Characterization of Escherichia coli type 1 pilus mutants with altered binding specificities

PCR mutagenesis and a unique enrichment scheme were used to obtain two mutants, each with a single lesion in fimH, the chromosomal gene that encodes the adhesin protein (FimH) of Escherichia coli type 1 pili. These mutants were noteworthy in part because both were altered in the normal range of cell types bound by FimH. One mutation altered an amino acid at a site previously shown to be involved in temperature-dependent binding, and the other altered an amino acid lining the predicted FimH binding pocket.     

Genetic characterization of Escherichia coli type 1 pilus adhesin mutants and identification of a novel binding phenotype

Five Escherichia coli type 1 pilus mutants that had point mutations in fimH, the gene encoding the type 1 pilus adhesin FimH, were characterized. FimH is a minor component of type 1 pili that is required for the pili to bind and agglutinate guinea pig erythrocytes in a mannose-inhibitable manner. Point mutations were located by DNA sequencing and deletion mapping. All mutations mapped within the signal sequence or in the first 28% of the predicted mature protein. All mutations were missense mutations except for one, a frameshift lesion that was predicted to cause the loss of approximately 60% of the mature FimH protein. Bacterial agglutination tests with polyclonal antiserum raised to a LacZ-FimH fusion protein failed to confirm that parental amounts of FimH cross-reacting material were expressed in four of the five mutants. The remaining mutant, a temperature-sensitive (ts) fimH mutant that agglutinated guinea pig erythrocytes after growth at 31 degrees C but not at 42 degrees C, reacted with antiserum at both temperatures in a manner similar to the parent. Consequently, this mutant was chosen for further study. Temperature shift experiments revealed that new FimH biosynthesis was required for the phenotypic change. Guinea pig erythrocyte and mouse macrophage binding experiments using the ts mutant grown at the restrictive and permissive temperatures revealed that whereas erythrocyte binding was reduced to a level comparable to that of a fimH insertion mutant at the restrictive temperature, mouse peritoneal macrophages were bound with parental efficiency at both the permissive and restrictive temperatures. Also, macrophage binding by the ts mutant was insensitive to mannose inhibition after growth at 42 degrees C but sensitive after growth at 31 degrees C. The ts mutant thus binds macrophages with one receptor specificity at 31 degrees C and another at 42 degrees C.     

Isolation and characterization of Escherichia coli phase variants and mutants deficient in type 1 pilus production.

Type 1 pili of Escherichia coli are the prototype of the somatic class of pili found on many strains of bacteria. As a first step in the genetic analysis of type 1 piliation, an extensive series of nonpiliated derivatives of E. coli K-12 strain AW405, was characterized to produce attached or free pili when examined in the antiserum or appeared to produce attached or free pili when examined in the electron microscope. The derivatives fell into two classes; phase variants and mutants. Phase variants that formed colonies of two distinctive types, one associated with a predominantly piliated (P+), and the other associated with a nonpiliated (P-) phase, were obtained. Each phase could give rise to the other at a relatively high rate, which was greater in the P- to P+ direction during culture in unshaken liquid medium. In addition, 77 Pil- mutants were selected on the basis of a subtle difference in colonial morphology. The mutants reverted, if at all, at a much lower rate than that of the P- to P+ change. The stability of Pil- derivatives grown in unshaken liquid medium was used as a criterion for distinguishing between phase variants and mutants, Phase variation also effected colonial morphology and chemotactic swarming. These properties did not directly depend upon piliation since Pil- mutants were only slightly altered in colonial form and unaltered in chemotactic swarming. Piliation of Pil+ bacteria was quantitatively affected by growth conditions.     

Genetic analysis of Escherichia coli oligopeptide transport mutants.

The composition of the outer membrane channels formed by the OmpF and OmpC porins is important in peptide permeation, and elimination of these proteins from the Escherichia coli outer membrane results in a cell in which the primary means for peptide permeation through this cell structure has been lost. E. coli peptide transport mutants which harbor defects in genes other than the ompF/ompC genes have been isolated on the basis of their resistance to toxic tripeptides. The genetic defects carried by these oligopeptide permease-negative (Opp-) strains were found to map in two distinct chromosomal locations. One opp locus was trp linked and mapped to the interval between att phi 80 and galU. Complementation studies with F'123 opp derivatives indicated that this peptide transport locus resembles that characterized in Salmonella typhimurium as a tetracistronic operon (B. G. Hogarth and C. F. Higgins, J. Bacteriol. 153:1548-1551, 1983). The second opp locus, which we have designated oppE, was mapped to the interval between dnaC and hsd at 98.5 min on the E. coli chromosome. The differences in peptide utilization, sensitivity and resistance to toxic peptides, and the L-[U-14C]alanyl-L-alanyl-L-alanine transport properties observed with these Opp-E. coli strains demonstrated that the transport systems encoded by the trp-linked opp genes and by the oppE gene(s) have different substrate preferences. Mutants harboring defects in both peptide transport loci defined in this study would not grow on nutritional peptides except for tri-L-methionine, were totally resistant to toxic peptides, and would not actively transport L-[U-14C]alanyl-L-alanyl-L-alanine.     

Conjugational complementation analysis of transfer-deficient mutants of Flac in Escherichia coli

A series of 102 transfer-deficient (tra(-)) mutants of Flac (84 of which have been previously described) were classified as carrying frameshift, amber, ochre, UGA, and nonsuppressible mutations. Techniques were evolved for using cultures of F prime strains as efficient recipients in matings, for measuring the number of (F'/F') heterozygote cells in transient populations, and for measuring complementation between different Flac tra(-) mutants. These techniques were used to define nine tra cistrons and to assign most of the tra(-) mutations to one or other of these.     

Intra-cistronic complementation among trpC mutants of Escherichia coli

Summary Some merodiploids containing two different trpC alleles grow in the absence of added tryptophan. The trpC gene product is the bifunctional enzyme indoleglycerol phosphate synthetase but the ability to grow on minimal medium does not require that the alleles be dificient in different functions. This indication of complementation is supported by the evidence that the trpC alleles, of the merodiploids, can be transferred by transduction or by the trp-colV,B episome. Genetic recombination between episome and chromosome is seen to occur, but at a rate too low to explain the observed results. The nature of the interaction between the trpC alleles is not readily explained since indoleglycerol phosphate synthetase appears to consist of a single polypeptide chain in in vitro studies.     

Phasmid vectors for identification of genes by complementation of Escherichia coli mutants.

A bacteriophage lambda cloning vector was designed to facilitate the isolation of genes from procaryotic organisms by complementation of Escherichia coli mutants. This vector, lambda SE4, was constructed by attaching a very-low-copy-number replication system (from the plasmid NR1) and a spectinomycin resistance gene to the left arm of lambda 1059 (Karn et al., Proc. Natl. Acad. Sci. U.S.A. 77:5172-5176, 1980). This phasmid cloning vector is capable of growing lytically as a phage in a nonimmune host or lysogenically as a phasmid in an immune host. This phasmid utilizes the Spi- selection for insertions of DNA into the vector and has the ability to accept 2- to 19-kilobase Sau3A1, BamHI, BglII, BclI, or XhoII fragments; recombinants lysogenize immune hosts as single-copy-number selectable plasmids at 100% frequency. An E. coli library was constructed by using the initial vector lambda SE4, and clones of a number of representative genes were identified. A typical clone, lambda ant+, was shown to be readily mutagenized by a mini-Tn10 transposon. A general method for transferring cloned DNA segments onto bacteriophage lambda was developed. The method involves the use of in vivo recombination with a selection and was used to construct two derivatives of lambda SE4. Possible uses of these vectors and of the method for transferring cloned DNA onto phage lambda are discussed.     

NMR structure of the Escherichia coli type 1 pilus subunit FimF and its interactions with other pilus subunits

Type 1 pili from uropathogenic Escherichia coli strains mediate bacterial attachment to target receptors on the host tissue. They are composed of up to 3000 copies of the subunit FimA, which form the stiff, helical pilus rod, and the subunits FimF, FimG, and FimH, which form the linear tip fibrillum. All subunits in the pilus interact via donor strand complementation, in which the incomplete immunoglobulin-like fold of each subunit is complemented by insertion of an N-terminal extension from the following subunit. We determined the NMR structure of a monomeric, self-complemented variant of FimF, FimF_F, which has a second FimF donor strand segment fused to its C-terminus that enables intramolecular complementation of the FimF fold. NMR studies on bimolecular complexes between FimF_F and donor strand-depleted variants of FimF and FimG revealed that the relative orientations of neighboring domains in the tip fibrillum cover a wide range. The data provide strong support for the intrinsic flexibility of the tip fibrillum. They lend further support to the hypothesis that this flexibility would significantly increase the probability that the adhesin at the distal end of the fibrillum successfully targets host cell receptors.     

Genetic analysis of lon mutants of strain K-12 of Escherichia coli

Summary Following UV irradiation of AB1157 31 mucoid ultraviolet light UV sensitive mutants were isolated. These were all induced to form filaments by UV irradiation, i.e. they had all the phenotypic properties of Lon mutants. These lon mutants fell into two phenotypic classes based on their sensitivity to UV. The gene determining UV sensitivity and mucoidy in all mutants of both Class A and Class B was cotransducible with proC. Intra-class crosses by Pl transduction yielded no UV resistant recombinants. Inter-class crosses yielded UV resistant nonmucoid recombinants, the frequency depending on the direction of the cross. The data imply two adjacent blocks in the lon region of E. coli and the order of markers in this region is probably proC tsx lon Class A lon purE Class B.This work was carried out under Public Health Service Grant CA 05687-08 from the National Cancer Institute.Recipient of a Public Health Service Career Development Award.     

Genetic diversity of the gene cluster encoding longus, a type IV pilus of enterotoxigenic Escherichia coli

Enterotoxigenic Escherichia coli (ETEC) strains produce a type IV pilus named Longus. We identified a 16-gene cluster involved in the biosynthesis of Longus that has 57 to 95% identity at the protein level to CFA/III, another type IV pilus of ETEC. Alleles of the Longus structural subunit gene lngA demonstrate a diversity of 12 to 19% at the protein level with strong positive selection for point replacements and horizontal transfer.     

The Product of the fimI gene is necessary for Escherichia coli type 1 pilus biosynthesis

Site-directed mutagenesis was employed to create lesions in fimI, a gene of uncertain function located in the chromosomal gene cluster (fim) involved in Escherichia coli type 1 pilus biosynthesis. Chromosomal fimI mutations produced a piliation-negative phenotype. Complementation analysis indicated that a fimI'-kan insertion mutation and a fimI frameshift mutation produced polarity-like effects not seen with an in-frame fimI deletion mutation. Minicell analysis associated fimI with a 16.4-kDa noncytoplasmic protein product (FimI). We conclude that FimI has a required role in normal pilus biosynthesis.