Pharmacokinetics of ceftiofur sodium in equine pregnancy.

Eleven pregnant pony mares (D270-326) were administered ceftiofur sodium intramuscularly at 2.2 mg/kg (n = 6) or 4.4 mg/kg (n = 5), once daily. Plasma was obtained prior to ceftiofur administration and at 0.5, 1, 2, 4, 8, 12, and 24 hr after administration. Eight pony mares were re-enrolled in the study at least 3 days from expected foaling to ensure steady-state concentrations of drug at the time of foaling. Mares were administered ceftiofur sodium (4.4 mg/kg, IM) daily until foaling. Parturition was induced using oxytocin 1 hr after ceftiofur sodium administration. Allantoic and amniotic fluid, plasma, and colostrum samples were collected at time of foaling. Serial foal plasma samples were obtained. Placental tissues were collected. Desfuroylceftiofur acetamide (DCA) concentrations were measured in samples by high-performance liquid chromatography (HPLC). Mean (±SD) peak serum concentrations of DCA were 3.97 ± 0.50 µg/ml (low dose) and 7.45 ± 1.05 µg/ml (high dose). Terminal half-life was significantly (p = .014) shorter after administration of the low dose (2.91 ± 0.59 hr) than after administration of the high dose (4.10 ± 0.72 hr). The mean serum concentration of DCA from mares at time of foaling was 7.96 ± 1.39 µg/ml. The mean DCA concentration in colostrum was 1.39 ± 0.70 µg/ml. DCA concentrations in allantoic fluid, amniotic fluid, placental tissues, and foal plasma were below the limit of quantification (<0.1 µg/ml) and below the minimum inhibitory concentration of ceftiofur against relevant pathogens. These results infer incomplete passage of DCA across fetal membranes after administration of ceftiofur sodium to normal pony mares.

Structural and functional characterization of OmpF porin mutants selected for larger pore size. I. Crystallographic analysis.

OmpF porin is a nonspecific pore protein from the outer membrane of Escherichia coli. Previously, a set of mutants was selected that allow the passage of long maltodextrins that do not translocate through the wild-type pore. Here, we describe the crystal structures of four point mutants and one deletion mutant from this set; their functional characterization is reported in the accompanying paper (Saint, N., Lou, K.-L., Widmer, C., Luckey, M., Schirmer, T., Rosenbusch, J. P. (1996) J. Biol. Chem. 271, 20676-20680). All mutations have a local effect on the structure of the pore constriction and result in a larger pore cross-section. Substitution of each of the three closely packed arginine residues at the pore constriction (Arg-42, Arg-82, and Arg-132) by shorter uncharged residues causes rearrangement of the adjacent basic residues. This demonstrates mutual stabilization of these residues in the wild-type porin. Deletion of six residues from the internal loop (Delta109-114) results in disorder of seven adjacent residues but does not alter the structure of the beta-barrel framework. Thus, the large hollow beta-barrel motif can be regarded as an autonomous structure.

Redundant homosexual F transfer facilitates selection-induced reversion of plasmid mutations.

F plasmids use surface exclusion to prevent the redundant entry of additional F plasmids during active growth of the host cells. This mechanism is relaxed during stationary phase and nonlethal selections, allowing homosexual redundant plasmid transfer. Homosexual redundant transfer occurs in stationary-phase liquid cultures, within nongrowing populations on solid media, and on media lacking a carbon source. We examined the relationship between homosexual redundant transfer, which occurs between F+ hosts, and reversion of a plasmid-encoded lac mutant allele, lacI33omegalacZ. Sodium dodecyl sulfate (SDS) and mutations that prevent normal transfer to F- cells reduced redundant transfer and selection-induced reversion of the lacI33omegalacZ allele. A recA null mutation reduced redundant transfer and selection-induced reversion of the lacI33omegalacZ mutation. Conversely, a recD null mutation increased redundant transfer and selection-induced reversion of the lacI33omegalacZ allele. These results suggest an explanation for why SDS and these mutations affect reversion of the plasmid lacI33omegalacZ allele. However, a direct causal relationship between transfer and reversion remains to be established. These results suggest that Rec proteins play an active role in redundant transfer and/or that redundant transfer is regulated with the activation of recombination. Redundant homosexual plasmid transfer during a period of stress may represent a genetic response that facilitates evolution of plasmid-encoded functions through mutation, recombination, reassortment, and dissemination of genetic elements present in the populations.

Characterization of a new rho mutation that relieves polarity of Mu insertions.

We report the identification and characterization of a new rho mutation, rho614, that relieves polarity of Mu insertions in Escherichia coli. The mutation was identified by its ability to suppress the polarity of the Mu-mediated phi(lamB'-'lacZ)hyb61-4 fusion that is located at codon four of the lamB signal sequence. The rho614 mutation alters residue 80 in the proposed RNA-binding domain of Rho and is recessive to wild-type rho. We suggest that in the presence of the rho614 allele transcripts initiated at the Mu promoter PcM fail to terminate at presumptive Rho-dependent termination sites, namely rut1 and rut2, and continue into the 3' 'lamB gene allowing a LamB+ phenotype. This contention is supported by deletion analysis of the region and the observation that insertional inactivation of genes that reduce transcription from PcM, clpP (ATP protease), himA (IHF-alpha), and himD (IHF-beta), block the LamB+ phenotype. rho614, rho4 and rho201 alleles suppress the polarity of a malK::Mu insertion on the downstream lamB gene. However, the polarity of the phi(lamB'-'lacZ)hyb61-4 insertion is only suppressed by the rho614 mutation. We propose that the rho614 mutation allows suppression of transcriptional polarity without interfering with translation initiation signals of the truncated 'lamB gene. In addition to identifying a new rho mutation and Rho-dependent terminator sequence, this system provides a means of studying Rho protein/terminator relationships through the identification of new classes of rho mutations.

Redundant transfer of F' plasmids occurs between Escherichia coli cells during nonlethal selections.

Surface exclusion is the mechanism by which F plasmids prevent the redundant entry of additional F plasmids into the host cell during exponential growth. This mechanism is relaxed in cells that are in stationary phase. Using genetically marked F' plasmids and host strains, we extend this finding to Escherichia coli populations during extended nonlethal selection in bacterial lawns. We show that a high level of redundant transfer occurs between these nongrowing cells during the selection. This result has implications for the mechanism of adaptive mutagenesis.

Isolation and characterization of a generalized transducing phage for Xanthomonas campestris pv. campestris.

We have isolated and characterized a lytic double-stranded DNA Xanthomonas campestris pv. campestris bacteriophage (XTP1) capable of mediating generalized transduction. The phage transduces chromosomal markers at frequencies of 10(-5) to 10(-6) transductants per PFU. We demonstrated its genetic utility by the isolation and cotransduction of linked transposon insertions to a nonselectable locus, xgl, required for the cleavage of 5-bromo-3-chloro-indoyl-beta-D-galactoside and showed that rif and str alleles in X. campestris are 75% linked. One-step growth experiments showed that the latent and rise periods were each 2 h and the average burst size was 35. The DNA genome is approximately 180 kb, presumably modified in a sequence-specific manner, and may be covalently attached to protein(s). Electron micrographs show the phage particle to have an icosahedral head and contractile tail with tail fibers uniquely attached to a location 40 nm proximal from the end of the tail.

Biochemical analysis of the biogenesis and function of the Escherichia coli export factor SecY.

SecY is an integral plasma-membrane protein of Escherichia coli which is essential for the export of periplasmic and outer-membrane proteins containing cleavable signal sequences. We have synthesized SecY in vitro using an E. coli transcription/translation system. In the absence of membranes, SecY remained largely soluble but cosedimented on sucrose gradients with the membrane fraction when inside-out plasma-membrane vesicles (INV) had been added cotranslationally. Membrane association of SecY was unaffected if the endogenous SecY of the INV had been inactivated by either antibodies, a mutation or trypsin treatment. In contrast, inactivation of the INV SecY interfered with membrane targeting and, consequently, the processing of precursors to beta-lactamase and lambda receptor. When SecY-deprived INV were, however, first functionally reconstituted with in-vitro-synthesized SecY, targeting and translocation of the lambda receptor were partially restored. Thus, the assembly of SecY into INV in vitro leads to an active enzyme. In addition, we show that the prlA4 allele of the secY gene suppresses signal-sequence mutations of the lambda receptor in vitro. Collectively, our results demonstrate that SecY, while functioning as a membrane-located receptor for precursors of exported proteins, appears to be virtually independent of pre-existing SecY for its own membrane integration.

OmpC and OmpF porins influence viability and culturability of Escherichia coli cells incubated in seawater.

The contribution of the major outer membrane porins OmpF and OmpC to the maintenance of viability and culturability of Escherichia coli cells in seawater was analyzed using isogenic mutant strains lacking one or both porins. Cells that possessed OmpF and OmpC survived better than those lacking one or both of them. However, the results differed, depending on whether the cells were adapted to high osmolarity or not before transfer to seawater. When cells were grown at low osmolarity, survival was largely influenced by porins, the OmpF+ strains surviving better than those lacking this porin. Addition of an OmpF plasmid to OmpF- OmpC- cells also improved their viability. When grown at high osmolarity, the role of porins was less critical since both the viability and culturability of the cells increased. However, cells that expressed only OmpC showed the most dramatic loss of viability. Cells lacking both OmpF and OmpC exhibited a higher loss of viability and culturability in seawater. Regarding the influence of porins on survival, these results show that the conditions that prevail during the growth of cells before their transfer to seawater are highly influential: cells that express the porin corresponding to the growth conditions they are in at the time of transfer survive better.

Phenotypic expression of the Pseudomonas syringae pv. syringae 61 hrp/hrm gene cluster in Escherichia coli MC4100 requires a functional porin.

Plants, in general, appear to be able to detect the presence of incompatible Pseudomonas syringae strains by a hypothetical cell-cell recognition process to initiate inducible defense mechanisms that contribute to disease resistance. A 25-kb hrp/hrm gene cluster isolated from P. syringae pv. syringae 61(pHIR11) enables Escherichia coli to elicit a hypersensitive response (HR), a plant response generally considered to be a manifestation of recognition and resistance. To identify the nature of the HR-eliciting signal produced by E. coli cells carrying pHIR11, bacterial surface features were surveyed by immunological and biochemical procedures. No immunoreactive epitopes or outer membrane proteins were detected that were associated with expression of the P. syringae pv. syringae 61 hrp/hrm cluster in E. coli MC4100. Phenotypic expression of the P. syringae pv. syringae 61 hrp/hrm cluster in E. coli MC4100, however, was found to be dependent upon ompC and ompF, which control outer membrane permeability to hydrophilic solutes. The results suggest that deployment of the HR-eliciting signal occurs via outer membrane porins and imply that a low-molecular-weight, hydrophilic factor mediates signal exchange between the bacterium and the responding plant cell.

Mutant bias in nonlethal selections results from selective recovery of mutants.

We have characterized a nonlethal selection for mutations that allow Escherichia coli to grow on large maltodextrins (Dex+) in the absence of the lamB encoded maltoporin LamB. These Dex+ mutations occur before and after imposition of the selection and the selection does not result in a general increase in mutagenesis. The recovered Dex+ mutations are almost exclusively mutations that alter the ompF gene that encodes a major E. coli porin, OmpF even though analogous mutations in the homologous ompC gene, which encodes the OmpC porin, can confer a Dex+ phenotype. We show that the bias for ompF mutations results from a biased recovery and that the genetic background of the starting strain and the selection itself influences the type of mutants that are recovered. When we use a strain carrying an amber mutation in the lamB gene we observe the same preference for ompF mutations as when we start with a lamB deletion strain. In addition, we show that there is no preferential mutagenesis of the lamB gene during the selection which induces transcription of the lamB gene. We present evidence that the biased recovery of mutants observed in this selection does not result from adaptive or directed mutagenesis and that the phenotypic fitness which allows recovery of Dex+ mutants involves more than the increased ability to take up maltodextrins.

Determinants of OmpF porin antigenicity and structure.

Sixty-six murine hybridomas raised to Escherichia coli B/r porin were used to identify and differentiate the epitopes of this outer membrane protein. Anti-porin monoclonal antibodies (mAb) were raised against outer membrane fragments, purified native trimeric porin (trimer), and purified sodium dodecyl sulfate-denatured monomeric porin (monomer). Immunochemical and flow cytometric methods identified five distinct cell surface-exposed determinants on OmpF. The peptide composition of porin epitopes was determined by analysis of mAb reactivity with cyanogen bromide-generated peptide fragments. Four of 43 anti-monomer mAb reacted with surface exposed sites on OmpF, defining epitopes that consist of residues within CNBr peptides d2, d3, and B. The anti-porin mAb panel was also used to evaluate changes in porin antigenic structure in strains with short ompF deletions. Flow cytometric experiments indicated that despite changes in porin permeability, little if any alteration of surface epitopes occurred in these strains. Western immunoblot analysis of the mutant porins showed loss of reactivity with numerous mAb, which was caused by changes in three spatially distinct epitopes at residues 108-111, 118-123, and 124-129. Our findings indicate that in these ompF mutants the residues responsible for altering porin permeability are not exposed on the cell surface, but are buried within the tertiary structure of the protein. One of these regions, which is apparently involved in the determination of channel permeability characteristics, is conserved among 15 of 16 different porin molecules which were screened with the anti-OmpF mAb panel.

A novel mutation, cog, which results in production of a new porin protein (OmpG) of Escherichia coli K-12.

A mutant of Escherichia coli K-12 which produces a new outer membrane protein, OmpG, was isolated and genetically and biochemically characterized. The presence of OmpG allows growth on maltodextrins in the absence of the LamB maltoporin. The data obtained from in vivo growth and uptake experiments suggested that the presence of the OmpG protein results in an increase in outer membrane permeability for small hydrophilic compounds. In light of these findings, we suggest that OmpG is a porinlike protein. The mutation which results in the expression of OmpG has been termed cog (for control of OmpG) and mapped to 29 min on the E. coli chromosome. Diploid analysis shows that the mutant cog-192 allele is recessive for both the Dex+ and OmpG+ phenotypes. We propose that the cog mutation destroys a negative regulatory function and therefore derepresses ompG expression.

Identification and characterization of a new gene of Escherichia coli K-12 involved in outer membrane permeability.

Using a genetic selection for mutations which allow large maltodextrins to cross the outer membrane of Escherichia coli in the absence of the LamB maltoporin, we have obtained and characterized two mutations that define a new locus of E. coli. We have designated this locus imp for increased membrane permeability. Mapping studies show that the imp gene resides at approximately 1.2 min on the E. coli chromosome. The mutations alter the permeability of the outer membrane resulting in increased sensitivity to detergents, antibiotics and dyes. The mutations are nonreverting and codominant. Genetic analysis of the mutations suggest that the imp gene is an essential gene. We describe a general cloning strategy that can be used to clone both dominant and recessive alleles. Using this technique, we have cloned the wild-type and mutant imp alleles onto a low copy number plasmid.

Mutations that alter the pore function of the OmpF porin of Escherichia coli K12.

We describe the isolation and characterization of mutations in ompF that alter the pore properties of the OmpF porin. The selection makes use of the fact that maltodextrins larger than maltotriose are too large to diffuse through the normal OmpF pore. By demanding growth on maltodextrins (Dex+) in the absence of the LamB protein, which is normally required for the uptake of these large sugars, we are able to obtain ompF mutations. These include transversions, transitions and small deletions. We obtained almost exclusively ompF mutations in spite of the fact that analogous alterations in ompC can result in similar phenotypes. Fifteen independent point mutations identify residues R42, R82, D113 and R132 of the mature peptide as important in pore function. The alterations result in uncharged amino acids being substituted for charged amino acids. Growth tests, antibiotic sensitivities and rates of [14C]maltose uptake suggest that the alterations result in an increased pore size. Small deletions of six to 15 amino acid residues in the region between A108 and V133 of mature OmpF dramatically alter outer membrane permeability to hydrophobic antibiotics and detergents as well as conferring a Dex+ phenotype. We suggest that these mutations affect both the pore function and interactions with other outer membrane components. A model of OmpF protein structure based on general rules for folding membrane proteins and these mutations is presented.

Genetic identification of the pore domain of the OmpC porin of Escherichia coli K-12.

We have isolated and characterized 31 mutations in the ompC gene which allow Escherichia coli to grow on maltotriose (Dex+) in the absence of the LamB and OmpF porins. These ompC(Dex) mutations include single-base-pair substitutions, small deletions, and small insertions. DNA sequence analysis shows that all of the alterations occur within the coding region for the first 110 amino acids of mature OmpC. The 26 independent point mutations repeatedly and exclusively alter residues R37, R74, and D105 of mature OmpC. In each case, a charged amino acid is changed to an uncharged residue. Biochemical and physiological tests suggest that these alterations increase the size of the pore channel. Starting with three different ompC(Dex) strains with alterations affecting R74, we isolated mutants that could grow on maltohexose (Hex+). These mutants each contained a second alteration in the ompC gene involving residues R37, D105, or R124. The combined effects on pore function of the two mutations appear to be additive. These experiments suggest that we have identified the important residues of OmpC peptide involved in pore function. On the basis of these mutations and general rules for membrane protein folding, a model for the topology of the OmpC protein is proposed.

Isolation and characterization of OmpC porin mutants with altered pore properties.

The LamB protein is normally required for the uptake of maltodextrins. Starting with a LamB- OmpF- strain, we have isolated mutants that will grow on maltodextrins. The mutation conferring the Dex+ phenotype in the majority of these mutants has been mapped to the ompC locus. These mutants, unlike LamB- OmpF- strains, grew on maltotriose and maltotetraose, but not on maltopentaose, and showed a significantly higher rate of [14C]maltose uptake than the parent strain did. In addition, these mutants showed increased sensitivity to certain beta-lactam antibiotics and sodium dodecyl sulfate, but did not exhibit an increase in sensitivity to other antibiotics and detergents. The nucleotide sequence of these mutants has been determined. In all cases, residue 74 (arginine) of the mature OmpC protein was affected. The results suggest that this region of the OmpC protein is involved in the pore domain and that the alterations lead to an increased pore size.

Bacteriophage K20 requires both the OmpF porin and lipopolysaccharide for receptor function.

Mutations which prevent absorption of the bacteriophage K20 to Escherichia coli K-12 were selected by using an altered OmpF protein which confers the ability to grow on maltodextrin in the absence of the LamB maltoporin. The mutations map in the rfa gene cluster and alter the structure of the lipopolysaccharide core.

Signal sequence mutations that alter coupling of secretion and translation of an Escherichia coli outer membrane protein.

The lamB701-708 signal sequence mutation reduces expression of LamB, an outer membrane protein of Escherichia coli. To investigate the possibility that synthesis and export of LamB are coupled, as suggested by the expression defect of the lamB701-708 mutation, we isolated intragenic suppressors of the lamB701-708 mutation. The expression defect imposed by the lamB701-708 mutation is suppressed by an export-defective signal sequence mutation, suggesting that translation and export are coupled. The additional observation that not all export-defective signal sequence mutations suppressed the lamB701-708 expression defect suggests that translational arrest can be uncoupled from export.

In vivo selection and characterization of internal deletions in the lamB::lacZ gene fusion.

Strain Pop3299 contains the lamB::lacZ42-12 gene fusion that encodes a hybrid protein that is efficiently exported to the cellular envelope of Escherichia coli. As a result of this efficient export, this strain is killed by the inducer maltose and unable to grow on minimal media supplemented with lactose. In an attempt to isolate mutants in which export of the hybrid protein is altered, we selected Lac+ mutants of strain Pop3299 on lactose tetrazolium media. Unlike mutants previously isolated on lactose minimal media, all the mutants we obtained carried large deletions within the lamB::lacZ gene fusion. Thus, it appears that the type of selection employed affects the type of mutations obtained. We have analyzed the nucleotide sequences of representative mutants, and demonstrate a correlation between the deletion size and the export-related maltose and lactose phenotypes. In addition, we demonstrate that the deletions do not appear to arise from regions of micro-homology.

Kinetic analysis of lamB mutants suggests the signal sequence plays multiple roles in protein export.

We have developed a quantitative assay to measure the rate of processing of precursor LamB into mature protein and have used this assay to characterize 10 previously isolated and 3 new lamB signal sequence mutants. The data suggest that the LamB signal sequence serves a complex function. Our assay has revealed five types of signal sequence defect: 1) a strong kinetic defect resulting from alteration of the secondary structure in the putative alpha-helical region in the hydrophobic core, 2) a strong, or 3) a weak kinetic defect due to placement of a charged residue in the hydrophobic core, 4) decreased synthesis of LamB, and 5) both a decrease in synthesis and a strong kinetic defect. The effect of an extragenic suppressor, prlA4 on the rate of processing pLamB containing signal sequence mutations was also examined and compared to the rates in wild-type strains. It was found that prlA4 increases the rate of processing in some, but not all, mutants having a kinetic defect while having no effect on the decreased synthesis seen in mutants of types 4 and 5.