Gram-positive bacteria use peptides as auto-inducing (AI) signals to regulate adaptive processes such as production of public goods (extracellular molecules that can be shared by the community). ComX is an AI peptide, mostly known for its role in the regulation of bacterial competence and surfactin production in Bacillus subtilis. These two traits are regulated accordingly to the bacterial population size, thus classifying ComX as a quorum sensing (QS) signal. We used this peptide-based AI system (the ComQXPA system), as a model to explore the links between cell-cell communication, exoprotease production and biofilm matrix production. The positive regulation of public goods (e.g. biofilm matrix components and exoproteases) by AI molecules in bacteria has been implied by several existing theories and experiments. In order to further corroborate these assumptions, we tested two hypotheses, predicting that the inactivation of the B. subtilis cell-cell communication system will have a negative impact on the production of exoproteases and biofilm matrix components. We also investigated the potential of ComX regulated proteases to degrade the ComX AI peptide. Obtained results confirmed that ComX plays an important role in exoprotease synthesis. Additionally, we confirmed that the ComX regulated exoproteases can degrade this signaling peptide. However, we also observed that the ComQXPA QS system slows down the overall production of biofilm matrix components and promotes sporulation. The floating biofilms of ComX deficient mutants produce more matrix components, more cells but less spores at an early stage of biofilm formation and exhibit a more synchronous induction into sporulation at the later stage. These results suggest that the ComQXPA QS system serves as a switch that down modulates investment into growth and biofilm formation and assures early investment into sporulation and aforementioned late growth adaptations.