Erythropoietic protoporphyria (EPP) results from an inherited partial deficiency of ferrochelatase, the terminal enzyme of haem biosynthesis. Excess protoporphyrin IX accumulates in erythrocytes, plasma, liver, and skin, which mediates a distinctive form of cutaneous photosensitivity that manifests during childhood. Ferrochelatase is synthesised on cytosolic ribosomes as a preprotein with a cleavable presequence at its amino-terminus. This leader sequence is thought to target ferrochelatase to mitochondria where it is cleaved to produce the active mature protein. In this study, we show that the 62 amino acid leader sequence is sufficient for targeting of a leader sequence-YFP fusion protein to mitochondria. A truncated fusion protein lacking the first 62 amino acids did not target to mitochondria, and formed punctate aggregates in the cytoplasm of cells. This suggests that all the information required for mitochondrial localisation resides within the first 62 amino acid presequence. A missense mutation, P62R, predicted to be located within the ferrochelatase presequence has been identified in a patient with EPP. We hypothesised that this mutation may exert its effect through defective targeting to mitochondria. Our data showed that this mutated full-length ferrochelatase successfully targeted to mitochondria. Interestingly, there was inhibited cleavage of YFP from wild-type and mutant leader sequence fusion proteins. Generation of leader sequence-YFP fusion proteins containing an additional 11 amino acids from the mature protein allowed proteolytic processing to occur. These data suggest that the first 62 amino acids allow targeting to mitochondria but do not contain sufficient information for efficient processing of the protein.