Cells rely on protein degradation by AAA+ proteases. A well-known example is the hexameric ClpX unfoldase, which captures ATP hydrolysis to feed substrates into the oligomeric ClpP peptidase. Recent studies show that an asymmetric ClpX spiral cycles protein translocation upon ATP hydrolysis. However, how this cycle affects peptide products is less explored in part because ClpP cleavage is thought to be solely defined by sequence constraints. Here, we comprehensively characterize peptides from Caulobacter crescentus ClpXP degradation of three different substrates using high-resolution mass spectrometry and find that cleavage of translocated substrates is driven by factors other than sequence. We report that defined locations in a translocated protein are especially sensitive to cleavage spaced on average every 10-13 residues. These sites are not exclusively controlled by sequence and are independent of bulk changes in catalytic peptidase sites, ATP hydrolysis, or the efficiency of initial recognition. These results fit a model in which processive translocation through ClpX starts at a specific location in a polypeptide and pauses during reset of the ClpX hexamer after a cycle of translocation. Our work suggests that defined peptides, which could be used as signaling molecules, can be generated from a given substrate by a nonspecific peptidase.