[Cloning of genomic sequences of human prointerleukin 1 beta]. / Klonirovanie genomnoi posledovatel'nosti prointerleikina 1 beta cheloveka.

The human brain library carried in the EMBL3 vector was employed for isolating prointerleukin 1 beta genomic sequences using three synthetic 20-member oligonucleotides. Oligonucleotides were homologous to the following mRNA regions: 3'-nontranslated region/C1/, 3'-translated region of mRNA/C2/ and the sequence coding N-terminal of mature protein/N1/. The oligonucleotide labeling utilized the terminal nucleotidyltransferase and [alpha-32P] dATP and specific activity of labeled oligonucleotides reached 1.6.10(10) cpm. The sizes of the synthesized labeled sequences (tails) were about 10 b.p. Hybridization probe C1 was used for the first screening and 24 hybridization positive clones were detected. For the next screening probe C2 was used and only 2 hybridization positive clones with different level of hybridization were detected from 24 clones. Probe N1 was used for the third screening and allowed to identify the only positive clone. The characterization by restriction mapping and Southern blot analyses have shown that recombinant phage DNA contains all three exons, coding the mature interleukin 1 beta. Some fragments were recloned to tg130 vector phage and nucleotide sequences of exon 5 (completely) and exon 7, intron 4 and 5 (partially) were determined.

[Synchronous (synphaseous) additive models for mitochondrial ATP synthetase complex and for other energy transducing systems of cells (a hypothesis)]. / Sinkhronnye (sinfaznye) additivnye modeli funktsionirovaniia ATP-sintetaznogo kompleksa mitokhondrii i drugikh énergoprevrashchaiushchikh sistem kletki (sipoteza).

There exist some energy transducing enzymes containing immobile molecules of substrates which are not exchangeable during protein functioning. According to the proposed models the immobile substrates are localized at the "idle" (or "partial" or "imitational") catalytic sites, which differ from normal ("working") active sites of enzymes. Only some steps of a complete reaction sequence which take place at the "working" sites are carried out at the "idle" sites. On the other hand, cyclic conversion of the immobile substrate at an "idle" catalytic site may include some steps which are absent in the "working" site cycle. The occurrence of identical steps on the "idle" and "working" catalytic sites allows to synchronize their action through conformational interconversions of tightly packed and structurally related "idle" and "working" subunits of the enzyme. The presence of covaletly bound substrates or substrates localized in closed cavities of the "idle" sites allows to synchronize the action of many monomers containing such sites due to the absence of the rate-limiting step of simultaneous saturation of many catalytic sites by substrate molecules from solution, and due to the lack of substrate inhibition on the "idle" sites. The functions of the "idle" sites are miscellaneous e.g. in ion-transporting systems these sites are directly involved in ion translocation. In the actomyosin complex the "idle" sites imitate conformational alterations of "working" sites, thus allowing synchronous functioning of the polymeric structure. Variations in the number of the "idle" sites operating simultaneously with one "working" site allow to regulate some parameters of enzymatic processes, e.g. the stoichiometry (number of transported ions per ATP hydrolysed (or synthesised) or electron-transported, or hv-absorbed ones) for ion transported systems or the ratio (velocity of contraction to developed efforts) for the actomyosin complex.

Kinetic mechanism of mitochondrial adenosine triphosphatase. Inhibition by azide and activation by sulphite.

1. The initial rapid phase of ATP hydrolysis by bovine heart submitochondrial particles or by soluble F1-ATPase is insensitive to anion activation (sulphite) or inhibition (azide). 2. The second slow phase of ATP hydrolysis is hyperbolically inhibited by azide (Ki approximately 10(-5) M); the inosine triphosphatase activity of submitochondrial particles or F1-ATPase is insensitive to azide or sulphite. 3. The rate of interconversion between rapid azide-insensitive and slow azide-sensitive phases of ATP hydrolysis does not depend on azide concentration, but strongly depends on ATP concentration. 4. Sulphite prevents the interconversion of the rapid initial phase of the reaction into the slower second phase, and also prevents and slowly reverses the inhibition by azide. 5. The presence of sulphite in the mixture when ADP reacts with ATPase of submitochondrial particles changes the pattern of the following activation process. 6. Azide blocks the activation of ATP-inhibited ATPase of submitochondrial particles by phosphoenolpyruvate and pyruvate kinase. 7. The results obtained suggest that the inhibiting effect of azide on mitochondrial ATPase is due to stabilization of inactive E*.ADP complex formed during ATP hydrolysis; the activation of ATPase by sulphite is also realized through the equilibrium between intermediate active E.ADP complex and inactive E*.ADP complex.

Kinetic mechanism of mitochondrial adenosine triphosphatase. ADP-specific inhibition as revealed by the steady-state kinetics.

1. A substantial increase of the initial rate of ATP hydrolysis was observed after preincubation of bovine heart submitochondrial particles with phosphoenolpyruvate and pyruvate kinase. 2. The activation was accompanied by an increase of Vmax, without change of Km for ATP. 3. The activated particles catalysed the biphasic hydrolysis of ATP in the presence of an ATP-regenerating system; the initial rapid phase was followed by a second, slower, phase in a time-dependent fashion. 4. The higher the ATP concentration used as a substrate, the higher is the rate of transition between these two phases. 5. The particles catalysed the hydrolysis of ITP with a lag phase; after preincubation with phosphoenolpyruvate and pyruvate kinase, ITP was hydrolysed at a constant rate. 6. Qualitatively the same phenomena were observed when soluble mitochondrial ATPase (F1-ATPase) prepared by the conventional method in the presence of ATP was used as nucleotide triphosphatase. 7. A kinetic scheme is proposed, in which the intermediate active enzyme-product complex (E.ADP) formed during ATP hydrolysis is in slow equilibrium with the inactive E*.ADP complex forming as a result of dislocation of ADP from the active site of ATPase to the other site, which is not in rapid equilibrium with the surrounding medium.

Kinetics of interaction of adenosine diphosphate and adenosine triphosphate with adenosine triphosphatase of bovine heart submitochondrial particles.

The short preincubation of submitochondrial particles with low concentrations of ADP in the presence of Mg2+ results in a complete loss of their ATPase and inosine triphosphatase activities. Other nucleoside diphosphates (IDP and GDP) do not affect the ATPase activity. The ADP-inhibited ATPase can be activated in a time-dependent manner by treatment of submitochondrial particles with the enzyme converting ADP into ATP (phosphoenolpyruvate plus pyruvate kinase). The activaton is a first-order reaction with rate constant 0.2 min-1 at 25 degrees C. The rate constant of activation is increased in the presence of ATP up to 2 min-1, and this increase shows saturation kinetics with Km value equal to that for ATPase reaction itself (10(-4) M at 25 degrees C at pH 8.0). The experimental results obtained are consistent with the model where two alternative pathways of ADP dissociation from the inhibitory site of ATPase exist; one is spontaneous dissociation and the second is ATP-dependent dissociation through the formation of the ternary complex between ADP, the enzyme and ATP. ADP-induced inactivation and ATP-dependent activation of ATPase activity of submitochondrial particles is accompanied by the same directed change of their ability to catalyse the ATP-dependent reverse electron transport from succinate to NAD+. The possible implication of the model suggested is discussed in terms of functional role of the inhibitory high-affinity binding site for ADP in the mitochondrial ATPase.