Inhibition of photophosphorylation by ATP and the role of magnesium in photophosphorylation.

ATP and pyrophosphate at high concentration (greater than 1 mM) inhibited photophosphorylation of isolated spinach chloroplasts in the normal salt medium and did not cause stimulation of electron transport. The inhibition of photophosphorylation by ATP or pyrophosphate was shown to be abolished by the addition of excess MgCl2, ADP and phosphate. It has been demonstrated that the rates of photophosphorylation in the absence and presence of ATP or pyrophosphate are determined similarly by the concentrations of magnesium-ADP (Mg - ADP-) and magnesiumphosphate (Mg - Pi) complexes. It is highly probable that Mg - ADP- and Mg - Pi, but not free ADP and free phosphate, are the active form of the substrates of photophosphorylation. This is in support of the view that ATP inhibits photophosphorylation by decreasing the concentration of Mg2+ which is available for the formation of the complex with ADP and phosphate.     

Inhibition of photophosphorylation by ATP and the role of magnesium in photophosphorylation

ATP and pyrophosphate at high concentration (> 1 mM) inhibited photophosphorylation of isolated spinach chloroplasts in the normal salt medium and did not cause stimulation of electron transport. The inhibition of photophosphorylation by ATP or pyrophosphate was shown to be abolished by the addition of excess MgCl₂, ADP and phosphate. It has been demonstrated that the rates of photophosphorylation in the absence and presence of ATP or pyrophosphate are determined similarly by the concentrations of magnesium-ADP (Mg · ADP^?) and magnesium-phosphate (Mg · P_i) complexes.It is highly probable that Mg · ADP^? and Mg · P_i, but not free ADP and free phosphate, are the active form of the substrates of photophosphorylation. This is in support of the view that ATP inhibits photophosphorylation by decreasing the concentration of Mg²⁺ which is available for the formation of the complex with ADP and phosphate.     

Factors affecting the ADP/O ratio in isolated chloroplasts.

(1) The effect of gradual disruption of the outer membrane of intact chloroplasts on CO2 fixation, electron transport and phosphorylation was investigated. The results suggested that whilst ferricyanide and substrate amounts of ADP enter intact chloroplasts only very slowly, methyl viologen rapidly penetrates the outer membrane. (2) Preparatwons of intact pea chloroplasts had an ATP-consuming reaction which resulted in decreased ADP/O ratios when noncyclic electron transport was measured after disruption of the outer membrane. The ATP-consuming reaction was removed into the supernatant after washing the disrupted chloroplasts. The resulting washed chloroplasts gave ADP/O ratios of 1.5-1.6 for ferricyanide and 1.9-2.0 for methyl viologen. (3) Preparations of intact spinach chloroplasts had lower activity of the ATP-consuming reaction and gave similar ADP/O ratios to washed pea chloroplasts. The ADP/O ratios of spinach chloroplasts did not alter significantly after washing. (4) An investigation of the effect of various assay conditions on the ADP/O ratio showed that the phosphate concentration was critical in obtaining optimal values for ADP/O ratio. Decreasing the phosphate concentration below 10 mM decreased the ADP/O ratio significantly. (5) It is suggested that the maximum ADP/O ratio of chloroplasts is 2.0 but that lower values can be obtained in the presence of an ATP-consuming reaction, under suboptimal assay conditions or where the chloroplasts are structurally damaged.     

Trypanosoma cruzi: infection of cultured human endothelial cells alters inositol phosphate synthesis

Infection of cultured endothelial cells with Trypanosoma cruzi alters intracellular Ca2+ homeostasis. To help understand the biochemical basis for this phenomenon, we determined the influence of infection on inositol phosphate formation in a broken cell preparation. Inositol phosphates participate in the regulation of cytosolic Ca2+. In uninfected endothelial cells, bradykinin guanosine 5'-O-thiophosphate (GTP tau S), and calcium all stimulated inositol phosphate (IP1), inositol bisphosphate (IP2), and inositol trisphosphate (IP3) formation within 5 sec of incubation. At longer periods of incubation with GTP tau S and bradykinin, formation of IP1 was linear for 30 sec, whereas the rate of IP2 and IP3 generation was maximal at 20 and 5 sec, respectively. Second, infection markedly changed these aspects of inositol phosphate generation. First, unstimulated (basal) levels of IP1 and IP3 were markedly increased over those levels in membranes of uninfected cells. Infection decreased the rate of formation for the three inositol phosphates in response to GTP tau S and bradykinin. Finally, infection diminished the magnitude of inositol phosphate synthesis in response to Ca2+ for IP1, IP2, and IP3, respectively. Studies on G proteins using cholera and pertussis toxin were carried out to determine if the infection-associated changes in inositol phosphate generation could be attributed to functional changes in these regulatory proteins known to participate in the activation of phospholipase C. Infection markedly decreased the magnitude of cholera and pertussis toxin-dependent ADP ribosylation, as compared to control uninfected cells. Incubation of uninfected endothelial cells with cholera and pertussis toxin also decreased the magnitude of cholera and pertussis toxin ADP ribosylation. Despite the similar effects of infection and toxin treatment on subsequent toxin-catalyzed ADP ribosylation, toxin treatment did not influence inositol phosphate generation. Collectively, these results demonstrate an influence of infection on receptor-dependent and -independent synthesis of inositol phosphates, possibly by an action on phospholipase C. The results help to explain the apparent infection-associated increase in basal Ca2+ previously observed and suggest that interference with signal transduction may be a consequence of the presence of the parasite.     

On the Mechanism of Respiratory Control

Control of oxidation is the key mechanism in the regulation of energy metabolism. In glycolysis the oxidation of glyceraldehyde-3-phosphate is controlled by DPNH, which inhibits glyceraldehyde-3-phosphate dehydrogenase. In oxidative phosphorylation the inhibition of electron flow from DPNH to oxygen, called "respiratory control," is the subject of this paper. After a discussion of the physiological significance of the "tight coupling" between phosphorylation and oxidation, studies on "loosely coupled" submitochondrial particles are reported. These particles are capable of oxidative phosphorylation in the presence of a suitable phosphate acceptor system, but in contrast to controlled, intact mitochondria they oxidize DPNH in the absence of phosphate and ADP. The addition of o-phenanthroline to submitochondrial particles gives rise to an inhibition of respiration, which is partly reversed by phosphate and ADP or by dinitrophenol. The properties of this model system of respiratory control will be described.     

The stimulation of the mitochondrial respiration by citrulline synthesis.

1. The influence of ammonia and ornithine on the oxygen uptake and the formation of citrulline was investigated with isolated rat liver mitochondria. The experiments were performed in a cytosol-like saline medium at 38 degrees C. 2. Under these conditions an increase of the respiration rate by ammonia and ornithine was observed, but a small response to external ADP, only. The missing stimulation by ADP was due to a partial inhibition of the respiratory chain by traces of zinc (approximately 1 microM) present in the medium. This inhibition was only detected at low concentrations of mitochondria. 3. For activation of respiration by ammonia plus ornithine two different processes were responsible: (i) chelation of the inhibiting zinc by ornithine, which could be prevented by EDTA; (ii) ADP production in the matrix space during formation of carbamoyl phosphate, which could be prevented by oligomycin but not by carboxyatractyloside. 4. This stimulus of the carbamoyl phosphate formation and of the equivalent citrulline synthesis on the mitochondrial respiration ran to 12% of that increase caused by phosphorylation of external ADP. The maximum rate of citrulline formation was limited by the activity of carbamoyl phosphate synthetase. 5. Added ADP suppresses the production of citrulline probably by the exchange of extramitochondrial ADP versus intramitochondrial ATP. The data suggest a common adenine nucleotide pool delivering ATP to the adenine nucleotide translocase as well as to the carbamoyl phosphate synthetase.     

The Coupling of Electron Flow to ATP Synthesis in Pea and Maize Mesophyll Chloroplasts : I. INTERACTION OF ADENINE NUCLEOTIDES AND ENERGY TRANSFER INHIBITORS WITH THE COUPLING FACTOR COMPLEX

The rate of nonphosphorylating electron transport (in the absence of ADP and inorganic phosphate) in well-coupled (ATP/2e⁻ = 0.9-1.1) maize mesophyll chloroplasts is not modulated by external pH (6.5-8.5), low levels of ADP or ATP, or energy transfer inhibitors, e.g. triphenyltin and Hg²⁺ ions. In contrast nonphosphorylating electron flow in pea chloroplasts is sensitive to alterations in medium pH, and to the presence of adenine nucleotides and energy transfer inhibitors in the assay medium. Although ATP is without effect on the rate of basal electron transport in maize chloroplasts, steady-state proton uptake is stimulated 3- to 5-fold by low levels of ATP. These results suggest that differences may exist in the manner in which the coupling factor complex controls proton efflux from the intrathylakoid space in C₃ and C₄ mesophyll chloroplasts.     

Influence of inorganic phosphate and pH on ATP utilization in fast and slow skeletal muscle fibers.

The influence of P(i) and pH was studied on myofibrillar ATP turnover and force development during maximally activated isometric contractions, in skinned single fibers from rabbit soleus and psoas muscle. ATP hydrolysis was coupled to the breakdown of NADH, which was monitored photometrically at 340 nm. In psoas the depression by phosphate of force is twice that of ATP turnover, but in soleus force and ATP turnover are depressed equally by P(i). Most, but not all, of the ATPase and force values observed for a combination of high P(i) and low pH could be explained by independent effects of P(i) and pH. The effects of P(i) and pH on ATP turnover can be understood by a three-state cross-bridge scheme. Mass action of phosphate on the reaction from the actomyosin(AM).ADP state to the AM.ADP.P(i) state may largely account for the phosphate dependencies of ATPase activity found. Protons affect cross-bridge detachment from the AM.ADP state and the rate of the AM.ADP.P(i)-to-AM.ADP transition. In this scheme, the effects of P(i) and pH on cross-bridge kinetics appeared to be largely independent.     

Heterotropic interactions of ligands with phosphorylase b.

1. The interaction of rabbit muscle glycogen phosphorylase b with pairs of ligands has been examined. 2. The electron spin resonance spectrum of a spin label, covalently attached to the protein, provided information about dissociation constants, formation of ternary complexes and both negative and positive interactions between different ligand pairs. 3. AMP competes with a series of nucleotides (ADP, ATP, CMP aand cytosine) but with adenosine a ternary enzyme - AMP - adenosine complex can be formed. 4. ADP binding is tight and ADP inhibits the AMP activation of phosphorylase b in a physiologically important concentration range. 5. The substrates glucose 1-phosphate and glycogen tighten AMP binding in the ternary complex as does the competitive inhibitor UDPG. Inorganic phosphate is different in this respect. Gluconolactone, a transition state analogue, competes with glucose 1-phosphate (but not with glycogen) but does not prevent completely the binding of the sugar phosphate. 6. The effect of glucose b-phosphate on phosphorylase is rather complex as it 'formally competes' with both AMP and UDPG probably mediated by a conformational changes and not by 'direct' interactions with these two ligands. Glycerol 2-phosphate, a commonly used buffer for phosphorylase, also shows complex interactions.     

Tightly bound nucleotides affect phosphate binding to mitochondrial F1-ATPase

The interaction of inorganic phosphate with native and nucleotide-depleted F1-ATPase was studied. F1-ATPase depleted of tightly bound nucleotides loses the ability to bind inorganic phosphate. The addition of ATP, ADP, GTP and GDP but not AMP, restores the phosphate binding. The nucleotides affecting the phosphate binding to F1-ATPase are located at the catalytic (exchangeable) site of the enzyme. The phosphate is thought to bind to the same catalytic site where the nucleotide is already bound. It is thought that ADP is the first substrate to bind to F1-ATPase in the ATP synthesis reaction.     

Electron paramagnetic resonance studies on nitrogenase. III. Function of magnesium adenosine 5′-triphosphate and adenosine 5′-diphosphate in catalysis by nitrogenase

The electron paramagnetic resonance spectra of azoferredoxin and molybdoferredoxin, components of the nitrogenase of Clostridium pasteurianum, disappear when the proteins are oxidized by certain dyes. When molybdoferredoxin and azoferredoxin were mixed in a 1 to 2 molar ratio, the electron paramagnetic resonance spectrum of the mixture was the sum of the two spectra with the exception of a slight change in the azoferredoxin signal. Addition of magnesium ATP and dithionite to this reconstituted nitrogenase resulted in a rapid change in the spectrum of both nitrogenase components; the molybdoferredoxin spectrum at all g-values decreased with a half-life less than 70 ms to 40% of its original size whereas the azoferredoxin signal changed in shape and size with a half-life of less than 40 ms. If an ATP-generating system was added instead of MgATP so that no ADP accumulated, then the molybdoferredoxin signal almost completely disappeared and the azoferredoxin signal changed in shape and slightly in size. These changes occurred at molar ratios of molybdoferredoxin to azoferredoxin from 1:14 to 1:0.2. If the reaction was allowed to consume the reductant, then the molybdoferredoxin signal(s) was restored but the azoferredoxin signal disappeared. The signal of azoferredoxin was restored and the signal of molybdoferredoxin again disappeared on addition of more reductant. The data suggest that for nitrogenase to catalyze the reduction of substrates, the magnesium ATP-reduced azoferredoxin complex is formed first and this complex then reacts with molybdoferredoxin to allow electron flow. In addition the data suggests that the rate-limiting reaction is an ATP-mediated electron flow from azoferredoxin to molybdoferredoxin. Finally the results show that no flow of electrons from azoferredoxin or molybdoferredoxin occurs when a mixture of ADP and ATP in a molar ratio of 2:1 is added initially or is reached by conversion of ATP to ADP and inorganic phosphate during reduction of protons. A mechanism consistent with these findings is proposed.     

Ca2+ ionophore A23187 and thrombin inhibit the pertussis-toxin-induced ADP-ribosylation of the alpha-subunit of the inhibitory guanine-nucleotide-binding protein and other proteins in human platelets

Inhibitory guanine-nucleotide-binding proteins (Gi proteins) are substrates for pertussis toxin and the decreased pertussis-toxin-dependent ADP ribosylation of Gi proteins upon prior specific hormonal stimulation of cells is thought to reflect the receptor-mediated activation of Gi proteins, leading to their subsequent dissociation into alpha i and beta/gamma subunits. In the present study, the effect of various platelet stimuli on the subsequent pertussis-toxin-dependent ADP ribosylation of the alpha subunit of Gi (Gi alpha) in saponized platelets and platelet membranes were studied. Stimulation of intact platelets with the Ca(2+)-ionophore A23187 or thrombin, but not phorbol 12,13-dibutyrate, decreased the subsequent pertussis-toxin-dependent ADP ribosylation of Gi alpha in saponin-permeabilized platelets in a time-dependent and dose-dependent manner. Thrombin was more effective than A23187. Parallel measurements of Ca2+ mobilization and pertussis-toxin-dependent ADP ribosylation of Gi alpha in platelets showed that Ca2+ mobilization could only partly account for the decrease in pertussis-toxin-dependent ADP ribosylation in platelets stimulated by thrombin. When the ADP-ribosylation reaction was carried out in platelet membranes, a decrease in ADP ribosylation was still observed after stimulation of platelets with thrombin, but not with A23187. In addition to Gi alpha, two other proteins were found to be ADP ribosylated by pertussis toxin; their ADP ribosylation was also decreased after A23187 and thrombin stimulation of platelets. The results indicate that Ca2+ mobilization can decrease the pertussis-toxin-dependent ADP ribosylation of Gi alpha in saponized platelets; the decrease of pertussis-toxin-dependent ADP ribosylation of Gi alpha after thrombin stimulation of platelets can only, in part, be explained by Ca2+ mobilization and involves additional mechanisms; the decrease in pertussis-toxin-dependent ADP ribosylation after A23187 and thrombin stimulation is not confined to G1 alpha and involves other proteins. We conclude that the decrease in pertussis-toxin-dependent ADP ribosylation of Gi in thrombin-stimulated platelets might not be solely caused by a specific structural change, such as dissociation of Gi. It is likely that A23187 and thrombin stimulation of platelets generates substances which interfere with the ADP-ribosylating activity of pertussis toxin.     

Detection of conformational changes in chloroplast coupling factor 1 by 8-anilino-1-naphthalene-sulphonate fluorescence changes

Chloroplast coupling factor 1 (CF1) contains a high-affinity binding site for 8-anilino-1-napthalene sulphonate (ANS,Kd = 5-6 microM). The binding of ANS to the enzyme is associated with a fluorescence enhancement and a blue-shift in the emission spectrum. ANS only slightly inhibits ATP hydrolysis by CF1. Adenine nucleotides and inorganic phosphate induce a fast ANS fluorescence quenching of about 50% which is due to a decrease in the affinity of the enzyme for ANS (Kd increases from 6 microM to 22 microM) and in the fluorescence quantum yield of the bound probe (by 33%) but not in the number of ANS sites (n = 1). Conversely, Mg and Ca ions induce a fluorescence enhancement of bound ANS. Inactivation of the enzyme enhances ANS fluorescence, eliminates the response to adenine nucleotides and inorganic phosphate but increases the response to divalent metals. The affinity of latent CF1 for ADP (Kd = 12 microM) is considerably higher than for ATP (Kd = 95 microM) in buffer containing EDTA. The Kd for inorganic phosphate is 140 microM. Mg increases the apparent affinity for ATP (Kd = 28 microM) but not for ADP or Pi. Binding of ATP to the tight-sites does not inhibit the ADP or Pi-induced fluorescence quenching but decreases the affinity for ADP (Kd = 34 microM) and for inorganic phosphate (Kd = 320 microM). These results suggest that the ADP and phosphate binding sites are different but not independent from the tight sites. Activation of a Mg-specific ATPase in CF1 by octyl glucoside decreases the affinity for ADP and inorganic phosphate by about threefold but increases the affinity for ATP. ATPase activation of CF1 also increases the Ki for ADP inhibition of ATP hydrolysis. ATPase activation also influences the ANS responses to Ca and Mg. Ca-ATPase activation increases the fluorescence enhancement and the apparent affinity for Ca whereas Mg-ATPase activation specifically increases the Mg-induced fluorescence enhancement. The fluorescence of CF1-bound ANS is enhanced by Dio-9 and quenched by phloridzin, quercetin, Nbf-Cl and FITC. Nbf-Cl and FITC completely inhibit the ADP-induced fluorescence quenching whereas Dio-9 inhibits the Mg-induced fluorescence enhancement. ANS does not relieve the quercetin or phloridzin inhibition of ATP hydrolysis indicating that these inhibitors do not compete with ANS for a common binding site. ANS may be used, therefore, as a sensitive probe to detect conformational changes in CF1 in response to activation or inactivation and to binding of substrates and of inhibitors.     

Study of the mitochondrial phosphate carrier in the course of calcium phosphate accumulation: A requirement for Mg2+ and ADP of its sensitivity to thiol reagents

1. The accumulation of calcium phosphate driven by succinate oxidation is ADP-dependent. In its absence the accumulation stops after a short incubation time and the oxygen uptake is permanently stimulated. This uncoupled oxygen uptake is insensitive to the inhibitors of phosphate transport, like mersalyl and N-ethylmaleimide. When ADP plus Mg²⁺ are added to the medium, or when ADP is added in the initial presence of magnesium, the inhibitory action of the thiol reagents on oxygen uptake is re-established. ADP alone or Mg²⁺ alone are without any effect.2. Phosphate/phosphate exchange has been studied, in the absence of ADP, when calcium phosphate accumulation had stopped and oxygen uptake is uncoupled. Under these conditions the exchange process becomes insensitive to thiol reagents. Sensitivity is recovered solely in the presence of ADP plus Mg²⁺.3. When mitochondrial swelling is studied according to the method of Chappell, it also appears that the phosphate carrier loses it sensitivity to mersalyl in the absence of ADP, which confirms the data obtained with phosphate/phosphate exchange experiments. When ADP plus Mg²⁺ are added (or present), together with mersalyl, the action of the thiol inhibitor is recovered. ADP and magnesium are inactive separately. EGTA plus Mg²⁺ (but not EGTA plus ADP) may substitute for ADP plus Mg²⁺ in this process.4. A possible interaction between the magnesium binding site and the phosphate carrier is considered and discussed.     

Induction of cell surface insulin antigenicity in fibroblasts transfected with islet genomic DNA

Intact platelets were stimulated with thrombin and the amount of GTP-binding protein (G-protein) oligomers was assessed by measuring ADP ribosylation of 40-41 kDa protein by pertussis toxin in isolated membranes. The toxin substrate fell by 57-62% in 10-60 s, but then returned towards normal over 5 min. Recovery was greatly enhanced by removal of thrombin from receptors with hirudin. Phorbol myristate acetate increased ADP-ribosylatable protein, but only back to initial levels prior to PMA. In contrast prostaglandin D2 plus theophylline (which increase cyclic AMP) did not increase ADP ribosylation, but could completely block the fall of the toxin substrate caused by thrombin. These results indicate that activation of thrombin receptors promotes the dissociation of G-protein oligomers to release free alpha-subunits, and this effect can be modulated by protein kinase C and cyclic AMP-dependent protein kinase. The possible relationships of these findings to the regulation of stimulus-response coupling in platelets is discussed.     

Helical order in tarantula thick filaments requires the "closed" conformation of the myosin head

Myosin heads are helically ordered on the thick filament surface in relaxed muscle. In mammalian and avian filaments this helical arrangement is dependent on temperature and it has been suggested that helical order is related to ATP hydrolysis by the heads. To test this hypothesis, we have used electron microscopy and image analysis to study the ability and temperature dependence of analogs of ATP and ADP.Pi to induce helical order in tarantula thick filaments. ATP or analogs were added to rigor myofibrils or purified thick filaments at 22 degrees C and 4 degrees C and the samples negatively stained. The ADP.Pi analogs ADP.AlF4 and ADP.Vi, and the ATP analogs ADP.BeFx, AMPPNP and ATPgammaNH2, all induced helical order in tarantula thick filaments, independent of temperature. In the absence of nucleotide, or in the presence of ADP or the ATP analog, ATPgammaS, there was no helical ordering. According to crystallographic and tryptophan fluorescence studies, all of these analogs, except ATPgammaS and ADP, induce the "closed" conformation of the myosin head (in which the gamma phosphate pocket is closed). We suggest that helical order requires the closed conformation of the myosin head but is not dependent on the hydrolysis of ATP.     

The effect of cholera toxin on the inhibition of vasopressin-stimulated inositol phospholipid hydrolysis is a cyclic AMP-mediated event at the level of receptor binding.

Incubation of L6 skeletal myoblasts for 16 h with cholera toxin but not with pertussis toxin, led to the inhibition of inositol phosphate generation induced by subsequent exposure to vasopressin. The effects of the toxin on inositol lipid metabolism were accompanied by the total ADP-ribosylation of the available cholera-toxin substrates within the cells. Immunological analysis demonstrated that the two polypeptides modified in vivo by cholera toxin were different forms of Gs alpha (alpha subunit of Gs). No novel cholera-toxin substrate(s) were detected. The cholera-toxin-mediated inhibition of vasopressin-stimulated inositol phosphate generation could be mimicked by both forskolin and dibutyryl cyclic AMP, but not by the separated subunits of the toxin. Receptor-binding studies demonstrated that the inhibition of agonist-stimulated inositol phosphate generation was accompanied by a decrease in cell-surface vasopressin-binding sites, with no effect on the affinity of these for the hormone. We suggest that the effect of cholera toxin and agents which increase intracellular cyclic AMP on vasopressin-stimulated inositol lipid hydrolysis is an effect on receptor number, and that there is no requirement to postulate a role for a novel G-protein, which is a substrate for cholera toxin, in the regulation of inositol phospholipid metabolism.     

ADP receptor antagonists inhibit platelet aggregation induced by the chemokines SDF-1, MDC and TARC

The ability of the chemokines SDF-1, MDC and TARC to induce platelet aggregation depends strongly on low levels of ADP. The ADP receptors involved have now been characterized using the P2Y(1) and P2T(AC) receptor antagonists, A2P5P and AR-C69931MX. Stimulation of aggregation by the chemokines at 10 s was not blocked by AR-C69931MX, but was strongly inhibited by A2P5P. Pertussis toxin abolished the chemokine-stimulated aggregation. We conclude that the P2Y(1) ADP receptor plays a critical role in the initial phases of SDF-1-, MDC- and TARC-induced platelet aggregation, which involve a pertussis toxin-sensitive G protein.     

Killer toxin for sake yeast: properties and effects of adenosine 5''-diphosphate and calcium ion on killing action.

The killer character of strain isolated from the main mash of sake brewing which produces a killer substance for sake yeast was transmitted to hybrids of the strain and a standard strain of Saccharomyces cerevisiae through a cytoplasmic determinant. The character was eliminated at 41 degrees C by incubation followed by growth at 30 degrees C. The killer strain produced the killer toxin in a growth-associated manner. A preparation of crude killer toxin extract showed first-order inactivation and a linear Arrhenius plot between 25 and 40 degrees C, with an activation of energy of 55.0 kcal/mol. Addition of 1% of synthetic polymer protected the toxin from inactivation by agitation but not by heat. Enhancement of the killer action toward sensitive yeast cells by only the nucleotide adenosine 5'-diphosphate (ADP) was observed after plating on agar medium as well as after incubation in liquid medium. The addition of CaCl2 reversed the enhancing effect of ADP on killing activity. This action of CaCl2 was inhibited by cycloheximide, suggesting that protein synthesis is required for recovery of toxin-induced cells in the presence of CaCl2. Further, CaCl2 overcame the decrease in the intracellular level of adenosine 5'-triphosphate (ATP) enhanced by ADP in killer-treated cells and also inhibited leakage of ATP from the cells with immediate response. The mode of killing action is discussed in terms of a transient state of the cells and the action of ADP and CaCl2.