Flagellar synthesis in Salmonella typhimurium: requirement for ribonucleic acid synthesis

The micro-complement-fixation assay has been demonstrated to be a sensitive assay for flagella which occur in nanogram amounts. By use of this assay, it was found that flagellar synthesis occurs during starvation of Salmonella typhimurium for tryptophan, an amino acid not present in flagellar protein. Under these conditions net ribonucleic acid (RNA) synthesis was reduced to approximately 10% of the control rate. Less than 1 mug of actinomycin D per ml further reduced RNA synthesis to less than 1% of the control rate in a culture sensitized by prior treatment for 5 min at 37 C with 5 x 10(-4)m ethylenediaminetetraacetate in 0.33 m tris(hydroxymethyl)aminomethane-chloride (pH 8.0). In the presence of actinomycin D, no synthesis of flagellar protein could be detected. Analysis of fractions of RNA separated by zone centrifugation indicated that actinomycin D reduces the production of template RNA as well as of ribosomal RNA. This suggests that in S. typhimurium the production of flagellar protein requires the concomitant synthesis of RNA. There is no evidence that a stable messenger RNA specific for flagellar synthesis is present.     

FLAGELLAR ELONGATION AND SHORTENING IN CHLAMYDOMONAS : The Use of Cycloheximide and Colchicine to Study the Synthesis and Assembly of Flagellar Proteins

Flagella can be removed from the biflagellate Chlamydomonas and the cells begin to regenerate flagella almost immediately by deceleratory kinetics. Under usual conditions of deflagellation, more than 98% of all flagella are removed. Under less drastic conditions, cells can be selected in which one flagellum is removed and the other left intact. When only one of the two flagella is amputated, the intact flagellum shortens by linear kinetics while the amputated one regenerates. The two flagella attain an equal intermediate length and then approach their initial length at the same rate. A concentration of cycloheximide which inhibits protein synthesis permits less than one-third of each flagellum to form when both flagella are amputated. When only one is amputated in cycloheximide, shortening proceeds normally and the degree of elongation in the amputated flagellum is greater than if both were amputated in the presence of cycloheximide. The shortening process is therefore independent of protein synthesis, and the protein from the shortening flagellum probably enters the pool of precursors available for flagellar formation. Partial regeneration of flagella occurs in concentrations of cycloheximide inhibitory to protein synthesis suggesting that some flagellar precursors are present. Cycloheximide and flagellar pulse-labeling studies indicate that precursor is used during the first part of elongation, is resynthesized at mid-elongation, and approaches its original level as the flagella reach their initial length. Colchicine completely blocks regeneration without affecting protein synthesis, and extended exposure of deflagellated cells to colchicine increases the amount of flagellar growth upon transfer to cycloheximide. When colchicine is applied to cells with only one flagellum removed, shortening continues normally but regeneration is blocked. Therefore, colchicine can be used to separate the processes of shortening and elongation. Radioautographic studies of the growth zone of Chlamydomonas flagella corroborate previous findings that assembly is occurring at the distal end (tip growth) of the organelle.     

Flagellar regeneration in Chlamydomonas reinhardtii: evidence that cycloheximide pulses induce a delay in morphogenesis.

The behaviour of a pool of flagellar precursors, assayed by the ability of cells to regenerate flagella in the absence of de novo protein synthesis, has been examined during organelle morphogenesis in the biflagellate alga Chlamydomonas. The results demonstrate that flagellar elongation can continue even when this pool is apparently empty and suggest that 2 sources of precursors are available to the regenerating flagella: those pre-existing in the cellular pool and those synthesized de novo. Further evidence for this was obtained by subjecting regenerating cells to pulses of cycloheximide. Cells exposed to this drug during the first 60 min post deflagellation formed only half-length (5-mum) flagella, whereas a pulse administered after this point allowed the formation of longer flagella and suggested that some de novo protein synthesis was required for the formation of full-length flagella, although it was not a prerequisite for the initiation of regeneration. In addition, it was found that, subsequent to the removal of the cycloheximide, flagellar regeneration did not recommence immediately, but was delayed for a period of approximately 45 min, irrespective of length of flagella formed prior to drug inhibition. The nature of this cycloheximide-induced delay is unclear and certain alternatives, based on the exhaustion of structural/regulatory components are considered. Although it is not possible to distinguish between these alternatives, tubulin is not the limiting component, since a pool of this protein is present when flagellar elongation is prevented by cycloheximide.     

FLAGELLAR REGENERATION IN PROTOZOAN FLAGELLATES

The flagella of populations of three protozoan species (Ochromonas, Euglena, and Astasia) were amputated and allowed to regenerate. The kinetics of regeneration in all species were characterized by a lag phase during which there was no apparent flagellar elongation; this phase was followed by elongation at a rate which constantly decelerated as the original length was regained. Inhibition by cycloheximide applied at the time of flagellar amputation showed that flagellar regeneration was dependent upon de novo protein synthesis. This was supported by evidence showing that a greater amount of leucine was incorporated into the proteins of regenerating than nonregenerating flagella. The degree of inhibition of flagellar elongation observed with cycloheximide depended on how soon after flagellar amputation it was applied: when applied to cells immediately following amputation, elongation was almost completely inhibited, but its application at various times thereafter permitted considerable elongation to occur prior to complete inhibition of flagellar elongation. Hence, a sufficient number of precursors were synthesized and accumulated prior to addition of cycloheximide so that their assembly (elongation) could occur for a time under conditions in which protein synthesis had been inhibited. Evidence that the site of this assembly may be at the tip of the elongating flagellum was obtained from radioautographic studies in which the flagella of Ochromonas were permitted to regenerate part way in the absence of labeled leucine and to complete their regeneration in the presence of the isotope. Possible mechanisms which may be operating to control flagellar regeneration are discussed in light of these and other observations.     

Effects of actinomycin D on ribosomal RNA and protein synthesis as revealed by high resolution autoradiography.

Incorporation of tritiated amino acids and uridine was studied in untreated and actinomycin D treated HeLa cells by high resolution autoradiography. Results showed a non-selective inhibition of protein synthesis by actinomycin, as measured by the decrease in radioactive amino acid uptake. When cells pretreated with actinomycin D were incubated with radioactive amino acids and uridine, amino acid uptake in the nucleolus still occurred, while uridine uptake was almost completely eliminated. These findings suggest that in the absence of ribosomal RNA precursor synthesis, nucleolar protein synthesis continues to some extent, and that this protein is transported to the nucleolus.     

Flagellar elongation and shortening in Chlamydomonas. IV. Effects of flagellar detachment, regeneration, and resorption on the induction of flagellar protein synthesis

Synthesis of new proteins is required to regenerate full length Chlamydomonas flagella after deflagellation. Using gametes, which have a low basal level of protein synthesis, it has been possible to label and detect the synthesis of many flagellar proteins in whole cells. The deflagellation-induced synthesis of the tubulins, dyneins, the flagellar membrane protein, and at least 20 other proteins which co- migrate with proteins in isolated axonemes, can be detected in gamete cytoplasm, and the times of initiation and termination of synthesis for each of the proteins can be studied. The nature of the signal that stimulates the cell to initiate flagellar protein synthesis is unknown. Flagellar regeneration and accompanying pool depletion are not necessary for either the onset or termination of flagellar protein synthesis, because colchicine, which blocks flagellar regeneration, does not change the pattern of proteins synthesized in the cytoplasm after deflagellation or the timing of their synthesis. Moreover, flagellar protein synthesis is stimulated after cells are chemically induced to resorb their flagella, indicating that the act of deflagellation itself is not necessary to stimulate synthesis. Methods were defined for inducing the cells to resorb their flagella by removing Ca++ from the medium and raising the concentration of K+ or Na+. The resorption was reversible and the flagellar components that were resorbed could be re-utilized to assemble flagella in the absence of protein synthesis. This new technique is used in this report to study the control of synthesis and assembly of flagella.     

Macromolecular Synthesis in Newly Transformed Cells of Bacillus subtilis

The capacity of newly transformed cells of Bacillus subtilis to synthesize deoxyribonucleic acid (DNA), ribonucleic acid (RNA), and protein has been determined by following the kinetics of suicide after their exposure to tritiated precursors of each of these macromolecules. Competent cells, whether transformed or not, are heterogeneous with respect to DNA synthesis. About 40 to 50% are latent in DNA synthesis. This latency may persist for 2.5 to 3 hr since transformants are resistant to thymineless death for this period after DNA addition. The remainder of the transformants synthesize DNA at one-half the rate of the cells of the total population. Synthesis of stable RNA does not occur at an appreciable rate in newly transformed cells. Newly transformed cells, however, do synthesize protein extensively, as demonstrated by the lethality of incorporated tritiated amino acids. Either chloramphenicol or actinomycin D treatment during the time of exposure to the tritiated amino acid prevented the suicide of transformants.     

Synthesis of Bacterial Flagella: Chromosomal Synchrony and Flagella Synthesis

Synchronous cultures of Bacillus subtilis 168 M were obtained from light-density spores germinated at 46 C and grown at 37 C. This procedure synchronizes both cell division and chromosome replication. The chromosome synchrony was demonstrated by using transformation to measure changes in marker frequency during the cell cycle. The synthesis of two enzymes and of bacterial flagellar protein was also followed. All of the proteins were found to be synthesized continuously with an abrupt doubling in the rate of synthesis at a specific time in the cell cycle. The time at which the doubling occurred for each enzyme corresponded to the time at which the structural gene for the enzyme was replicated. The doubling of the rate of flagella synthesis corresponded to the time of replication of the hisA1 gene. We conclude that the genetic locus for the factors involved in the rate-limiting steps in flagella synthesis are located on the genetic map near the hisA1 locus.     

Regulation of Staphylococcal Penicillinase Synthesis

5-Methyl tryptophan was found to be an efficient inducer of penicillinase synthesis in Staphylococcus aureus. Addition of actinomycin D or tryptophan to the culture medium shuts off the 5-methyl tryptophan-induced synthesis of penicillinase with an apparent half-life of approximately 1 to 2 min, respectively. Hence, in the induction of penicillinase synthesis, 5-methyl tryptophan seems to function as a structural analogue of penicillin rather than by becoming incorporated in proteins and thereby creating faulty penicillinase repressor or antirepressor. This conclusion is supported by similarities in the structures of the two compounds as revealed by solid atomic models. The fact that S. aureus exposed to (14)C-penicillin in the absence of protein synthesis failed to synthesize penicillinase at an increased level when cell growth was resumed strongly suggests that a protein involved in the regulation of penicillinase synthesis must be synthesized in the presence of the penicillinase inducer. In turn, this observation suggests that the penicillinase inducer promotes penicillinase synthesis by directing the penicillinase regulatory protein (i.e., the penicillinase antirepressor) to acquire a different conformation when it is synthesized in the presence of the penicillinase inducer. A working model for the regulation of penicillinase synthesis based on these and other data has been constructed and is presented.     

FLAGELLAR DEVELOPMENT AND REGENERATION IN VOLVOX CARTERI (CHLOROPHYTA)1

The biflagellate somatic cells of Volvox carteri f. nagariensis lyengar exhibit an asymmetric pattern of flagellar development. Initiallt each somatic cell has two short (4 μm) flagella but after several hours one flagellum on each cell elongates unitl it reaches a length of 12 μm. Due to the regular arrangement of somatic cells in the Volvox spheroid it is apparent that the same flagellum on each somatic is the first to elongale. The asymmetric flagellar length is maintained for about 8 h after which the second flagellum on each somatic cell elongates. When the second flagellum attains the same length (12 μm) as the first flagellum, both flagella elongale at the same rate until reaching a final length of 22 μm. Experimental removal of somatic cell flagella results in their regeneration. Somatis cells regenerate both flagella simultaneously and full length flagella are produced in about 2 h. The intial rate of flagellar regeneration is about ten times faster than the intial rate of flagllar growth in development. Cycloheximide, an inhibitor of protein synthesis, has no effect on the initial rate of flagellar regeneration but the flagella produced in the presence of the drug are half the length of flagella produced in its absence. Somatic cells are able to regenerate flagella up to the time of α and β tubulin, the major structural proteins of the flagellar axoneme, and other cellular proteins.     

Cilia regeneration in starved tetrahymena: an inducible system for studying gene expression and organelle biogenesis.

Deciliated starved Tetrahymena recover motility with kinetics similar to those of growing cells and, like growing cells, require RNA and protein synthesis for regeneration. Comparisons of polysome profiles and electrophoretic analyses of newly synthesized proteins indicate, however, that the basal level of protein synthesis in starved cells is markedly lower than that in growing cells. This difference allows demonstration of changes in protein synthesis following deciliation of starved cells which cannot be detected (if they occur at all) in growing cells. Deciliation of starved cells induces a specific and orderly program of protein synthesis. The synthesis of an 80,000 dalton protein (deciliation-induced protein, DIP) begins shortly after deciliation, comprises 15% of the protein synthesized from 20-60 min, and declines around 60 min after deciliation, shortly after most cells have begun to regenerate cilia. The synthesis of a 55,000 dalton protein is also induced during regeneration and has been identified as tubulin using a well characterized antibody made to ciliary tubulin. Tubulin synthesis is undetectable during the first hour after deciliation even though 60-80% of the cells regain mobility and regenerate short but clearly visible cilia. Tubulin synthesis begins 60 min after deciliation and continues for 2 hr. At its peak, tubulin comprises 7-8% of the protein synthesized. The results of actinomycin D addition at different times after deciliation suggest that RNA required for DIP synthesis is synthesized early (0-30 min), while RNA required for tubulin is synthesized later and over a longer period (30-90 min). Thus deciliation of starved cells, an event occurring at the cell periphery, initiates a well defined and reproducible series of events culminating in cilia formation. This system should be useful in elucidating the molecular mechanisms regulating gene expression and organelle biogenesis in Tetrahymena.     

Polyribosomes from Bacillus subtilis During Amino Acid Starvation in the Presence and in the Absence of Actinomycin

Polysomes were extracted from Bacillus subtilis cells starved for a required amino acid. The monosome peak appeared soon after starvation; no difference in the rate of degradation was detected when the cells were starved for arginine or tryptophan in a double auxotroph. RNA production during starvation was not inhibited by actinomycin, but the molecular weight of the product made in the presence of the antibiotic was much lower. Indications that stable messenger ribonucleic acid is present for up to 90 min after amino acid starvation are also presented.     

Rapid changes in tubulin RNA synthesis and stability induced by deflagellation in Chlamydomonas

Detachment of the flagella of Chlamydomonas induces a rapid accumulation of mRNAs for tubulin and other flagellar proteins. Measurement of the rate of alpha and beta tubulin RNA synthesis during flagellar regeneration shows that deflagellation elicits a rapid, 4-7- fold burst in tubulin RNA synthesis. The synthesis rate peaks within 10- 15 min, then declines back to the predeflagellation rate. Redeflagellation of cells at times before the first flagellar regeneration is completed (and when cells have already accumulated elevated levels of tubulin RNA) induces another burst in tubulin RNA synthesis which is identical to the first in magnitude and duration. This finding indicates that the induction signal may act to simply reprogram the tubulin genes for a transient burst of maximal synthesis. Evidence is presented that the stability of the tubulin RNAs changes during regeneration. Stability changes include both an apparent stabilization during regeneration and accelerated decay following regeneration.     

Phospholipid Synthesis in Sindbis Virus-Infected Cells

We investigated the metabolic requirements for the decrease in phospholipid synthesis previously observed by Pfefferkorn and Hunter in primary cultures of chick embryo fibroblasts infected with Sindbis virus. The incorporation of (32)PO(4) into all classes of phospholipids was found to decline at the same rate and to the same extent; thus, incorporation of (14)C-choline into acid-precipitable form provided a convenient measure of phospholipid synthesis that was used in subsequent experiments. Experiments with temperature-sensitive mutants suggested that some viral ribonucleic acid (RNA) synthesis was essential for the inhibition of choline incorporation, but that functional viral structural proteins were not required. The reduction in phospholipid synthesis was probably a secondary effect of infection resulting from viral inhibition of the cellular RNA and protein synthesis. All three inhibitory effects required about the same amount of viral RNA synthesis; the inhibition of host RNA and protein synthesis began sooner than the decline in phospholipid synthesis; and both actinomycin D and cycloheximide inhibited (14)C-choline incorporation in uninfected cells. In contrast, incorporation of (14)C-choline into BHK-21 cells was not decreased by 10 hr of exposure to actinomycin D and declined only slowly after cycloheximide treatment. Growth of Sindbis virus in BHK cells did not cause the marked stimulation of phospholipid synthesis seen in picornavirus infections of other mammalian cells; however, inhibition was seen only late in infection.     

Tubulin synthesis in a temperature-sensitive mutant of Chlamydomonas reinhardii

A temperature-sensitive mutant (TSF-1) of Chlamydomonas reinhardii which exhibits altered regulation of tubulin synthesis has been isolated. This mutant grows equally well at permissive (25 °C) and non-permissive (36 °C) temperatures but possesses flagella only at 25 °C. As with wild-type cells, when flagella are detached by ‘pH shock’ at 25 °C there is a rapid regeneration of flagella and a marked induction of tubulin synthesis, the major flagellar protein. However, if flagella are removed at 25 °C and the cells immediately placed at 36 °C, there is little or no flagellar regeneration or tubulin induction. If these flagella-less cells are maintained at 36 °C and subsequently shifted back to 25 °C, there is a rapid initiation of both flagellar outgrowth and tubulin synthesis.An additional temperature-sensitive phenotype exhibited by TSF-1 when shifted from 25 to 36 °C is a spontaneous detachment of flagella. Associated with the loss of flagella is limited (but perhaps repeated) flagellar regeneration and a marked increase in tubulin synthesis. Interestingly, ‘pH shock’ treatment at 30 or 60 min after the shift to 36 °C results in a rapid de-induction of tubulin synthesis. This complements the observation that flagellar excision by ‘pH shock’ just prior to a shift to 36 °C results in little or no tubulin induction. Taken together these results suggest that two independent pathways for tubulin induction may be operable in TSF-1.The short response times observed in both the shift-up and shift-down experiments demonstrate that the conditional process involved responds very rapidly to both positive and negative temperature changes and, moreover, indicate that this process may be intimately associated with the regulation of both flagellar regeneration and flagellar tubulin synthesis.     

Use of Radioactive Antibodies for Characterizing Antigens and Application to the Study of Flagella Synthesis

A simple rapid immunochemical procedure has been developed which provides information about the qualitative and quantitative nature of antigens. It involves the use of purified radioactive ((125)I-labeled) antibodies. The amount of antibody bound to the antigen is determined by filtering the mixture through diethylaminoethyl (DEAE)-cellulose paper. All of the antigen, as well as the antibody complexed with it, is trapped on the paper, whereas free antibody is removed by repeated washing. This technique has been applied to the study of three immune systems, bovine serum albumin, Escherichia coli tryptophan synthetase B protein, and Bacillus subtilis flagella. The results obtained by the DEAE-antibody binding technique were comparable, in terms of sensitivity, specificity, and accuracy, to data obtained by microcomplement fixation and precipitin methods. The assay was used to measure the kinetics of flagella regeneration in B. subtilis.     

The breakdown of Tetrahymena ribosomes in vivo. The effects of inhibitors.

1. When Tetrahymena were deprived of nutrients 50% of the polysomes disaggregated within 20 min and 20% of the total RNA broke down in 2 h. Ribosomal RNA accounted for 75% of the RNA breakdown. 2. RNA labelled by a long incubation with [14C]uridine was stable in growing cells and in the presence of actinomycin D, but broke down at the same rate as bulk RNA in starved cells. 3. The following substances inhibited the loss of RNA during starvation: cycloheximide (which inhibited both polysome disaggregation and protein synthesis), inhibitors of energy metabolism and puromycin (all of which caused polysome disaggregation and inhibited protein synthesis), and chloroquine and 7-amino-1-chloro-3-L-tosylamidoheptan-2-one ('TLCK') (neither of which affected polysomes or protein synthesis). 4. Starvation appears to activate a ribosome degradation mechanism that may involve lysosomal and non-lysosomal enzymes.     

Regulation of Herpesvirus Macromolecular Synthesis I. Cascade Regulation of the Synthesis of Three Groups of Viral Proteins

Based on evidence that 50% of herpes simplex 1 DNA is transcribed in HEp-2 cells in the absence of protein synthesis we examined the order and rates of synthesis of viral polypeptides in infected cells after reversal of cycloheximide- or puromycin-mediated inhibition of protein synthesis. These experiments showed that viral polypeptides formed three sequentially synthesized, coordinately regulated groups designated alpha, beta, and gamma. Specifically: (i) The alpha group, containing one minor structural and several nonstructural polypeptides, was synthesized at highest rates from 3 to 4 h postinfection in untreated cells and at diminishing rates thereafter. The beta group, also containing minor structural and nonstructural polypeptides, was synthesized at highest rates from 5 to 7 h and at decreasing rates thereafter. The gamma group containing major structural polypeptides was synthesized at increasing rates until at least 12 h postinfection. (ii) The synthesis of alpha polypeptides did not require prior infected cell protein synthesis. In contrast, the synthesis of beta polypeptides required both prior alpha polypeptide synthesis as well as new RNA synthesis, since the addition of actinomycin D immediately after removal of cycloheximide precluded beta polypeptide synthesis. The function supplied by the alpha polypeptides was stable since interruption of protein synthesis after alpha polypeptide synthesis began and before beta polypeptides were made did not prevent the immediate synthesis of beta polypeptides once the drug was withdrawn. The requirement of gamma polypeptide synthesis for prior synthesis of beta polypeptides seemed to be similar to that of beta polypeptides for prior synthesis of the alpha group. (iii) The rates of synthesis of alpha polypeptides were highest immediately after removal of cycloheximide and declined thereafter concomitant with the initiation of beta polypeptide synthesis; this decline in alpha polypeptide synthesis was less rapid in the presence of actinomycin D which prevented the appearance of beta and gamma polypeptides. The decrease in rates of synthesis of beta polypeptides normally occurring after 7 h postinfection was also less rapid in the presence of actinomycin D than in its absence, whereas ongoing synthesis of gamma polypeptides at this time was rapidly reduced by actinomycin D. (iv) Inhibitors of DNA synthesis (cytosine arabinoside or hydroxyurea) did not prevent the synthesis of alpha, beta, or gamma polypeptides, but did reduce the amounts of gamma polypeptides made.