Donald P. Weeks

Induction of microtubule protein synthesis in Chlamydomonas reinhardi during flagellar regeneration

Flagellar regeneration in gametes of Chlamydomonas reinhardi is initiated within 15-20 min after flagellar amputation and proceeds at a rapid but decelerating rate until by 90 min flagellar outgrowth in 80-85% complete. Sufficient flagellar protein reserves exist in the cytoplasm to allow regeneration of flagella 1/3-1/2 normal length. Nevertheless, in vivo labeling with 14C-amino acids shows that microtubule protein and other flagellar proteins are synthesized de novo during flagellar regeneration. To determine whether tubulin is synthesized continuously by gametic cells or whether its synthesis is induced as a consequence of deflagellation, we have isolated polyribosomes from deflagellated and control cells, and analyzed the proteins produced by these polyribosomes during in vitro translation. Two proteins of 53,000 and 56,000 molecular weight which co-migrate with flagellar and chick brain tubulin on SDS-polyacrylamide gels and which selectively co-assemble with chick brain tubulin during in vitro microtubule assembly are synthesized by polyribosomes (or polyadenylated mRNA) from deflagellated cells. No microtubule proteins can be detected in the translation products synthesized by polyribosomes (or mRNA) from control cells, clearly indicating that deflagellation results in the induction ot tubulin synthesis. Kinetics of tubulin synthesis demonstrate that induction takes place immediately after deflagellation; polyribosomes bearing tubulin mRNA can be detected in the cytoplasm in as little as 15 min after removal of flagella. Maximal rates of tubulin synthesis occur between 45 and 90 min after deflagellation when approximately 14% of the protein being synthesized by the cell is tubulin. This estimate of tubulin synthesis based on in vitro translation data agrees well with in vivo measurements of flagellar tubulin synthesis. While high levels of tubulin production extend well beyond the period of rapid flagellar assembly, synthesis begins to decline after 90 min, and by 180 min after deflagellation only low levels of tubulin mRNA are detectable in polyribosomes.

Preformed messenger of quiescent wheat embryos

Abstract A subcellular fraction (messenger fraction) which supports in vitro amino acid incorporation, has been isolated from dry wheat embryos. Analyses of the characteristics of messenger fraction directed amino acid incorporation (kinetics, nucleotide requirements, K+ and Mg2+ optima, and response to inhibitors) indicate that a ribosome-messenger attachment reaction is a prerequisite for messenger fraction activity. Direct demonstration of this reaction is provided by experiments in which messenger fraction is allowed to react in vitro with messenger-free ribosomes. Sucrose density gradient analysis of the reaction shows a progressive conversion of monoribosomes to functional polyribosomes. Upon storage at o° the activity of messenger fraction decays with a half-life of 12–13 h. Loss of activity is not due to ribonuclease as shown by complete stability of tobacco mosaic virus (TMV) RNA stored in the presence of messenger fraction. These data as well as experiments demonstrating the sensitivity of messenger fraction to low concentrations of pronase and N-ethyl maleimide suggest that a component other than RNA is necessary for messenger fraction activity and that the functional form of messenger fraction may be a ribonucleoprotein. The low level of template activity of purified messenger fraction RNA is consistent with this conclusion. In vivo studies show a rapid decrease in messenger fraction concomitant with polyribosome formation during early germination. These data suggest an important physiological role for messenger fraction in the initiation of protein synthesis which occurs at the outset of germination.

Induction and synthesis of tubulin during the cell cycle and life cycle of Chlamydomonas reinhardi

Abstract Two types of tubulin induction are observed in Chlamydomonas reinhardi . One is elicited by flagellar detachment and the other occurs as a normal event of the vegetative cell cycle. In the former case, a strong and extensive induction of tubulin synthesis occurs following deflagellation of cells in all phases of the life cycle [vegetative, gametic, and (early) zygotic]. Synthesis is initiated in all three cell types within 15 min after deflagellation. In gametic and zygotic cells, tubulin synthesis so induced accounts for 15 to 20% of the total protein synthesis during the 1-hr peak period of tubulin production. The ability to support both tubulin synthesis and flagellar regeneration is lost in zygotes at 1.5 hr after the initiation of zygotic development. This alteration represents one of several dramatic shifts in the programming of protein synthesis that occur during the first 4 hr of zygotic differentiation in C. reinhardi . The second (i.e., cell cycle-dependent) type of induction is observed in synchronously growing vegetative cells at ∼1.5–2 hr prior to cytokinesis. Tubulin synthesis, in this case, persists at relatively high levels (∼5% of the total protein synthesis) for the next 9 hr, i.e., through the entire period of cell division to a time just before the liberation of fully flagellated daughter cells at hr 20 of the cell cycle. Changes in the programming of protein synthesis, and of tubulin synthesis in particular, are discussed in relation to specific physiological and cytological transitions that occur during the growth and differentiation of C. reinhardi .

Tubulin induction in C. reinhardii: requirement for tubulin mRNA synthesis

Flagellar excision in Chlamydomonas reinhardii triggers a rapid and extensive induction of tubulin synthesis. Cloned plasmids, pFT beta 1 and pFT beta 2, carrying cDNA inserts complementary to beta-tubulin mRNA, have been prepared and used to demonstrate a direct requirement for tubulin mRNA synthesis during tubulin induction. Increased tubulin mRNA synthesis is detected within 5 min after deflagellation. During the 45 min peak period of tubulin synthesis, tubulin mRNA accumulates to levels 15- to 35-fold higher than those found in control (non-deflagellated) cells. In addition, there appears to be a direct correlation between tubulin mRNA concentrations and the levels of tubulin production during the induction and deinduction cycle that accompanies flagellar regeneration. Amiprophosmethyl (APM), a compound we reported earlier as a selective inhibitor of tubulin synthesis in deflagellated cells, is shown to block the accumulation of tubulin mRNA following flagellar excision and to cause the rapid loss of tubulin mRNA from cells treated at the peak of induction.

Tubulin synthesis in a temperature-sensitive mutant of Chlamydomonas reinhardii.

Abstract 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.