G-quadruplexes (G4) are fascinating non-canonical DNA/RNA secondary structures that occur in genomic Guanine-rich regions. The over-representation of such structures in specific regions such as promoters of oncogenes and telomeres, suggests their involvement in key processes such as transcription, replication or RNA maturation. The development of in silico, in vitro and in cellulo tools for G4 prediction is emerging, reflecting the increasing relevance of these structures. Putative G4 forming sequences (PQS) have been reported in Homo sapiens, yeast, bacteria, viruses and many others. However, one of the problems in studying G4 structures in the human genome is indeed the high number of putative G4 forming sequences (370,000 PQS according to Quadparser and over 1 million when using a threshold of 1.5 with G4Hunter). It is therefore difficult to deconvolute G4-related biological effects in human cells. For this, we chose Dictyostelium discoideum - a G4 poor genome - as a eukaryotic model to complement the human studies. By an in silico analysis of dicty genome with G4Hunter a home-made algorithm, we detected 249 (threshold=2) to 1055 (threshold=1.5) G4-prone motifs. Interestingly, despite an even lower GC content in comparison to the whole dicty genome, the density of G4 motifs in dicty promoters is significantly higher than in the rest of the genome. By using a combination of different biophysical and biochemical methods, we demonstrated that 14 dicty sequences located in key genes fold into stable G4 structures. In addition, five dicty genes containing G4-prone motifs in their promoters were studied for the effect of a new Porphyrin derivative on their expression. Our results demonstrated that the new ligand decreased the expression of the several dicty genes significantly. Overall, our results constitute the first step to adopt Dictyostelium discoideum as a model for G4 studies.