Structure and function of periplasmic chaperone-like proteins involved in the biosynthesis of K88 and K99 fimbriae in enterotoxigenic Escherichia coli.

The nucleotide sequence of faeE and fanE, two genes involved in the biosynthesis of K88 and K99 fimbriae, respectively, was determined and the amino acid sequence of the FaeE and FanE proteins was deduced. Immunoblotting of subcellular fractions with an antiserum raised against purified FaeE confirmed that FaeE is located in the periplasm. Indications were obtained that FaeE functions as a chaperone-like protein. Its interaction with the fimbrial subunit (FaeG) in the periplasm stabilized this polypeptide and prevents its degradation by the cell-envelope protease DegP. Furthermore, FaeE prevents the formation of FaeG multimers which cannot be incorporated into fimbriae. The reactions of the FaeE/FaeG dimers with a set of monoclonal antibodies directed against the various epitopes present on K88 fimbriae revealed that the fimbrial subunits associated with FaeE were present in a conformation resembling their native configuration. Indications about the domains in FaeG involved in the interaction with FaeE are discussed.

Detection and identification of FaeC as a minor component of K88 fibrillae of Escherichia coli.

A tribrid gene containing ompF, faeC, and lacZ sequences was constructed by subcloning a large central segment of the K88ab gene encoding the fibrillar subunit-like protein FaeC into the open reading frame expression vector pORF2. The resulting tribrid protein was isolated and used to raise antibodies against the FaeC protein. These antibodies were then used for the detection and subcellular localization of the FaeC protein in Escherichia coli harbouring the K88ab-encoding plasmid pFM205 or mutant derivatives. Immunoblotting of subcellular fractions and of purified fibrillae, and agglutination experiments using whole cells revealed that the FaeC protein is present in the periplasm and as a minor component in the K88ab fibrillae. FaeC was also detected in purified K88ac and K88ad fibrillae. Immunoelectron microscopy confirmed the presence of FaeC in K88ab fibrillae, particularly at the tips of the longer fibrillae.

Molybdenum cofactor from the cytoplasmic membrane of Proteus mirabilis.

Molybdenum cofactor was extracted from membranes of Proteus mirabilis by three methods: acidification, heat treatment and heat treatment in the presence of sodium-dodecylsulphate (SDS). Extracts prepared by the latter method contained the highest concentration of molybdenum cofactor. In these extracts molybdenum cofactor was present in a low molecular weight form. It could not penetrate an YM-2 membrane during ultrafiltration suggesting a molecular weight above 1000. During aerobic incubation of cofactor extracts from membranes at least four fluorescent species were formed as observed in a reversed-phase high performance liquid chromatography (HPLC) system. The species in the first peak was inhomogeneous while the species in the others seem to be homogeneous. In water, all fluorescent products had an excitation maximum at 380 nm and an emission maximum at 455 nm. Their absorption spectra showed maxima at around 270 nm and 400 nm. Fluorescent compounds present in the first peak could penetrate an YM-2 membrane during ultrafiltration, whereas the compounds in the other peaks hardly did. Using xanthine oxidase from milk as source of molybdenum cofactor apparently identical cofactor species were found. Cytoplasmic nor membrane extracts of the chlorate resistant mutant chl S 556 of P. mirabilis could complement nitrate reductase of Neurospora crassa nit-1 in the presence of 20 mM molybdate. However, fluorescent species with identical properties as found for the wild-type were formed during aerobic incubation of extracts from membranes of this mutant.