Haloperidol binding to monoclonal antibodies. Predictions of three-dimensional combining site structure via computer modeling

The amino acid sequences of five monoclonal antibodies (designated mAbs A-E) which bind to the dopaminergic D-2 antagonist, haloperidol, with a variety of affinities (Kd = 4-810 nM), have been used to build theoretical, three-dimensional, computer models of the variable region combining sites. Physiocochemical interactions which have been previously determined from in vitro binding data have been used to orient the drug molecule within the combining site model. The results indicate that hydrophobic, aromatic, and ionic amino acids are involved in specific interactions with the antagonist molecule. For example, fluorescence quenching data suggests that a tryptophan residue is intimately involved in the binding of haloperidol by mAb A. Examination of the modeled structure reveals five tryptophans within the variable fragment, only one of which (H-50) is within the classical beta-barrel binding pocket and is readily accessible to the antigen. Haloperidol's relatively electron poor fluorophenyl ring system stacks with the electron-rich tryptophan ring system at a distance of 3.3 A and in so doing, places haloperidol's positively charged piperidinyl nitrogen atom within hydrogen bond distance of the negatively charged Glu-95 and Asp-100A residues of the H3 loop (Glu-H-95 and Asp-H-100A). This type of analysis for each antibody provides an interesting profile of changes in amino acid composition and hypervariable loop length which markedly effect binding affinity and specificity for a series of proteins which have similar combining site.     

Rebound cue state following a single dose of haloperidol

It has been reported that chronic administration of haloperidol produces an amphetamine-like rebound cue state. The experiments reported here were designed to assess whether a similar rebound phenomenon would result from a single dose of haloperidol. Rats were trained to discriminate .5 mg/kg amphetamine from distilled water. Five groups were formed to allow testing of haloperidol's effect at 12, 18, 24, 30, and 36 hr postinjection. Each animal was given 0, .5, 1.0, and 1.5 mg/kg haloperidol at its appropriate injection time in a counterbalanced fashion with one week between each test. A shift in the dose-response function of amphetamine that occurred during these weeks, however, precluded appropriate analysis of haloperidol's effects. Given this result, a second experiment was conducted using a between-subjects design. Half of the animals were injected with 1 mg/kg haloperidol 23 hr prior to testing, whereas the others were injected with distilled water. When tested, the haloperidol group responded 33% of the time on the amphetamine-correct lever, whereas the control group responded at 20%. The observation of posthaloperidol rebound in the between-subjects study and the failure to find significant temporal patterns of rebound phenomena using a within-subjects design have both theoretical and methodological importance.     

The D2 dopamine receptor occupancy of risperidone and its relationship to extrapyramidal symptoms: A pet study

Risperidone is a recently introduced neuroleptic distinguished by a decreased incidence of extrapyramidal side effects (EPS). The mechanism of its low EPS is unclear. Since it has been shown that EPS is related to the level of D₂ receptor occupancy, we studied nine patients receiving 2–6 mg/day of risperidone using [¹¹C]-raclopride PET scans in order to determine the in vivo D₂ receptor binding characteristics of risperidone. The mean level of receptor occupancy was 66% at 2 mg; 73% at 4 mg; and 79% at 6 mg. Three patients, those with the highest receptor occupancies, exhibited mild EPS, though none required anitparkinsonian medications. Our results suggest that at doses of 4–6 mg the in vivo D₂ receptor occupancy of risperidone is similar to that of typical neuroleptics and higher than that of clozapine. This would suggest that the EPS benefits of risperidone cannot be explained by a low D₂ binding but may be related to its high 5-HT₂ affinity. However, the emergence of EPS at higher levels of D₂ receptor occupancy, in this study and in previous clinical trials, would suggest that risperidone's high 5-HT₂ affinity provides only a relative protection from EPS. and once the D₂ occupancy exceeds a certain threshold this ‘relative’ 5-HT₂-mediated protection from EPS may be lost.     

Relations between extraction protocols for activated sludge extracellular polymeric substances (EPS) and complexation properties of Pb and Cd with EPS: Part II. Consequences of EPS extraction methods on Pb2+ and Cd2+ complexation

To study the effect of extraction protocols on extracellular polymeric substances (EPS) metal binding ability, EPS from two activated sludges were extracted by eight extraction protocols: three chemical treatments, four physical treatments and a control. Two pK_a, for each EPS, were determined: pK_a1 may be specific for carboxyl and phosphoric and pK_a2 may be attributed to phenolic and amino functional groups according to EPS composition and IR spectra. EPS pK_a values could be affected by the presence of extraction reagents and/or the modifications of EPS by extraction reagents.Complexation study performed at pH 7 by a polarographic method has always showed a greater affinity of EPS for Pb²⁺ than for Cd²⁺. The complexation properties of EPS extracted by chemical methods were greatly modified. Concerning EPS extracted by physical methods, their complexation properties were close except for EPS obtained by heating. Standardized extraction methods must be established as a function of the aims of the EPS study.     

Haloperidol: towards further understanding of the structural contributions of its pharmacophoric elements at D2-like receptors

An attempt to understand the pharmacophore-relevant position of the alcoholic moiety in haloperidol and the contributions of other pharmacophoric elements led to the re-synthesis of its tropane analogue (compound 2). An analysis of the binding data suggests that haloperidol binds to the DA receptors with the OH group in the axial position and the OH group, while not essential for binding, enhances binding especially at the D2 receptor. It also became clear that shortening the butyrophenone chain not only reduces binding affinity at the DA receptors but eliminates subtype selectivity.     

Metal binding capabilities of Rhizobium etli and its extracellular polymeric substances

Extracellular polymeric substances (EPS) produced from a strain of Rhizobium etli demonstrated an ability to bind a variety of metals. Cells and capsular EPS rapidly bound Mn²⁺ ions preferentially to Pb²⁺ and Cu²⁺, but also showed an affinity for Pb²⁺. The binding capabilities of soluble EPS were affected by its extraction and processing. The results suggest potential applications in the field of bioremediation.     

Chronic haloperidol increases voltage-gated Na currents in mouse cortical neurons

Typical antipsychotics are characterized by extrapyramidal syndrome (EPS). Previous studies demonstrated that typical antipsychotics could inhibit neuronal voltage-gated sodium channel (VGSC). However, EPS typically emerge only upon prolonged exposure. As a result, we examined effects of haloperidol, a prototype typical antipsychotic, on neuronal VGSC upon incubation for varying duration. Briefly, VGSC currents were activated and recorded using a whole-cell patch-clamp technique in primary culture of mouse cortical neurons. VGSC activity was inhibited by acute haloperidol exposure (for minutes), but enhanced in a time- and concentration-dependent manner by chronic haloperidol exposure (for hours). The effects of chronic haloperidol were associated with increased expression of VGSC subunits as well as corresponding electrophysiological channel properties. In summary, we found enhanced VGSC currents upon chronic haloperidol exposure in cortical neurons in contrast to inhibition by acute haloperidol exposure. Such a results may contribute to EPS of typical antipsychotics.     

Engineered streptavidin monomer and dimer with improved stability and function

Although streptavidin's high affinity for biotin has made it a widely used and studied binding protein and labeling tool, its tetrameric structure may interfere with some assays. A streptavidin mutant with a simpler quaternary structure would demonstrate a molecular-level understanding of its structural organization and lead to the development of a novel molecular reagent. However, modulating the tetrameric structure without disrupting biotin binding has been extremely difficult. In this study, we describe the design of a stable monomer that binds biotin both in vitro and in vivo. To this end, we constructed and characterized monomers containing rationally designed mutations. The mutations improved the stability of the monomer (increase in T(m) from 31 to 47 °C) as well as its affinity (increase in K(d) from 123 to 38 nM). We also used the stability-improved monomer to construct a dimer consisting of two streptavidin subunits that interact across the dimer-dimer interface, which we call the A/D dimer. The biotin binding pocket is conserved between the tetramer and the A/D dimer, and therefore, the dimer is expected to have a significantly higher affinity than the monomer. The affinity of the dimer (K(d) = 17 nM) is higher than that of the monomer but is still many orders of magnitude lower than that of the wild-type tetramer, which suggests there are other factors important for high-affinity biotin binding. We show that the engineered streptavidin monomer and dimer can selectively bind biotinylated targets in vivo by labeling the cells displaying biotinylated receptors. Therefore, the designed mutants may be useful in novel applications as well as in future studies in elucidating the role of oligomerization in streptavidin function.     

Further evaluation of the tropane analogs of haloperidol

Previous work from our labs has indicated that a tropane analog of haloperidol with potent D₂ binding but designed to avoid the formation of MPP⁺-like metabolites, such as 4-(4-chlorophenyl)-1-(4-(4-fluorophenyl)-4-oxobutyl)pyridin-1-ium (BCPP⁺) still produced catalepsy, suggesting a strong role for the D₂ receptor in the production of catalepsy in rats, and hence EPS in humans. This study tested the hypothesis that further modifications of the tropane analog to produce compounds with less potent binding to the D₂ receptor than haloperidol, would produce less catalepsy. These tests have now revealed that while haloperidol produced maximum catalepsy, these compounds produced moderate to low levels of catalepsy. Compound 9, with the least binding affinity to the D₂R, produced the least catalepsy and highest Minimum Adverse Effective Dose (MAED) of the analogs tested regardless of their affinities at other receptors including the 5-HT_1AR. These observations support the hypothesis that moderation of the D₂ binding of the tropane analogs could reduce catalepsy potential in rats and consequently EPS in man.     

Epitope mapping of monoclonal antibody to integrin alphaL beta2 hybrid domain suggests different requirements of affinity states for intercellular adhesion molecules (ICAM)-1 and ICAM-3 binding

Integrin undergoes different activation states by changing its quaternary conformation. The integrin beta hybrid domain acts as a lever for the transmission of activation signal. The displacement of the hybrid domain can serve to report different integrin activation states. The monoclonal antibody (mAb) MEM148 is a reporter antibody that recognizes Mg/EGTA-activated but not resting integrin alpha(L) beta2. Herein, we mapped its epitope to the critical residue Pro374 located on the inner face of the beta2 hybrid domain. Integrin alpha(L) beta2 binds to its ligands ICAM-1 and ICAM-3 with different affinities. Integrin is proposed to have at least three affinity states, and the position of the hybrid domain differs in each. We made use of the property of mAb MEM148 to analyze and correlate these affinity states in regard to alpha(L) beta2/intercellular adhesion molecule (ICAM) binding. Our study showed that Mg/EGTA-activated alpha(L)beta2 can adopt a different conformation from that activated by activating mAbs KIM185 or MEM48. Unlike ICAM-1 binding, which required only one activating agent, alpha(L) beta2/ICAM-3 binding required both Mg/EGTA and an activating mAb. This suggests that alpha(L)beta2 with intermediate affinity is sufficient to bind ICAM-1 but not ICAM-3, which requires a high affinity state. Furthermore, we showed that the conformation adopted by alpha(L)beta2 in the presence of Mg/EGTA, depicting an intermediate activation state, could be reverted to its resting conformation.     

Immunologic and physicochemical evidence for conformational changes occurring on conversion of human mast cell tryptase from active tetramer to inactive monomer. Production of monoclonal antibodies recognizing active tryptase

The catalytic activity of human tryptase, a mast cell neutral endoprotease, is expressed when the enzyme is in its tetrameric form, but is lost under physiologic conditions concomitant with a quaternary structural alteration involving conversion to a monomeric form. The associated changes in the CD spectra noted in the current study indicate accompanying alterations in the secondary structure of the protein. In particular, the progressive disappearance of the negative minimum centered at 228 nm suggests an effect on beta-sheet structure, which may be important for monomer-monomer interaction and/or stabilization of catalytic activity. Dextran sulfate, like heparin, stabilizes the catalytic activity and quaternary structure of tryptase and also maintains the native secondary structure of the enzyme at and beyond a temperature of 40 degrees C. Dextran sulfate-stabilized tryptase therefore was used as an immunogen to which were produced three murine mAb (B2, C11, and G4) recognizing the catalytically active form of the enzyme. Inactive tryptase bound to plastic microtiter wells was not recognized by any of the newly made antibodies, whereas inactive tryptase in solution was recognized by G4, which when biotinylated, could be used as a detector antibody in a sandwich ELISA for tryptase. Each of the newly made mAb recognized the catalytically active form of tryptase. Thus, alterations in epitopes, perhaps reflecting tertiary structural alterations as well as changes in secondary and quaternary conformations, occur with tryptase inactivation. A pragmatic result of these newly generated antibodies is the affinity purification to homogeneity of active tryptase by sequential chromatography with B2 coupled to CH-Sepharose and heparin-agarose. Tryptase purified by this technique had a specific activity with p-tosyl-L-arginine methyl ester of 117 +/- 9 U/mg and had 3.9 +/- 0.3 active sites per molecule of active enzyme (134,000 m.w.) as titrated with p-nitrophenyl-p'-guanidinobenzoate. The spectral and immunologic data in the current study are consistent with concerted conformational alterations in the secondary and tertiary as well as quaternary structures of tryptase associated with loss of catalytic activity. Failure to reverse any of these alterations with dextran sulfate suggests that the pathway of tetramer assembly in vivo is more complicated than simple subunit association.     

Quantitative response of cell growth and Tuber polysaccharides biosynthesis by medicinal mushroom Chinese truffle Tuber sinense to metal ion in culture medium

During the submerged fermentation of medicinal mushroom Chinese truffle Tuber sinense, there was no significant effect of metal ion on the cell growth and the production of intracellular polysaccharides, while metal ion and its concentration significantly affected the production of extracellular polysaccharides (EPS). By using the approach of "one-variable-at-a-time", 50 mM Mg2+ was identified to be the most favorable for EPS production, and the next was 10 mM K+. A mathematical model, constructed by response surface methodology combination with full factorial design, was applied to study the synergic effect of Mg2+ and K+. EPS production reached its peak value of 5.86 g/L under their optimal combination of 30 mM Mg2+ and 5 mM K+ predicted by the model, which was higher by 130.7% compared with the basal fermentation medium without metal ion. The validation experiment showed the experimental values agreed with the predicted values well. EPS production obtained in this work was the highest reported in the culture of T. sinense.     

Anti-idiotypes against a monoclonal anti-haloperidol antibody bind to dopamine receptor

Anti-idiotypic antibodies were raised in rabbits by immunization with a monoclonal anti-haloperidol antibody. Some of these anti-idiotypic antibodies bind in a concentration dependent manner to bovine striatal membranes. Following affinity purification, these antibodies inhibit haloperidol binding to striatal membranes and deplete [3H]-spiperone binding sites from a solubilized preparation of striatal membranes. It is thus concluded that these anti-idiotypic antibodies are an internal image of haloperidol and as such can interact with D2-dopamine receptors.     

CYP3A is responsible for N-dealkylation of haloperidol and bromperidol and oxidation of their reduced forms by human liver microsomes

We studied the biotransformation of haloperidol, bromperidol and their reduced forms by human liver microsomes. Nifedipine oxidation (CYP3A) activity correlated significantly with N-dealkylation rates of haloperidol and bromperidol and oxidation rates of their reduced forms, while neither ethoxyresorufin O-deethylation (CYP1A2) activity nor dextromethorphan O-deethylation (CYP2D6) activity did. In chemical and immunoinhibition studies, only troleandomycin and anti-CYP3A4 serum inhibited both formation rates of 4-fluorobenzoylpropionic acid, a metabolite of haloperidol and bromperidol, and back oxidation rates. Among 10 recombinant isoforms examined, only CYP3A4 showed catalytic activity. The Vmax and Km values of N-dealkylation of bromperidol and reoxidation of reduced bromperidol were similar to those of haloperidol and reduced haloperidol, respectively. The present study indicates that CYP3A plays a major role in N-dealkylation of and oxidation back to bromperidol as well as haloperidol and suggests that modification of in vivo CYP3A activity by inhibition or induction may affect the pharmacokinetics and therapeutic effects of haloperidol and bromperidol.     

Effects of cocaine alone and in combination with haloperidol and SCH 23390 on cardiovascular function in squirrel monkeys

The potential involvement of D1 and D2 dopamine receptors in the effects of cocaine on cardiovascular function in squirrel monkeys was evaluated. A low dose of cocaine (0.1 mg/kg i.v.) produced increases in both blood pressure and heart rate. At the higher doses of cocaine (1.0-3.0 mg/kg) the heart rate response was biphasic, consisting of an early decrease followed by an increase in heart rate 10-20 min following injection. The dopamine D2 antagonist haloperidol (0.1 mg/kg i.m.) attenuated the heart rate increasing effect of cocaine, but doses as high as 0.03 mg/kg did not alter the blood pressure increase. The D1 antagonist SCH 23390 (0.01-0.03 mg/kg i.m.) did not attenuate either the blood pressure or heart rate increasing effects of cocaine. The D2 agonist quinpirole (1.0 mg/kg i.v.) produced increases in heart rate similar to cocaine, with little effect on blood pressure. Although effective against the heart rate increasing effect of cocaine, haloperidol (0.01 mg/kg) did not antagonize the heart rate increasing effects of quinpirole. The D1 agonist SKF 38393 (3.0 mg/kg i.v.) decreased heart rate and increased blood pressure. The blood pressure increasing effect of SKF 38393 was antagonized by 0.01 mg/kg SCH 23390. Haloperidol's ability to partially antagonize the tachycardiac response to cocaine suggests the involvement of D2 receptors in that response. However, the failure of haloperidol to antagonize quinpirole's tachycardiac effect suggests that non-dopaminergic mechanisms may also be involved in haloperidol's antagonism of cocaine's tachycardiac effect. The pressor effects of cocaine do not appear to be controlled by selective dopamine receptors.     

Structural and functional characterization of HQL-79, an orally selective inhibitor of human hematopoietic prostaglandin D synthase

We determined the crystal structure of human hematopoietic prostaglandin (PG) D synthase (H-PGDS) as the quaternary complex with glutathione (GSH), Mg2+, and an inhibitor, HQL-79, having anti-inflammatory activities in vivo, at a 1.45-A resolution. In the quaternary complex, HQL-79 was found to reside within the catalytic cleft between Trp104 and GSH. HQL-79 was stabilized by interaction of a phenyl ring of its diphenyl group with Trp104 and by its piperidine group with GSH and Arg14 through water molecules, which form a network with hydrogen bonding and salt bridges linked to Mg2+. HQL-79 inhibited human H-PGDS competitively against the substrate PGH2 and non-competitively against GSH with Ki of 5 and 3 microm, respectively. Surface plasmon resonance analysis revealed that HQL-79 bound to H-PGDS with an affinity that was 12-fold higher in the presence of GSH and Mg2+ (Kd, 0.8 microm) than in their absence. Mutational studies revealed that Arg14 was important for the Mg2+-mediated increase in the binding affinity of H-PGDS for HQL-79, and that Trp104, Lys112, and Lys198 were important for maintaining the HQL-binding pocket. HQL-79 selectively inhibited PGD2 production by H-PGDS-expressing human megakaryocytes and rat mastocytoma cells with an IC50 value of about 100 microm but only marginally affected the production of other prostanoids, suggesting the tight functional engagement between H-PGDS and cyclooxygenase. Orally administered HQL-79 (30 mg/kg body weight) inhibited antigen-induced production of PGD2, without affecting the production of PGE2 and PGF2alpha, and ameliorated airway inflammation in wild-type and human H-PGDS-overexpressing mice. Knowledge about this structure of quaternary complex is useful for understanding the inhibitory mechanism of HQL-79 and should accelerate the structure-based development of novel anti-inflammatory drugs that inhibit PGD2 production specifically.     

Synthesis and characterization of selective dopamine D2 receptor antagonists

A series of indole compounds have been prepared and evaluated for affinity at D2-like dopamine receptors using stably transfected HEK cells expressing human D2, D3, or D4 dopamine receptors. These compounds share structural elements with the classical D2-like dopamine receptor antagonists, haloperidol, N-methylspiperone, and benperidol. The compounds that share structural elements with N-methylspiperone and benperidol bind non-selectively to the D2 and D3 dopamine receptor subtypes. However, several of the compounds structurally similar to haloperidol were found to (a) bind to the human D2 receptor subtype with nanomolar affinity, (b) be 10- to 100-fold selective for the human D2 receptor compared to the human D3 receptor, and (c) bind with low affinity to the human D4 dopamine receptor subtype. Binding at sigma (sigma) receptor subtypes, sigma1 and sigma2, were also examined and it was found that the position of the methoxy group on the indole was pivotal in both (a) D2 versus D3 receptor selectivity and (b) affinity at sigma1 receptors. Adenylyl cyclase studies indicate that our indole compounds with the greatest D2 receptor selectivity are neutral antagonists at human D2 dopamine receptor subtypes. With stably transfected HEK cells expressing human D2 (hD2-HEK), these compounds (a) have no intrinsic activity and (b) attenuated quinpirole inhibition of adenylyl cyclase. The D2 receptor selective compounds that have been identified represent unique pharmacological tools that have potential for use in studies on the relative contribution of the D2 dopamine receptor subtypes in physiological and behavioral situations where D2-like dopaminergic receptor involvement is indicated.     

Flocculation behavior and mechanism of an exopolysaccharide from the deep-sea psychrophilic bacterium Pseudoalteromonas sp. SM9913

Flocculation behavior and mechanism of the exopolysaccharide secreted by Pseudoalteromonas sp. SM9913 (EPS SM9913), a psychrophilic bacterium isolated from 1855m deep-sea sediment, has been studied in this paper. EPS SM9913 showed a peak flocculating activity of 49.3 in 1g/L kaolin suspension with 4.55mmol/L CaCl2 and the optimum pH range of 5-8. It appears that the flocculating activity of EPS SM9913 was stimulated by Ca2+ and Fe2+. This study found that EPS SM9913 showed a better flocculation performance than Al2(SO4)3 at salinity of 5-100 per thousand or temperatures of 5-15 degrees C. In addition, this EPS was effective to flocculate several other suspended solids. The measured zeta-potentials, the size of flocs formed during the flocculation process and the surface profile of flocs revealed by scan electron micrograph suggest that bridging is the main flocculation mechanism of the studied EPS. Deacetylation of EPS SM9913 resulted in a significant decrease in its flocculating activity indicating that the large number of acetyl groups in EPS SM9913 played an important role in its flocculation performance.     

Microbial influence on dolomite and authigenic clay mineralisation in dolocrete profiles of NW Australia

Dolomite (CaMg(CO₃)₂) precipitation is kinetically inhibited at surface temperatures and pressures. Experimental studies have demonstrated that microbial extracellular polymeric substances (EPS) as well as certain clay minerals may catalyse dolomite precipitation. However, the combined association of EPS with clay minerals and dolomite and their occurrence in the natural environment are not well documented. We investigated the mineral and textural associations within groundwater dolocrete profiles from arid northwest Australia. Microbial EPS is a site of nucleation for both dolomite and authigenic clay minerals in this Late Miocene to Pliocene dolocrete. Dolomite crystals are commonly encased in EPS alveolar structures, which have been mineralised by various clay minerals, including montmorillonite, trioctahedral smectite and palygorskite-sepiolite. Observations of microbial microstructures and their association with minerals resemble textures documented in various lacustrine and marine microbialites, indicating that similar mineralisation processes may have occurred to form these dolocretes. EPS may attract and bind cations that concentrate to form the initial particles for mineral nucleation. The dolomite developed as nanocrystals, likely via a disordered precursor, which coalesced to form larger micritic crystal aggregates and rhombic crystals. Spheroidal dolomite textures, commonly with hollow cores, are also present and may reflect the mineralisation of a biofilm surrounding coccoid bacterial cells. Dolomite formation within an Mg-clay matrix is also observed, more commonly within a shallow pedogenic horizon. The ability of the negatively charged surfaces of clay and EPS to bind and dewater Mg²⁺, as well as the slow diffusion of ions through a viscous clay or EPS matrix, may promote the incorporation of Mg²⁺ into the mineral and overcome the kinetic effects to allow disordered dolomite nucleation and its later growth. The results of this study show that the precipitation of clay and carbonate minerals in alkaline environments may be closely associated and can develop from the same initial amorphous Ca–Mg–Si-rich matrix within EPS. The abundance of EPS preserved within the profiles is evidence of past microbial activity. Local fluctuations in chemistry, such as small increases in alkalinity, associated with the degradation of EPS or microbial activity, were likely important for both clay and dolomite formation. Groundwater environments may be important and hitherto understudied settings for microbially influenced mineralisation and for low-temperature dolomite precipitation.     

Perturbation of ATP-induced tetramerization of human cytosolic thymidine kinase by substitution of serine-13 with aspartic acid at the mitotic phosphorylation site

Human cytosolic thymidine kinase (TK1) is tightly regulated in the cell cycle by multiple mechanisms. Our laboratory has previously shown that in mitotic-arrested cells human TK1 is phosphorylated at serine-13, accompanied by a decrease in catalytic efficiency. In this study we investigated whether serine-13 phosphorylation regulated TK1 activity and found that substitution of serine-13 with aspartic acid (S13D), which mimics phosphorylation, not only diminished the ATP-activating effect on the enzyme, but also decreased its thymidine substrate affinity. Our experimental results further showed that the S13D mutation perturbed ATP-induced tetramerization of TK1. Given that the dimeric form of TK1 is less active than the tetrameric, we propose that mitotic phosphorylation of serine-13 is of physiological importance, in that it may counteract ATP-dependent activation of TK1 by affecting its quaternary structure, thus attenuating its enzymatic function at the G2/M phase.