Circadian clocks rely on transcriptional/translational feedback loops involving clock genes and their corresponding proteins. While the primary oscillations originate from gene expression, the precise control of clock protein stability plays a pivotal role in establishing the 24-hour circadian rhythms. Most clock proteins are degraded through the ubiquitin/26S proteasome pathway, yet the enzymes responsible for ubiquitination and deubiquitination remain poorly characterised. We identified a missense allele (ubp12-3, S327F) of the UBP12 gene/protein in Arabidopsis. Despite ubp12-3 exhibited a short period phenotype similar to that of a loss-of-function allele, molecular analysis indicated elevated protease activity in ubp12-3. We demonstrated that early flowering of ubp12 mutants is a result of the shortened circadian period rather than a direct alteration of UBP12 function. Analysis of protease activity of non-phosphorylatable (S327A, S327F) and phosphomimetic (S327D) derivatives in bacteria suggested that phosphorylation of serine 327 inhibits UBP12 enzymatic activity, which could explain the over-functioning of S327F in vivo. We showed that phosphomimetic mutations of the conserved serine in the Neurospora and human orthologues reduced ubiquitin cleavage activity suggesting that not only the primary structures of UBP12-like enzymes are phylogenetically conserved across a wide range of species, but also the molecular mechanisms governing their enzymatic activity.