Temperature-shock induction of multiple flagella induces additional synthesis of flagellum specific mRNAs and tubulin

Four mRNAs (alpha- and beta-tubulin, flagellar calmodulin and Class-I), specifically expressed when Naegleria amebae differentiate into flagellates, were followed at 5-10 min intervals during the temperature-shock induction of multiple flagella in order to better understand how basal body and flagellum number are regulated. Surprisingly, tubulin synthesis continued during the 37 min temperature shock. An initial rapid decline in alpha- and beta-tubulin and flagellar calmodulin mRNAs was followed by a rapid re-accumulation of mRNAs before the temperature was lowered. mRNA levels continued to increase until they exceeded control levels by 4-21%. Temperature shock delayed flagella formation 37 min, produced twice as much tubulin protein synthesis and three fold more flagella. Labeling with an antibody against Naegleria centrin suggested that basal body formation was also delayed 30-40 min. An extended temperature shock demonstrated that lowering the temperature was not required for return of mRNAs to near control levels suggesting that induction of multiple flagella and the formation of flagella per se are affected in different ways. We suggest that temperature-shock induction of multiple flagella reflects increased mRNA accumulation combined with interference with the regulation of the recently reported microtubule-nucleating complex needed for basal body formation.     

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.     

Synthesis and assembly of the cytoskeleton of Naegleria gruberi flagellates

When Naegleria gruberi flagellates were extracted with nonionic detergent and stained by the indirect immunofluorescence method with AA-4.3 (a monoclonal antibody against Naegleria beta-tubulin), flagella and a network of cytoskeletal microtubules (CSMT) were seen. When Naegleria amebae were examined in the same way, no cytoplasmic tubulin-containing structures were seen. Formation of the flagellate cytoskeleton was followed during the differentiation of amebae into flagellates by staining cells with AA-4.3. The first tubulin containing structures were a few cytoplasmic microtubules that formed at the time amebae rounded up into spherical cells. The formation of these microtubules was followed by the appearance of basal bodies and flagella and then by the formation of the CSMT. The CSMT formed before the cells assumed the flagellate shape. In flagellate shaped cells the CSMT radiate from the base of the flagella and follow a curving path the full length of the cell. Protein synthetic requirements for the formation of CSMT were examined by transferring cells to cycloheximide at various times after initiation. One-half the population completed the protein synthesis essential for formation of CSMT 61 min after initiation of the differentiation. This is 10 min after the time when protein synthesis for formation of flagella is completed and 10-15 min before the time when the protein synthesis necessary for formation of the flagellate shape is completed.     

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.     

Rapid disappearance of translatable actin mRNA during cell differentiation in Naegleria

Actin, the major protein of Naegleria gruberi, is selectively not synthesized during the differentiation of amebae to flagellates. When RNA extracted from cells at intervals during differentiation is translated in the wheat germ cell-free system, a major translation product with the electrophoretic mobility of actin is seen to disappear with time during differentiation. This translation product is shown to be actin by its electrophoretic mobility, copolymerization with rabbit actin, peptide map, and immunoprecipitation by antibodies specific to Naegleria actin. Multiple isoforms of actin are synthesized in the cell-free system. Quantitative immunoprecipitation of translation products was employed to measure the relative amount of actin mRNA. Translatable actin mRNA begins to decrease in abundance within 7 min after the initiation of differentiation and thereafter decreases with a half-life of about 25 min. The selective disappearance of this major translatable mRNA provides a favorable opportunity to dissect the rules governing the half-life of a specific mRNA.     

New poly(A)+RNAs appear coordinately during the differentiation of Naegleria gruberi amebae into flagellates

We have examined the nature of the requirement for RNA synthesis during the differentiation of Naegleria gruberi amebae into flagellates (Fulton, C., and C. Walsh, 1980, J. Cell Biol., 85:346-360) by looking for poly(A)+RNAs that are specific to differentiating cells. A cDNA library prepared from poly(A)+RNA extracted from cells 40 min after initiation of the differentiation (40-min RNA), the time when formation of flagella becomes insensitive to inhibitors of RNA synthesis, was cloned into pBR322. Recombinant clones were screened for sequences that were complementary to 40-min RNA but not to RNA from amebae (0-min RNA). Ten of these differentiation-specific (DS) plasmids were identified. The DS plasmids were found to represent at least four different poly(A)+RNAs based on cross-hybridization, restriction mapping, and Northern blot analysis. Dot blot analysis was used to quantify changes in DS RNA concentration. The four DS RNAs appeared coordinately during the differentiation. They were first detectable at 10-15 min after initiation, reached a peak at 70 min as flagella formed, and then declined to low levels by 120 min when flagella reached full length. The concentration of the DS RNAs was found to be at least 20-fold higher in cells at 70 min than in amebae. The changes in DS RNA concentration closely parallel changes in tubulin mRNA as measured by in vitro translation (Lai, E.Y., C. Walsh, D. Wardell, and C. Fulton, 1979, Cell, 17:867-878).     

Sequential regulation of developmental events during polar morphogenesis in Caulobacter crescentus: assembly of pili on swarmer cells requires cell separation.

Pili, along with the flagellum and DNA bacteriophage receptors, are structural markers for polar morphogenesis in Caulobacter crescentus. Pili act as primary receptors for a number of small, C. crescentus-specific DNA and RNA bacteriophages, and the timing of pilus-dependent adsorption of bacteriophage phiCb5 in synchronized cell populations has led to the general conclusion that pili are formed coordinately with the flagellum and other polar surface structures in the predivisional cell. The use of rotary platinum shadow casting and electron microscopy as a direct assay for formation of flagella and pili in synchronous cell cultures now shows, however, that when expressed as fractions of the swarmer cell cycle, flagella are assembled on the predivisional cells at approximately 0.8 and that pili are assembled on the new swarmer cells at approximately 0.1 of the next cell cycle. Adsorption of pilus-specific bacteriophage phiCb5 prevented the loss of pili from swarmer cells during development, which suggests that these structures are retracted at the time of stalk formation. Examination of temperature-sensitive cell division mutants showed that the assembly of pili depends on completion of cell separation. These results indicate that the stage-specific events required for polar morphogenesis in C. crescentus occur sequentially, rather than coordinately in the cell cycle, and that the timing of these events reflects the order of underlying cell cycle steps.     

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.     

The Effects of Selected Chemical Agents on the Amoeba-Flagellate Transformation in Naegleria gruberi*

SYNOPSIS. Amoeboid Naegleria gruberi grown on an agar surface were induced to transform synchronously into flagellates by changing the pH of the environment from 3.8 to 7.2. Flagellates started to appear 70 min after stimulation, reached the 90% level within the next 30–40 min, and gradually reverted to the amoeboid form in the next several hrs. The presence of previously induced cells did not influence normal induction of transformation, indicating that no interaction took place during transformation. Inhibitors of oxidative phosphorylation (DNP and cyanide), of protein synthesis (puromycin and cycloheximide), and of RNA synthesis (actinomycin D), delayed or blocked the transformation, suggesting that RNA and protein synthesis are required. Because the flagellated stage is shortened by puromycin treatment, protein synthesis appears to be linked to the duration of the flagellated stage.     

Transformation in Naegleria gruberi: patterns of RNA synthesis examined by polyacrylamide gel electrophoresis

Naegleria gruberi were grown on bacteria and methods were devised to free the cellular RNA from bacterial RNA contamination. Use of actinomycin D and cycloheximide showed that the transformation of Naegleria from amoeba to flagellate required RNA synthesis for 30 min and protein synthesis for 40 min after the initial stimulus of distilled water. Comparison of the patterns of RNA synthesized during transformation with those during growth indicated a considerable amount of new RNA produced during the phenotypic change. Most marked was the increase in RNA co-migrating on polyacrylamide gels with the small ribosomal sub-unit RNA, together with RNAs between the latter and transfer RNA. These results were compared with other published results using axenically-grown cells cells and sucrose density gradient centrifugation. Cells placed in 80 mM NaCl instead of distilled water fail to transform but the pattern of newly-synthesized RNAs was not significantly different from that seen in transforming cells. This suggested that high salt concentrations inhibit transformation by inhibiting synthesis and/or assembly of certain proteins rather than RNA synthesis. Eluted material from various regions of polyacrylamide gels containing RNA extracted from transforming cells was used in a cell-free system. Incorporation of 3H-glutamic acid but not 3H-tryptophan was stimulated by material extracted from the 18S regions of the gels.