We propose the development of a new generation of an integrated ion source system for the production of very pure radioactive ion beams at low energy, including isomeric beams. This ion source is also, in its own right, an experimental tool for laser spectroscopy. The Rare Elements in-Gas Laser Ion Source and Spectroscopy device will be installed at the S3 spectrometer, currently under construction as part of the SPIRAL-2 facility at the GANIL laboratory in Caen. Thus, REGLIS3 will be a source for the production of new and pure radioactive ion beams at low energy as well as a spectroscopic tool to measure nuclear hyperfine interactions, giving access to charge radii, electromagnetic moments and nuclear spins of exotic nuclei so far not studied. It consists of a gas cell in which the heavy-ion beam coming from S3 will stopped and neutralized, coupled to a laser system that assures a selective re-ionisation of the atoms of interest. Ionization can be performed in the gas cell or in the gas jet streaming out of the cell. A radiofrequency quadrupole is added to capture the photo-ions and to guide them to the low-pressure zone thereby achieving good emittance of the produced low-energy beam that will be sent to a standard measurement station. Owing to the unique combination of such a device with the radioactive heavy ion beams from S3, a new realm of unknown isotopes at unusual isospin (N/Z ratio, refered to as exotic isotopes) will become accessible. The scientific goals focus on the study of ground-state properties of the N=Z nuclei up to the doubly-magic 100Sn and those of the very heavy and superheavy elements even beyond fermium. Once routine operation is achieved the beams will be used by a new users community as e.g. decay studies and mass measurements. The goal of the proposal is to develop this new, efficient, and universal source for pure, even isomeric, beams and for pioneering high-resolution laser spectroscopy that will overcome the present experimental constraints to study very exotic nuclei.