Effects of insulin-free plasma on the charcoal-separation method for radioimmunoassay of insulin.

Radioimmunoassay of insulin in rat plasma using a popular method (Albano, Ekins, Maritz and Turner 1972) involving charcoal-separation of free and antibody-bound insulin was found to be unsatisfactory despite inclusion in standard tubes of insulin-free plasma prepared in either of two ways. Insulin-free plasma and untreated plasma had different effects on adsorption of free insulin to the charcoal. It was concluded that separation with charcoal is very sensitive to any prior treatment of the plasma. Particular care must be taken to ensure that hormone-free plasma is identical in all other respects to untreated plasma.     

Regulation of heparan sulphate metabolism by adenosine 3′:5′-cyclic monophosphate in hepatocytes in culture

Freshly isolated rat hepatocytes maintained as monolayers in a serum-free medium synthesize sulphated glycosaminoglycans, most of which behave as heparan sulphate and are mainly distributed into intracellular compartments. Cyclic AMP, dibutyryl cyclic AMP, glucagon, noradrenaline, prostaglandin E(1), and theophylline, all drugs and hormones known to increase intracellular cyclic AMP concentrations, decreased the incorporation of (35)SO(4) (2-) into heparan sulphate of intra-, extra- and peri-cellular pools. The inhibition mediated by dibutyryl cyclic AMP was dose-dependent and observed as early as 2h after exposure to the drug. In the presence of 1mm-dibutyryl cyclic AMP, incorporation of (35)SO(4) (2-) or [(14)C]glucosamine into heparan sulphate was decreased to 40-50%, suggesting that dibutyryl cyclic AMP interfered with the synthesis of heparan sulphate. This was further supported by pulse-chase experiments, where dibutyryl cyclic AMP had no effect on the degradation of sulphated glycosaminoglycans. Heparan sulphates synthesized and secreted into the extracellular pool in the presence of dibutyryl cyclic AMP were smaller in size, whereas the degree of sulphation and molecular size of the heparan sulphate chains released by beta-elimination from these proteoglycans were not different from control values. In the presence of 1mm-cycloheximide, (35)SO(4) (2-) incorporation was decreased to 5%. Addition of p-nitrophenyl beta-d-xyloside, an artificial acceptor of glycosaminoglycan chain synthesis, enhanced this incorporation to 18%. Dibutyryl cyclic AMP did not have any inhibitory effect on the synthesis of chains initiated on p-nitrophenyl beta-d-xylosides. Incorporation of [(3)H]serine into heparan sulphate was not affected by dibutyryl cyclic AMP, whereas the degree of substitution of serine residues with heparan sulphate chains was less in heparan sulphate synthesized in the presence of dibutyryl cyclic AMP, suggesting that cyclic AMP exerts its effect on the metabolism of sulphated glycosaminoglycans by affecting the transfer of xylose on to the protein core.     

Heparan sulphate sulphotransferase. Properties of an enzyme from ox lung

A heparan sulphate sulphotransferase was partially purified from an ox lung homogenate by (NH(4))(2)SO(4) precipitation. Various glycosaminoglycans were assayed as sulphate acceptors with this enzyme. The highest acceptor activity was obtained with desulphated heparin and heparan sulphate, which indicates that sulphate transfer may be to free amino groups of the substrate. Some heparan sulphate was (35)S-labelled by incubation with the enzyme and re-isolated. On treatment of this heparan [(35)S]sulphate with nitrous acid and separation of the degradation products on Sephadex G-15, a major peak of radioactivity was obtained, and identified as [(35)S]sulphate by high-voltage electrophoresis at pH5.3. The [(35)S]sulphate is believed to be derived from N-[(35)S]sulphated groups of heparan [(35)S]-sulphate. That the ox lung preparation contained an N-sulphotransferase was confirmed by the isolation of 2-deoxy-2-[(35)S]sulphoamino-d-glucose as the major product from the flavobacterial degradation of heparan [(35)S]sulphate.     

Separation and purification of the alkaline phosphatase and a phosphodiesterase from Halobacterium cutirubrum.

1. Halobacterium cutirubrum alkaline phosphatase is associated in crude extracts with a phosphodiesterase. 2. The enzymes were stabilized in buffers containing both (NH4)2SO4 and 10 mM-Mn2+. 3. Adsorption chromatography on Sepharose 6B/agarose-gel columns in the presence of 1.4M-(NH4)2SO4 gave a phosphatase-free phosphodiesterase and the alkaline phosphatase associated with some phosphodiesterase activity. 4. Further chromatography of the separated enzymes gave a good recovery of greater than 600-fold purified phosphodiesterase and greater than 3000-fold purified alkaline phosphatase. 5. The requirements of these enzymes and their relationship to each other was examined. 6. A detailed study showed that the alkaline phosphatase was adsorbed at least partially to agarose and dextran columns at all (NH4)2SO4 concentrations from 0.25 to 2M. 7. In contrast, no adsorption of the enzyme or protein standards was evident in 2.5M-KCl/l M-NaCl or 0.25 M-KCl/0.1 M-NaCl, in agreement with previous studies by Louis, Peterkin & Fitt [(1971) Biochem. J. 121, 635-641], thus confirming the validity of gel filtration in 2.5 M-KCl/1 M-NaCl as a method for determining the approximate molecular weights of extremehalophile proteins.     

A characterization of the nucleotide uptake by chromaffin granules of bovine adrenal medulla

Chromaffin granules isolated from bovine adrenal gland were incubated with (3)H-labelled nucleotides and [(14)C]noradrenaline to study the uptake of these substances. [(3)H]ATP, [(3)H]ADP and [(3)H]AMP are taken up by these organelles by the same temperature-dependent mechanism. The apparent K(m) for ATP and ADP is 1.4mm, and for AMP it is 2.9mm. The uptake of ATP has a flat pH optimum, whereas the catecholamine uptake increases with more alkaline pH. Atractyloside and carboxyatractyloside are competitive and specific inhibitors of nucleotide uptake, whereas reserpine inhibits only that for catecholamines. Mg(2+) ions activate uptake of both catecholamine and nucleotides, whereas EDTA and N-ethylmaleimide inhibit these processes. Nucleotide and catecholamine uptakes are inhibited by uncouplers of oxidative phosphorylation and by two ATP analogues. NH(4) (+) ions and nigericin in the presence of KCl inhibit only catecholamine uptake. It is concluded that nucleotide uptake, as proposed previously for catecholamine uptake, depends on an electrochemical proton gradient produced by a proton-translocating adenosine triphosphatase localized in the membrane of chromaffin granules. Furthermore, as suggested by the effect of NH(4) (+) and nigericin, catecholamine uptake apparently depends on the chemical part of this gradient, whereas the results for nucleotide uptake are consistent with its dependence on the electrical component.     

The metabolism of sodium cortisone 27-[35S]-sulphate in the rat

1. The metabolism of sodium cortisone 21-[(35)S]sulphate was investigated in rats. 2. Quantitative and qualitative experiments showed that substantial amounts of (35)SO(4) (2-) appeared in the urine of free-ranging rats receiving the ester. 3. Whole-body radioautograms indicated considerable biliary elimination of (35)S and also pointed to the liver as the site of metabolism. 4. When female rats with bile-duct cannulae received sodium cortisone 21-[(35)S]sulphate approx. 70% of the dose appeared in the bile as a doubly conjugated steroid (metabolite I). This metabolite was identified as 3alpha-(beta-d-glucopyranuronosido)- 17alpha-hydroxy-21-[(35)S]sulpho-oxy-5alpha-pregnane-11,20-dione. 5. When metabolite I was administered to a rat with a bile-duct cannula 90% of the dose appeared in the bile unchanged. After the administration (intraperitoneally or orally) of metabolite I to free-ranging rats considerable amounts of (35)SO(4) (2-) appeared in the urine. 6. The route by which (35)SO(4) (2-) might be produced from cortisone [(35)S]sulphate in free-ranging animals is discussed.     

[35S]Thiosulphate oxidation by rat liver mitochondria in the presence of glutathione

1. Rat liver mitochondria incubated in oxygen with glutathione and [(35)S]-thiosulphate produced labelled sulphate. 2. Inner-labelled thiosulphate (S.(35)SO(3))(2-) was converted into [(35)S]sulphate more rapidly than outer-labelled thiosulphate ((35)S.SO(3))(2-). 3. Thiosulphate labelled in both sulphur atoms was formed during ((35)S.SO(3))(2-) oxidation; the outer sulphur atom before oxidation to sulphate was incorporated into the inner position. 4. A thiosulphate cycle in the metabolic pathway of sulphate formation in animal tissues is discussed.     

Dicyclohexylcarbodiimide binds to cytochrome b and subunit VIII in soluble complex III from beef heart mitochondria

Incubation of soluble complex III isolated from either yeast or beef heart mitochondria with 25-100 nmol of [14C]dicyclohexylcarbodiimide (DCCD)/nmol of cytochrome b followed by centrifugation through 10% sucrose or precipitation with trichloroacetic acid did not result in any changes in the appearance of the subunits of either complex. The [14C]DCCD was bound to cytochrome b and phospholipids in the yeast complex and with similar kinetics to both cytochrome b and subunit VIII (Mr = 4000-8000) plus phospholipids of the beef complex. Subunit VIII of the beef complex was partially extracted with chloroform:methanol; however, no subunit of this mobility was present in the yeast complex. Incubation of the beef complex in phosphate buffer for short times resulted in a doubling of the [14C]DCCD bound to cytochrome b relative to that to subunit VIII. Preincubation of both complexes with venturicidin prior to treatment with DCCD resulted in a 50% decrease in the binding of [14C]DCCD to cytochrome b. Reisolation of the beef complex III by precipitation with (NH4)2SO4 after incubation with [14C]DCCD resulted in the formation of a new band with an apparent molecular weight of 39,000 even in the zero time control. The [14C]DCCD was bound to subunit VIII and the core proteins but not to cytochrome b at all times, suggesting that precipitation with (NH)2SO4 in the presence of DCCD causes cross-linking of the subunits of complex III.     

Design and synthesis of novel celecoxib analogues as selective cyclooxygenase-2 (COX-2) inhibitors: replacement of the sulfonamide pharmacophore by a sulfonylazide bioisostere

A group of celecoxib analogues in which the para-SO(2)NH(2) substituent on the N(1)-phenyl ring was replaced by a para-sulfonylazido (SO(2)N(3)) 4, or a meta-SO(2)N(3) 8, substituent were designed for evaluation as selective cyclooxygenase-2 (COX-2) inhibitors. In vitro COX-1 and COX-2 inhibition studies showed that 4-[5-(4-methylphenyl)-3-trifluoromethyl-1H-pyrazol-1-yl]benzenesulfonyl azide (4) with a para-SO(2)N(3) substituent was a selective COX-1 inhibitor. In contrast, 3-[5-(4-methylphenyl)-3-trifluoromethylpyrazol-1-yl]benzenesulfonyl azide (8a) having a meta-SO(2)N(3) substituent (COX-1 IC(50) >100microM; COX-2 IC(50)=5.16microM; COX-2 selectivity index >19.3) is a selective COX-2 inhibitor. A molecular modeling (docking) study showed that the SO(2)N(3) group of 8a inserts deep inside the secondary pocket of the COX-2 binding site. The SO(2)N(3) moiety of 8a can undergo a dual H-bonding interaction via one of its SO(2) oxygen-atoms, and an electrostatic (ion-ion) interaction via the terminal azido (N(3)) nitrogen-atom, to the guanidino NH(2) of Arg(513) in the secondary pocket of COX-2. These observations indicate that an appropriately positioned SO(2)N(3) moiety is a novel alternative bioisostere to the traditional SO(2)NH(2) and SO(2)Me pharmacophores present in selective COX-2 inhibitors, that are only capable of H-bonding interactions with the COX-2 isozyme, for use in drug design.     

硫酸铵对两株钾矿物分解细菌生长代谢和风化钾长石的影响

【目的】为了明确钾矿物分解细菌Bacillus globisporus Q12和Rhizobium sp.Q32最合适的产酸和胞外多糖条件,并进一步阐明供试菌株对钾长石的溶解效应及其机制。【方法】分别向培养基中加入0-1.2 g/L(NH4)2SO4,选择菌株最适的产酸及合成胞外多糖条件,研究菌株对钾长石的溶解效果,并采用扫描电镜(SEM)观察钾长石表面形态及菌体分布特征。【结果】0.6、0和0.3 g/L(NH4)2SO4分别能使菌株Q12、Q32和混合菌株(Q12+Q32)产生较多的有机酸、胞外多糖以及有机酸和胞外多糖的复合物。菌株Q12、Q32及其混合菌株均能够显著地溶解钾长石,并释放出矿质元素,其中混合菌株的溶解效果要优于单一菌株;SEM分析表明,混合菌株对钾长石的溶蚀作用最强。【结论】(NH4)2SO4的含量能够影响供试菌株Q12和Q32的生长代谢及其对钾长石的风化作用,混合菌株可以通过产生的有机酸和胞外多糖的联合作用加速对钾长石的风化。     

A methylsulfonyl metabolite of a polychlorinated biphenyl can serve as a ligand for liver fatty acid binding protein in rat intestinal mucosa

When a 100,000 x g supernatant from rat intestinal mucosa was incubated with 4,4'-bis([3H]methylsulfonyl)-2,2',5,5'-tetrachlorobiphenyl, [(CT3SO2)2TCB] a (CT3SO2)2TCB-protein complex was formed. The (CT3SO2)2TCB-protein complex was isolated and purified using gel filtration and ion-exchange chromatography. The protein portion of this complex was characterized to be liver fatty acid binding protein (L-FABP) by SDS-polyacrylamide gel electrophoresis and immunoblot analysis. No cross reactivity was observed in the immunoblot analysis between the purified protein and anti-heart or anti-intestinal fatty acid binding protein. (CT3SO2)2TCB was extractable from L-FABP and therefore not covalently bound to L-FABP.     

[35S]Thiosulphate oxidation by Thiobacillus strain C

1. Thiobacillus strain C oxidized [(35)S]thiosulphate completely to sulphate. 2. During thiosulphate oxidation [(35)S]sulphate was formed more rapidly from (S.(35)SO(3))(2-) than from ((35)S.SO(3))(2-). (35)S disappeared less rapidly from thiosulphate with ((35)S.SO(3))(2-) as substrate than with (S.(35)SO(3))(2-). 3. Thiosulphate labelled in both atoms was produced during ((35)S.SO(3))(2-) oxidation, but not during (S.(35)SO(3))(2-) oxidation. 4. No (35)S was precipitated as elementary sulphur either in the presence or absence of exogenous unlabelled sulphur. 5. During [(35)S]thiosulphate oxidation, appreciable quantities of [(35)S]trithionate accumulated and later disappeared. Other polythionates did not accumulate consistently. 6. [(35)S]Trithionate was formed initially at a greater rate from (S.(35)SO(3))(2-) than from ((35)S.SO(3))(2-), but subsequently at a similar rate from each. 7. Trithionate formed from (S.(35)SO(3))(2-) was labelled only in the oxidized sulphur atoms, but that formed from ((35)S.SO(3))(2-) was labelled in both oxidized and reduced atoms. The proportion of (35)S in the oxidized atoms increased as more trithionate accumulated. 8. The results eliminate some mechanisms of trithionate formation but are consistent both with a mechanism of thiosulphate oxidation based on an initial reductive cleavage of the molecule and with a mechanism in which thiosulphate undergoes an initial oxidative reaction.     

Phosphofructokinase D from the epithelial cells of rat small intestine.

Phosphofructokinase from the epithelial cells of rat small intestine was characterized with respect to isoenzyme type in a comparison of its properties with those of the skeletal-muscle, brain and major liver isoenzymes by using five different techniques, namely electrophoresis on cellulose acetate and in polyacrylamide gels, chromatography on DEAE-cellulose, (NH4)2SO4 precipitation and immunotitration. When precautions were taken to inhibit the formation of active proteolytic artifacts by the action of endogenous proteinases, each technique revealed that rat intestinal mucosa contains only a single form of phosphofructokinase. The mucosal isoenzyme was found to be very similar to, although not identical with, the major liver isoenzyme and to be quite distinct from the skeletal-muscle isoenzyme when studied by the techniques of cellulose acetate electrophoresis, chromatography on DEAE-cellulose and immunotitration, whereas the converse was true when studied by the techniques of (NH4)2SO4 precipitation and polyacrylamide-gel electrophoresis. The mucosal isoenzyme was distinct from the brain isoenzyme when studied by each of the five techniques. Tsai & Kemp [(1973) J. Biol. Chem. 248, 785-792] reported that animal tissues contain three principal isoenzymes of phosphofructokinase, type A found as the sole isoenzyme in skeletal muscle, type B found as the major isoenzyme in liver and type C found as a significant isoenzyme in brain. Phosphofructokinase from mucosa is distinct from each of these isoenzymes. Following the nomenclature of Tsai & Kemp (1973), the isoenzyme from the mucosa of rat intestinal epithelial cells is designated phosphofructokinase D. The mucosal and liver isoenzymes behave so similarly with respect to their charge and immunological characteristics, on which the typing of isoenzymes is conventionally based, that it is likely that some tissues reported to contain the liver isoenzyme contain instead the mucosal isoenzyme.     

Multiplicity of affinity modification of RNAse during its alkylation with a reactive analog of 5-deoxyribonucleotide

The interaction of pancreatic RNase with 5'-deoxyribodinucleotide alkylating derivative, 4-(N-2-chloroethyl-N-methylamino)benzylamide of d(pTpA) d[(ClRCH2NH)pTpA], was studied. The unreactive oxyanalogue d[(HORCH2NH)pTpA] was shown to act as competitive inhibitor of cCMP hydrolysis by RNase. d[(ClRCH2NH)pTpA] irreversibly inactivated RNase. A protective effect was exerted by d(pTpA) and d[(HORCH2NH)pTpA]. The modification, although having an affinity character, was not accompanied by total inactivation of the enzyme. It was supposed that covalent bonding between the reagent and enzyme induced the dinucleotide displacement from the recognition site. The formation of four RNase monolabeled forms retaining the activity in the hydrolysis of cCMP and poly(U) was demonstrated.     

Purification and properties of alpha-D-mannosidase from the germinated seeds of Medicago sativa (alfalfa).

alpha-Mannosidase of Medicago sativa (alfalfa) was purified 1340-fold. The purification method included dialysis of the crude extract against a citrate/phosphate buffer, pH 3.9, (NH4)SO4 precipitation, hydroxyapatite chromatography, chromatography on Sephadex G-200 and finally a preparatory electrophoresis on polyacrylamide-gel gradient by Doly & Petek's [(1977) J. Chromatogr. 137. 69--81] method. Each step of purification was checked by polyacrylamide-gel disc electrophoresis. The purified enzyme showed a single band, corresponding to alpha-mannosidase activity. alpha-Mannosidase has a mol.wt. 230 000 as estimated by Hedrick & Smith's [(1968) Arch. Biochem. Biophys. 126, 155--164] method and also by polyacrylamide-gel electrophoresis in the presence of sodium dodecyl sulphate by Weber & Osborn [(1969) J. Biol. Chem. 244, 4406--4412]. The enzyme comprises four subunits of different molecular weight. Optimum pH and Km values were determined with p-nitrophenyl alpha-D-mannoside as substrate. When incubated at a temperature between 20 and 62 degrees C before assay, alpha-mannosidase initially shows an increase in activity. alpha-Mannosidase is stable when the pH is about neutrality. It can be inactivated by several metal ions, including Zn2+. At a pH below 5 the enzyme undergoes irreversible inactivation. The presence of EDTA at acid pH considerably enhances the inactivation of the enzyme. This inactivation due to EDTA can be specifically reversed by incubation with Zn2+.     

The comparative metabolism of 2,6-dichlorothiobenzamide (prefix) and 2,6-dichlorobenzonitrile in the dog and rat

1. A single oral dose of either [(14)C]Prefix or 2,6-dichlorobenzo[(14)C]nitrile to rats is almost entirely eliminated in 4 days: 84.8-100.5% of (14)C from [(14)C]Prefix is excreted, 67.3-79.7% in the urine, and 85.8-97.2% of (14)C from 2,6-dichlorobenzo-[(14)C]nitrile is excreted, 72.3-80.7% in the urine. Only 0.37+/-0.03% of the dose of [(14)C]Prefix and 0.25+/-0.03% of the dose of 2,6-dichlorobenzo[(14)C]nitrile are present in the carcass plus viscera after removal of the gut. Rats do not show sex differences in the pattern of elimination of the respective metabolites of the two herbicides. The rates of elimination of (14)C from the two compounds in the 24hr. and 48hr. urines are not significantly different (P >0.05) from one another. 2. After oral administration to dogs, 85.9-106.1% of (14)C from [(14)C]Prefix is excreted, 66.6-80.9% in the urine, and 86.8-92.5% of (14)C from 2,6-dichlorobenzo[(14)C]nitrile is excreted, 60.0-70.1% in the urine. Dogs do not show sex differences in the pattern of eliminating the metabolites of either Prefix or 2,6-dichlorobenzonitrile. 3. Dogs and rats do not show species differences in the patterns of elimination of the two herbicides. 4. Prefix and 2,6-dichlorobenzonitrile are completely metabolized; unchanged Prefix and 2,6-dichlorobenzonitrile are absent from the urine and faeces, and from the carcasses when elimination is complete. In the hydrolysed urine of rats dosed with either [(14)C]Prefix or 2,6-dichlorobenzo[(14)C]nitrile, 2,6-dichloro-3-hydroxybenzonitrile accounts for approx. 42% of the (14)C, a further 10-11% is accounted for by 2,6-dichlorobenzamide, 2,6-dichlorobenzoic acid, 2,6-dichloro-3- and -4-hydroxybenzoic acid and 2,6-dichloro-4-hydroxybenzonitrile collectively, and 25-30% by six polar constituents, of which two are sulphur-containing amino acids. 5. In the unhydrolysed urines of rats dosed with either [(14)C]Prefix or 2,6-dichlorobenzo[(14)C]nitrile, there are present free 2,6-dichloro-3- and -4-hydroxybenzonitrile, their glucuronide conjugates, ester glucuronides of the principal aromatic acids that are present in the hydrolysed urines, and two sulphur-containing metabolites analogous to mercapturic acids or premercapturic acids. 6. Prefix is thus extensively transformed into 2,6-dichlorobenzonitrile: R.CS.NH(2)-->R.CN+H(2)S, where R=C(6)H(3)Cl(2). However, the competitive reaction: R.CS.NH(2)+H(2)O-->R.CO.NH(2)+H(2)S takes place to a very limited extent.     

Ammonium sulfate modifies adenylate cyclase and the chemotactic receptor of Dictyostelium discoideum. Evidence for a G protein effect

(NH4)2SO4 was found to activate adenylate cyclase in Dictyostelium discoideum membranes. The effect of (NH4)2SO4 on the enzyme was observed after pretreatment of membranes but could not be observed if the salt was added to the assay mixture. Activation was seen when membranes were pretreated with 0.16 M (NH4)2SO4 and was maximal at 0.6-1.0 M. The maximal activation of the enzyme was observed within 3 min of pretreatment and was not readily reversible. The effect was specific for the NH+4 ion since pretreatment of membranes with other NH+4 salts could activate the enzyme, whereas pretreatment with NaCl or KCl could not. Pretreatment of plasma membranes with (NH4)2SO4 eliminated the sensitivity of the enzyme to the inhibitory effect of guanine nucleotides. (NH4)2SO4 pretreatment also significantly attenuated the inhibition by guanine nucleotides of cAMP binding to its plasma membrane receptor. The effect of (NH4)2SO4 on GTP inhibition of cAMP binding to its receptor was even more dramatic when the salt was present in the binding assay. (NH4)2SO4 also increased the ADP-ribosylation by cholera toxin of a 39,000-Da membrane protein. The data support the hypothesis that (NH4)2SO4-induced changes in adenylate cyclase and the cAMP receptor are due to an alteration of a putative G protein.     

Studies of the nucleotide-binding sites on the mitochondrial F1-ATPase through the use of a photoactivable derivative of adenylyl imidodiphosphate

(1)N-4-Azido-2-nitrophenyl-gamma-[3H]aminobutyryl-AdoPP[NH] P(NAP4-AdoPP[NH]P) a photoactivable derivative of 5-adenylyl imidodiphosphate (AdoPP[NH]P), was synthesized. (2) Binding of [3H]NAP4-AdoPP[NH]P to soluble ATPase from beef heart mitochondria (F1) was studied in the absence of photoirradiation, and compared to that of [3H]AdoPP[NH]P. The photoactivable derivative of AdoPP[NH]P was found to bind to F1 with high affinity, like AdoPP[NH]P. Once [3H]NAP4-AdoPP[NH]P had bound to F1 in the dark, it could be released by AdoPP[NH]P, ADP and ATP, but not at all by NAP4 or AMP. Furthermore, preincubation of F1 with unlabeled AdoPP[NH]P, ADP, or ATP prevented the covalent labeling of the enzyme by [3H]NAP4-AdoPP[NH]P upon photoirradiation. (3) Photoirradiation of F1 by [3H]NAP4-AdoPP[NH]P resulted in covalent photolabeling and concomitant inactivation of the enzyme. Full inactivation corresponded to the binding of about 2 mol [3H]NAP4-AdoPP[NH]P/mol F1. Photolabeling by NAP4-AdoPP[NH]P was much more efficient in the presence than in the absence of MgCl2. (4) Bound [3H]NAP4-AdoPP[NH]P was localized on the alpha- and beta- subunits of F1. At low concentrations (less than 10 microM), bound [3H]NAP4-AdoPP[NH]P was predominantly localized on the alpha-subunit; at concentrations equal to, or greater than 75 microM, both alpha- and beta-subunits were equally labeled. (5) The extent of inactivation was independent of the nature of the photolabeled subunit (alpha or beta), suggesting that each of the two subunits, alpha and beta, is required for the activity of F1. (6) The covalently photolabeled F1 was able to form a complex with aurovertin, as does native F1. The ADP-induced fluorescence enhancement was more severely inhibited than the fluorescence quenching caused by ATP. The precentage of inactivation of F1 was virtually the same as the percentage of inhibition of the ATP-induced fluorescence quenching, suggestion that fluorescence quenching is related to the binding of ATP to the catalytic site of F1.