bpee, bpy). Such a combination of molecular precursors results in bimetallic SrII-ReV cyanido-bridged layers further bonded by organic ligands into pillared Hofmann-type coordination skeletons. Because of the formation of {Re-V-(L)-Re-V} moieties providing emissive metal-to-ligand charge-transfer states, 1 center dot MeOH-3 center dot MeOH exhibit solid-state room-temperature photoluminescence tunable from green to orange by the applied organic ligand. The most stable MOF of 3 center dot MeOH, based on the alternating {Re-V-(bpy)-Re-V} and {Sr-II-(bpy)-Sr-II} linkages, exhibits three interconvertible, variously solvated phases, methanolsolvated 3 center dot MeOH, hydrated {[Sr-II(bpy)(0.5)(H2O)(2)][Re-V(CN)(4)(N)(bpy)(0.5)]center dot 0.6H(2)O}(n) (3 center dot H2O), and desolvated {[Sr-II(bpy)(0.5)][Re-V(CN)(4)(N)(bpy)(0.5)]}(n) (3). Their formation was correlated with water and methanol vapor sorption properties investigated for 3 center dot H2O. The solvent content affects the luminescence mainly by tuning the emission energy within the series of 3 center dot MeOH, 3 center dot H2O, and 3. All of the obtained compounds exhibit temperature-driven modulation of luminescence, including the shift of the emission maximum and lifetime. The thermochromic luminescent response was found to be sensitive to the presence and type of solvent in the crystal lattice. This work shows that the construction of [ReV(CN)(4)(N)](2-)-based MOFs is an efficient route toward advanced solid luminophores tunable by external stimuli such as solvent or temperature.