DNA stimulates ATP-dependent proteolysis and protein-dependent ATPase activity of protease La from Escherichia coli

N-terminal domains of putative helicases of flavi- and pestiviruses may be serine proteases

Recently we tentatively identified, by sequence comparison, central domains of the NS3 proteins of flaviviruses and the respective portion of the pestivirus polyprotein as RNA helicases (A.E.G. et al., submitted). Alignment of the N-proximal domains of the same proteins revealed conservation of short sequence stretches resembling those around the catalytic Ser, His and Asp residues of chymotrypsin-like proteases. A statistically significant similarity has been detected between the sequences of these domains and those of the C-terminal serine protease domains of alphavirus capsid proteins. It is suggested that flavivirus NS3 and the respective pestivirus protein contain at least two functional domains, the N-proximal protease and the C-proximal helicase one. The protease domain is probably involved in the processing of viral non-structural proteins.

Stimulation by ATP-Mg2+ and inactivation by cyclic-AMP-dependent phosphorylation of a cytosolic monkey brain aminopeptidase

The activity of a purified cytosolic aminopeptidase (Mr 79,000) from monkey brain was stimulated about 4-fold by ATP-Mg2+. The stimulation was seen with either synthetic aminopeptidase substrates or natural peptides such as enkephalins. Both ATP and Mg2+ were required for stimulation, and ADP did not inhibit the stimulation. Non-hydrolysable analogues of ATP, deoxy-ATP and other nucleoside triphosphates stimulated to a lesser extent compared with ATP, whereas nucleoside mono- or di-phosphates were ineffective. The enzyme did not exhibit any ATPase activity. An ATPase inhibitor, orthovanadate, had no inhibitory effect on the ATP-Mg2+ stimulation. The aminopeptidase was not autophosphorylated by [gamma-32P]ATP and Mg2+, but in the presence of cyclic AMP-dependent protein kinase underwent phosphorylation on serine residue(s). Phosphorylation resulted in inactivation of the aminopeptidase activity, and also resulted in a decreased stimulation of the enzyme by ATP-Mg2+.

Location of enzymatic and DNA-binding domains on E. coli protease La

Escherichia coli protease La is an ATP-dependent enzyme that has a DNA-binding site. The locations of the enzymatic and DNA-binding sites are not known. We report that a 75-residue segment at the carboxy-terminus of the protease La is similar to part of Bacillus licheniformis beta-lactamase, a serine enzyme. The comparison score is 8.2 standard deviations higher than that obtained with 10,000 comparisons of randomized sequences of these segments. The probability of obtaining such a score by chance is 1.2 x 10(-16). We also find that a 107-residue segment in the amino-terminus half of protease La is similar to part of the sopB protein, a DNA-binding protein of the plasmid F of E. coli. The comparison score for these segments is 8 standard deviations (P = 6 x 10(-16)). These strong amino acid sequence similarities suggest the locations of the catalytic serine and the DNA-binding domains of protease La.

Divergent effects of a dnaK mutation on abnormal protein degradation in Escherichia coli

Escherichia coli bacteria produce at least one 70 kD stress protein, the product of the dnaK gene. We have compared the rates of degradation of different types of abnormal proteins in null Ion E. coli with a partial deletion of the dnaK gene with the rates observed in null Ion dnaK+ cells. We have found that both canavanyl proteins and puromycyl polypeptides are degraded more slowly in the null dnaK mutants than in the dnaK+ strain. However, a temperature-sensitive mutant LacI protein is degraded more rapidly in the null dnaK strain. The stability of this temperature-sensitive LacI protein was also examined in detail under various other conditions.

Escherichia coli contains a soluble ATP-dependent protease (Ti) distinct from protease La

The energy requirement for protein breakdown in Escherichia coli has generally been attributed to the ATP-dependence of protease La, the lon gene product. We have partially purified another ATP-dependent protease from lon-cells that lack protease La (as shown by immunoblotting). This enzyme hydrolyzes [3H]methyl-casein to acid-soluble products in the presence of ATP and Mg2+. ATP hydrolysis appears necessary for proteolytic activity. Since this enzyme is inhibited by diisopropyl fluorophosphate, it appears to be a serine protease, but it also contains essential thiol residues. We propose to name this enzyme protease Ti. It differs from protease La in nucleotide specificity, inhibitor sensitivity, and subunit composition. On gel filtration, protease Ti has an apparent molecular weight of 370,000. It can be fractionated by phosphocellulose chromatography or by DEAE chromatography into two components with apparent molecular weights of 260,000 and 140,000. When separated, they do not show proteolytic activity. One of these components, by itself, has ATPase activity and is labile in the absence of ATP. The other contains the diisopropyl fluorophosphate-sensitive proteolytic site. These results and the similar findings of Katayama-Fujimura et al. [Katayama-Fujimura, Y., Gottesman, S. & Maurizi, M. R. (1987) J. Biol. Chem. 262, 4477-4485] indicate that E. coli contains two ATP-hydrolyzing proteases, which differ in many biochemical features and probably in their physiological roles.

DNA-stimulated ATPase activity on the lon (CapR) protein

The gene product of the pleiotropic lon (also called capR) locus in Escherichia coli, the CapR protein, is an ATP hydrolysis-dependent protease and a nonspecific nucleic acid-binding protein. We demonstrated that it is also a DNA-stimulated adenosine triphosphatase (ATPase). This new activity is distinct from the protease-associated ATPase activity and occurs in the absence of proteolytic substrate. The reaction requires the presence of a divalent cation and has a pH optimum of 8.0. The products of the reaction are ADP and inorganic phosphate. No adenylation or phosphorylation of the DNA or proteins was detected. The maximum rate of ATP hydrolysis occurs in the presence of supercoiled (form I) DNA. Relaxed circles (form II), double-stranded DNA, and single-stranded DNA are less effective in promoting ATPase activity, whereas RNA is inactive. The DNA-stimulated ATPase activity is inhibited by a mutationally altered form of the CapR protein called the CapR9 protein. The interaction of the CapR and CapR9 subunits suggests that this enzymatic activity of the CapR protein is oligomeric in the presence of DNA. Our in vitro experiments indicate a possible role for nucleic acids in the regulation of all lon (capR) activity.

The ubiquitin-mediated proteolytic pathway and mechanisms of energy-dependent intracellular protein degradation

In this review we briefly describe the lysosomal system, consider the evidence for multiplicity of protein degradation pathways in vivo, discuss in detail the ubiquitin-mediated pathway of intracellular ATP-dependent protein degradation, and also the possible significance of ubiquitin-histone conjugates in chromatin. For detailed discussions of the various characteristics and physiological roles of intracellular protein breakdown, the reader is referred to earlier reviews [1-7] and reports of recent symposia [8-10]. Information on the ubiquitin system prior to 1981 was described in an earlier review [11]. Hershko has briefly reviewed more recent information [12].

Protease La from Escherichia coli hydrolyzes ATP and proteins in a linked fashion

The energy requirement for protein breakdown in Escherichia coli results from an ATP requirement for the function of protease La, the product of the lon gene. This novel serine protease contains an ATPase activity that is essential for proteolysis. ATP and protein hydrolysis show the same Km for ATP (30-40 muM) and are affected similarly by various inhibitors, activators, and ATP analogs. Vanadate inhibited ATP cleavage and caused a proportionate reduction in casein hydrolysis, and inhibitors of serine proteases reduced ATP cleavage. Thus, ATP and protein hydrolysis appear to be linked stoichiometrically. Furthermore, ATP hydrolysis is stimulated two- to threefold by polypeptides that are substrates for the protease (casein, glucagon) but not by nonhydrolyzed polypeptides (insulin, RNase). Unlike hemoglobin or native albumin, globin and denatured albumin stimulated ATP hydrolysis and were substrates for proteolysis. It is suggested that the stimulation of ATP hydrolysis by potential substrates triggers activation of the proteolytic function.