Enhancement by Putrescine of Gibberellin-Induced Elongation in Hypocotyls of Lettuce Seedlings

Effects of diamines, polyamines, and other basic amino acidson the growth of lettuce hypocotyls were investigated. Putrescine,cadaverine and agmatine enhanced the hypocotyl growth in thepresence of gibberellin, while spermidine and spermine werenon-effective. Arginine and ornithine, which may be precursorsof putrescine, had similar effect. While the growth inhibitiondue to arcaine (1,4-diguanidinobutane), which is a agmatineiminohydrolase inhibitor, was recovered by agmatine, cadaverine,putrescine, and spermidine, putrescine most effectively recoveredits growth-enhancing effect. (Received August 25, 1982; Accepted December 27, 1982)     

Effects of Cytokinin and Several Inorganic Cations on the Polyamine Content of Lettuce Cotyledons

Kinetin (4.7 x 10^–5 M) and 6-benzyladenine (2.22 x 10^–5M) were found to increase ca. 2-fold the putrescine contentin cotyledons of lettuce (Lactuca sativa L.) seedlings grownfor 3 days under fluorescent light. On the other hand, severalinorganic ions (K⁺, Na⁺, Ga⁺⁺, Mg⁺⁺) at a concentration of 3x 10^–2 M reduced the putrescine content. The combinationof kinetin with one of several inorganic ions at the same levelmarkedly increased the spermine content, but the putrescinecontent decreased; calcium and magnesium ions were less effective.The physiological significance of these findings is discussed. (Received July 4, 1982; Accepted November 6, 1982)     

Deoxyribonucleic Acid Replication in Simian Virus 40-Infected Cells IV. Two Different Requirements for Protein Synthesis During Simian Virus 40 Deoxyribonucleic Acid Replication

The replication of simian virus 40 (SV40) deoxyribonucleic acid (DNA) was inhibited by 99% 2 hr after the addition of cycloheximide to SV40-infected primary African green monkey kidney cells. The levels of 25S (replicating) and 21S (mature) SV40 DNA synthesized after cycloheximide treatment were always lower than those observed in an infected untreated control culture. This is consistent with a requirement for a protein(s) or for protein synthesis at the initiation step in SV40 DNA replication. The relative proportion of 25S DNA as compared with 21S viral DNA increased with increasing time after cycloheximide treatment. Removal of cycloheximide from inhibited cultures allowed the recovery of viral DNA synthesis to normal levels within 3 hr. During the recovery period, the ratio of 25S DNA to 21S DNA was 10 times higher than that observed after a 30-min pulse with (3)H-thymidine with an infected untreated control culture. The accumulation of 25S replicating SV40 DNA during cycloheximide inhibition or shortly after its removal is interpreted to mean that a protein(s) or protein synthesis is required to convert the 25S replicating DNA to 21S mature viral DNA. Further evidence of a requirement for protein synthesis in the 25S to 21S conversion was obtained by comparing the rate of this conversion in growing and resting cells. The conversion of 25S DNA to 21S DNA took place at a faster rate in infected growing cells than in infected confluent monolayer cultures. A temperature-sensitive SV40 coat protein mutation (large-plaque SV40) had no effect on the replication of SV40 DNA at the nonpermissive temperature.     

Proteins of Vasicular Stomatitis Virus: I. Polyacrylamide Gel Analysis of Viral Antigens

Infection of L cells with vesicular stomatitis virus results in the release, into the cell-free fluid, of four antigenic components separable by rate zonal centrifugation on sucrose gradients. The largest antigens are the infectious (B) particle and a shorter noninfectious, autointerfering (T) particle. The two small antigens are characterized by sedimentation coefficients of approximately 20S and 6S. Treatment of purified B or T particles with sodium deoxycholate results in the release from the particle of a nucleoprotein core which can be purified on sucrose gradient and which has a sedimentation coefficient characteristic of the virus from which it arose. Utilizing purified antigens labeled with (14)C-amino acids during growth, we examined the protein constituents of each antigen by acrylamide-gel electrophoresis. The proteins of B and T particles are identical, each containing one minor (virus protein 1) and three major (virus proteins 2, 3, and 4) proteins, numbered in order of increasing mobility. Virus protein 3 originates from the nucleoprotein core, whereas proteins 2 and 4 come from the coat. The origin of virus protein 1 is not known. The 20S antigen contains a single protein equivalent to virus protein 3, whereas the 6S antigen shows a single protein which is similar to, but probably distinct from, virus protein 2.     

Induction of capsular polysaccharide synthesis by rho-fluorophenylalanine in Escherichia coli wild type and strains with altered phenylalanyl soluble ribonucleic acid synthetase

Escherichia coli K-12 strain AB259 can be induced to form capsular polysaccharide (mucoid clones) by dl-p-fluorophenylalanine (FPA; 5 x 10(-6)m on agar plates at 37 C or 8 x 10(-5)m in liquid medium at 30 C). The change was shown to be phenotypic. An increase in enzymes probably involved in capsular polysaccharide synthesis [phosphomannose isomerase (3.3-fold), uridine diphosphate-d-galactose-4-epimerase (2.5-fold), and guanine diphosphate-l-fucose synthetase] was demonstrated as a result of growth in FPA. These increases appear sufficient to account for the increased synthesis of capsular polysaccharide due to growth in FPA. FPA-resistant derivatives of strain AB259 were obtained by selecting mutants on FPA-containing agar or by transducing in an altered phenylalanyl soluble ribonucleic acid synthetase that activates FPA poorly. Mucoid clones were formed by these strains only in the presence of 30 to 1,000 times as much FPA. Among these strains, there was a close correlation between incorporation of FPA-C(14) and induction of capsular polysaccharide synthesis. The results are thus consistent with the following model: FPA is incorporated into the protein product of the R(1) gene (repressor) and alters it sufficiently to allow derepression of several enzymes.     

Factors Affecting the Pathways of Glucose Catabolism and the Tricarboxylic Acid Cycle in Pseudomonas natriegens

Less than 50% of theoretical oxygen uptake was observed when glucose was dissimilated by resting cells of Pseudomonas natriegens. Low oxygen uptakes were also observed when a variety of other substrates were dissimilated. When uniformly labeled glucose-(14)C was used as substrate, 56% of the label was shown to accumulate in these resting cells. This material consisted, in part, of a polysaccharide which, although it did not give typical glycogen reactions, yielded glucose after its hydrolysis. Resting cells previously cultivated on media containing glucose completely catabolized glucose and formed a large amount of pyruvate within 30 min. Resting cells cultivated in the absence of glucose catabolized glucose more slowly and produced little pyruvate. Pyruvate disappeared after further incubation. In this latter case, experimental results suggested (i) that pyruvate was converted to other acidic products (e.g., acetate and lactate) and (ii) that pyruvate was further catabolized via the tricarboxylic acid cycle. Growth on glucose repressed the level of key enzymes of the tricarboxylic acid cycle and of lactic dehydrogenase. Growth on glycerol stimulated the level of these enzymes. A low level of isocitratase, but not malate synthetase, was noted in extracts of glucose-grown cells. Isocitric dehydrogenase was shown to require nicotinamide adenine dinucleotide phosphate (NADP) as cofactor. Previous experiments have shown that reduced NADP (NADPH(2)) cannot be readily oxidized and that pyridine nucleotide transhydrogenase could not be detected in extracts. It was concluded that acetate, lactate, and pyruvate accumulate under growing conditions when P. natriegens is cultivated on glucose (i) because of a rapid initial catabolism of glucose via an aerobic glycolytic pathway and (ii) because of a sluggishly functioning tricarboxylic acid cycle due to the accumulation of NADPH(2) and to repressed levels of key enzymes.