Molecular genetic analysis of virulence in Mannheimia (pasteurella) haemolytica.

Mannheimia haemolytica (previously known as Pasteurella haemolytica) is a weakly hemolytic, gram-negative coccobacillus that is an opportunistic pathogen of cattle, sheep and other ruminants. In stressed, immunocompromised animals, the organism causes a fibrinous, necrotic pneumonia, commonly called "shipping fever". In the United States, economic losses due to shipping fever pneumonia surpass the combined cost of all other diseases of cattle. M. haemolytica, which is a member of the family Pasteurelleaceae, includes twelve serotypes (A1, A2, A5-A9, A12-14, A16 and A17) based on capsular antigen typing. Worldwide, serotypes A1 and A2 predominate, though all serotypes can cause disease. Serotype A1 causes pasteurellosis in cattle and has been the subject extensive study, while serotype A2 causes disease in sheep and is less-well characterized. Potential virulence factors of M. haemolytica have been identified and characterized by gene cloning and DNA sequence analysis. These factors include a ruminant-specific leukotoxin, an anti-phagocytic capsule, lipopolysaccharide, iron-regulated outer membrane proteins, lipoproteins, a sialoglycoprotease, a neuraminidase and two potential immunoglobulin proteases. Unlike the well-characterized leukotoxin, little is known about the expression of these other virulence factors. Attempts to dissect the mechanisms of M. haemolytica pathogenesis have been hindered by the lack of a robust genetic system for mutation of the organism, though new tools for genetic manipulation of M. haemolytica have been developed. Expression plasmids and operon fusion plasmids have been created and a series of antibiotic resistance cassettes useful for site-specific recombination have been constructed. It is anticipated that use of these tools for gene expression and mutagenesis, in combination with the soon to be released genomic sequence of a serotype A1 organism, will aid in understanding the molecular mechanisms of pathogenesis of M. haemolytica and will help to drive development of new vaccines to prevent shipping fever.

Use of operon fusions in Mannheimia haemolytica to identify environmental and cis-acting regulators of leukotoxin transcription.

The leukotoxin of Mannheimia haemolytica is an important virulence factor that contributes to much of the pathology observed in the lungs of animals with bovine shipping fever pneumonia. We believe that identification of factors that regulate leukotoxin expression may provide insight into M. haemolytica pathogenicity. The DNA sequence upstream of the leukotoxin operon is divergently shared by P(lapT), which transcribes an arginine permease gene. The intergenic region contains several elements that are potential sites for transcriptional modulation of the promoters. We have developed plasmid-borne chloramphenicol acetyltransferase (cat) operon fusions, as well as lktC::cat chromosomal fusions, to study transcription initiation in M. haemolytica. Using these genetic tools, we have identified cis-acting sequences and environmental conditions that modulate transcription of the leukotoxin and lapT promoters. By deletion analysis, promoters were shown to rely on sequences upstream of their -10 and -35 regions for full activity. Direct repeats of the sequence TGT-N(11)-ACA and a static bend region caused by phased adenine tracts were necessary for full activation of P(lkt). A computer-generated model of the promoter's structure shows how DNA bending brings the repeat sequences within close proximity to the P(lkt) RNA polymerase, and we hypothesize that these repeats are a binding site for an activator of leukotoxin transcription. The lktC::cat operon fusion was also used to demonstrate that, like that of other RTX toxins, leukotoxin transcription is environmentally regulated. Roles for iron deprivation and temperature change were identified.

Inactivation of Pasteurella (Mannheimia) haemolytica leukotoxin causes partial attenuation of virulence in a calf challenge model.

The leukotoxin of Pasteurella (Mannheimia) haemolytica is believed to play a significant role in pathogenesis, causing cell lysis and apoptosis that lead to the lung pathology characteristic of bovine shipping fever. Using a system for Cre-lox recombination, a nonpolar mutation within the lktC transacylase gene of the leukotoxin operon was created. The lktC locus was insertionally inactivated using a loxP-aph3-loxP cassette, and then the aph3 marker was excised from the chromosome by Cre recombinase expressed from a P. haemolytica plasmid. The resulting lktC strain (SH2099) secretes inactive leukotoxin and carries no known antibiotic resistance genes. Strain SH2099 was tested for virulence in a calf challenge model. We inoculated 3 x 10(8) or 3 x 10(9) CFU of wild-type or mutant bacteria into the lungs of healthy, colostrum-deprived calves via transthoracic injection. Animals were observed for clinical signs and for nasal colonization for 4 days, after which they were euthanized and necropsied. The lower inoculum (3 x 10(8) CFU) caused significantly fewer deaths and allowed lung pathology to be scored and compared, while the 3 x 10(9) CFU dose of either the wild-type or mutant was lethal to >/=50% of the calves. The estimated 50% lethal dose of SH2099 was four times higher than that of the wild-type strain. Lung lesion scores were reduced twofold in animals inoculated with the mutant, while clinical scores were nearly equivalent for both strains. The wild-type and mutant strains were equally capable of colonizing the upper respiratory tracts of the calves. In this study, the P. haemolytica lktC mutant was shown to be less virulent than the parent strain.

Ultrastructural characterization of apoptosis in bovine lymphocytes exposed to Pasteurella haemolytica leukotoxin.

OBJECTIVE: To characterize ultrastructural changes of bovine lymphocytes exposed to Pasteurella haemolytica leukotoxin (LKT). SAMPLE POPULATION: Partially purified LKT from a wild type P. haemolytica A1 strain and inactive pro-LKT from an isogeneic mutant Phaemolytica strain. Isolated bovine lymphocytes were obtained from 2 healthy calves. PROCEDURE: Isolated bovine lymphocytes were incubated with various concentrations of LKT and pro-LKT for 3 hours at 37 C and examined by use of transmission electron microscopy. A cytochemical Klenow DNA fragmentation assay was used to examine lymphocytes for DNA fragmentation. RESULTS: Lymphocytes incubated with LKT at a high concentration (1.0 toxic U/ml) had ultrastructural evidence of cytoplasmic and nuclear membrane rupture and swelling or lysis of mitochondria. Low concentrations of leukotoxin (0.1 toxic U/ml) induced DNA fragmentation in 80% of lymphocytes. Ultrastructurally, these cells had nuclear membrane blebbing, cytoplasmic vaculation, chromatin condensation, nuclear fragmentation, and membrane-bound apoptotic bodies. Incubation of lymphocytes with LKT at extremely low concentrations (0.001 toxic U/ml) or with pro-LKT did not alter their ultrastructure. Inclusion of 0.5 mM ZnCl2 in the medium blocked leukotoxin-induced ultrastructural changes in bovine lymphocytes. CONCLUSIONS AND CLINICAL RELEVANCE: Low concentrations of LKT induce apoptosis and high concentrations induce oncotic cell lysis in bovine lymphocytes. The ability of low LKT concentrations to induce apoptosis in host leukocytes may allow bacteria to escape host immune surveillance and colonize the host.

Actin polymerization enhances Pasteurella haemolytica leukotoxicity.

Pasteurella haemolytica leukotoxin is cytotoxic to bovine leukocytes, causing increased cell membrane permeability, osmotic swelling, release of cytosolic proteins and cell lysis. These studies were designed to test if leukotoxin causes release of the cytoskeletal protein, actin, from bovine leukemia cells and if purified actin-influenced bacterial growth or leukotoxin production. Culture supernatants caused a 7-fold decrease in viability of bovine leukemia cells and increased cell permeability that was accompanied by release of beta-actin into the cell culture supernatant. Exposing P. haemolytica to purified actin solutions induced the conversion of monomeric G-actin to polymerized F-actin. This conversion was partially inhibited by bovine P. haemolytica immune, but not pre-immune, serum. Loss of streptomycin resistance following treatment of the organism with acridine orange ablated the polymerizing activity. Incubation of P. haemolytica in the presence of purified F-actin did not affect growth but resulted in culture supernatant that had 3.0-3.9-fold greater leukotoxicity compared to medium alone or medium containing G-actin, heat-denatured actin or albumin. The effect of actin on leukotoxicity was concentration-dependent and directly associated with increases in secreted leukotoxin. The interaction between P. haemolytica and actin is potentially detrimental to the host by inducing polymerization of actin into insoluble filaments and by enhancing leukotoxicity.

Pasteurella haemolytica leukotoxin induced apoptosis of bovine lymphocytes involves DNA fragmentation.

It has been reported that Pasteurella haemolytica leukotoxin (LKT) induces morphologic changes in bovine leukocytes consistent with apoptosis in vitro, but DNA fragmentation was not observed. We investigated whether bovine lymphocytes undergo DNA fragmentation during LKT-induced apoptosis. Bovine peripheral blood lymphocytes were isolated by density gradient centrifugation and exposed to LKT or inactive pro-LKT protein from a lktC- mutant strain. After exposure, DNA fragmentation in lymphocytes was quantified colorimetrically by diphenylamine assay and visualized by agarose gel electrophoresis. At high LKT concentrations, bovine lymphocytes were lysed, but at low concentrations, LKT caused DNA fragmentation characteristic of apoptosis. Maximal DNA fragmentation in bovine lymphocytes was induced by 0.1 TU ml(-1) LKT following 3 h exposure, but only background level of DNA fragmentation was observed with the inactive pro-LKT. Equine lymphocytes that are resistant to LKT intoxication did not show DNA fragmentation following exposure to LKT. Preincubation of LKT with a neutralizing anti-LKT monoclonal antibody inhibited LKT-induced DNA fragmentation. Electrophoresis of DNA from bovine lymphocytes treated with 0.1 TU ml(-1) LKT demonstrated the typical 'ladder' pattern of internucleosomal DNA cleavage, the hallmark of apoptosis associated with activation of endonucleases. LKT-induced DNA fragmentation was inhibited by 0.5 mM ZnCl2, an endonuclease inhibitor. The results indicated that LKT at low concentrations induced apoptotic cell death of bovine lymphocytes, which may play a role in initiation and persistence of P. haemolytica infection.

A putative leucine zipper activator of Pasteurella haemolytica leukotoxin transcription and the potential for modulation of its synthesis by slipped-strand mispairing.

A Pasteurella haemolytica cosmid clone that activates leukotoxin transcription in Escherichia coli has been isolated. The activator locus, alxA, is part of a continuous open reading frame that includes the type I hsdM methylase gene. AlxA and HsdM peptides are processed from a precursor, and translation of the polyprotein can be modulated by slipped-strand mispairing across a pentanucleotide repeat, ACAGC, within the 5' end of alxA-hsdM. Extracts containing AlxA can bind to a leukotoxin promoter fragment.

Growth of Pasteurella haemolytica and production of its leukotoxin in semi-defined media.

OBJECTIVE: To develop semi-defined media that support growth of the bovine pathogen, Pasteurella haemolytica, and use them to examine production of leukotoxin and an arginine-binding protein by this organism. SAMPLE POPULATION: 10 P haemolytica A1 strains and 1 P multocida strain. PROCEDURE: Bacterial strains were cultivated at 37 C in media containing various amino acids, carbon sources, vitamins, and cofactors, and absorbance (OD600) was measured. Leukotoxin and arginine-binding protein production were assessed by immunoblot analysis. RESULTS: Optimal growth required supplementation with 0.1% fetal bovine serum, gelatin, or purified bovine serum albumin. Calcium pantothenate and thiamine were essential for growth, and a variety of carbon sources could be utilized. In the complete medium, 15 amino acids were included; however, in the minimal medium, no amino acids were required. All strains (except P multocida) grew in the complete medium and 7 grew well in the minimal medium. Leukotoxin was not produced when amino acids were limiting, but could be enhanced by addition of 0.2% NH4SO4. Production of the arginine-binding protein was not affected by nitrogen availability or by presence of L-arginine. CONCLUSIONS: Two media that support good growth of P haemolytica strains were developed. The minimal medium is simple to prepare and manipulate and its use revealed a potential role of nitrogen availability in the regulation of leukotoxin expression. CLINICAL RELEVANCE: Creation of these media will permit continued studies of the response of P haemolytica to environmental conditions that may mimic those encountered in the bovine respiratory tract during shipping.

Generation of targeted nonpolar gene insertions and operon fusions in Pasteurella haemolytica and creation of a strain that produces and secretes inactive leukotoxin.

An efficient method for targeted gene inactivation and generation of chromosomal gene fusions in Pasteurella haemolytica has been devised and used to create an lktC::cat operon fusion by allelic exchange at the leukotoxin gene cluster (lktCABD). A copy of the lktC gene was insertionally inactivated by using a nonpolar, promoterless cat cassette and then delivered into P. haemolytica on a shuttle vector. Plasmid incompatibility was used to detect clones where double recombination events had occurred at the chromosomal locus. The insertion in lktC did not affect expression of the downstream genes, and the mutant strain secreted an antigenic proleukotoxin that was neither leukotoxic nor hemolytic. Expression of the lktC gene in trans restored the wild-type phenotype, confirming that LktC is required for activation of the proleukotoxin to the mature leukotoxin. Construction of the lktC::cat operon fusion allowed us to quantitate leukotoxin promoter activity in P. haemolytica and to demonstrate that transcription was maximal during early logarithmic growth phase but was reduced following entry into late logarithmic phase. This allelic exchange system should be useful for future genetic studies in P. haemolytica and could potentially be applied to other members of Haemophilus-Actinobacillus-Pasteurella family, where genetic manipulation is limited.

Plasmids for heterologous expression in Pasteurella haemolytica.

New cloning and expression vectors that replicate both in Pasteurella haemolytica and in Escherichia coli were constructed based on a native sulfonamide (SuR) and streptomycin (SmR) resistant plasmid of P. haemolytica called pYFC1. Each shuttle vector includes an MCS and a selectable antibiotic resistance marker that is expressed in both organisms. Plasmid pNF2176 carries the P. haemolytica ROB-1 beta-lactamase gene (blaP, ApR) and pNF2214 carries the Tn903 aph3 kanamycin resistance (KmR) element. The expression vector, pNF2176, was created by placing the MCS downstream of the sulfonamide gene promoter (PsulII) on pYFC1; this was used to clone and express the promoterless Tn9 chloramphenicol resistance gene (cat, CmR) in P. haemolytica (pNF2200). A promoter-probe vector (pNF2283) was constructed from pNF2200 by deleting PsulII.

Isolation and characterization of the integration host factor genes of Pasteurella haemolytica.

Using a bacteriophage lambda complementation system in Escherichia coli, we cloned genes encoding subunits of the heterodimeric DNA binding/bending protein, integration host factor, from the bovine pathogen, Pasteurella haemolytica. Complementation of ihfA and ihfB mutations in E. coli demonstrated that the P. haemolytica gene products form functional heterologous heterodimers. The ihfA and ihfB genes encode polypeptides predicted to be 99 and 93 amino acids long, respectively, and are very similar to integration host factor subunits from other Gram-negative bacteria, although phylogenetic analysis indicated that the P. haemolytica sequences are distantly related to those from other bacteria. Most significant amino acid differences were restricted to the amino-terminal domains of the predicted peptides.

The restriction-modification system of Pasteurella haemolytica is a member of a new family of type I enzymes.

Genes encoding the type I restriction-modification (R-M) system of the bovine pathogen, Pasteurella haemolytica, have been identified immediately downstream of a locus that encodes a transcriptional activator of P. haemolytica leukotoxin expression. Type I enzymes are encoded by three genes called hsdM, hsdS and hsdR, and have fallen into three groups, called Ia, Ib and Ic. HsdS provides a sequence recognition function which in concert with HsdM forms an active methyltransferase (MTase). Inclusion of the HsdR subunit in the complex creates an active restriction endonuclease (ENase) capable of cleaving unmethylated target DNA. The P. haemolytica hsdMSR genes were mapped using transposon Tn10d-Cam insertions, and bacteriophage restriction and modification assays in Escherichia coli. We determined the nucleotide sequences of hsdM, hsdS and hsdR, and observed that the deduced amino acid (aa) sequences were very similar to predicted R-M subunits in the respiratory pathogen, Haemophilus influenzae. Phylogenetic comparisons of all known Hsd aa sequences placed the P. haemolytica and H. influenzae proteins into a new group which we labeled the Type Id R-M family. Expression of the P. haemolytica R-M genes in E. coli was inefficient and is likely to be a consequence of the unusual codon usage in P. haemolytica genes.

Binding-protein-dependent arginine transport in Pasteurella haemolytica.

A periplasmic arginine transport system that is a member of the ATP -dependent transport superfamily was identified in Pasteurella haemolytica. The gene encoding the periplasmic binding protein (lapT) was cloned and the protein overexpressed in Escherichia coli. LapT was purified to homogeneity using a modified osmotic shock procedure and anion-exchange column chromatography. Filter-binding assays established that LapT is an L-arginine-binding protein. Various amino acids were tested for their ability to inhibit L-arginine binding to LapT. When present in 100-fold excess, only L-arginine, D-arginine and citrulline competed with L-arginine for binding. Arginine transport in P. haemolytica whole cells was competitively inhibited by the same amino acids, suggesting that the LapT permease specifically transports L-arginine. The dissociation constant for the L-arginine-LapT complex was 170 nM and the stoichiometry of binding was approximately 0.8 mol L-arginine (mol LapT)-1. A polyclonal antibody raised against the purified protein permitted detection of LapT in P. haemolytica periplasmic fractions.

Static DNA bending and protein interactions within the Pasteurella haemolytica leukotoxin promoter region: development of an activation model for leukotoxin transcriptional control.

In this study, we define cis-acting elements involved in regulation of the Pasteurella haemolytica leukotoxin promoter. In place of a canonical promoter -35 sequence, the leukotoxin promoter contains four adenine-rich repeats of sequence CA6(C/T)A, phased at approximately 10-base intervals. DNA fragments containing these repeats exhibit retarded mobility in polyacrylamide gels and permitted identification of a static DNA bend in the promoter -70 region. Deletion of the static DNA bend caused a two-fold reduction of leukotoxin transcription in Escherichia coli, suggesting that it is involved in promoter regulation. Three putative upstream activator sites (UAS), similar to those that bind the NifA activator in Klebsiella pneumoniae, are found 130 bp upstream from the transcription start site and are protected from DNase I cleavage by a P. haemolytica-specific factor. The promoter region also binds the DNA bending protein, the integration host factor (IHF), although IHF mutations do not affect its expression in E. coli. The arrangement of these elements suggests that leukotoxin expression is activated by a factor that interacts with the UAS and regulates transcription initiation at a distance via DNA looping. Activation and DNA bending may also influence a second, divergent promoter that lies 340 bp upstream from the leukotoxin start site.

Expression of the Pasteurella haemolytica leukotoxin is inhibited by a locus that encodes an ATP-binding cassette homolog.

Multicopy and single-copy chromosomal fusions between the Pasteurella haemolytica leukotoxin regulatory region and the Escherichia coli beta-galactosidase gene have been constructed. These fusions were used as reporters to identify and isolate regulators of leukotoxin expression from a P. haemolytica cosmid library. A cosmid clone, which inhibited leukotoxin expression from multicopy and single-copy protein fusions, was isolated and found to contain the complete leukotoxin gene cluster plus additional upstream sequences. The locus responsible for inhibition of expression from leukotoxin-beta-galactosidase fusions was mapped within these upstream sequences, by transposon mutagenesis with Tn5, and its DNA sequence was determined. The inhibitory activity was found to be associated with a predicted 440-amino-acid reading frame (lapA) that lies within a four-gene arginine transport locus. LapA is predicted to be the nucleotide-binding component of this transport system and shares homology with the Clp family of proteases.

Mutation of the disulfide loop in staphylococcal enterotoxin A. Consequences for T cell recognition.

The hallmark of T cell responses to staphylococcal enterotoxins (SE) and other super-Ag is a selective stimulation of cells expressing particular TCR-V beta segments. Our previous studies suggested that the disulfide loop in SE is critical for their interaction with the TCR. To investigate this concept in further detail we constructed disulfide loop mutants of staphylococcal enterotoxin A (SEA), and examined these altered toxins for mitogenicity, class II MHC binding, and V beta specificity. We found that substitutions of either Cys-96 or Cys-106 decreased mitogenicity by 100-fold without significantly affecting class II binding or resistance of the molecule to proteolysis. Several mutants lost the capacity to stimulate V beta 11+ cells, except a Cys-106----Gln mutant for which V beta 11-stimulatory activity was increased. By contrast, mutants containing Cys----Ala substitutions acquired the capacity to stimulate V beta 6+ cells. Despite these effects of V beta specificity, all mutants retained the predominant preference of SEA for V beta 3+ cells. Neither exchange of regions flanking the loop in SEA with corresponding residues in SEB, nor conversion of the entire loop region of SEA to that of SEE, were associated with transfers of V beta specificity. Our results suggest that the disulfide loop in SEA contributes to toxin avidity for the TCR, rather than specificity for particular V beta.

Secretion and expression of the Pasteurella haemolytica Leukotoxin.

The Pasteurella haemolytica leukotoxin gene cluster (lktCABD) is homologous to the Escherichia coli hemolysin locus (hlyCABD). Since the cloned leukotoxin (LktA) is not secreted from E. coli cells, a heteroplasmid complementation system was developed that permits secretion of the leukotoxin from cells expressing the hemolysin transport proteins HlyB and HlyD. We observed that the secreted leukotoxin protein had weak hemolytic activity when activated by either the HlyC or LktC proteins and that LktC expressed in E. coli could confer weak hemolytic activity upon hemolysin. Thus, it appears that the accessory proteins of the leukotoxin and hemolysin gene clusters are functionally similar, although their expression in E. coli is not equivalent. Northern (RNA) blot analysis of the P. haemolytica leukotoxin gene cluster revealed a major 3.5-kilobase transcript that includes the lktC and lktA genes. The start site for this transcript mapped to a cytosine residue 30 nucleotides upstream from the putative start of lktC; a similar initiation site was observed in E. coli, although adjacent cytosine and adenine residues were also utilized. The 3.5-kilobase transcript terminated near the rho-independent terminator structure between lktA and lktB, but transcription may continue, via antitermination or de novo transcription initiation, into the downstream lktB and lktD genes. We propose that the lack of LktB and LktD function in E. coli is a result, at least in part, of poor lktBD transcription and suggest that a P. haemolytica-specific regulator is required for optimal expression of the leukotoxin genes.

Mutational and physiological analyses of plasmid pT181 functions expressing incompatibility.

Plasmid pT181 is a small multicopy plasmid from Staphylococcus aureus that belongs to incompatibility group 3 and expresses two distinct types of incompatibility, Inc3A and Inc3B. Inc3A incompatibility is expressed by the primary replication control determinant, copA, which specifies two small transcripts, RNA I and RNA II, that jointly inhibit the synthesis of the rate-limiting initiator protein, RepC. Inc3B incompatibility is expressed by the leading strand replication origin and is due to competition for RepC. The copA region from each of 11 different pT181 copy number mutants was cloned onto the pT181-compatible vector, pE194, and tested for its ability to inhibit the replication of pT181 and its copy number mutants. The pT181 replication origin was also cloned and tested for its ability to inhibit the replication of the same plasmids. In general copA mutations that alter the production or sequence of RNA I and RNA II greatly reduced or completely eliminated Inc3A activity. Unlike the wild-type, all of the copy mutants were resistant to Inc3B inhibition. The separately cloned wild-type copA and ori regions each reduced the copy number of pT181 in proportion to their gene dosage, but neither blocked replication completely. It is proposed that the cloned Inc determinants cause incompatibility by interfering with the plasmid's copy correction mechanism; this interference destabilizes the plasmid even under conditions where its average copy number is not greatly reduced.

DNA sequence of the Pasteurella haemolytica leukotoxin gene cluster.

Bovine serum was used to identify a recombinant phage clone carrying the Pasteurella haemolytica leukotoxin gene. This fragment produced the 102-kD leukotoxin and several smaller P. haemolytica-specific protein antigens in Escherichia coli. An additional contiguous fragment, containing sequences upstream from the leukotoxin gene. Using these clones, we determined the nucleotide sequence of a 7745-bp region that included four open reading frames: an upstream gene, lktC; the leukotoxin gene, lktA; and two downstream genes, lktB, and lktD. The predicted molecular weights of the proteins encoded by these genes were 19.9, 102, 79.6, and 54.7 kD, respectively. These genes and their predicted proteins were similar in organization and in sequence to the corresponding elements of the gene cluster that encodes an E. coli alpha-hemolysin and its activation and secretion functions. Expression of the leukotoxin was enhanced in E. coli, by fusing the gene to the lac promoter. Under these conditions the leukotoxin was not secreted into the medium, as it is in P. haemolytica. However, in the presence of the alpha-hemolysin genes, the leukotoxin was secreted into the medium, demonstrating functional complementation by the hemolysin secretory system.

Plasmid repopulation kinetics in Staphylococcus aureus.

We have analyzed the kinetic route by which the indirectly controlled Staphylococcus aureus plasmid, pT181, responds to and corrects fluctuations in copy number. The kinetics of copy number correction from low to steady-state levels (termed repopulation) were determined using two different methods of copy number reduction. Thermosensitive replication (Tsr) mutants of pT181 were grown at nonpermissive temperatures to lower copy number and then shifted to a permissive temperature to allow repopulation. After the downshift, both wild-type and copy mutant plasmids, with active inhibitors, exhibited a burst of exponential replication that resulted in a two- to threefold overshoot of normal steady-state copy numbers. This was followed by inhibition of replication and eventual reestablishment of the steady-state replication rate. Similar replication kinetics were observed when these plasmids were introduced into naive cells by high-frequency transduction. By contrast, a pT181 copy mutant with a nonfunctional inhibitor-target regulation did not overshoot its steady-state copy number, but instead repopulated asymptotically. These results suggest that at low copy numbers, pT181 and its derivatives replicate at near-maximal rates and overshoot prior to the establishment of an inhibitory concentration of repressor. The maximal replication rate is independent of the plasmid's cop genotype. As the copy number increases, inhibitor accumulates and eventually reduces the replication rate. In the absence of an active inhibitor, the steady-state copy number is established at a level that must be limited by some other invariant factor.