Pharmacological and genetic evidence for a role of rootlet and phycoplast microtubules in the positioning and assembly of cleavage furrows in Chlamydomonas reinhardtii.

In Chlamydomonas reinhardtii, specialized cytoskeletal structures known as rootlet microtubules are present throughout interphase and mitosis. During cytokinesis, an array of microtubules termed the phycoplast is nucleated from rootlet microtubules and forms coincidentally with the cleavage furrow [Johnson and Porter, 1968: J. Cell Biol. 38:403-425; Holmes and Dutcher, 1989: J. Cell Sci. 94:273-285; Gaffel and el-Gammel, 1990: Protoplasma 156:139-148; Schibler and Huang, 1991: J. Cell Biol. 113:605-614]. We have obtained two independent lines of evidence that support the hypothesis that the rootlet and phycoplast microtubules play a direct role in cleavage furrow placement and assembly. First, the destabilization of spindle and phycoplast microtubules by pharmacological agents was accompanied by the aberrant distribution of actin and a failure of cytokinesis. Second, we characterized mutant strains that failed to complete cytokinesis properly. Actin and myosin were mislocalized to additional rootlet microtubules in the cyt2-1 strain, and this mislocalization was correlated with the presence of additional cleavage furrows. This evidence suggests that microtubules are necessary for the correct positioning and assembly of functional cleavage furrows in C. reinhardtii.

Loss of spatial control of the mitotic spindle apparatus in a Chlamydomonas reinhardtii mutant strain lacking basal bodies.

The bld2-1 mutation in the green alga Chlamydomonas reinhardtii is the only known mutation that results in the loss of centrioles/basal bodies and the loss of coordination between spindle position and cleavage furrow position during cell division. Based on several different assays, bld2-1 cells lack basal bodies in > 99% of cells. The stereotypical cytoskeletal morphology and precise positioning of the cleavage furrow observed in wild-type cells is disrupted in bld2-1 cells. The positions of the mitotic spindle and of the cleavage furrow are not correlated with respect to each other or with a specific cellular landmark during cell division in bld2-1 cells. Actin has a variable distribution during mitosis in bld2-1 cells, but this aberrant distribution is not correlated with the spindle positioning defect. In both wild-type and bld2-1 cells, the position of the cleavage furrow is coincident with a specialized set of microtubules found in green algae known as the rootlet microtubules. We propose that the rootlet microtubules perform the functions of astral microtubules and that functional centrioles are necessary for the organization of the cytoskeletal superstructure critical for correct spindle and cleavage furrow placement in Chlamydomonas.

The characteristics and effect on catalysis of nucleotide binding to noncatalytic sites of chloroplast F1-ATPase.

The recent finding that the presence of ATP at non-catalytic sites of chloroplast F1-ATPase (CF1) is necessary for ATPase activity (Milgrom, Y. M., Ehler, L. L., and Boyer, P. D. (1990) J. Biol. Chem. 265,18725-18728) prompted more detailed studies of the effect of noncatalytic site nucleotides on catalysis. CF1 containing at noncatalytic sites less than one ADP or about two ATP was prepared by heat activation in the absence of Mg2+ and in the presence of ADP or ATP, respectively. After removal of medium nucleotides, the CF1 preparations were used for measurement of the time course of nucleotide binding from 10 to 100 microM concentrations of 3H-labeled ADP, ATP, or GTP. The presence of Mg2+ strongly promotes the tight binding of ADP and ATP at noncatalytic sites. For example, the ADP-heat-activated enzyme in presence of 1 mM Mg2+ binds ADP with a rate constant of 0.5 x 10(6) M-1 min-1 to give an enzyme with two ADP at noncatalytic sites with a Kd of about 0.1 microM. Upon exposure to Mg2+ and ATP the vacant noncatalytic site binds an ATP rapidly and, as an ADP slowly dissociates, a second ATP binds. The binding correlates with an increase in the ATPase activity. In contrast the tight binding of [3H]GTP to noncatalytic sites gives an enzyme with no ATPase activity. The three noncatalytic sites differ in their binding properties. The noncatalytic site that remains vacant after the ADP-heat-activated CF1 is exposed to Mg2+ and ADP and that can bind ATP rapidly is designated as site A; the site that fills with ATP as ADP dissociates when this enzyme is exposed to Mg2+ and ATP is called site B, and the site to which ADP remains bound is called site C. Procedures are given for attaining CF1 with ADP at sites B and C, with GTP at sites A and/or B, and with ATP at sites A, B, and/or C, and catalytic activities of such preparations are measured. For example, little or no ATPase activity is found unless ATP is at site A, but ADP can remain at site C with no effect on ATPase. Maximal GTPase activity requires ATP at site A but about one-fifth of maximal GTPase is attained when GTP is at sites A and B and ATP at site C. Noncatalytic site occupancy can thus have profound effects on the ATPase and GTPase activities of CF1.

ATP binding at noncatalytic sites of soluble chloroplast F1-ATPase is required for expression of the enzyme activity.

The F1-ATPase from chloroplasts (CF1) lacks catalytic capacity for ATP hydrolysis if ATP is not bound at noncatalytic sites. CF1 heat activated in the presence of ADP, with less than one ADP and no ATP at non-catalytic sites, shows a pronounced lag in the onset of ATP hydrolysis after exposure to 5-20 microM ATP. The onset of activity correlates well with the binding of ATP at the last two of the three noncatalytic sites. The dependence of activity on the presence of ATP at non-catalytic sites is shown at relatively low or high free Mg2+ concentrations, with or without bicarbonate as an activating anion, and when the binding of ATP at noncatalytic sites is slowed 3-4-fold by sulfate. The latent CF1 activated by dithiothreitol also requires ATP at noncatalytic sites for ATPase activity. A similar requirement by other F1-ATPases and by ATP synthases seems plausible.

Guanosine and formycin triphosphates bind at non-catalytic nucleotide binding sites of CF1 ATPase and inhibit ATP hydrolysis.

Guanosine triphosphate and formycin triphosphate (FTP) in the presence of excess Mg2+ can bind to empty non-catalytic sites of spinach chloroplast ATPase (CF1). This results in a greatly reduced capacity for ATP hydrolysis compared to the enzyme with non-catalytic sites filled with ATP. With two GTP bound at non-catalytic sites the inhibition is about 90%; with two FTP bound about 80% inhibition is obtained. Binding and release of the nucleotides from the non-catalytic sites are relatively slow processes. Exposure of CF1 with one or two empty non-catalytic sites to 5-10 microM FTP or GTP for 15 min suffices for about 50% of the maximum inhibition. Reactivation of CF1 after exposure to higher FTP or GTP concentrations requires long exposure to 2 microM EDTA. The findings show that, contrary to previous assumptions, GTP can bind tightly to non-catalytic sites of CF1. They suggest that the presence of adenine nucleotides at non-catalytic sites might be essential for high catalytic capacity of the F1 ATPases.