The ftsH gene, present in all eubacterial species, is anchored in the cytoplasmic membrane and contains an ATP- and a Zn-binding domain that are both part of a metalloprotease activity. The Bacillus subtilis ftsH is not essential, but null mutants exhibit a pleiotropic phenotype including filamentous growth; hypersensitivity towards heat and salt stress and a failure to sporulate. To find out whether one or the other functional domain is involved in these different phenotypes, point mutations were introduced into the coding region for both domains leading to a replacement of conserved amino acid residues. The mutant alleles were fused to a xylose-inducible promoter and integrated ectopically into two different strains, one expressing the wild-type ftsH allele and the other carrying a ftsH knockout. While none of the strains exhibited a growth defect in rich medium at 37degreesC, those strains expressing only the mutant alleles did not resume growth after heat or salt stress challenge. Furthermore, none of the mutant alleles promoted sporulation. While only those purified mutant FtsH proteins with an intact Walker A box exhibited ATPase activity, all of them failed to degrade beta-casein.