Imbalances in dietary amino acid (AA) supply, including deficits in one or more indispensable amino acids (IAA), are stressful conditions for the organism that needs to modulate a number of physiological functions to adapt to this situation. In particular, since there is no system dedicated for storing AA in the body, the release of free AA occurs by proteolysis at the expense of functional proteins, notably in the liver by up-regulating autophagy. This process can be rapidly mobilized within the cell in response to a number of stresses, by post-translational regulations of autophagy-related proteins already present in the cytosol. The protein kinase GCN2 is activated upon IAA scarcity in order to promote cell adaptation to a nutritional stress condition. In response to IAA limitation, GCN2 couples the accumulation of uncharged transfer RNAs to the phosphorylation of eIF2a on serine 51. By this mean, GCN2 diminishes the overall protein synthesis rate, while simultaneously activating a gene expression program mediated by the translational upregulation of the transcription factor ATF4. Our recent work has shown that the GCN2/p-eIF2a/ATF4 signaling pathway plays an essential role in the induction of transcription of a number of autophagy-related genes involved in the maintenance of the autophagic process in response to an IAA deficiency (B’chir et al., 2013). In the present study we sought to determine whether GCN2 could play a role in regulating the early stages of autophagy. The most upstream complex for triggering the autophagic process (initiation complex) is notably composed of the ULK kinase and the ATG13 bridging protein, and is classically viewed to be controlled by mTORC1. Indeed, the activity of the autophagy initiation complex has been shown to be modulated according to AA availability by the activity of mTORC1, which phosphorylates different sites in ULK. Here, by using a GCN2 knock-out mouse model we investigated the role of GCN2 in the upregulation of autophagy in the first hour of an IAA deficiency. Our results show that 1) GCN2 is required for upregulating liver autophagy in response to an IAA-deficient diet, which is confirmed in cell culture model; 2) this early activation of the autophagic process does not require the transcription factor ATF4; 3) moreover, while this effect can occur without concomitant inhibition of mTORC1 activity, our results suggest that ULK/ATG13 couple is involved in the GCN2-dependent activation of autophagy. Our results demonstrate that in the particular model of an IAA deficiency GCN2 plays a preponderant role in triggering the adaptive autophagy upregulation, a mechanism which can operate without concomitant inhibition of mTORC1 activity