Mechanical removal of F pili, type I pili, and flagella from Hfr and RTF donor cells and the kinetics of their reappearance

The effect of mechanical agitation (blending) on the removal of F pili, type I pili, and flagella from Hfr (high-frequency recombinant) and resistance transfer factor (RTF) fi(+)Escherichia coli cells was studied by electron microscopy. The reduction in number and length of appendages was measured as a function of blendor speed under standard conditions of temperature, medium, cell density, and blendor configuration. F pili and flagella were removed within the same narrow range of blendor speeds. Type I pili were removed within a higher and broader range of speeds. The speed which reduced the average length of type I pili to 50% was 3.5 times the speed which reduced the average length of F pili to 50%. None of the speeds employed inhibited cell growth, viability, or the ability to produce cell appendages. The kinetics of reappearance of F pili and type I pili after removal by blending were also different. F pili grew out very rapidly, reaching 50% of their full length in 30 sec and their full length in 4 to 5 min. The number of attached F pili per cell also increased rapidly, reaching a constant value in 4 to 5 min. After 5 min, F pilus lengths were distributed around a modal value of about 1.2 mum, and the numbers of F pili per cell were distributed according to a Poisson distribution, with an average of 1.0 per cell. These reappearance kinetics, length distributions, and number distributions are consistent with a model of F-pilus outgrowth in which new F pili appear at random locations on the cell surface at an average rate of about once every 4 min, grow to their characteristic length in about 4 min, and then separate from the cell. F pili which had separated could absorb to the cells, leading to the presence of two classes of F pili on cells: those in the process of natural out-growth and those attached by absorption. Type I pili increased in length much more slowly than did F pili, although the fraction of cells having visible type I pili increased very rapidly after blending because of the large number of type I pili per cell. The fraction of flagellated cells increased even more slowly, reaching only 30% of the unblended fraction in 30 min. The application of blending spectra and reappearance kinetics to the identification of cell functions with surface structures is discussed.     

Some Effects of Temperature on the Growth of F Pili

The effect of temperature on the production of F pili by an F(+) strain of Escherichia coli B/r was studied by electron microscopy and by a technique involving serum-blocking power. The latter method is based on the ability of F pili to adsorb F pili antibody which inhibits male-specific phage infection. The total amount of pili in a sample was estimated by serum-blocking power; the length of F pili and number per cell was determined by electron microscopy. Cell extracts prepared by sonic oscillation lacked serum-blocking power, suggesting that F pili are not present in the cytoplasm. The number of F pili per cell varied with the growth temperature, but the average length of F pili remained constant. Maximum number of pili per cell occurs between 37 and 42 C; below 37 C the number decreases, reaching zero at about 25 C. When cells are grown at 37 C, blended, and resuspended in fresh media at 25 C, they make F pili. These pili are probably assembled from a pool of subunits that were synthesized during growth at 37 C. The rates of assembly at 25 and 37 C, as judged by the rate of increase in length of F pili, are similar. When cells were grown at 25 C and shifted up to 37 C, there was a 30-min lag in pili production followed by a period of rapid outgrowth. When cells were shifted down from 37 to 20 C, outgrowth (assembly) of pili ceased, and approximately 50% of the attached pili were released in 2 min. No release was observed when cells were shifted to 0 C. This suggests that pili may be released from the cell by a mechanism that requires metabolic activity, but not the outgrowth of F pili.     

Mechanism of conjugation and recombination in bacteria. XXI. Role of F factor genes in post-conjugational recombination in Escherichia coli K-12

Temperature sensitive dnaA recipient crossed at the restrictive temperature with HfrH, free from contaminating F+ cells, forms recombinants almost as proficiently as at the permissive temperature. The merozygotes are able to synthesize DNA at 42 degrees C, although the recipient and donor cells do not incorporate 3H-thymine. A substantial fraction of Lac+ recombinants, irrespective of the mating temperature, is temperature resistant (42 C-R); 15% from among those mated at 35 C and 30% from those mated at 42 C. The presence of dnaA mutation in these Lac+ 42 C-R recombinants was ascertained by co-transduction with ilv. Cell division at 42 C is inhibited in the Lac 42 C-R recombinants by acridine orange. The presence of F factor DNA in these recombinants was demonstrated directly by DNA: DNA hybridization. Suppression of dnaA mutation in Lac+ 42 degrees C-R recombinants and their sensitivity to acridine orange at 42 degrees C suggests that at least part of the F factor is integrated into the recombinant chromosome. A large fraction of the Lac+ 42 degrees C-R recombinants (up to 80%) is sensitive to male phage R17 and fertile. In crosses with HfrC there is a marked decrease of recombination frequency at 42 degrees C in the dnaA recipient. The fraction of Lac+ 42 degrees C-R recombinants is low (up to 10%) and the 42 degrees C-R recombinants are neither sensitive to male phage nor fertile. The results are discussed on the basis of the previously proposed model of post-conjugational recombination.     

Effects of growth inhibitors and ultraviolet irradiation on F pili

The effects of chloramphenicol, nalidixic acid, mitomycin C, NaCN, and ultraviolet irradiation at 253.7 nm on F pili production by Escherichia coli cells was studied by electron microscopy. The results show that cells contain pools of pili protein, and that assembly does not require synthesis of protein or deoxyribonucleic acid (DNA). NaCN (2 x 10(-2)m) prevents the reappearance of pili and causes existing pili to disappear quickly from the cell surface. This suggests that energy is used in the assembly of pili and to retain pili on the cell. Cells irradiated with high doses (10(4)ergs/mm(2)) of 253. 7 nm light produce fewer pili, and these are shorter than normal. Dose-response curves for number of pili per cell and length of pili resemble single hit kinetics, showing 37% survival at 10(4) ergs/mm(2) and 2 x 10(4) ergs/mm(2), respectively. This suggests that DNA is at the site where pili are produced, and that it may be involved in the assembly of pili.     

Identification of uracil as a major lesion in E. coli DNA following the incorporation of 5-bromouracil, and some of the accompanying effects

Cultivation of E. coli cells in the presence of 5-bromodeoxyuridine (BUdR) leads to formation of lesions in the cellular DNA which affect its secondary structure, as reflected by changes in temperature profiles. Such DNA contains single-stranded regions susceptible to endonuclease S1. One of the major sources of the BU-induced lesions appears to be dehalogenation of incorporated 5-bromouracil (BU) residues, with accompanying formation of uracil. The presence of uracil residues in such DNA was demonstrated directly by chromatography of hydrolyzates, and by the susceptibility of such residues to uracil-DNA glycosylase. The number of uracil residues was dependent on the extent of damage in the DNA, and decreased during the DNA repair that accompanied reactivation of bromouracil-inactivated cells. Dehalogenation of incorporated BU presumably results in formation of apyrimidinic sites by uracil-DNA glycosylase, and then single-strand nicks either by AP-endonuclease and/or dehalogenation. The findings are relevant to the mechanism of BU-induced mutagenesis.     

Involvement of DNA lesions and SOS functions in 5-bromouracil-induced mutagenesis

Mutagenesis resulting from incorporation of 5-bromouracil (BU) in the DNA of E. coli K12 proceeds largely (approximately 80%) via misrepair of the lesions resulting from incorporation of the analogue. The premutational lesions are due principally to dehalogenation of incorporated BU residues, leading to formation of uracil residues, and removal of these by uracil-DNA glycosylase with formation of apyrimidinic sites. In the xthA mutant, defective in AP endonuclease, there is a several-fold increase in the frequency of BU-induced mutations, underlining the importance of AP sites in BU-induced mutagenesis. Premutational lesions undergo mutation frequency decline (MFD), which is subject to delay in the xthA mutant, pointing to some role of AP endonuclease in MFD, and further supporting involvement of AP sites in BU-induced mutagenesis. Efficient BU mutagenesis is dependent on the functions of the genes recA and umuC and non-mutated lexA protein.     

Lactic acid secretion by human neutrophils. Evidence for an H+ + lactate- cotransport system.

The pathway by which L-lactate (Lac) crosses the plasma membrane of isolated human neutrophils was investigated. The influx of [14C]Lac from a 2 mM Lac, 145 mM Cl-, 5.6 mM glucose medium was approximately 1.5 meq/liter of cell water.min and was sensitive to the organomercurial agent mersalyl (apparent Ki approximately 20 microM), to alpha-cyano-4-hydroxycinnamate (CHC), the classical inhibitor of monocarboxylate transport in mitochondria, and to UK-5099 (apparent Ki approximately 40 microM), a more potent analogue of CHC. Transport was also strongly blocked (greater than 80%) by 1 mM of either 3,5-diiodosalicylic acid, MK-473 (an indanyloxyacetate derivative), or diphenyl-amine-2-carboxylate, and by 0.4 mM pentachlorophenol, but not by 1 mM ethacrynic acid, furosemide, or the disulfonic stilbenes SITS or H2DIDS. One-way [14C]Lac efflux from steady-state cells amounted to approximately 6 meq/liter.min and was likewise affected by the agents listed above. Influx, which was membrane potential insensitive and Na+ independent, displayed a strong pH dependence: extracellular acidification enhanced uptake while alkalinization inhibited the process (pK' approximately 5.7 at 2 mM external Lac). The rate of [14C]Lac influx was a saturable function of external Lac, the Km being approximately 7 mM. Steady-state cells exhibited an intracellular Lac content of approximately 5 mM and secreted lactic acid into the bathing medium a a rate of approximately 4 meq/liter.min. Secretion was completely suppressed by 1 mM mersalyl which inactivates the carrier, leading to an internal accumulation of Lac. That the Lac carrier truly mediates an H+ + Lac- cotransport (or formally equivalent Lac-/OH- exchange) was documented by pH-stat techniques wherein an alkalinization of poorly buffered medium could be detected upon the addition of Lac; these pH changes were sensitive to mersalyl. Thus, the Lac carrier of neutrophils possesses several features in common with other monocarboxylate transport systems in erythrocytes and epithelia.     

Effect of pH on the base-mispairing properties of 5-bromouracil during DNA synthesis

We have utilized an electrophoretic assay of misincorporation to investigate the possibility that ionization of 5-bromouracil (BU) may play a role in its mispairing during DNA synthesis in vitro. We examined the effects of increasing pH on the relative rates of formation of BU.G and T.G mispairs during chain elongation catalyzed by various DNA polymerases. For the Klenow fragment of Escherichia coli DNA polymerase I, increasing pH facilitated BU.G mispair formation (relative to T.G mispairing) when BU was present in the template strand. This effect showed a strong dependence on sequence context. Increasing pH had little effect on the relative rate of misincorporation of BrdUMP versus dTMP (at template G) by the Klenow polymerase. Misincorporation opposite template BU residues catalyzed by Maloney murine leukemia virus DNA polymerase and DNA polymerase beta (Novikoff hepatoma) also increased with pH, but for these two enzymes, there was no apparent dependence on sequence context. With T4 DNA polymerase and E. coli DNA polymerase III holoenzyme, a similar occurrence of BU.G and T.G mispairing during polymerization was observed, whether BU was present in the template or in the incoming nucleotide, and there was little effect of pH. The results reported here are consistent with a mispairing mechanism for template BU wherein the anionic form of the base mispairs with G.     

DNA transfer occurs during a cell surface contact stage of F sex factor-mediated bacterial conjugation.

Donor bacteria containing JCFL39, a temperature-sensitive traD mutant of the F sex factor, were used at the nonpermissive temperature to accumulate stable mating pairs with recipient cells. At this stage in conjugation, extracellular F pili were removed by treatment with 0.01% sodium dodecyl sulfate. Upon then shifting to the permissive temperature for JCFL39, transfer of the F plasmid was observed. The mating pairs that were accumulated with JCFL39 at the nonpermissive temperature were readily observed by electron microscopy in wall-to-wall contact with the recipient bacteria. These results demonstrate that the traD product, which is known to be required in transferring DNA to a recipient bacterium, acts after the stage at which extracellular F pili are required. In addition, we concluded that DNA transfer takes place while donor and recipient cells are in surface contact and not necessarily through an extended F pilus as envisioned in some models of bacterial conjugation.     

Sensitization of Escherichia coli C to gamma-radiation by 5-bromouracil incorporation.

Escherichia coli C cells, unifilarly substituted with 5-bromouracil (BrUra) were 2-25 times as sensitive as unsubstituted cells to killing by gamma-irradiation under aerobic conditions. The yield of DNA double-strand breaks in BrUra-substituted cells was increased by a factor only 1-55, suggesting that other lesions also contribute to cell-killing. Alkaline sucrose density gradient analysis of the 3H-thymine labelled DNA strand showed there was less repair of gamma-ray-induced single-strand breaks when BrUra was in the complementary strand. Since there are more of these unrepaired breaks than can be accounted for by BrUra-induced DNA double-strand breakage, some fraction of the lethal events in BrUra-substituted E. coli cells may be unrepaired DNA single-strand breaks.     

Specific Role of Sex Pili in the Effective Eliminatory Action of Sodium Dodecyl Sulfate on Sex and Drug Resistance Factors in Escherichia coli

Evidence is presented for the specific role of sex pili in the eliminatory action of sodium dodecyl sulfate (SDS) on sex (F) and drug resistance (R) factors in Escherichia coli K-12 strains leading to their loss. SDS at 0.03% concentration lysed JE3100 F(8) (+) (F-gal)/gal(-)fla(-)pil(-) in Penassay broth after they had grown exponentially and reached maximum growth to the extent that the agent at concentrations higher than 1% did. However, the agent was only effective in eliminating sex factors from JE3100 in high frequencies at concentrations higher than 1%. Increase of osmotic pressure of the culture with SDS at concentrations as low as 0.03 to 0.1% by addition of sucrose led to the substantial increase of elimination efficiency. Reconstruction experiments between F(8) (+) and F(-) cells in the SDS culture revealed the selective growth of F(-) cells as well as a delay of maximum growth of F(-) variants derived from F(8) (+) cells, compared with those of F(8) (+) cells, as well as F(-) cells originally added to the culture. The agent was not very effective in eliminating sex factors from JE3427 F(8)m(+)5/fla(-)pil(-) cells which lack the function of production of F pili. F(8)m(+)5 cells showed a sensitivity toward SDS intermediate between those of F(8) (+) and F(-) cells. SDS was further effective in eliminating R factors from KE132 R(100-1) (+)/fla(-)pil(-) cells in high efficiency; however, the action was not efficient with KE133 F(100) (+) cells possibly with fewer sex pili than R(100-1) (+). Action of acridine orange on these F(+) or R(+) strains was found to be different in some aspects from that of SDS.     

Purification of Sex Pili from Escherichia coli Carrying a Derepressed F-Like R Factor

A procedure for the purification of sex pili is described. Escherichia coli K-12 carrying Rldrd19 was grown in nutrient broth and blended at the time of peak sex pilus production. The cells were removed by centrifugation, and the supernatant fraction was concentrated, dialyzed, and clarified in an ultrafiltration system. After an additional blend and a clearing spin, the material was centrifuged in a CsCl gradient, and the fractions containing the sex pili were subjected to isoelectric focusing. About 5 mg of intact pili of approximately 98% purity were obtained by this method from about 100 g (wet weight) of cells.     

Influence of starvation for methionine and other amino acids on subsequent bacterial deoxyribonucleic acid replication

Billen, Daniel (University of Texas M. D. Anderson Hospital and Tumor Institute, Houston, Tex.), and Roger Hewitt. Influence of starvation for methionine and other amino acids on subsequent bacterial deoxyribonucleic acid replication. J. Bacteriol. 92:609-617. 1966.-A study has been made of the subsequent replicative fate of deoxyribonucleic acid (DNA) synthesized during amino acid starvation by several multiauxotrophic strains of Escherichia coli. Using radioisotopic and density labels and a procedure whereby total cellular DNA is analyzed, we have confirmed and extended a recent report that the DNA made during amino acid starvation behaves anomalously during subsequent DNA replication. When 5-bromouracil (BU) serves as the density lable, 40% or more of the DNA synthesized during starvation will subsequently fail to replicate during three cell generations. Selective amino acid effects were noted. In two methionine-requiring bacteria, methionine deprivation appeared to be of singular importance in influencing the subsequent replicative fate of the DNA made in its absence.When a non-BU density label (N(15), C(13)) was utilized, the effects of amino acid starvation were less obvious. Although the DNA synthesized during complete amino acid starvation in a methionine-requiring E. coli was subsequently more slowly replicated, most of the DNA was finally duplicated during three generations of growth. If methionine was present during starvation for other required amino acids, the subsequent replication rate of the DNA synthesized during this time was more nearly normal, and complete replication was observed. The results have been interpreted as indicating that DNA synthesized during amino acid starvation, and especially during methionine starvation, is somehow altered, and that BU substitution for thymine may interfere with the restoration of such DNA to its replicative state.     

DNA synthesis and induced mutations in the presence of 5-bromouracil II. Induction of mutations

Summary An investigation has been carried out on the heritable changes caused by the incorporation of 5-bromouracil (BU) into the DNA of a number of amino acid-requiring derivatives of a thymineless mutant ofEscherichia coli 15. Results revealed that the number of mutations induced by the analogue was linearly related to the amount of BU incorporated into DNA. DNA replication was necessary in the presence of BU for the induction of mutations, but concomitant RNA and protein synthesis were not necessary. Induced revertants were found to arise in either one of two distinct patterns: 1. in a single burst one replication after incorporation of BU, with no further increase upon subsequent DNA replication, and 2. continually with each additional DNA replication. Based on theFreese theory, these patterns allowed tentative identification of the base pairs involved. Further, the number of DNA replications necessary for the expression of BU induced reversions was determined. It was found that a transition from A:T to G:C required two DNA replications in addition to incorporation of BU, while the transition C:G to A:T required only one. Results obtained by the use of BU were compared with results obtained using AP. It was found that the pattern of mutant induction and the number of DNA replications necessary for the expression of each mutant were the same with AP as with BU. This implied that AP preferentially replaces adenine. As the number of DNA replications necessary for the expression of BU-and AP-induced reversions was the same for each mutant tested, it was concluded that both strands of the DNA molecule were necessary to carry the genetic message. An attempt was made to synchronize the replication of DNA and, thereby to synchronize the appearance of mutations during one replication cycle. Revertants, however, occurred uniformly throughout the cycle. The results were further discussed in relation to existing models of DNA replication.With 10 Figures in the TextSupported in part by grants from the American Cancer Society, the U.S. Public Health Service and the National Science Foundation administered by ProfessorF. J. Ryan.     

Induction of SOS functions in Escherichia coli by lesions resulting from incorporation of 5-bromouracil into DNA

Lesions induced by 5-bromouracil (BU), after its incorporation into DNA, led to effective induction of prophage lambda and W reactivation (or BU reactivation). Prophage induction due to incorporated BU occurred only with the wild-type prophage, and not for the lambda c1857 mutant with a thermosensitive repressor. Antipain, a protease inhibitor, inhibited wild-type prophage induction 70-90%. This indicates that BU-induced lesions may induce the SOS repair system. The finding that such lesions provoke BU reactivation permits the inference that BU-induced mutagenesis also proceeds via involvement of the error-prone repair system, and not directly as a result of base-pairing errors. Genetic evidence suggests that induction of the SOS repair system as a result of incorporation of BU into DNA is linked to the subsequent appearance of uracil residues and apyrimidinic sites, resulting from dehalogenation of incorporated BU. Apyrimidinic sites appear to be more effective than uracil residues in induction of the SOS system.     

5-Bromouracil-tolerant mutants of Bacillus subtilis

5-Bromouracil (BU)-tolerant mutants of Bacillus subtilis 23 (thy his) have been isolated. Several classes of tolerant mutants were obtained by a sequential selection procedure. The classes can be distinguished by their relative BU tolerance as well as several other phenotypic characteristics. The mutants can grow for an extended period of time in minimal medium supplemented with amino acids and BU, in which the sensitive parental strain (Bu(+)) undergoes rapid cell death. Both mutants But-1 and But-1310 have a greater rate of deoxyribonucleic acid (DNA) synthesis by a factor of two in the presence of BU than Bu(+), But-1 being somewhat faster than But-1310. The preferential incorporation of thymine to BU of But-1 is about half that of the Bu(+) strain during DNA replication in minimal medium supplemented with 10 mug of BU/ml and 1 mug of thymine/ml. It is not known at what step or steps this reduction in selectivity occurs.     

5-Bromouracil disrupts nucleosome positioning by inducing A-form-like DNA conformation in yeast cells

5-Bromodeoxyuridine (BrdU) modulates expression of particular genes associated with cellular differentiation and senescence. Our previous studies have suggested an involvement of chromatin structure in this phenomenon. Here, we examined the effect of 5-bromouracil on nucleosome positioning in vivo using TALS plasmid in yeast cells. This plasmid can stably and precisely be assembled nucleosomes aided by the α2 repressor complex bound to its α2 operator. Insertion of AT-rich sequences into a site near the operator destabilized nucleosome positioning dependent on their length and sequences. Addition of BrdU almost completely disrupted nucleosome positioning through specific AT-tracts. The effective AT-rich sequences migrated faster on polyacrylamide gel electrophoresis, and their mobility was further accelerated by substitution of thymine with 5-bromouracil. Since this property is indicative of a rigid conformation of DNA, our results suggest that 5-bromouracil disrupts nucleosome positioning by inducing A-form-like DNA.     

Comparative Biochemical Studies on F and EDP208 Conjugative Pili

EDP208 pili are encoded by a derepressed derivative of a naturally occurring lac plasmid, F(0)lac (incompatibility group FV), originally isolated from Salmonella typhi. EDP208 pili are serologically unrelated to F pili and do not promote infection by F-specific ribonucleic acid bacteriophages. However, they do confer sensitivity to the F-specific filamentous deoxyribonucleic acid phages. EDP208-containing cells are multi-piliated and contain approximately 20 pili per cell. These pili contain a single polypeptide subunit of 11,500 daltons. EDP208-specific RNA phages were readily isolated from local sewage. These phages were somewhat smaller in diameter than the F-specific ribonucleic acid phages and absorbed relatively weakly to EDP208 pili. Comparing EDP208 pilin to F, it was found that both contain the equivalent of two to three hexose units per subunit as well as blocked N-termini. EDP208 pilin contains one covalently linked phosphate residue per subunit, whereas the F pilin subunit contains two such residues. Although notable differences were found in the case of three or four amino acids, the overall amino acid compositions of F and EDP208 were very similar. Moreover, the tryptic peptide maps of the two proteins contained seven peptides with similar mobilities, suggesting considerable homology in their amino acid sequences. Substantial similarities were also noted in the secondary structures of F and EDP208 pilin on the basis of circular dichroism studies. The alpha-helix content of both proteins was calculated to be 65 to 70%. X-ray fiber diffraction studies have indicated that the arrangements of subunits in F and EDP208 pili are also similar. It was concluded that F and EDP208 pili are closely related structures.     

Synthesis and hybridization properties of DNA-PNA chimeras carrying 5-bromouracil and 5-methylcytosine

The preparation of 5-bromouracil and 5-methylcytosine peptide nucleic acid (PNA) monomers is described. These PNA monomers were used for the preparation of several DNA-PNA chimeras and their hybridization properties are described. The substitution of cytosine by 5-methylcytosine in DNA-PNA chimeras increased duplex stability while substitution of thymine by 5-bromouracil maintained it. Moreover, binding of DNA-PNA chimeras to double-stranded DNA to form triple helices was studied. In contrast to DNA, the presence of 5-methylcytosine and 5-bromouracil in DNA-PNA chimeras destabilized triple helix.