The vegetative development of plants results from the rate of leaf emergence (RLE), internode elongation and branching. Assuming that these processes are under genetic control and affected by environmental conditions such as temperature and soil water content, this study aimed at modelling them in the case of 1 year old apple tree. Previous studies have suggested that RLE modulates sylleptic branching since the number of sylleptic branches is often higher when the RLE is high during the season. We thus proposed to model the influence of RLE on sylleptic branching assuming that the plasticity of sylleptic branching results from that in RLE. These three processes, i.e. RLE, sylleptic branching and internode elongation are included in MAppleT, a functional-structural plant model (FPSM) for apple tree, to simulate its development. Experimental data were collected on one year-old trees corresponding to a progeny issued from 'Starkrimson' × 'Granny Smith' cross (116 genotypes), with four replicates per genotype submitted to water stress or optimal irrigation. The number of newly emitted metamers was counted every week whereas the mean length of internodes and the number and position of sylleptic axes were assessed at the end of the growth season. Temperature and soil water potential (SWP) were measured over the experiment. The RLE was modelled using a thermal-time based approach in degree days (dd). The probability of emergence of a sylleptic lateral (Psyll) was estimated as a linear function of RLEdd, for each well-watered tree. Then, the markers effects on phenotypic values for RLEdd, and its interaction with SWP, Psyll and the mean internode length, in either well-watered or water stress conditions, were estimated using a ridge regression (RR) for 106 out of the 116 genotypes. The accuracy of genomic predictions obtained by these RR was estimated using a 5-fold cross-validation and ranged from 0.24 to 0.37. The last step of our approach will consist in considering the