Quantitative Extraction of Adenosine Triphosphate from Cultivable and Host-Grown Microbes: Calculation of Adenosine Triphosphate Pools

Existing data on adenosine triphosphate (ATP) pools in microbes are deficient for two reasons: (i) incomplete extractions of ATP, and (ii) the failure to take into account that the adverse effects of extracting procedures on standard ATP exert analogous effects on the ATP released from bacterial cells. Methods for correcting observed yields and calculating ATP pools have been demonstrated. Three bacterial species were used in the studies on extraction of ATP: Escherichia coli, Mycobacterium phlei, and Mycobacterium lepraemurium. Perchloric acid and n-butanol were disqualified because of their failure to extract total bacterial ATP even from E. coli and because of inconvenient procedures. The new extraction procedure had minimal effects on standard ATP, liberated 100% of the ATP pools from the three representative species of microbes, and caused no ionic imbalance or quenching of bioluminescence. This method involves vortexing of cell suspensions for 10 s with 23% chloroform (vol/vol), heating at 98 C for the required time (E. coli, 3 min; M. phlei, 5 min; M. lepraemurium, 10 min) and then 1 min at 98 C with vacuum to dry the samples. Heat or chloroform alone may suffice for some microbes and release total ATP from plant and animal cells.     

The role of nucleoside-diphosphate kinase reactions in G protein activation of NADPH oxidase by guanine and adenine nucleotides

NADPH-oxidase-catalyzed superoxide (O2-) formation in membranes of HL-60 leukemic cells was activated by arachidonic acid in the presence of Mg2+ and HL-60 cytosol. The GTP analogues, guanosine 5'-[gamma-thio]triphosphate (GTP[gamma S] and guanosine 5'-[beta,gamma-imido]triphosphate, being potent activators of guanine-nucleotide-binding proteins (G proteins), stimulated O2- formation up to 3.5-fold. The adenine analogue of GTP[gamma S], adenosine 5'-[gamma-thio]triphosphate (ATP[gamma S]), which can serve as donor of thiophosphoryl groups in kinase-mediated reactions, stimulated O2- formation up to 2.5-fold, whereas the non-phosphorylating adenosine 5'-[beta,gamma-imido]triphosphate was inactive. The effect of ATP[gamma S] was half-maximal at a concentration of 2 microM, was observed in the absence of added GDP and occurred with a lag period two times longer than the one with GTP[gamma S]. HL-60 membranes exhibited nucleoside-diphosphate kinase activity, catalyzing the thiophosphorylation of GDP to GTP[gamma S] by ATP[gamma S]. GTP[gamma S] formation was half-maximal at a concentration of 3-4 microM ATP[gamma S] and was suppressed by removal of GDP by creatine kinase/creatine phosphate (CK/CP). The stimulatory effect of ATP[gamma S] on O2- formation was abolished by the nucleoside-diphosphate kinase inhibitor UDP. Mg2+ chelation with EDTA and removal of endogenous GDP by CK/CP abolished NADPH oxidase activation by ATP[gamma S] and considerably diminished stimulation by GTP[gamma S]. GTP[gamma S] also served as a thiophosphoryl group donor to GDP, with an even higher efficiency than ATP[gamma S]. Transthiophosphorylation of GDP to GTP[gamma S] was only partially inhibited by CK/CP. Our results suggest that NADPH oxidase is regulated by a G protein, which may be activated either by exchange of bound GDP by guanosine triphosphate or by thiophosphoryl group transfer to endogenous GDP by nucleoside-diphosphate kinase.     

Catalytic and regulatory site composition of yeast AMP deaminase by comparative binding and rate studies. Resolution of the cooperative mechanism

Yeast AMP deaminase is allosterically activated by ATP and MgATP and inhibited by GTP and PO4. The tetrameric enzyme binds 2 mol each of ATP, GTP, and PO4/subunit with Kd values of 8.4 +/- 4.0, 4.1 +/- 0.6, and 169 +/- 12 microM, respectively. At 0.7 M KCl, ATP binds to the enzyme, but no longer activates. Titration with coformycin 5'-monophosphate, a slow, tight-binding inhibitor, indicates a single catalytic site/subunit. ATP and GTP bind at regulatory sites distinct from the catalytic site and their binding is mutually exclusive. Inorganic phosphate competes poorly with ATP for the ATP sites (Kd = 20.1 +/- 4.1 mM). However, near-saturating ATP reduces the moles of phosphate bound per subunit to 1 PO4, which binds with a Kd = 275 +/- 22 microM. In the presence of ATP, PO4 cannot effectively compete with ATP for the nucleotide triphosphate sites. The PO4 which binds in the presence of ATP is competitive with AMP at the catalytic site since the Kd equals the kinetic inhibition constant for PO4. Initial reaction rate curves are a cooperative function of AMP concentration and activation by ATP is also cooperative. However, no cooperativity is observed in the binding of any of the regulator ligands and ATP binding and kinetic activation by ATP is independent of substrate analog concentration. Cooperativity in initial rate curves results, therefore, from altered rate constants for product formation from each (enzyme.substrate)n species and not from cooperative substrate binding. The traditional cooperative binding models of allosteric regulation do not apply to yeast AMP deaminase, which regulates catalytic activity by kinetic control of product formation. The data are used to estimate the rates of AMP hydrolysis under reported metabolite concentrations in yeast.     

Phospholipase C in human endometrial fibroblasts and its regulation by estrogens

1. Stimulated inositolphospholipid turnover has been proposed as a signal-transducing mechanism in many cell types. It appears to be initiated by stimulation of hydrolysis of inositolphospholipid by a phospholipase C. 2. In human endometrial fibroblasts, estradiol was observed to cause sequential enhancement of [32P]phosphate incorporation into phosphatidic acid (PA) and phosphatidylinositol (PI), indicating an accelerating effect of estradiol on inositolphospholipid turnover. Specific 32P-radioactivity in the gamma-phosphate of ATP was increased in response to estradiol. Estrone or estriol were without any effects. 3. To investigate possible mechanisms by which estradiol activates a phospholipase C enzyme in the fibroblasts, the plasma membrane fraction isolated from the fibroblasts was exposed to estradiol in the presence of guanosine triphosphate (GTP) to detect inositol trisphosphate (IP3) production. The IP3 production was Ca2+ dependent, a dependency not affected by estradiol. 4. However, ATP decreased the Ca2+ concentration required for IP3 production in a dose-dependent manner; adenosine diphosphate (ADP), cytidine triphosphate (CTP) showed no effects. 5. These findings from cell and cell-free systems might suggest that estradiol stimulates a phospholipase C, as a result of enhancement of intracellular ATP synthesis, but not as a result of a direct effect on the enzyme molecule or direct activation of receptor-phospholipase C unit. 6. This may give us new insight into estrogen-stimulated cellular phenomenon through some mechanisms other than that classically associated with the action of estrogen.     

A quantitative method for the measurement of cellular guanosine triphosphate pool specific activities

Studies on quantitation of RNA synthesis in eucaryotic cells have frequently used adenosine as the radioactively labeled precursor, largely because of the convenience of the firefly luciferin-luciferase assay in measuring ATP pool specific activity (1,2). This could result in some difficulties if the addition of poly(A) to the 3′ OH end of RNA represents a significant portion of total incorporation, as is the case in sea-urchin embryos (3). In addition, in some cases, the ATP pool may be large enough to prevent the use of adenosine as an effective labeling agent. Hence, a simple and sensitive method for the determination of the specific activity of the other nucleic acid precursor pools would be of value.Although the crystalline luciferase is specific for ATP, extracts of firefly lanterns most commonly used for quantitating ATP (4–9) also exhibit activity with other ribonucleoside triphosphates, adenosine tetraphosphate, ADP, and the deoxyribonucleoside triphosphates. This activity is due to the presence of contaminating enzymes such as nucleoside 5′-diphosphate kinase and adenylate kinase which catalyze the formation of ATP from these nucleotides and trace amounts of ADP, also present in the extracts (10–13). Recently, Manandhar and Van Dyke (14) have reported a procedure for quantitating picomole levels of GTP with a crude extract of firefly lanterns. In the present study, we have adapted their procedure to develop an assay for GTP pool specific activity in Xenopus laevis oocytes microinjected with [8-³H]GTP. Our assay may be extended to the analysis of any nucleoside triphosphate pool, provided that an adequate chromatography system is available for the separation of the extracted nucleotides.     

Interactions of GTP with the ATP-grasp domain of GTP-specific succinyl-CoA synthetase

Two isoforms of succinyl-CoA synthetase exist in mammals, one specific for ATP and the other for GTP. The GTP-specific form of pig succinyl-CoA synthetase has been crystallized in the presence of GTP and the structure determined to 2.1 A resolution. GTP is bound in the ATP-grasp domain, where interactions of the guanine base with a glutamine residue (Gln-20beta) and with backbone atoms provide the specificity. The gamma-phosphate interacts with the side chain of an arginine residue (Arg-54beta) and with backbone amide nitrogen atoms, leading to tight interactions between the gamma-phosphate and the protein. This contrasts with the structures of ATP bound to other members of the family of ATP-grasp proteins where the gamma-phosphate is exposed, free to react with the other substrate. To test if GDP would interact with GTP-specific succinyl-CoA synthetase in the same way that ADP interacts with other members of the family of ATP-grasp proteins, the structure of GDP bound to GTP-specific succinyl-CoA synthetase was also determined. A comparison of the conformations of GTP and GDP shows that the bases adopt the same position but that changes in conformation of the ribose moieties and the alpha- and beta-phosphates allow the gamma-phosphate to interact with the arginine residue and amide nitrogen atoms in GTP, while the beta-phosphate interacts with these residues in GDP. The complex of GTP with succinyl-CoA synthetase shows that the enzyme is able to protect GTP from hydrolysis when the active-site histidine residue is not in position to be phosphorylated.     

The pre-hydrolysis state of p21(ras) in complex with GTP: new insights into the role of water molecules in the GTP hydrolysis reaction of ras-like proteins

BACKGROUND: In numerous biological events the hydrolysis of guanine triphosphate (GTP) is a trigger to switch from the active to the inactive protein form. In spite of the availability of several high-resolution crystal structures, the details of the mechanism of nucleotide hydrolysis by GTPases are still unclear. This is partly because the structures of the proteins in their active states had to be determined in the presence of non-hydrolyzable GTP analogues (e.g. GppNHp). Knowledge of the structure of the true Michaelis complex might provide additional insights into the intrinsic protein hydrolysis mechanism of GTP and related nucleotides. RESULTS: The structure of the complex formed between p21(ras) and GTP has been determined by X-ray diffraction at 1.6 A using a combination of photolysis of an inactive GTP precursor (caged GTP) and rapid freezing (100K). The structure of this complex differs from that of p21(ras)-GppNHp (determined at 277K) with respect to the degree of order and conformation of the catalytic loop (loop 4 of the switch II region) and the positioning of water molecules around the gamma-phosphate group. The changes in the arrangement of water molecules were induced by the cryo-temperature technique. CONCLUSIONS: The results shed light on the function of Gln61 in the intrinsic GTP hydrolysis reaction. Furthermore, the possibility of a proton shuffling mechanism between two attacking water molecules and an oxygen of the gamma-phosphate group can be proposed for the basal GTPase mechanism, but arguments are presented that render this protonation mechanism unlikely for the GTPase activating protein (GAP)-activated GTPase.     

QM/MM modeling the Ras-GAP catalyzed hydrolysis of guanosine triphosphate

The mechanism of the hydrolysis reaction of guanosine triphosphate (GTP) by the protein complex Ras-GAP (p21(ras) - p120(GAP)) has been modeled by the quantum mechanical-molecular mechanical (QM/MM) and ab initio quantum calculations. Initial geometry configurations have been prompted by atomic coordinates of a structural analog (PDBID:1WQ1). It is shown that the minimum energy reaction path is consistent with an assumption of two-step chemical transformations. At the first stage, a unified motion of Arg789 of GAP, Gln61, Thr35 of Ras, and the lytic water molecule results in a substantial spatial separation of the gamma-phosphate group of GTP from the rest of the molecule (GDP). This phase of hydrolysis process proceeds through the low-barrier transition state TS1. At the second stage, Gln61 abstracts and releases protons within the subsystem including Gln61, the lytic water molecule and the gamma-phosphate group of GTP through the corresponding transition state TS2. Direct quantum calculations show that, in this particular environment, the reaction GTP + H(2)O --> GDP + H(2)PO(4) (-) can proceed with reasonable activation barriers of less than 15 kcal/mol at every stage. This conclusion leads to a better understanding of the anticatalytic effect of cancer-causing mutations of Ras, which has been debated in recent years.     

Isomerization couples chemistry in the ATP sulfurylase-GTPase system.

ATP sulfurylase catalyzes and couples the free energies of two reactions: GTP hydrolysis and the synthesis of activated sulfate, or APS. The GTPase active site undergoes changes during its catalytic cycle that are driven by events that occur at the APS-forming active site, which is located in a separate subunit. GTP responds to its changing environment by moving along its reaction path. The response, which may change the affinity or reactivity of GTP, can, in turn, produce alterations at the APS active site that drive APS synthesis. The resulting stepwise progression of the two reactions couples their free energies. The mechanism of ATP sulfurylase involves an enzyme isomerization that precedes and rate limits cleavage of the beta,gamma-bond of GTP. These fluorescence studies demonstrate that the isomerization is controlled by the binding of activators that drive ATP sulfurylase into forms that mimic different stages of the APS reaction. Only certain activators elicit the isomerization, suggesting that the APS reaction must proceed to a specific point in the catalytic cycle before the conformational "switch" that controls GTP hydrolysis is thrown. The isomerization is shown to require occupancy of the gamma-phosphate subsite of the GTP binding pocket. This requirement establishes that the isomerization results in a change in the interaction between the enzyme and the gamma-phosphate of GTP that emerges in the catalytic cycle during the transition from the nonisomerized to the isomerized E.GTP complex. The newly formed contact(s) appears to carry into the bond-breaking transition state, and to be essential for the enhanced affinity and reactivity of the nucleotide.     

Effect of wounding on nucleotide pools inBidens pilosa L.

Wounding both cotyledons ofBidens pilosa (var.radiatus) induces the inhibition of hypocotyl growth. The wound signal is transmitted very rapidly from cotyledon to hypocotyl and can be visualized by the change in nucleotide pools. First we have shown that the irradiance of the plant can change the ATP level without plant wounding. Therefore, plants were harvested at the start of the light period. Under these conditions, we have determined in hypocotyl the levels of adenosine triphosphate (ATP), guanosine triphosphate (GTP) and non adenylic triphosphates (NTP), and adenylate energy charge (AEC) after wounding. We have observed a transient (2 min) increase in the ATP level followed by a decrease 5 to 30 min later. A similar result was obtained for the GTP level but with some delay. The GTP level increased in 5 min and then decreased after 60 min. For the NTP level the decrease is effective from 5 to 60 min after wounding. The calculation of AEC has shown that a very tight control in the level of ATP may be involved in response to wounding.     

Identification of d-Erythro-Dihydroneopterin Triphosphate as a Product of Guanosine Triphosphate Cyclohydrolase from Serratia indica

Guanosine triphosphate cyclohydrolase (EC 3.5.4.16) was previously shown to exist in two forms (GTP cyclohydrolase D-I and D-II) in Serratia indica IFO 3759, and they were homogeneously isolated. The present study deals with the characterization of their reaction products. A fluorescent product formed from guanosine triphosphate by GTP cyclohydrolase D-II was identified as 7,8-dihydroneopterin triphosphate by its absorption spectra, phosphate analysis and gas chromatography-mass spectrometry of the dephosphorylated trimethylsilyl derivative. After oxidation and dephosphorylation, the d-erythro configuration of the side chain was made clear by the elution profile on ECTEOLA-cellulose chromatography, Rf values on thin-layer chromatography and by biological activity to Crithidia fasciculata ATCC 12857. The fluorescent products from GTP cyclohydrolase D-I and D-II were indistinguishable.     

A novel method for the synthesis of nucleoside triphosphates labelled with inorganic [32P]phosphate specifically in the beta-position.

A method was developed for the introduction of [32p]Pi specifically into the beta-position of ATP and GTP. The method is based on two separate reactions involving (a) phosphorolysis of poly(A) or poly(G) [Soreq, Nudel, Salomon, Revel & Littauer (1974) J. Mol Biol. 88, 233-245] in the presence of [32P]Pi and (b) conversion of the labelled diphosphate into the corresponding triphosphate by transferring the active phosphate group from 1,3-diphosphoglycerate in a coupled reaction as decribed by Glynn & Chappell [(1964) Biochem. J. 90, 147-149]. Radioactivity in the beta- and gamma-phosphate groups of the labelled triphosphate was measured by using polynucleotide kinase. No detectable radioactivity was found in the gamma-phosphate group. The suitability of this method for the synthesis of other nucleoside triphosphates specifically labelled in the beta-position is discussed.     

Invariance of the nucleoside triphosphate pools of Escherichia coli with growth rate

The ATP and GTP pools of Escherichia coli have recently been reported to increase approximately 10-fold with increasing growth rates in the range from 0.4 to 1.4 generations/hour (Gaal, T., Bartlett, M. S., Ross, W., Turnbough, C. L., and Gourse, R. L. (1997) Science 278, 2092-2097). Moreover, it was proposed that this variation of the nucleotide pools, particularly the ATP pool, might be responsible for the well known growth rate-dependent regulation of rRNA synthesis in E. coli. To test this hypothesis we have measured the nucleoside triphosphate pools as a function of growth rate for several E. coli strains. We found that the size of all four RNA precursor pools are essentially invariant with growth rate, in the range from 0.5 to 2.3 generations/hour. Nevertheless we observed the expected growth rate-dependent increase of RNA accumulation in these strains. In light of these results, it seems unlikely that nucleotide pool variations should be responsible for the growth rate-dependent regulation of rRNA synthesis.     

Effect of nucleotide cofactor structure on recA protein-promoted DNA pairing. 1. Three-strand exchange reaction.

The structurally related nucleoside triphosphates, adenosine triphosphate (ATP), purine riboside triphosphate (PTP), inosine triphosphate (ITP), and guanosine triphosphate (GTP), are all hydrolyzed by the recA protein with the same turnover number (17.5 min-1). The S0.5 values for these nucleotides increase progressively in the order ATP (45 microM), PTP (100 microM), ITP (300 microM), and GTP (750 microM). PTP, ITP, and GTP are each competitive inhibitors of recA protein-catalyzed ssDNA-dependent ATP hydrolysis, indicating that these nucleotides all compete for the same catalytic site on the recA protein. Despite these similarities, ATP and PTP function as cofactors for the recA protein-promoted three-strand exchange reaction, whereas ITP and GTP are inactive as cofactors. The strand exchange activity of the various nucleotides correlates directly with their ability to support the isomerization of the recA protein to a strand exchange-active conformational state. The mechanistic deficiency of ITP and GTP appears to arise as a consequence of the hydrolysis of these nucleotides to the corresponding nucleoside diphosphates, IDP and GDP. We speculate the nucleoside triphosphates with S0.5 values greater than 100 microM will be intrinsically unable to sustain the strand exchange-active conformational state of the recA protein during ongoing NTP hydrolysis and will therefore be inactive as cofactors for the strand exchange reaction.     

The Relation Between Adenosine Triphosphate and Microbial Biomass in Diverse Aquatic Ecosystems

By using autoradiographic examination of ¹⁴C labeled viable cells, natural phytoplankton communities were separated into living and non-living components. Comparisons of carbon to adenosine triphosphate (ATP) content of living cells yielded consistent ratios with depth, during periods of high and low nutrient supply at Lake Tahoe. Over time the ratio fluctuated by no more than ± 17% of the mean between the time of maximum nutrient supplies and nutrient depletion. The viability of specific phytoplankton groups was surprisingly low at times, indicating that conventional counting methods tend to overestimate live biomass. A survey of lakes differing in trophic states and having diverse phytoplankton and bacterial assemblages has shown that ATP measurements can be used as an accurate measure of total living microbial biomass.     

Selective high metabolic lability of uridine, guanosine and cytosine triphosphates in response to glucose deprivation and refeeding of untransformed and polyoma virus-transformed hamster fibroblasts.

Sugar deprivation of hamster fibroblasts (NIL) affected the steady state levels (pool sizes) of cellular acid soluble nucleotides in the folloing fashion: the pools of UTP, GTP and CTP decreased to a much greater extent than the cellular ATP pools, with the UTP pools undergoing the most dramatic reduction. Sugar deprivation of polyoma-transformed NIL cells (PyNIL) yielded even sharper decreases in the nucleoside triphosphate pools with relative changes similar to those of the untransformed cells. Inhibition of protein synthesis by cycloheximide, initiated at the onset of (and continued during) sugar deprivation, prevented the reduction in pool sizes and yielded values slightly higher than those observed for pool sizes in cells cultured in sugar-supplemented medium.Refeeding glucose to sugar-depleted hamster fibroblasts led to rapid increases (within 1 hour) in the UTP and CTP pools to levels well above the pool sizes observed in cells which were continuously cultured (16 hours) in sugar supplemented medium. Feeding NIL or PyNIL cells with fructose instead of glucose as the only hexose source did not appreciably affect any of the ribonucleoside triphosphate pool sizes. Measurements of hexose uptake by NIL and PyNIL cells under a variety of conditions suggest that hexose transport is not regulated by the total cellular pools of ATP or any of the other ribonucleoside triphosphates.     

Deoxythymidine sugars are not direct precursors of DNA-thymine.

A theoretical model for the kinetics of uptake of a putative precursor molecule into nucleotide pools and into replicating DNA has been developed. The relationship between the accumulation of radioactively labeled precursors in the pool and the appearance of radioactivity in DNA is then derived. Experiments have been carried out in bacteria to compare the uptake of radioactive thymine into deoxythymidine triphosphate, deoxythymidine diphosphate sugars, and DNA to test the suitability of either compound as the direct precursor of thymine in DNA. New one-dimensional, thin-layer chromatographic procedures were used to determine the specific activity of deoxythymidine triphosphate and deoxythymidine triphosphate and deoxythymidine diphosphate sugars in growing cultures of 32PO4-labeled Escherichia coli during pulse labeling with [3H]-thymine. A comparison of the experimental data with our theoretical model supports the hypothesis that deoxythymidine triphosphate, but not deoxythymidine sugar, is the direct precursor of thymine in normally replicating DNA in vivo.     

Fructokinases from developing maize kernels differ in their specificity for nucleoside triphosphates

A new form of fructokinase has been identified from developing maize (Zea mays L.) kernels that utilizes CTP, UTP, and GTP from four to eight times more effectively than ATP at nonlimiting concentrations. Ten millimolar dithiothreitol was necessary to stabilize activity. A second form of fructokinase was nonspecific for nucleoside triphosphate whereas a third form was fairly specific for ATP.     

Ring opening is not rate-limiting in the GTP cyclohydrolase I reaction

GTP cyclohydrolase I catalyzes a mechanistically complex ring expansion affording dihydroneopterin triphosphate and formate from GTP. Single turnover quenched flow experiments were performed with the recombinant enzyme from Escherichia coli. The consumption of GTP and the formation of 5-formylamino-6-ribosylamino-2-amino-4(3H)-pyrimidinone triphosphate, formate, and dihydroneopterin triphosphate were determined by high pressure liquid chromatography analysis. A kinetic model comprising three consecutive unimolecular steps was used for interpretations where the first intermediate, 5-formylamino-6-ribosylamino-2-amino-4(3H)-pyrimidinone 5'-triphosphate, was formed in a reversible reaction. The rate constant k(1) for the reversible opening of the imidazole ring of GTP was 0.9 s(-1), the rate constant k(3) for the release of formate from 5-formylamino-6-ribosylamino-2-amino-4(3H)-pyrimidinone triphosphate was 2.0 s(-1), and the rate constant k(4) for the formation of dihydroneopterin triphosphate was 0.03 s(-1). Thus, the hydrolytic opening of the imidazole ring of GTP is rapid by comparison with the overall reaction.     

Rapid in vitro assembly dynamics and subunit turnover of FtsZ demonstrated by fluorescence resonance energy transfer

We have developed an assay for the assembly of FtsZ based on fluorescence resonance energy transfer (FRET). We mutated an innocuous surface residue to cysteine and labeled separate pools with fluorescein (donor) and tetramethylrhodamine (acceptor). When the pools were mixed and GTP was added, assembly produced a FRET signal that was linearly proportional to FtsZ concentration from 0.7 microm (the critical concentration (C(c))) to 3 microm. At concentrations greater than 3 microm, an enhanced FRET signal was observed with both GTP and GDP, indicating additional assembly above this second C(c). This second C(c) varied with Mg(2+) concentration, whereas the 0.7 microm C(c) did not. We used the FRET assay to measure the kinetics of initial assembly by stopped flow. The data were fit by the simple kinetic model used previously: monomer activation, a weak dimer nucleus, and elongation, although with some differences in kinetic parameters from the L68W mutant. We then studied the rate of turnover at steady state by pre-assembling separate pools of donor and acceptor protofilaments. When the pools were mixed, a FRET signal developed with a half-time of 7 s, demonstrating a rapid and continuous disassembly and reassembly of protofilaments at steady state. This is comparable with the 9-s half-time for FtsZ turnover in vivo and the 8-s turnover time of GTP hydrolysis in vitro. Finally, we found that an excess of GDP caused disassembly of protofilaments with a half-time of 5 s. Our new data suggest that GDP does not exchange into intact protofilaments. Rather, our interpretation is that subunits are released following GTP hydrolysis, and then they exchange GDP for GTP and reassemble into new protofilaments, all on a time scale of 7 s. The mechanism may be related to the dynamic instability of microtubules.