Synthesis of ribonucleic acid by isolated rat liver mitochondria

Rat liver mitochondria isolated in sucrose-N-tris(hydroxymethyl)methyl-2-aminoethane-sulphonic acid (TES) incorporated [(3)H]UTP into RNA for 1h. Incorporation was inhibited 50% by 1mug of actinomycin D/ml, 1mug of acriflavine/ml and 0.5mug of ethidium bromide/ml but was insensitive to rifampicin, rifamycin SV, streptovarcin and deoxyribonuclease. After the first 10min of incubation, the synthesis was insensitive to ribonuclease. RNA synthesis by mitochondria isolated in sucrose-EDTA was insensitive to actinomycin D and sensitive to ribonuclease during the first 10min of the incubation but thereafter the sensitivities were the same as for mitochondria isolated in sucrose-TES. In a hypo-osmotic medium the relative extent of incorporation of the four ribonucleoside triphosphates into RNA was CTP>UTP=ATP>GTP. In an iso-osmotic medium the incorporation of CTP and GTP decreased. All four nucleotides were incorporated into RNA in a DNA-dependent process, as indicated by the inhibition by actinomycin D. In addition, CTP and ATP were incorporated into the CCA end of mitochondrial tRNA. ATP was also incorporated into an unidentified acid-insoluble compound, which hydrolysed in alkali to a product that was not ATP, ADP or 5'- or 2(3')-AMP. Atractyloside inhibited the incorporation of ATP into RNA with 50% inhibition at 2-3nmol/mg of protein. The [(3)H]UTP-labelled RNA had peaks of 16S and 13S characteristic of mitochondrial rRNA. In addition a peak at 20-21S was observed as well as heterogeneous RNA sedimenting throughout the gradient. The synthesis of all these species was inhibited by actinomycin D, indicating that rat liver mitochondrial DNA codes for mitochondrial rRNA as well as other as yet unidentified species.     

The effect of pancreatic ribonuclease on rabbit reticulocyte ribosomes and its interpretation in terms of ribosome structure

1. Parts of the 16s and 30s RNA species of reticulocytes are readily hydrolysed by pancreatic ribonuclease. The biological activity of the ribosomes is diminished after treatment with low concentrations of the enzyme (e.g. 1ng. of ribonuclease/2.5mg. of polyribosome fraction/ml.). A high proportion of the chain scissions are ;hidden' owing to the secondary structure of the RNA moiety. 2. As the concentration of ribonuclease is increased RNA is lost from the ribosome. About 20-30% of the RNA may be removed from the ribosome without altering appreciably its sedimentation coefficient or its appearance in the electron microscope. 3. The amount of RNA removed from the ribosome is not increased by raising the concentration of enzyme from about 1mug. to 2.5mg. of ribonuclease/2.5mg. of polyribosome fraction/ml., or by increasing the temperature from 0 degrees to 30 degrees , or by first converting the RNA moiety into a single-stranded form before exposure to ribonuclease. 4. Untreated polyribosomes aggregate at about 75 degrees , whereas ribosomes treated with ribonuclease aggregate at about 45 degrees . The aggregates that are found on heating ribosomes after enzymic hydrolysis contain about 40-50% of the complement of RNA of intact ribosomes. 5. From the size of the fragments of RNA isolated from RNA-depleted ribosomes it is inferred that there is one site/60-100 nucleotides that is sensitive to ribonuclease. 6. The RNA moiety of RNA-depleted ribosomes has some double-helical character as shown by the optical properties and X-ray-diffraction pattern of ribonuclease-treated ribosomes and by the ;melting' properties of the isolated RNA. 7. Subparticles prepared by titration with an excess of EDTA are readily hydrolysed by ribonuclease to fragments of S(20,w) less than 4s, in contrast with the intact particle.     

Transfection in Agrobacterium tumefaciens

Intact cells of Agrobacterium tumefaciens were examined for ability to take up biologically active LR-4 phage deoxyribonucleic acid (DNA) from the surrounding medium. DNA incorporation as measured by subsequent plaque formation (transfection) failed to occur when the bacteria were grown in defined minimal salts media, and was restricted to a 4-hr period in the early log phase of growth in enriched media. In the latter case, maximal transfection frequencies were obtained after a 25- to 30-min incubation with 22.5 mug of phage DNA/ml. Higher DNA concentrations or longer incubation times were inhibitory. Transfection was completely inhibited by deoxyribonuclease but not by ribonuclease, trypsin, or phage-specific antisera.     

Transcription of specific genes in isolated nuclei from HeLa cells in vitro.

Isolated HeLa cell nuclei were employed to catalyze the synthesis of RNA in vitro. In the presence of low concentrations of alpha-amanitin (1 mug/ml), used to suppress the formation heterogeneous nRNA, these nuclei synthesize RNA very efficiently for extended periods of time (at least 60 min) at an elongation rate of about seven nucleotides per second. The product, analyzed on sucrose density gradients and polyacrylamide gels was found to exist of two predominant size classes. Synthesis of the 45-S ribosomal precursor was completely resistant even to high concentrations of alpha-amanitin (150 mug/ml) and hence was catalyzed by enzyme A (or I). A limited degree of processing of the 45-S precursor occurred in vitro. In addition, a second RNA class of low molecular weight (4-8 S) was synthesized by HeLa cell nuclei in the presence of 1 mug/ml alpha-amanitin in vitro. Analysis on 8% polyacrylamide gels resolved the RNA into four distinct components. Their synthesis was resistant to low (1 mug/ml) but clearly sensitive to high (150 mug/ml) concentrations of alpha-amanitin. Consequently the synthesis of all these small-molecular-weight RNA species is catalyzed by RNA polymerase C (or III). For the assessment of the initiation frequency of the individual classes of RNA, a new technique was developed independent of labelling the 5' end of the RNA molecule with the gamma-phosphate of the initiating nucleotide. It employs the double labelling of an RNA molecule with two different isotopes added sequentially at different stages of completion of the chain. From the incorporation ratio of the two isotopes into a particular class of RNA, conclusions can be drawn concerning their initiation frequency. The results obtained have shown a high reinitiation frequency for the small-molecular-weight RNA species at all stages of the incubation reaction. In contrast, reinitiation of the 45-S precursor RNA occurs only to a limited extent in isolated HeLa cell nuclei in vitro.     

The host-dependent restriction of growth of an RNA coliphage FI.

Phage FIC is a spontaneous host-dependent mutant of phage FI which is classified into the fourth group of RNA Escherichia coli phages (RNA coliphages). The mutant phage (FIC) grows normally in E. coli strain Q13 (permissive host), but poorly in strain A/lambda (non-permissive host) (9). Attempts to elucidate the regulatory mechanism of growth of the mutant phage in the non-permissive host revealed the following: (a) growth of the mutant phage was specifically restricted in E. coli strains that have certain suppressor genes for amber mutation; (b) the mutant phage RNA (FIC-RNA) could not produce progeny in the spheroplasts of the non-permissive host; (c) adsorption of the mutant phage to, and penetration of the mutant phage RNA into, the non-permissive host were normal; and (d) biosynthesis of the phage-specific late protein and RNA did not occur in the non-permissive host. Based on these results we conclude that phage FIC is a spontaneous azure-type mutant of the fourth group of RNA coliphage FI.     

Synthesis of reovirus ribonucleic acid in L cells

Kudo, Hajime (The Wistar Institute of Anatomy and Biology, Philadelphia, Pa.), and A. F. Graham. Synthesis of reovirus ribonucleic acid in L cells. J. Bacteriol. 90:936-945. 1965.-There is no inhibition of protein or deoxyribonucleic acid (DNA) synthesis in L cells infected with reovirus until the time that new virus starts to form about 8 hr after infection. At this time, both protein synthesis and DNA synthesis commence to be inhibited. Neither the synthesis of ribosomal ribonucleic acid (RNA) nor that of the rapidly labeled RNA of the cell nucleus is inhibited before 10 hr after infection. Actinomycin at a concentration of 0.5 mug/ml does not inhibit the formation of reovirus, although higher concentrations of the antibiotic do so. Pulse-labeling experiments with uridine-C(14) carried out in the presence of 0.5 mug/ml of actinomycin show that, at 6 to 8 hr after infection, two species of virus-specific RNA begin to form and increase in quantity as time goes on. One species is sensitive to ribonuclease action and the other is very resistant. The latter RNA is probably double-stranded viral progeny RNA, and it constitutes approximately 40% of the RNA formed up to 16 hr after infection. The function of the ribonuclease-sensitive RNA is not yet known. Synthesis of both species of RNA is inhibited by 5 mug/ml of actinomycin added at early times after infection. Added 6 to 8 hr after infection, when virus-specific RNA has already commenced to form, 5 mug/ml of actinomycin no longer inhibit the formation of either species of RNA.     

Inhibitory Effect of Fatty Acids on the Entry of the Lipid-Containing Bacteriophage PR4 into Escherichia coli

Various unsaturated fatty acids (notably palmitoleic acid and oleic acid) interfered with plaque production by the lipid-containing bacteriophage PR4 on lawns of Escherichia coli. Addition of fatty acid to give 50 mug/ml ( approximately 0.2 mM) at the time of infection prevented phage replication. If, however, the fatty acid was added after infection, normal amounts of phage were produced. If the fatty acid was added (to 50 mug/ml) to the host cell culture a long enough time before infection such that the fatty acid concentration in the growth medium at the time of infection was reduced to less, similar5 mug/ml (due to fatty acid incorporation by the host cells), normal phage replication occurred also. Neither palmitoleic acid nor oleic acid prevented PR4 attachment to E. coli. Several types of experiments indicated that it is the entry process of the virus that is inhibited by these fatty acids. Specifically, if the fatty acid was added at the time of infection, the host cells were not killed by the virus and no detectable amounts of viral protein were synthesized. In addition, experiments using purified radioisotope-labeled virions showed directly that entry is inhibited. Mutants of PR4 that did replicate in the presence of oleic acid arose spontaneously at a frequency of 10(-6). Three of these mutants that have been further characterized have protein and phospholipid compositions indistinguishable from those of wild-type PR4.     

Effect of Polymyxin on the Bacteriophage Receptors of the Cell Walls of Gram-Negative Bacteria

Treatment of gram-negative bacteria with lethal doses of polymyxin B and colistin resulted in the formation of projections of the outer layer of the cell wall. Phages T3, T4, and T7, which use wall lipopolysaccharide as receptors, were specifically prevented from adsorbing to Escherichia coli B cells treated with polymyxin, whereas phages T1, T2, T5, and T6 were not. In the systems of phage P22C-Salmonella typhimurium LT2 and phage C21-S. typhimurium variant SL1069, the phage were prevented from adsorbing to the host cell treated with the antibiotics. Electron microscopic observations show that phage T2 adsorbed irreversibly to the normal smooth surface between the projections on the outer layer caused by the drug treatment. These results indicate that lipopolysaccharide is affected by polymyxin functionally and morphologically, but lipoprotein is not. The purified lipopolysaccharide showed a ribbon-like structure when viewed face on and showed trilamellar structure when viewed edge on. The lipopolysaccharide from E. coli B was irreversibly adsorbed by phages T3, T4, and T7, but not phage T2. Often, phage T4 adsorbed to both sides of the lipopolysaccharide strand at comparable distances. Phage P22C adsorbed through the spikes of the tail-plates to the lipopolysaccharide from S. typhimurium LT2. Lipopolysaccharide which was treated with low doses of the drug (2.5 to 6.25 mug of polymyxin B per ml to 100 mug of lipopolysaccharide per ml) turned into the coiled form and was partially broken down into short segments with coiled form. The loosely coiled lipopolysaccharide retains both its function as the receptor and its trilamellar structure. Treatment with high doses of the drug (12.5 to 25 mug of polymyxin B per ml to 100 mug of lipopolysaccharide per ml) caused the collapse of the trilamellar structure of the strand. These collapsed lipopolysaccharides became flat and fused with each other, making an amorphous mass, and finally they were broken into small collapsed fragments.     

Virucidal effect of sodium p-chloromercuribenzoate on influenza viruses attributable to inhibition of virus particle-associated RNA-dependent RNA polymerase.

Sodium p-chloromercuribenzoate (PCMB) caused a noticeable reduction of infectivity of prototype strains of type A and Lee strain of type B influenza viruses at concentrations of 100 and 200 mug/ml, respectively, after an incubation at 37 C for 60 min. The virucidal effect on A/AA/2/60 (H2N2) strain was dependent on the concentration of the drug and temperature as well as on the time of incubation. The reagent exerted this effect at a concentration which induced little change in the hemagglutinating and neuraminidase activities of the virus. PCMB inhibited by 50% the virus particle-associated RNA polymerase activity of all prototype strains of type A influenza virus at about 2 mug/ml and that of Lee strain of type B influenza virus at 8.5 mug/ml. Other sulfhydryl reagent such as phenylmercuric nitrate also exhibited virucidal effect on A/AA/2/60 virus which paralleled their inhibition of the virus particle-associated RNA polymerase activity. From these results it was considered likely that the virucidal action of PCMB on influenza viruses was attributable to inhibition of the virus particle-associated RNA polymerase activity.     

Synthesis of Ribonucleic Acid in Cells Infected with LSc Poliovirus at Elevated Temperatures

The synthesis of viral ribonucleic acid (RNA) was detected within 2 hr after infection with LSc poliovirus at 35 C. This RNA eluted as a single peak with 0.9 m NaCl on methylated albumin celite columns, was sensitive to ribonuclease, precipitated in the presence of 2 m LiCl, and had an S(20) value at 34 +/- 2 in linear sucrose gradients. When cells were infected at 39 to 40 C, there was also early synthesis of RNA. However, 2 hr after infection this synthesis was drastically inhibited. The absence of net RNA synthesis at 39 to 40 C during the late stages of infection was not caused by rapid degradation of newly formed RNA, since the RNA produced between 1 and 2 hr at 39 to 40 C was still present 3.5 hr after infection. There was a 3 log(10) inhibition in the production of infectious virus when p-fluorophenylalanine was present in the medium at a concentration of 25 mug/ml. This concentration of analogue had little effect upon the production of viral polymerase and viral RNA. Virus grown in the presence of analogue at a concentration of 10 mug/ml exhibited increased heat sensitivity compared to control virus. However, viral polymerase exhibited no change in sensitivity to heat or manganese when cells were exposed to 25 mug of p-fluorophenylalanine per ml during infection. p-Fluorophenylalanine had a relatively selective effect on viral capsid protein but did not reverse the inhibition of synthesis of viral RNA at 39 to 40 C.     

Selective Inhibition of Deoxyribonucleic Acid Synthesis by 2-Deoxyadenosine in the Blue-Green Bacterium Agmenellum quadruplicatum

Concentrations of deoxyadenosine which have little effect on net ribonucleic acid (RNA) synthesis or on increase in cell mass selectively inhibit deoxyribonucleic acid (DNA) synthesis in Agmenellum quadruplicatum. Exogenously supplied deoxyadenosine, at concentrations above 10 mug/ml, stimulates DNA degradation. These results are correlated with a rapid loss in viability. Over a narrow concentration range (6-15 mug/ml), deoxyadenosine impairs the division process and induces the formation of elongated cells. Low exogenous concentrations of deoxyadenosine are readily incorporated into both DNA and RNA, with the major portion as DNA.     

Use of Miracil D to Suppress Bacterial Ribonucleic Acid and Protein Synthesis During Bacteriophage MS2 Infection

Under certain culture conditions, Miracil (35 mug/ml) halts the growth of uninfected Escherichia coli. Cellular ribonucleic acid (RNA) synthesis is almost completely suppressed, whereas deoxyribonucleic acid and protein synthesis are inhibited to a lesser extent. When the drug is added to host bacteria prior to infection with bacteriophage MS2, the phage adsorb to the cells, but penetration of the viral RNA is inhibited. Penetration may be achieved without further viral development by infection in the presence of chloramphenicol. If the bacteria are infected with MS2 in the presence of chloramphenicol, subsequently washed to remove the chloramphenicol, and then treated with Miracil at any time between 0 and 20 min postinfection, a second viral function is inhibited and the yield of progeny phage is reduced. Addition of the drug after 20 min postinfection does not inhibit the infection process. When Miracil is present from early times in infection, only a limited synthesis of both double- and single-stranded virus-specific RNA is observed. The viral RNA species thus produced do not appear to differ from those made in the absence of the drug. A comparison of the activities of the viral RNA synthetase produced during the course of infection in the presence and in the absence of Miracil suggests that a possible cause of the inhibition is the synthesis of an unstable enzyme in the presence of the drug.     

Effect of trypsin and ribonuclease on the immunogenic activity of ribosomes and ribonucleic acid isolated from Mycobacterium tuberculosis

Youmans, Anne S. (Northwestern University Medical School, Chicago, Ill.), and Guy P. Youmans. Effect of trypsin and ribonuclease on the immunogenic activity of ribosomes and ribonucleic acid isolated from Myobacterium tuberculosis. J. Bacteriol. 91:2146-2154. 1966.-The ribosomal fraction of the attenuated strain, H37Ra, of Mycobacterium tuberculosis was treated with trypsin alone, ethylenediaminetetraacetic acid (EDTA) alone, EDTA and pancreatic ribonuclease, or with trypsin and ribonuclease. After each of these treatments, the ribosomal fractions were injected intraperitoneally into male CF-1 mice to test their capacity to produce an immune response to infection with virulent tubercle bacilli, strain H37Rv. Removal of protein with trypsin left the immunogenicity unchanged; EDTA alone reduced immunogenicity in the smaller vaccinating doses; EDTA plus ribonuclease reduced the immunogenicity by approximately 50% in the highest (1.0 mg) vaccinating dose; ribonuclease alone, after treatment with trypsin, reduced immunogenicity also approximately 50%. A crude mycobacterial ribonucleic acid (RNA) was prepared by extraction of the ribosomal fraction with alcohol. This RNA preparation was as effective in producing an immune response as the ribosomal fraction from which it was prepared, unless the RNA was partially or completely degraded during the preparation. The effect of ribonuclease on the immunogenicity of the RNA was similar to that obtained with the ribosomal fractions, except that ribonuclease completely destroyed the immunogenicity of a partially degraded RNA. RNA appears to be an essential part of an immunizing substance in attenuated tubercle bacilli, which produces a high degree of immunity in mice; 50 mug (dry weight) will protect approximately 80% of the mice, and as little as 0.5 mug will protect approximately 30% of the mice. Mycobacterial RNA not incorporated in Freund's incomplete adjuvant was nonimmunogenic. Yeast RNA incorporated in Freund's incomplete adjuvant was not immunogenic.     

Mode of Action of Myxin on Escherichia coli

The effect of the new antibiotic, myxin, on the syntheses of deoxyribonucleic acid (DNA), ribonucleic acid (RNA), and protein in Escherichia coli (strains B and 15T(-)) was examined. Within 7 min of the addition of myxin at 5 mug/ml, the synthesis of new bacterial DNA was almost completely inhibited. This was followed by an extensive degradation of the pre-existing DNA to an acid-soluble form. All of the evidence indicated that the primary effect of the antibiotic was on cellular DNA. The synthesis of RNA was completely inhibited after 15 min of exposure to myxin (5 mug/ml), and the synthesis of protein was markedly reduced after 30 min. There was no measurable breakdown of either RNA or protein in the myxin-treated cells. A marked stimulation of (14)C-uracil incorporation was found in the presence of myxin in 15T(-) cells only. This did not result from an increased rate of RNA synthesis but was due to an increase in the proportion of exogenous uracil, relative to endogenous uracil, incorporated into cellular RNA. This probably reflected a partial inhibition of the biosynthesis of uridine monophosphate from orotate. At 4.5 mug of myxin per ml and with 0.8 x 10(8) cells per ml, 50% of the antibiotic was reduced in 15 min from the biologically active oxidized form to the biologically inactive state. Under these conditions, a maximum of 0.6% (27 mumug/ml) of the myxin was retained in the cells.     

Photodynamic Action of Proflavine on Coliphage T3 I. Kinetics of Inactivation

The photodynamic inactivation of coliphage T3 was studied over a wide range of concentrations of the dye proflavine. With 2 x 10(7) phage/ml, two modes of inactivation were observed. Between 0.25 and 12 to 13 mug/ml, inactivation was biphasic. There was an initial first-order inactivation (Rx1) which became temporally associated with an apparently multiorder process (Rx2) at higher light doses. Dye concentrations above 12 to 13 mug/ml showed only two-target inactivation curves (Rx3), except at high dye concentrations where processes kinetically identical to Rx1 and Rx2 reappeared. Rx2 showed a normal rectangular hyperbolic saturation curve but Rx1 and Rx3 appeared to saturate prematurely. The saturation behavior of Rx1 and Rx2 was independent of phage concentration, but Rx3 was lost at phage titers above 2 x 10(7)/ml. No dark inactivation was seen with Rx1 and Rx2 subsequent to a period of illumination. With Rx3, an exponential dark inactivation was seen for at least 1 hr after a period of illumination. The dye-phage system equilibrated immediately, at any temperature, at proflavine concentrations where Rx1 and Rx2 occurred. With Rx3, prolonged equilibration times were necessary. Moreover, there was a temperature effect. The rate of inactivation at equilibrium was temperature-dependent, whereas the initial rate at which equilibrium was approached was essentially temperature-independent.     

Adrenocorticotropic hormone stimulation of adrenal RNA polymerase I and III activities. Nucleotide incorporation into internal positions and 3' chain termini.

In the presence of 50 mM (NH4)2SO4 and low concentrations of alpha-amanitin (7.7 mug/ml), adrenal nuclei synthesize predominately rRNA as characterized by size and base composition. Approximately 10% of the RNA synthesized under these conditions sediments at 4-5 S; this RNA synthesizing activity is inhibited by high concentrations of alpha-amanitin (231 mug/ml) indicating the presence of RNA polymerase III activity. ACTH administration to guinea pigs results in a twofold increase in adrenal nuclear RNA polymerase I and III activities at 14 hr of hormone treatment. Analysis of the amount of radiolabeled nucleoside triphosphate incorporated in vitro into 3' chain termini and into internal nucleotide positions has been utilized to measure the number of RNA chains and the average chain length synthesized in vitro. Incorporation into 3' chain termini is not changed by ACTH; incorporation into internal nucleotides is doubled in parallel with the increase in RNA polymerase I activity. These results are not due to an altered Km of RNA polymerase I for the four nucleoside triphosphates, nor to differential R Nase or phosphatase activity. These studies suggest that the regulation of RNA polymerase I by ACTH is accomplished in part through an increase in the rate of RNA chain elongation.     

Mechanism of Ozone Inactivation of Bacteriophage f2

The inactivation kinetics of bacteriophage f2 were studied by using ozone under controlled laboratory conditions. The phage were rapidly inactivated during the first 5 s of the reaction by 5 and 7 logs at ozone concentrations of 0.09 and 0.8 mg/liter, respectively. During the next 10 min, the phage were further inactivated at a slower rate in both treatments. The [³H]uridine-labeled f2 phage and its ribonucleic acid (RNA) were examined to elucidate the mechanism of ozone inactivation, utilizing adsorption to host bacteria, sucrose density gradient analysis, and electron microscopy. The specific adsorption of the phage was reduced by ozonation in the same pattern as plaque-forming unit reduction. RNA was released from the phage particles during ozonation, although it had reduced infectivity for spheroplasts. Electron microscopic examination showed that the phage coat was broken by ozonation into many protein subunit pieces and that the specific adsorption of the phage to host pili was inversely related to the extent of phage breakage. The RNA enclosed in the phage coat was inactivated less by ozonation than were whole phage, but inactivated more than naked RNA. These findings suggest that ozone breaks the protein capsid into subunits, liberating RNA and disrupting adsorption to the host pili, and that the RNA may be secondarily sheared by a reduction with and/or without the coat protein molecules, which have been modified by ozonation.     

Mutagenesis in cultured human diploid cells. IV. Induction of 8-azaguanine resistant mutations by phloxine, a mutagenic red dye.

Disodium 9-(3',4',5',6'-tetrachloro-o-carboxyphenyl)-6-hydroxy-2,4,5,7-tetrabromo-3-isoxanthone (phloxine), a red dye used as a food additive, was tested for its activity to induce 8-azaguanine (8AG) resistant mutations in cultured human embryonic cells. Phloxine had a severe cytotoxic effect on the cells at concentrations of 1 to 10 mug/ml. At concentrations of more than 30 mug/ml of phloxine no further decrease in cell survival was found. This cytotoxic effect of phloxine was not dependent on the duration of treatment. After treatment with phloxine for 2 h division of cells in normal medium was inhibited for 120 h. When cells were treated with phloxine at various concentrations for 2 h, cultured in normal medium for 48 h, and then selected with 30 mug/ml of 8AG, an increase in the induced mutation frequency was found. This increase in mutation frequency was dependent on the concentration of phloxine used as a mutagen and treatment with 100 mug/ml of phloxine increased the frequency to six times that in untreated cultures.     

Physiological and biochemical effects of the mycotoxin patulin on Chang liver cell cultures.

Patulin exhibits both cytotoxic and cytopathic effects on cultured Chang liver cells. The LD50 found was 1.85 mug per ml of patulin. Effects on growth were observed with as little as 0.1 mug per ml of patulin; a 50% reduction in growth was observed at 0.38 mug per ml of patulin. Using a challenge dose of 2.5 mug per ml of patulin, the cytotoxic effect was reversible after an exposure of 10 min, but was not reversible after 20 min. Protein synthesis was depressed after 60 min and RNA synthesis after 20 min of contact with patulin. Neither protein nor RNA synthesis was completely inhibited after 260 min.