The photoproduction of H2 and NH4 fixed from N2 by a derepressed mutant of Rhodospirillum rubrum.

A mutant of Rhodospirillum rubrum has been isolated, after mutagenesis with nitrosoguanidine, which is characterized by its inability to grow in the light on malate-minimal media with exogenous ammonia or alanine, poor growth on glutamine and vigorous growth on glutamate. This mutant produces low levels of a key NH+4 assimilation enzyme, glutamate synthase (NADPH-dependent). It also exhibits significant derepression of nitrogenase biosynthesis in the presence of ammonia or alanine, being 15% derepressed for the former and about 70% derepressed for the latter. Some of this mutant's fixed N2 is excreted into the medium as NH+4 (1 mumol NH+4 per mg cell protein in 50 h). Nitrogenase-mediated H2 production by this strain is considerable (42 mumol H2 per mg cell protein in 50 h), approximately twice that of the wild type assayed under similar conditions. These results demonstrate that genetic alteration of the photosynthetic N2-fixer's NH+4 assimilation system disrupts the tight coupling of N2 fixation and NH+4 assimilation normally observed in these organisms, enabling photochemical conversion steps to be utilized for the photoproduction of NH+4 and H2.     

Intermediates in the limited proteolytic conversion of procollagen to collagen.

The conversion of chick bone procollagen to collagen proceeds in a stepwise fashion to produce a limited number of intermediates. Initial proteolytic cleavages remove NH2-terminal nonhelical extensions and yield an intermediate which remains disulfide-bonded via COOH-terminal extensions. Subsequent stepwise scission of one or two chains of the triple-stranded molecule in its COOH-terminal domain produces intermediates which can only be distinguished after dissociation of the noncovalently bonded alpha chains. A final cleavage in this region produces the collagen molecule and a disulfide-bonded triple-stranded fragment which represents the COOH-terminal domain. In all likelihood the endopeptidases which effect cleavage in the NH2- and COOH-terminal regions differ. More than two enzymes may be required for conversion of procollagen to collagen if the nonhelical domains are not released in an en bloc fashion.     

The prion protein unstructured N-terminal region is a broad-spectrum molecular sensor with diverse and contrasting potential functions

The physiological function of the prion protein (PrP(C) ) and its conversion into its infectious form (PrP(Sc) ) are central issues to understanding the pathogenesis of prion diseases. The N-terminal moiety of PrP(C) (NH(2) -PrP(C) ) is an unstructured region with the characteristic of interacting with a broad range of partners. These interactions endow PrP(C) with multifunctional and sometimes contrasting capabilities, including neuroprotection and neurotoxicity. Recently, binding of β-sheet rich conformers to NH(2) -PrP(C) demonstrated a probable neurotoxic function for PrP(C) in Alzheimer's disease. NH(2) -PrP(C) also enhances the propagation of prions in vivo and is the target of the most potent antiprion compounds. Another level of complexity is provided by endoproteolysis and release of most of NH(2) -PrP(C) into the extracellular space. Further studies will be necessary to understand how NH(2) -PrP(C) regulates the physiological function of PrP(C) and how it is involved in the corruption of its normal function in diseases.     

Changes in the regulatory form of Rhodospirillum rubrum nitrogenase as influenced by nutritional and environmental factors.

The photosynthetic bacterium Rhodospirillum rubrum regulates the activity of its nitrogenase (N2ase) by interconverting the enzyme into three distinct enzymatic species: N2ase A (a fully active form) and two regulatory forms, N2ase Ractive and N2ase Rinactive. N2ase R is distinguished from N2ase A in vitro by the requirement of its Fe protein for activation by a Mn2+-dependent activating factor. N2ase is converted from the A to the R form in response to certain environmental factors such as carbon starvation, depletion of intracellular adenosine triphosphate, or the addition of NH4+ (or glutamate) to a culture of N-starved cells. The rapid inhibition of R. rubrum N2ase in vivo by NH4+ was shown to result from the conversion of N2ase A to N2ase Rinactive. On depletion of NH4+ from the culture, whole-cell N2ase activity returned; however, the enzyme remained in the R form. Unlike the effect of NH4+, adding glutamate to cells containing N2ase A did not inhibit in vivo activity, but converted the enzyme to the R form (N2ase Ractive). Although glutamate-induced N2ase R formation was much slower than the NH4+-induced reaction, it occurred in the presence of rifampin, indicating that de novo protein synthesis was not involved. This suggested that N2ase R was formed by a modification of N2ase A. Although glutamine synthetase in involved in the conversion of N2ase A to R, the adenylylation state of glutamine synthetase appears not to be involved in regulating this nitrogenase reaction.     

The mode of conversion of proparathormone to parathormone by a particulate converting enzymic activity of the parathyroid gland

The cleavage products from the conversion of proparathormone to parathormone by a bovine and porcine parathyroid microsomal converting activity have been analyzed. In the conversion reaction, the first 6 amino acid residues of the prohormone (Lys-Ser-Val-Lys-Lys-Arg-) are released as an intact hexapeptide. This is rapidly converted to a pentapeptide by removal of the NH2-terminal lysine and then to a tetrapeptide by removal of the COOH-terminal arginine. In order to test for the presence of a postulated COOH-terminal extension of the parathormone sequence in proparathormone, mixtures of 14C-proparathormone and 3H-parathormone were subjected to digestion by trypsin or Staphylococcus aureus protease. The resulting radioactive peptides from the hormone and its precursor were compared. There was no evidence that any fragments different from those from the hormone were released from the prohormone except those accounted for by the NH2-terminal hexapeptide adduct on proparathormone. Thus, the conversion of the prohormone to the hormone catalyzed by the microsomal membrane activity requires only the cleavage of this hexapeptide.     

Incorporation of Molecular Oxygen and Water during Enzymatic Oxidation of Cyanide by Pseudomonas fluorescens NCIMB 11764

Cell extracts (high-speed [150,000 x g] supernatants) from Pseudomonas fluorescens NCIMB 11764 catalyzed the oxidation of cyanide to CO(inf2) (and NH(inf3)). Conversion was both oxygen and NADH dependent, with 1 mol of each being consumed per mol of cyanide degraded. Analysis of (sup13)CO(inf2) by mass spectrometry indicated that one atom each of isotopically labelled oxygen 18 from molecular oxygen and water were incorporated during enzymatic conversion. The results confirm earlier reports of oxygenase-mediated cyanide conversion in this organism. A reaction pathway for cyanide oxidation involving initial monooxygenation followed by hydrolysis of a hypothetical oxygenated intermediate to CO(inf2) (and NH(inf3)) is proposed.     

Characterization of alternative molecular forms of xanthine oxidase in the mouse

1. Two major forms of xanthine oxidase are demonstrated for the mouse. On polyacrylamide-gel electrophoresis the duodenal form migrates faster towards the anode than that of the liver. Both forms also differ in their (NH(4))(2)SO(4) precipitation patterns and sucrose-density-gradient molecular-weight determinations. 2. The liver form is fully converted into the duodenal form by incubation at 37 degrees C with 2.5mg of crude trypsin/ml for 1(1/2)h, without loss of activity. The trypsin-treated liver form behaves like the normal duodenal form as characterized by electrophoresis, (NH(4))(2)SO(4) precipitation patterns, and sucrose-density-gradient molecular-weight determinations. 3. Partial conversion is also brought about by purified trypsin and chymotrypsin, but not with beta-carboxypeptidase or lipase. The conversion is inhibited by soya-bean trypsin inhibitor. 4. In embryo mice the duodenal form is similar to the liver form on electrophoresis. 5. These studies indicate, as might be expected, that the duodenal form is a modified version of the liver enzyme, probably caused by proteolytic alteration.     

Decomposition of hydroxylamine by hemoglobin

The reaction between hydroxylamine (NH2OH) and human hemoglobin (Hb) at pH 6-8 and the reaction between NH2OH and methemoglobin (Hb+) chiefly at pH 7 were studied under anaerobic conditions at 25 degrees C. In presence of cyanide, which was used to trap Hb+, Hb was oxidized by NH2OH to methemoglobin cyanide with production of about 0.5 mol NH+4/mol of heme oxidized at pH 7. The conversion of Hb to Hb+ was first order in [Hb] (or nearly so) but the pseudo-first-order rate constant was not strictly proportional to [NH2OH]. Thus, the apparent second-order rate constant at pH 7 decreased from about 30 M-1 X s-1 to a limiting value of 11.3 M-1 X s-1 with increasing [NH2OH]. The rate of Hb oxidation was not much affected by cyanide, whereas there was no reaction between NH2OH and carbonmonoxyhemoglobin (HbCO). The pseudo-first-order rate constant for Hb oxidation at 500 microM NH2OH increased from about 0.008 s-1 at pH 6 to 0.02 s-1 at pH 8. The oxidation of Hb by NH2OH terminated prematurely at 75-90% completion at pH 7 and at 30-35% completion at pH 8. Data on the premature termination of reaction fit the titration curve for a group with pK = 7.5-7.7. NH2OH was decomposed by Hb+ to N2, NH+4, and a small amount of N2O in what appears to be a dismutation reaction. Nitrite and hydrazine were not detected, and N2 and NH+4 were produced in nearly equimolar amounts. The dismutation reaction was first order in [Hb+] and [NH2OH] only at low concentrations of reactants and was cleanly inhibited by cyanide. The spectrum of Hb+ remained unchanged during the reaction, except for the gradual formation of some choleglobin-like (green) pigment, whereas in the presence of CO, HbCO was formed. Kinetics are consistent with the view advanced previously by J. S. Colter and J. H. Quastel [1950) Arch. Biochem. 27, 368-389) that the decomposition of NH2OH proceeds by a mechanism involving a Hb/Hb+ cycle (reactions [1] and [2]) in which Hb is oxidized to Hb+ by NH2OH.     

Glucosaminephosphate synthase of human liver.

Although human liver contains glucosaminephosphate synthase (glucosaminephosphate isomerase (glutamine-forming), EC 5.3.1.19), its activity is rapidly lost during the course of extraction. The inactivation, however, is largely prevented if the extraction medium contains isopropanol at 1% concentration; using these "stabilized" extracts, the glucosaminephosphate synthase activity of human liver has been shown to be similar to the activity previously reported in rat liver. The enzyme precipitated from these extracts by (NH4)2SO4 is inhibited by UDP-N-acetylglucosamine, the concentration required to produce a half-maximal inhibition being 6 muM. These results seem to be sufficient to postulate that glucosaminephosphate synthase is important for UDP-N-acetylglucosamine synthesis in human liver. In contrast to the rat liver enzyme, the (NH4)2SO4-precipitated human liver enzyme is resistant to trypsin and undergoes no conversion reaction when incubated with glucose 6-phosphate.     

Physiology, biochemistry, and specific inhibitors of CH4, NH4+, and CO oxidation by methanotrophs and nitrifiers.

Ammonia oxidizers (family Nitrobacteraceae) and methanotrophs (family Methylococcaceae) oxidize CO and CH4 to CO2 and NH4+ to NO2-. However, the relative contributions of the two groups of organisms to the metabolism of CO, CH4, and NH4+ in various environments are not known. In the ammonia oxidizers, ammonia monooxygenase, the enzyme responsible for the conversion of NH4+ to NH2OH, also catalyzes the oxidation of CH4 to CH3OH. Ammonia monooxygenase also mediates the transformation of CH3OH to CO2 and cell carbon, but the pathway by which this is done is not known. At least one species of ammonia oxidizer, Nitrosococcus oceanus, exhibits a Km for CH4 oxidation similar to that of methanotrophs. However, the highest rate of CH4 oxidation recorded in an ammonia oxidizer is still five times lower than rates in methanotrophs, and ammonia oxidizers are apparently unable to grow on CH4. Methanotrophs oxidize NH4+ to NH2OH via methane monooxygenase and NH4+ to NH2OH via methane monooxygenase and NH2OH to NO2- via an NH2OH oxidase which may resemble the enzyme found in ammonia oxidizers. Maximum rates of NH4+ oxidation are considerably lower than in ammonia oxidizers, and the affinity for NH4+ is generally lower than in ammonia oxidizers. NH4+ does not apparently support growth in methanotrophs. Both ammonia monooxygenase and methane monooxygenase oxidize CO to CO2, but CO cannot support growth in either ammonia oxidizers or methanotrophs. These organisms have affinities for CO which are comparable to those for their growth substrates and often higher than those in carboxydobacteria. The methane monooxygenases of methanotrophs exist in two forms: a soluble form and a particulate form. The soluble form is well characterized and appears unrelated to the particulate. Ammonia monooxygenase and the particulate methane monooxygenase share a number of similarities. Both enzymes contain copper and are membrane bound. They oxidize a variety of inorganic and organic compounds, and their inhibitor profiles are similar. Inhibitors thought to be specific to ammonia oxidizers have been used in environmental studies of nitrification. However, almost all of the numerous compounds found to inhibit ammonia oxidizers also inhibit methanotrophs, and most of the inhibitors act upon the monooxygenases. Many probably exert their effect by chelating copper, which is essential to the proper functioning of some monooxygenases. The lack of inhibitors specific for one or the other of the two groups of bacteria hampers the determination of their relative roles in nature.     

NH2-terminal processing of Bacillus subtilis alpha-amylase

Mature alpha-amylase of Bacillus subtilis is known to be formed from its precursor by removal of the NH2-terminal 41-amino acid sequence. To study the mechanism of this processing, the extracellular forms of alpha-amylase were analyzed for B. subtilis N7 alpha-amylase cloned and expressed in B. subtilis. The major form (form N34) isolated from log phase cultures in L-broth had an NH2 terminus corresponding to position 34 from the initiator Met but appeared to be microheterogeneous, as judged by native gel electrophoresis. The major forms from stationary phase cultures had NH2 termini at positions 40 (form N40) or 42 (form N42) and were homogeneous. The conversion of the larger to smaller forms could be achieved in culture supernatants or partially purified samples. The process N34----N40 was inhibited by EDTA; N40----N42 was facilitated by Ca2+. Phenylmethylsulfonyl fluoride inhibited the former but not the latter process. These results suggest that the signal peptidase cleavage site 30 decreases 35 is -Ala-Ala-Ala-Ser-Ala-Glu-Thr- (arrow or further upstream) and that proteolytic maturation occurs after secretion, which involves at least two different processing enzymes.     

Neomycin, spermine and hexaamminecobalt (III) share common structural motifs in converting B- to A-DNA.

The (dG)n.(dC)n-containing 34mer DNA duplex [d(A2G15C15T2)]2 can be effectively converted from the B-DNA to the A-DNA conformation by neomycin, spermine and Co(NH3)6(3+). Conversion is demonstrated by a characteristic red shift in the circular dichroism spectra and dramatic NMR spectral changes in chemical shifts. Additional support comes from the substantially stronger CH6/GH8-H3'NOE intensities of the ligand-DNA complexes than those from the native DNA duplex. Such changes are consistent with a deoxyribose pucker transition from the predominate C2'-endo (S-type) to the C3'-endo (N-type). The changes for all three ligand-DNA complexes are identical, suggesting that those three complex cations share common structural motifs for the B- to A-DNA conversion. The A-DNA structure of the 4:1 complex of Co(NH3)6(3+)/d(ACCCGCGGGT) has been analyzed by NOE-restrained refinement. The structural basis of the transition may be related to the closeness of the two negatively charged sugar-phosphate backbones along the major groove in A-DNA, which can be effectively neutralized by the multivalent positively charged amine functions of these ligands. In addition, ligands like spermine or Co(NH3)6(3+) can adhere to guanine bases in the deep major groove of the double helix, as is evident from the significant direct NOE cross-peaks from the protons of Co(NH3)6(3+) to GH8, GH1 (imino) and CH4 (amino) protons. Our results point to future directions in preparing more potent derivatives of Co(NH3)6(3+) for RNA binding or the induction of A-DNA.     

Mechanism of the urokinase-catalyzed activation of human plasminogen.

When human plasminogen (Glu-Pga) is activated by urokinase in the presence of pancreatic trypsin inhibitor, the plasmin produced (Glu-Pma) exclusively contains a heavy chain (Glu-Ha) derived intact from the original NH2 terminus of Glu-Pga. Similar activations, utilizing a low molecular weight synthetic plasmin acylating agent, p-nitrophenyl-p-(pyridiniummethyl) benzoate, still result in a plasmin molecule with approximately 50% of the plasmin heavy chain containing the intact NH2 terminus of the original Glu-Pga. Activations performed at high levels of urokinase in the absence of any inhibitors initially produce Glu-Pma. However, the final stable plasmin, Lys-Pmb, which is obtained contains a heavy chain (Lys-Hb) which arises by plasminolysis of a small peptide from the NH2 terminus of Glu-Ha. Alternatively, Lys-Pmb can be formed in a separate series of reactions initially involving plasminolysis of Glu-Pga to yield Lys-Pgb. The peptide removed in this step is identical to the peptide removed in the Glu-Ha to Lys-Hb reaction. Next, urokinase catalyzes the conversion of Lys-Pgb to Lys-Pmb without further loss of peptide material. This latter pathway involving Lys-Pgb is probably the major pathway for human Lys-Pmb generation. These studies support a mechanism of activation of human plasminogen which involves at least two bond cleavages in Glu-Pga. However, these same studies strongly indicate that the Nh2-terminal peptide need not be released from Glu-Pga prior to plasmin formation. Further, we feel that plasmin and not urokinase catalyzes cleavage of the NH2-terminal peptide bond from Glu-Pga and the Glu-Ha heavy chain of Glu-Pma.     

Method for In Situ Measurement of Nitrification in a Stream

A method is described in which the oxidation of NH(3)-N to NO(2)-N and NO(3)-N in a stream was measured in situ by use of an equilibration chamber. The conversion was stoichiometric.     

Identification of mixed di-cation forms of G-quadruplex in solution

Multinuclear NMR study has demonstrated that G-quadruplex adopted by d(G3T4G4) exhibits two cation binding sites between three of its G-quartets. Titration of tighter binding K+ ions into the solution of d(G3T4G4)2 folded in the presence of 15NH4+ ions uncovered a mixed mono-K+-mono-15NH4+ form that represents intermediate in the conversion of di-15NH4+ into di-K+ form. Analogously, 15NH4+ ions were found to replace Na+ ions inside d(G3T4G4)2 quadruplex. The preference of 15NH4+ over Na+ ions for the two binding sites is considerably smaller than the preference of K+ over 15NH4+ ions. The two cation binding sites within the G-quadruplex core differ to such a degree that 15NH4+ ions bound to the site, which is closer to the edge-type loop, are always replaced first during titration by K+ ions. The second binding site is not taken up by K+ ion until K+ ion already resides at the first binding site. Quantitative analysis of concentrations of the three di-cation forms, which are in slow exchange on the NMR time scale, at 12 K+ ion concentrations afforded equilibrium binding constants. K+ ion binding to sites U and L within d(G3T4G4)2 is more favorable with respect to 15NH4+ ions by Gibbs free energies of approximately -24 and -18 kJ mol(-1) which includes differences in cation dehydration energies, respectively.     

Modeling the partial nitrification in sequencing batch reactor for biomass adapted to high ammonia concentrations

Partial nitrification has proven to be an economic way for treatment of industrial N-rich effluent, reducing oxygen and external COD requirements during nitrification/denitrification process. One of the key issues of this system is the intermediate nitrite accumulation stability. This work presents a control strategy and a modeling tool for maintaining nitrite build-up. Partial nitrification process has been carried out in a sequencing batch reactor at 30 degrees C, maintaining strong changing ammonia concentration in the reactor (sequencing feed). Stable nitrite accumulation has been obtained with the help of an on-line oxygen uptake rate (OUR)-based control system, with removal rate of 2 kg NH4 (+)-N x m(-3)/day and 90%-95% of conversion of ammonium into nitrite. A mathematical model, identified through the occurring biological reactions, is proposed to optimize the process (preventing nitrate production). Most of the kinetic parameters have been estimated from specific respirometric tests on biomass and validated on pilot-scale experiments of one-cycle duration. Comparison of dynamic data at different pH confirms that NH3 and NO2- should be considered as the true substrate of nitritation and nitratation, respectively. The proposed model represents major features: the inhibition of ammonia-oxidizing bacteria by its substrate (NH3) and product (HNO2), the inhibition of nitrite-oxidizing bacteria by free ammonia (NH3), the INFluence of pH. It appears that the model correctly describes the short-term dynamics of nitrogenous compounds in SBR, when both ammonia oxidizers and nitrite oxidizers are present and active in the reactor. The model proposed represents a useful tool for process design and optimization.     

Oxidative modification of IkappaB by monochloramine inhibits tumor necrosis factor alpha-induced NF-kappaB activation

We have previously reported that monochloramine (NH(2)Cl), a neutrophil-derived oxidant, inhibited tumor necrosis factor alpha (TNFalpha)-induced expression of cell adhesion molecules and nuclear factor-kappaB (NF-kappaB) activation (Free Radical Research 36 (2002) 845-852). Here, we studied the mechanism how NH(2)Cl inhibited TNFalpha-induced NF-kappaB activation, and compared the effects with taurine chloramine (Tau-NHCl). Pretreatment of Jurkat cells with NH(2)Cl at 70 microM resulted in suppression of TNFalpha-induced IkappaB phosphorylation and degradation, and inhibited NF-kappaB activation. In addition, a slow-moving IkappaB band appeared on SDS-PAGE. By contrast, Tau-NHCl for up to 200 microM had no effects. Interestingly, NH(2)Cl did not inhibit IkappaB kinase activation by TNFalpha. Protein phosphatase activity did not show apparent change. When recombinant IkappaB was oxidized by NH(2)Cl in vitro and phosphorylated by TNFalpha-stimulated Jurkat cell lysate, its phosphorylation occurred less effectively than non-oxidized IkappaB. In addition, when NF-kappaB-IkappaB complex was immunoprecipitated from NH(2)Cl-treated cells and phosphorylated in vitro by recombinant active IkappaB kinase, native IkappaB but not oxidized IkappaB was phosphorylated. Amino acid analysis of the in vitro oxidized IkappaB showed methionine oxidation to methionine sulfoxide. Although Tau-NHCl alone had little effects on TNFalpha-induced NF-kappaB activation, simultaneous presence of Tau-NHCl and ammonium ion significantly inhibited the NF-kappaB activation, probably through the conversion of Tau-NHCl to NH(2)Cl. These results indicated that NH(2)Cl inhibited TNFalpha-induced NF-kappaB activation through the oxidation of IkappaB, and that NH(2)Cl is physiologically more relevant than Tau-NHCl in modifying NF-kappaB-mediated cellular responses.     

Use of 2,3,5-F(3)Y-β2 and 3-NH(2)Y-α2 to study proton-coupled electron transfer in Escherichia coli ribonucleotide reductase

Escherichia coli ribonucleotide reductase is an α2β2 complex that catalyzes the conversion of nucleoside 5'-diphosphates (NDPs) to deoxynucleotides (dNDPs). The active site for NDP reduction resides in α2, and the essential diferric-tyrosyl radical (Y(122)(?)) cofactor that initiates transfer of the radical to the active site cysteine in α2 (C(439)), 35 ? removed, is in β2. The oxidation is proposed to involve a hopping mechanism through aromatic amino acids (Y(122) → W(48) → Y(356) in β2 to Y(731) → Y(730) → C(439) in α2) and reversible proton-coupled electron transfer (PCET). Recently, 2,3,5-F(3)Y (F(3)Y) was site-specifically incorporated in place of Y(356) in β2 and 3-NH(2)Y (NH(2)Y) in place of Y(731) and Y(730) in α2. A pH-rate profile with F(3)Y(356)-β2 suggested that as the pH is elevated, the rate-determining step of RNR can be altered from a conformational change to PCET and that the altered driving force for F(3)Y oxidation, by residues adjacent to it in the pathway, is responsible for this change. Studies with NH(2)Y(731(730))-α2, β2, CDP, and ATP resulted in detection of NH(2)Y radical (NH(2)Y(?)) intermediates capable of dNDP formation. In this study, the reaction of F(3)Y(356)-β2, α2, CDP, and ATP has been examined by stopped-flow (SF) absorption and rapid freeze quench electron paramagnetic resonance spectroscopy and has failed to reveal any radical intermediates. The reaction of F(3)Y(356)-β2, CDP, and ATP has also been examined with NH(2)Y(731)-α2 (or NH(2)Y(730)-α2) by SF kinetics from pH 6.5 to 9.2 and exhibited rate constants for NH(2)Y(?) formation that support a change in the rate-limiting step at elevated pH. The results together with kinetic simulations provide a guide for future studies to detect radical intermediates in the pathway.     

The activation of coagulation factor X. Identity of cleavage sites in the alternative activation pathways and characterization of the COOH-terminal peptide.

Bovine Factor X can be activated by two alternative pathways. The first, favored at high concentrations of the complex of tissue factor and Factor VII, is initiated by the action of Factor VII on Factor X to cleave an activation peptide from the NH2 terminus of the heavy chain, to produce alpha-Xa. This is then converted autocatalytically to another form of Factor Xa, beta-Xa, by the loss of a 17-residue glycopeptide from the COOH terminus of the heavy chain, in a lipid-dependent reaction. The alternative pathway, favored at lower activator concentrations, is initiated by the action of Factor Xa on Factor X, in the presence of lipid, to release the same COOH-terminal peptide as is produced in the conversion of alpha-Xa to beta-Xa. The intermediate produced by the loss of this peptide from Factor X,I1, can be activated directly to beta-Xa by the tissue factor-Factor VII complex, with the loss of the same NH2-terminal peptide as is produced in the conversion of Factor X to alpha-Xa. The autocatalytic activation of Factor X by Factor Xa described previously occurs to a marked extent only at very low activator concentrations, and has been shown to proceed largely by the loss of the normal NH2-terminal peptide from the heavy chain of I1-Initial experiments show that neither peptide affects the rate of coagulation by either the extrinsic or intrinsic pathways. The amino acid sequences have been determined on both sides of the peptide cleavages, and it has been shown that the cleavage sites are the same, regardless of the pathway of activation. The amino acid sequence and carbohydrate composition of the COOH-terminal peptide have been determined. The carbohydrate moiety is attached via an O-glycosidic linkage at a threonine residue, and contains galactosamine but no glucosamine.     

Inhibition and reactivation of Mn-catalase. Implications for valence changes at the active site manganese

The Mn-catalase of Lactobacillus plantarum was inactivated when exposed to NH2OH plus H2O2, an effect which was not reversed by dialysis. N-Methylhydroxylamine was approximately 1% as effective as was NH2OH, while O-methylhydroxylamine was not detectably active in this regard. Approximately 40% of the lost activity could be restored by dithionite or by O-2, whereas other reductants such as ethanol, ascorbate, or nitrite were without effect. Oxidants such as persulfate and ferricyanide also failed to reactivate the enzyme. The active enzyme was inactivated, to an apparent limit of 50%, by an enzymic or photochemical flux of O-2 and this was entirely prevented by superoxide dismutase. The catalytic cycle of the enzyme is thought to involve the trivalent and pentavalent forms of the active site Mn; while inactivation by H2O2 + NH2OH appears to be due to conversion to the quadrivalent state. Partial bleaching of the enzyme by H2O2 and the nearly complete bleaching caused by NH2OH + H2O2 are in accord with this interpretation. The enzyme was unaffected by 2.0 mM EDTA, thiourea, o-phenanthroline, alpha, alpha'-dipyridyl, 8-hydroxyquinoline, diethyldithiocarbamate, thiourea, hydrazine, phenylhydrazine, isoniazid, semicarbazide, sulfite, nitrite, or sulfide, all at pH 7.0.