In recent years, the selective role of ribosomes in the translational process of eukaryotes has been suggested. Evidence indicates that ribosomal heterogeneity at the level of protein stoichiometry and phosphorylation status differs among organisms, suggesting ribosomal specialization according to the state of development and the surrounding environment. During germination, protein synthesis is an active process that begins with the translation of the mRNAs stored in quiescent seeds and continues with the newly synthesized mRNAs. In this study, we identified differences in the abundance of ribosomal proteins (RPs) in maize embryos at different developmental stages. The relative quantification of RPs during germination revealed changes in six small subunit proteins, S3 (uS3), S5 (uS7), S7 (eS7), two isoforms of S17 (eS17), and S18 (uS13), and nine large subunit proteins, L1 (uL1), L5 (uL18), two isoforms of P0 (uL10), L11 (uL5), L14 (eL14), L15 (eL15), L19 (eL19), and L27 (eL27). Further analysis of ribosomal protein phosphorylation during germination revealed that the phosphorylation of PRP0 (uL10) and P1 increased and that of PRS3 (uS3) decreased in germinated versus quiescent embryos. The addition of insulin during germination increased the phosphorylation of the P1 protein, suggesting that its phosphorylation is controlled by the TOR pathway. Our results indicate that a heterogeneous ribosomal population provides to maize ribosomes during germination a different ability to translate mRNAs, suggesting another level of regulation by the ribosomes.