Differential Effect of Polyamines on T4 Morphogenesis

The 5-fluorouracil (5 FU) technique for the phenotypic reversion of amber mutants was used to demonstrate that under certain circumstances, in the presence of putrescine or spermidine, early mutants have an enhanced response to 5 FU, whereas late mutants have a delayed response. Bacteria infected by T4D wild-type bacteriophage did not produce phage in the presence of high putrescine concentrations. Pulse treatments with putrescine showed that the production of lysozyme depends on a putrescine-sensitive process that begins immediately after infection at 26 C and ends at 36 min or even later. The addition of putrescine at any time during the critical period between 0 and 36 min led to a corresponding delay in lysozyme synthesis after the inhibitor was removed. Intracellular phage maturation was delayed by the addition of 100 mumoles of putrescine per ml. Early enzymes were not affected by the diamine, but the level of phage deoxyribonucleic acid was considerably decreased by the inhibitor. The putrescine-sensitive process that affects the timing of maturation is suggested to be the natural process controlling the T4 "clock."     

Dissociation of cellular functions in Bacillus cereus by 5-fluorouracil

Reich, Melvin (The George Washington University School of Medicine, Washington, D.C.), and H. George Mandel. Dissociation of cellular functions in Bacillus cereus by 5-fluorouracil. J. Bacteriol. 91:517-523. 1966.-5-Fluorouracil (FU) produced a marked inhibition of growth and deoxyribonucleic acid (DNA) synthesis in Bacillus cereus 569H. Protein and ribonucleic acid (RNA) synthesis were not specifically inhibited, and proceeded at the rate of turbidometric increase of the cells. Cell-wall synthesis, respiration, and penicillinase production continued in the presence of FU at essentially the control rate. The addition of equimolar concentrations of uracil and FU prevented growth inhibition but did not restore DNA synthesis. The addition of thymidine with FU did not relieve growth inhibition but did restore the DNA content to normal. Thymidine supplementation also increased the quantity of FU, but not uracil, incorporated into RNA and the acid-soluble fraction. The data indicate that inhibition of growth can be dissociated from inhibition of DNA synthesis and that more DNA is present in normal cells than is needed for growth and reproduction.     

Mode of action of 5-fluorocytosine and 5-fluorouracil in dematiaceous fungi

The mode of action of 5-fluorocytosine (5FC) and 5-fluorouracil (5FU) in dematiaceous fungi was studied and compared with results of experiments in yeasts and Aspergillus species. In dematiaceous fungi 5FU is more potent than 5FC. The high activity of 5FU is related to a good and rapid uptake of this compound into the fungus cell. Both compounds exert fungistatic and fungicidal activity. A correlation exists between the amount of 5FU incorporated into RNA and its antifungal activity. The resistance frequency to 5FC varies from 2 x 10(-3) to 1 x 10(-7); resistance frequency to 5FU is generally lower. Addition of 5FC and 5FU to logarithmically multiplying cells inhibits increases of cell numbers and cell constituents after a delay period. The effects on the increase of protein and carbohydrate are more delayed than on the increase of DNA and RNA, indicating unbalanced growth. The concept of a dual biochemical mechanism, i.e. incorporation of 5FU into RNA and formation of 5-fluorodeoxy UMP leading to inhibition of DNA synthesis, previously proposed for the antifungal action of 5FC is also applicable to the action of 5FC and 5FU on the dematiaceous fungi.     

Comparative effects of 5-fluorouracil on strains of Bacillus megaterium

Wachsman, J. T. (University of Illinois, Urbana), S. Kemp, and L. Hogg. Comparative effects of 5-fluorouracil on strains of Bacillus megaterium. J. Bacteriol. 87:1011-1018. 1964.-Growth of Bacillus megaterium strain KM is severely inhibited by 5-fluorouracil (FU). Both thymidine and uridine are required to overcome this inhibition. The addition of uridine alone to a FU-inhibited culture permits good ribonucleic acid (RNA) and protein synthesis for the first 2 hr, but rather poor deoxyribonucleic acid synthesis. Uridine enhances the bactericidal effect of FU, promoting a decrease in the viable count of from 4 to 5 decades in 5 hr. Death begins after a 1-hr lag and is accompanied by hydrolysis of RNA and cell lysis, commencing during the 2- to 5-hr interval. The combination of FU and uridine is not bactericidal, when a methionine auxotroph is deprived of its required amino acid. Substrains of KM, partially resistant to FU, were isolated. Strain T(2) requires only thymidine to overcome the inhibitory effects of FU, whereas strain FU/2 requires only uridine. With a uridine auxotroph of strain KM, FU partially replaces uridine by permitting a small, but reproducible, increase in the amount of protein.     

Transfection: enhancement by assembly protein of bacteriophage R17.

Assembly protein was isolated by DEAE cellulose chromatography from disrupted R17 bacteriophage and reconstituted with purified R17 phage RNA. Following reconstitution, ¹²⁵I labeled assembly protein co-sediments with 27S R17 phage RNA in a sucrose gradient. SDS-polyacrylamide gel analysis of the 27S ¹²⁵I labeled protein-RNA complex confirmed that assembly protein was the only phage protein associated with the RNA. The specific infectivity (PFU/μg RNA) of the R17 phage RNA-assembly protein complex was 35-fold greater than that of R17 phage RNA when assayed on $\text{Escherichia coli}$ spheroplasts. Infectivity of both preparations was destroyed by treatment with pancreatic ribonuclease A. Furthermore, the assembly protein-RNA complex was infectious for intact cells whereas phage RNA was not infectious. Infectivity of this 27S complex for intact cells was totally eliminated by pretreatment with ribonuclease.     

Discriminative effect of rifampin of RNA replication of various RNA bacteriophages.

Rifampin interferes exclusively with RNA replication in vivo of the group I phages MS2, f2, and R17, whereas QbetaRNA replication is unaffected by the drug. In addition, rifampin has a discriminative effect of group I phage RNA replication. In the experimental system employed by us the antibiotic differentially interferes with the synthesis of minus RNA strands in f2, whereas it has almost no effect on the synthesis of progeny plus strands. In MS2, the drug differentially arrests the synthesis of progeny plus strands and almost fails to affect the synthesis of minus RNA strands. In R17 both steps of its RNA replication are affected by rifampin, although each step is only partially (approximately 50%) inhibited. The relation of the present results to the possible role of bacterial proteins and tertiary structure of phage RNA in the process of template recognition is discussed.     

Quantitative analysis of the bacteriophage Qbeta infection cycle

In this study, the infection cycle of bacteriophage Qbeta was investigated. Adsorption of bacteriophage Qbeta to Escherichia coli is explained in terms of a collision reaction, the rate constant of which was estimated to be 4x10(-10) ml/cells/min. In infected cells, approximately 130 molecules of beta-subunit and 2x10(5) molecules of coat protein were translated in 15 min. Replication of Qbeta RNA proceeded in 2 steps-an exponential phase until 20 min and a non-exponential phase after 30 min. Prior to the burst of infected cells, phage RNAs and coat proteins accumulated in the cells at an average of up to 2300 molecules and 5x10(5) molecules, respectively. An average of 90 infectious phage particles per infected cell was released during a single infection cycle up to 105 min.     

Streptomycin Action: Greater Inhibition of Escherichia coli Ribosome Function with Exogenous than with Endogenous Messenger Ribonucleic Acid

Inhibition of protein synthesis by streptomycin was tested in extracts from a strain of Escherichia coli sensitive to streptomycin. Three kinds of messenger ribonucleic acid (RNA) were employed: endogenous cellular RNA, extracted cellular RNA, and phage R17 RNA. Protein synthesis directed by extracted cellular RNA was inhibited three- to fourfold more than protein synthesis directed by endogenous RNA. With R17 RNA as messenger, nearly total inhibition of protein synthesis at initiation was again observed. The greater inhibition of function of extracted RNA, which must initiate new polypeptide chains in vitro, is in accord with the observation that in whole cells streptomycin blocks ribosomes at an early stage in protein synthesis. When streptomycin was added at successively later times during protein synthesis, the subsequent inhibition was progressively less. This was observed with either extracted cellular RNA or phage R17 RNA. A model is presented that can explain the less drastic inhibition by streptomycin of messenger RNA that is already functioning on ribosomes.     

Mutagenesis versus inhibition in the efficiency of extinction of foot-and-mouth disease virus

RNA viruses replicate near the error threshold for maintenance of genetic information, and an increase in mutation frequency during replication may drive RNA viruses to extinction in a process termed lethal mutagenesis. This report addresses the efficiency of extinction (versus escape from extinction) of foot-and-mouth disease virus (FMDV) by combinations of the mutagenic base analog 5-fluorouracil (FU) and the antiviral inhibitors guanidine hydrochloride (G) and heparin (H). Selection of G- or H-resistant, extinction-escape mutants occurred with low-fitness virus only in the absence of FU and with high-fitness virus with some mutagen-inhibitor combinations tested. The combination of FU, G, and H prevented selection of extinction-escape mutants in all cases examined, and extinction of high-fitness FMDV could not be achieved by equivalent inhibitory activity exerted by the nonmutagenic agents. The G-resistant phenotype was mapped in nonstructural protein 2C by introducing the relevant mutations in infectious cDNA clones. Decreases in FMDV infectivity were accompanied by modest decreases in the intracellular and extracellular levels of FMDV RNA, maximal intracellular concentrations of FU triphosphate, and a decrease in the intracellular concentrations of UTP. In addition to indicating a key participation of mutagenesis in virus extinction, the results suggest that picornaviruses provide versatile experimental systems to approach the problem of extinction failure associated with inhibitor-escape mutants during treatments based on enhanced mutagenesis.     

Does 5-fluorodeoxyuridine inhibit growth by indirectly inhibiting RNA synthesis?

5-Fluorodeoxyuridine (FdUrd), a specific inhibitor of DNA synthesis,inhibits elongation growth in the cucumber hypocotyl. It alsoinhibits both DNA and RNA synthesis, as measured by incorporationof labelled precursors. Possible changes in internal pools orinhibition of RNA synthesis by conversion of FdUrd to 5-fluorouracil(FU) have been ruled out. The possible implications of these findings are discussed. (Received February 13, 1973; )     

Effect of 5-fluorouracil on the synthesis and stability of ribosomal RNA in Saccharomyces carlsbergensis

A study has been made of the effects of 5-fluorouracil on the synthesis and stability of ribosomal RNA in yeast. The analog causes ribosomal precursor RNA to accumulate. Mature ribosomal RNA species synthesized in the presence of 5-fluorouracil are unstable and are degraded. Pulse chase experiments showed that the 26 S ribosomal RNA is more rapidly degraded than the 17 S component, explaining our observations that in long term experiments apparently less 26 S than 17 S ribosomal RNA is formed. Possible reasons for the instability of ribosomal RNA containing 5-fluorouracil are discussed.     

Synthesis and functional activity of initiation regions of mRNA translation. II. RNA-ligase synthesis of hepta- and decaribonucleotides--components of 20-base polyribonucleotide templates

Preparative RNA-ligase synthesis of decaribonucleotides, the 5'-and 3'-constituent parts to be used for the synthesis of 20-base polyribonucleotides] simulating minimal translation initiation regions for phage RNA was carried out. The decamers were obtained via appropriate heptamers also by RNA-ligase catalyzed synthesis. Apart from decamers used to prepare the functionally active 20-base polyribonucleotide, the minimal translation initiation region of the replicase gene (R) in MS2 and fr phage--sequence R(-17----3) and two its variants, decanucleotides for other template modification were also synthesized. Three 5'-terminal decamers were isolated and identified including the natural decamer ApApApCpApUpGpApGpG (-17----(-)8) and those with G(-9)----A(-9) and U(-12)----C(-12) nucleotide substitutions, as well as three 3'-terminal products differing from the natural region ApUpUpCpCpCpApUpG (-7----3) in MS2 RNA by U(-6)----A(-6), U(-6)U(-5)----A(-6)A(-5) and CCC----UUU (-3----(-)1) substitutions.     

Properties of 5-fluorouracil-containing ribonucleic acid and ribosomes from Bacillus subtilis

Growth of a strain of Bacillus subtilis that requires uracil, thymine, adenine, and tryptophan in the presence of 5-fluorouracil (FU) results in the synthesis of ribonucleic acid (RNA) and ribosomes in which 55 to 65% of the RNA uracil has been replaced by the fluorine derivative. Examination of analogue-containing ribosomes by sucrose density gradient centrifugation and thermal denaturation studies suggests that, as far as the size, shape, and packing structure are concerned, extensive FU substitution has little or no effect. FU appears to replace uracil in RNA without selectivity for one RNA class over another, as determined by methylated albumin-kieselguhr column chromatography and sucrose density gradient centrifugation. The total amino acid content of the cells is markedly affected by growth in the presence of FU. The possibility of an FU effect on genetic translation is discussed.     

The effect of ribonuclease on the penetration of R17 phage A-protein and RNA.

In an attempt to throw further light on the relationship of R17 phage RNA and A-protein during the early stages of infection, studies were carried out to determine the effect of ribonuclease (ribonuclease I, EC 3.1.4.22) on the ability of these two phage components to penetrate into host bacteria. It was found that the penetration of phage RNA is affected by ribonuclease concentrations as low as 0.1 mug/ml, while the penetration of phage A-protein was unaffected by ribonuclease concentrations as high as 20 mug/ml. In addition, it was found that a significant fraction of the phage RNA is resistant to the ribonuclease effect. This RNase-resistant portion of the phage population increased with increasing phage concentrations, and gave rise to the penetration of intact, 28S RNA molecules that produced the expected number of infectious centers. These findings are discussed in terms of a model for phage RNA injection in which the A-protein functions both as an attachment organelle and a pilot protein that guides the RNA from the capsid to the exterior surface of the F pilus, and thence into the host bacterium.     

Control of Replication in RNA Bacteriophages

The rates of viral RNA and protein syntheses for wild-type RNA bacteriophages and their nonpolar, coat protein amber mutants were determined in amber suppressor (S26R1E, Su-1 and H12R8a, Su-3) and nonsuppressor (AB259, S26, and Q13) strains of Escherichia coli in the presence of rifamycin. It was demonstrated that the rates of synthesis of phage-specific replicase and RNA minus strands drop off concurrently in both wild-type and coat protein mutant-infected Su(-) and Su(+) cells after 10 and 15 min postinfection, respectively. The rate of synthesis of RNA plus strands started to decline 5 to 10 min later in both cases. Excessive synthesis of replicase in the coat protein mutant-infected cells was accompanied by a similar overproduction of RNA minus strands, but not of plus strands. Partial suppression of protein synthesis in wild-type phage-infected cells abolishing coat protein control over replicase accumulation led to prolongation of replicase synthesis. Such an effect was observed also in coat protein mutant-infected cells, indicating that the excess of replicase itself may be capable of suppression of replicase synthesis in the absence of coat protein. The prolongation of replicase synthesis was followed by the prolonged synthesis of RNA minus strands in both cases. Moreover, replicase and minus strands were formed in nearly equal amounts when protein synthesis was partially inhibited. Assuming functional instability of phage RNAs, the observed coupling of replicase and minus-strand RNA synthesis offers a possibility for control of viral RNA replication by means of control of replicase synthesis on the translational level. A hypothesis is put forward to explain the molecular mechanism of such coupling between the syntheses of replicase and RNA minus strands.     

Effect of Bacteriophage R17 Infection on Hostdirected Synthesis of Ribosomal Ribonucleates

Studies were performed on the synthesis of ribosomal ribonucleates in cells of Escherichia coli K-12 infected by the ribonucleic acid (RNA) bacteriophage R17. Host-specific RNA was measured in the presence of phage RNA by in vitro hybridization of the purified ribonucleates with E. coli deoxyribonucleic acid. The results showed that, although the overall rate of RNA synthesis was only slightly affected by phage infection, the level of host RNA synthesis was decreased by 70 to 80%. Fractionation of the purified ribonucleates by sucrose gradient sedimentation, followed by hybridization of fractions sedimenting in the 23S and 16S regions, revealed that the level of ribosomal RNA synthesis was also decreased by 70 to 80%, and that this inhibition occurred during the first 15 to 20 min after infection. These findings are discussed in light of what is known about the inhibition of host RNA synthesis by other virus systems.