ABSTRACT: Recent studies have shown that haloarchaea employ leaderless and Shine-Dalgarno (SD)-less mechanisms for translation initiation of leaderless transcripts with a 5' untranslated region (5' UTR) of <10 nucleotides (nt) and leadered transcripts with a 5' UTR of ?10 nt, respectively. However, whether the two mechanisms can operate on the same naturally occurring haloarchaeal transcript carrying multiple potential start codons is unknown. In this study, the transcript of the sptA gene (encoding an extracellular serine protease of Natrinema sp. strain J7-2) was experimentally determined and found to contain two potential in-frame AUG codons (AUG(1) and AUG(2)) located 5 and 29 nt, respectively, downstream of the transcription start site. Mutational analysis revealed that both AUGs can function as the translation start codon for production of active SptA, although AUG(1) is more efficient than AUG(2) for translation initiation. Insertion of a stable stem-loop structure between the two AUGs completely abolished initiation at AUG(1) but did not affect initiation at AUG(2), indicating that AUG(2)-initiated translation does not involve ribosome scanning from the 5' end of the transcript. Furthermore, the efficiency of AUG(2)-initiated translation was not influenced by an upstream SD-like sequence. In addition, both AUG(1) and AUG(2) contribute to transcript stability, probably by recruiting ribosomes to protect the transcript against degradation. These data suggest that depending on which of two in-frame start codons is used, the sptA transcript can act as either a leaderless or a leadered transcript for SptA production in haloarchaea.In eukaryotes and bacteria, alternative translation start sites contribute to proteome complexity and can be used as a functional mechanism to increase translation efficiency. However, little is known about alternative translation initiation in archaea. Our results demonstrate that leaderless and SD-less mechanisms can be used for translation initiation of the sptA transcript from two in-frame start codons, raising the possibility that in haloarchaea, alternative translation initiation on one transcript functions to increase translation efficiency and/or contribute to proteome complexity.