Overproduction and purification of Lon protease from Escherichia coli using a maltose-binding protein fusion system

Lon protease, which plays a major role in degradation of abnormal proteins in Escherichia coli, was overproduced and efficiently purified using the maltose-binding protein (MBP) fusion vector. The MBP-Lon fusion protein was expressed in a soluble form in E. coli and purified to homogeneity by amylose resin in a single step. Lon protease was split from MBP by cleaving a fusion point between MBP and Lon with factor Xa and purified by amylose resin and subsequent gel filtration. In this simple method, Lon protease was purified to homogeneity. Purified MBP-Lon fusion protein and Lon protease showed similar breakdown activities with a peptide (succinyl-L-phenylalanyl-L-leucyl-phenylalanyl-beta-D-methoxynaphthyl amide) and protein (alpha-casein) in the presence of ATP. Therefore, the gene-fusion approach described in this study is useful for the production of functional Lon protease. MBP-Lon fusion protein, which both binds to the amylose resin and has ATP-dependent protease activity, should be especially valuable for its application in the degradation of abnormal proteins by immobilized enzymes.

Cloning, nucleotide sequence, and expression of the Bacillus subtilis lon gene

The lon gene of Escherichia coli encodes the ATP-dependent serine protease La and belongs to the family of sigma 32-dependent heat shock genes. In this paper, we report the cloning and characterization of the lon gene from the gram-positive bacterium Bacillus subtilis. The nucleotide sequence of the lon locus, which is localized upstream of the hemAXCDBL operon, was determined. The lon gene codes for an 87-kDa protein consisting of 774 amino acid residues. A comparison of the deduced amino acid sequence with previously described lon gene products from E. coli, Bacillus brevis, and Myxococcus xanthus revealed strong homologies among all known bacterial Lon proteins. Like the E. coli lon gene, the B. subtilis lon gene is induced by heat shock. Furthermore, the amount of lon-specific mRNA is increased after salt, ethanol, and oxidative stress as well as after treatment with puromycin. The potential promoter region does not show similarities to promoters recognized by sigma 32 of E. coli but contains sequences which resemble promoters recognized by the vegetative RNA polymerase E sigma A of B. subtilis. A second gene designated orfX is suggested to be transcribed together with lon and encodes a protein with 195 amino acid residues and a calculated molecular weight of 22,000.

Evidence for structural conservation of Lon and RcsA

DNA probes specific to the Escherichia coli genes encoding Lon protease and RcsA hybridized to specific DNA sequences in a number of different microorganisms. Antiserum to either E. coli protein Lon or RcsA reacted with specific proteins in these organisms. These results provide structural evidence of the presence of Lon and RcsA in organisms other than E. coli.

Alp suppression of Lon: dependence on the slpA gene

We have previously found that plasmids carrying the Escherichia coli alp gene (now to be called alpA) suppress two phenotypes of a delta lon protease mutant, overproduction of capsular polysaccharide and sensitivity to UV light. Suppression of these lon phenotypes is most likely explained by the increased degradation of the Lon substrates responsible for these phenotypes. We have called this suppressing protease activity Alp protease. The Alp protease activity is detected in cells after introduction of plasmids carrying the alpA gene, which encodes an open reading frame of 70 amino acids. Insertions which abolish Alp activity interrupt this open reading frame. We have used Tn10 and lambda placMu mutagenesis to identify a chromosomal locus, slpA, that is required for alpA+ suppression of delta lon. This locus maps at 57 min, close to the chromosomal location of alpA. The expression of beta-galactosidase from a lac transcriptional fusion to slpA is increased six- to eightfold when the alpA+ gene is present on a multicopy plasmid. Therefore, AlpA acts as a transcriptional regulator of the slpA gene(s); activation of slpA transcription is necessary to suppress the phenotypes of a delta lon mutation. In an accompanying paper (J. E. Kirby, J. E. Trempy, and S. Gottesman, J. Bacteriol. 176:2068-2081, 1994), we show that neither AlpA nor SlpA is a component of the protease itself but that they are part of a regulatory cascade which leads to expression of the Alp protease.

[Lon-protease participates in the regulation of transcription of the Lux-operon of Vibrio fischeri]

Lon protease of Escherichia coli specifically inhibits the activity of the regulatory protein LuxI responsible for synthesis of the autoinducer N-(3-oxo-hexanoyl)homoserine lactone. As a result, transcription of the right lux operon is initiated in lon+ bacteria much later than in lon- mutants. Lon protease does not affect the activity of LuxAB proteins (luciferase) and LuxC, LuxD, and LuxE proteins involved in synthesis of an aldehyde substrate for luciferase.

Lon-dependent proteolysis of CcdA is the key control for activation of CcdB in plasmid-free segregant bacteria

The ccd locus contributes to the stability of plasmid F by post-segregational killing of plasmid-free bacteria. The ccdB gene product is a potent cell-killing protein and its activity is negatively regulated by the CcdA protein. In this paper, we show that the CcdA protein is unstable and that the degradation of CcdA is dependent on the Lon protease. Differences in the stability of the killer CcdB protein and its antidote CcdA are the key to post-segregational killing. Because the half-life of active CcdA protein is shorter than that of active CcdB protein, persistence of the CcdB protein leads to the death of plasmid-free bacterial segregants.

Cloning and sequence analysis of cDNA for a human homolog of eubacterial ATP-dependent Lon proteases

Overlapping cDNA clones containing mRNA for a putative Lon protease (LonHS) were isolated from cDNA libraries prepared from human brain poly(A)+ RNA. The determined nucleotide sequence contains a 2814-bp open reading frame with two potential initiation codons (positions 62-64 and 338-340). The 5'-terminal 337-nucleotide fragment of LonHS mRNA is highly enriched with G and C nucleotides and could direct synthesis of the LonHS N-terminal domain. More likely this region promotes initiation of protein synthesis from the second AUG codon in a cap-independent manner. The amino acid sequence initiated at the second AUG codon includes 845 residues, over 30% of which are identical to those of eubacterial Lon proteases. Residues of the 'A' and 'B' motifs of NTP-binding pattern and a plausible catalytic serine residue are conserved in LonHS. Northern blot analysis revealed LonHS mRNA in lung, duodenum, liver and heart, but not in thymus cells.

[ATP-dependent proteinase La from Escherichia coli]

Homogeneous preparations of the ATP-dependent La proteinase from E. coli and two its mutant forms, containing an alanine residue instead of Ser679 or Ser368, were isolated. Ser679 was shown to be catalytically active rather than Ser368 as suggested in the literature. To choose between the alternative structures of the gene lon La proteinase fragments within the controversial regions were analysed and the gene structure established at the Laboratory of Proteolytic Enzymes (Institute of Bioorganic Chemistry) was confirmed. Inactivity of La proteinase in some in vitro systems suggests its functioning in vivo to be not autonomous, requiring additional factors.

PIM1 encodes a mitochondrial ATP-dependent protease that is required for mitochondrial function in the yeast Saccharomyces cerevisiae

The PIM1 nuclear gene in the yeast Saccharomyces cerevisiae encodes a mitochondrial ATP-dependent protease that exhibits over 30% identity with ATP-dependent protease La from Escherichia coli, Lon from Bacillus brevis, and one from Myxococcus xanthus. In addition, Pim1 is 1133 amino acids long and has a putative mitochondrial import signal in the N-terminal region. Enzymatic comparisons of normal PIM1+ and deficient pim1-delta strains revealed that the ATP-dependent protease is located within the mitochondrial matrix. The pim1-delta strains are unable to utilize nonfermentable substrates as the sole carbon source and are unable to maintain functional mitochondrial DNA, indicating that the Pim1 protease is required for mitochondrial function. PIM1 mRNA is constitutively expressed but is increased after thermal stress, suggesting that Pim1 may play a role in the heat shock response.

[Restoration of transcription antitermination of N- bacteriophages in Escherichia coli with a mutant RNA polymerase]

The N protein of bacteriophage lambda modifies Escherichia coli RNA polymerase in such a way that it transcribes through termination signals, in a process called antitermination. In general N-mutants are not able to perform transcription antitermination. In this paper we report the suppression of N7 and Nmar3 mutations by Escherichia coli ron-lon strain. The lon mutation causes the N protein half-life to raise, suggesting that excess of N7 fragment or Nmar3 protein overcome the defect in antitermination. Under these conditions the lambda N-phages produced a titer similar to lambda wild type, although the plaques were smaller. These observations highlight the relevance of N half life in the regulation of transcription antitermination.

Controlled high-level expression of the lon gene of Escherichia coli allows overproduction of Lon protease

Lon protease from Escherichia coli is an ATP-dependent protease which plays important roles in regulating the levels of specific proteins and in eliminating abnormal proteins. A major problem of working with Lon protease, the inability to substantially overproduce the enzyme, has been overcome by placing the lon gene under the control of an inducible trp promoter within a copy-number-controllable plasmid. Induction resulted in higher levels of production of the protease (approximately 100 micrograms/ml of cell culture) than were previously possible. The enzyme has been purified to apparent homogeneity and shown to possess the characteristic ATP-dependent proteolytic activity. Sequence verification during DNA manipulations revealed differences from two previously published sequences for the lon gene.

An imbalance of HU synthesis induces mucoidy in Escherichia coli

Mutations in a number of loci, including the lon gene, dramatically increase the production of colanic acid capsular polysaccharide and render Escherichia coli K-12 mucoid. The lon gene, which encodes an ATP-dependent protease, is localized at ten minutes on the E. coli map and is very closely linked to the hupB gene coding for one of the two subunits of the histone-like protein HU. Surprisingly the introduction of a multi-copy plasmid carrying either the hupB or hupA gene into a wild-type E. coli strain, results in the overproduction of one of the HU subunits and repression of the synthesis of the other without changing the overall concentration of HU, also renders the cells mucoid. As in a lon strain, the transcription of the cps genes, the structural genes for the synthesis of colanic acid, is induced dramatically. Protease Lon negatively regulates cps genes by destabilizing RcsA, a positive regulator of capsule synthesis. Regulation of HU synthesis does not affect the steady state level of Lon, as judged by Western blotting. The UV sensitivity of the hup transformed lon+ bacteria is identical to the lon+ parental strain, suggesting that Lon activity for the degradation of SulA in these cells is normal. Using lac operon fusions to cps gene promoters and to the rcsA promoter we show that the deregulation of HU synthesis does not by pass the positive regulatory action of RcsA and RcsB for the expression of cps genes but functions by stimulating RcsA synthesis.

An extraintestinal, pathogenic isolate of Escherichia coli (O4/K54/H5) can produce a group 1 capsule which is divergently regulated from its constitutively produced group 2, K54 capsular polysaccharide

We are studying an O4/K54/H5 Escherichia coli bacteremic isolate (CP9) as a model pathogen for extraintestinal infection. Its group 2, K54 capsular polysaccharide is an important virulence determinant and confers serum resistance. In this study the effect of the group 1 capsule regulators, RcsA, RcsB, and Lon protease, on the regulation of CP9's capsular polysaccharides was assessed. It was established that in the presence of multicopy rcsA or with disruption of lon, CP9 can be induced to produce a group 1 capsule. RcsA, RcsB, and Lon are present in this K54 background and regulate group 1 capsule expression in a fashion similar to that described for K-12 strains. Two independent group 2 capsule gene protein fusions (cl1.29::TnphoA and cl1.137::TnphoA) were used to evaluate the effects of these regulators on group 2 K54 capsule production. Disruption of lon resulted in 1.9-fold (TR293 [cl1.29::TnphoA lon-146]) and 3.4-fold (TR1373 [cl1.137::TnphoA lon-146]) decreases in fusion activity at 28 degrees C, relative to the baseline level. However, decreases in fusion activity at 42 degrees C were only 1.2- and 1.4-fold, respectively. Inactivation of both lon and rcsA or lon and rcsB restored fusion activity to baseline levels at 28 degrees C, but only a partial restoration of activity was seen at higher temperatures. To assess whether these differences in fusion activity reflected a functional change in capsule production, the effects of 80% normal human serum (NHS) were tested against CP9 and TR93 (lon-146). Since the group 2 K54 capsule protects against the bactericidal activity of 80% NHS, a decrease in its production results in an increase in serum sensitivity. Viable counts of CP9 increased 10-fold in 80% NHS over 3 h at 28 degrees C, as expected. In contrast to CP9, TR93 (lon-146) incurred a 10-fold loss in viability under the same conditions. The levels of RcsA are increased in TR93 (lon 146) as consequence of lon disruption; therefore, these results in conjunction with the cl1::TnphoA protein fusion data establish RcsA as a negative regulator of the group 2 K54 capsular polysaccharide. Furthermore, these results also suggest existence of another Lon-sensitive negative regulator of group 2 K54 capsule production, which is active higher temperatures.

A human mitochondrial ATP-dependent protease that is highly homologous to bacterial Lon protease

We have cloned a human ATP-dependent protease that is highly homologous to members of the bacterial Lon protease family. The cloned gene encodes a protein of 963 amino acids with a calculated molecular mass of 106 kDa, slightly higher than that observed by Western blotting the protein from human tissues and cell lines (100 kDa). A single species of mRNA was found for this Lon protease in all human tissues examined. The protease is encoded in the nucleus, and the amino-terminal portion of the protein sequence contains a potential mitochondrial targeting presequence. Immunofluorescence microscopy suggested a predominantly mitochondrial localization for the Lon protease in cultured human cells. A truncated LON gene, in which translation was initiated at Met118 of the coding sequence, was expressed in Escherichia coli and produced a protease that degraded alpha-casein in vitro in an ATP-dependent manner and had other properties similar to E. coli Lon protease.

Formation of linear plasmid multimers promoted by the phage lambda Red-system in lon mutants of Escherichia coli

We report here the formation of plasmid linear multimers promoted by the Red-system of phage lambda using a multicopy plasmid comprised of lambda red alpha and red beta genes, under the control of the lambda cI857 repressor. Our observations have revealed that the multimerization of plasmid DNA is dependent on the red beta and recA genes, suggesting a concerted role for these functions in the formation of plasmid multimers. The formation of multimers occurred in a recBCD+ sbcB+ xthA+ lon genetic background at a higher frequency than in the isogenic lon+ host cells. The multimers comprised tandem repeats of monomer plasmid DNA. Treatment of purified plasmid DNA with exonuclease III revealed the presence of free double-chain ends in the molecules. Determination of the size of multimeric DNA, by pulse field gel electrophoresis, revealed that the bulk of the DNA was in the range 50-240 kb, representing approximately 5-24 unit lengths of monomeric plasmid DNA. We provide a conceptual framework for Red-system-promoted formation and enhanced accumulation of plasmid linear multimers in lon mutants of E. coli.

The lonD gene is homologous to the lon gene encoding an ATP-dependent protease and is essential for the development of Myxococcus xanthus

Myxococcus xanthus contains two genes (lonV and lonD) homologous to the Escherichia coli lon gene for an ATP-dependent protease. We found that the lonD gene encodes a 90-kDa protein consisting of 827 amino acid residues. The lonD gene product shows 49, 48, and 52% sequence identity to the products of the M. xanthus lonV, E. coli lon, and Bacillus brevis lon genes, respectively. When a lonD-lacZ fusion was used, lonD was expressed during both vegetative growth and development. However, while lonD-disrupted strains were able to grow normally vegetatively, the development of M. xanthus was found to be arrested at an early stage in these strains. The mutant strains were able to form neither fruiting bodies nor myxospores.

Myxococcus xanthus encodes an ATP-dependent protease which is required for developmental gene transcription and intercellular signaling

The bsgA gene of Myxococcus xanthus plays an essential role in the regulation of early gene expression during fruiting body formation and sporulation. bsgA mutants behave as though unable to initiate a required cell-cell interaction and consequently fail to transcribe normal levels of many developmentally induced genes. We determined the nucleotide sequence of bsgA, which predicts a single gene encoding a 90.4-kDa protein. The deduced BsgA protein shares 45 and 48% amino acid identity with the lon genes of Escherichia coli and Bacillus brevis, respectively. The cloned bsgA gene was expressed in E. coli, and the BsgA protein was partially purified and found, like its E. coli homolog, to be an ATP-dependent protease. Thus, the basis for the phenotype of bsgA mutants is likely to be a defect in intracellular proteolysis.

Cloning and nucleotide sequence of the Myxococcus xanthus lon gene: indispensability of lon for vegetative growth

The lon gene of Escherichia coli is known to encode protease La, an ATP-dependent protease associated with cellular protein degradation. A lon gene homolog from Myxococcus xanthus, a soil bacterium which differentiates to form fruiting bodies upon nutrient starvation, was cloned and characterized by use of the lon gene of E. coli as a probe. The nucleotide sequence of the M. xanthus lon gene was determined. It contains an open reading frame that encodes a 92-kDa protein consisting of 817 amino acid residues. The deduced amino acid sequence of the M. xanthus lon gene product showed 60 and 56% identity with those of the E. coli and Bacillus brevis lon gene products, respectively. Analysis of an M. xanthus strain carrying a lon-lacZ operon fusion suggested that the lon gene is similarly expressed during vegetative growth and development in M. xanthus. In contrast to that of E. coli, the M. xanthus lon gene was shown to be essential for cell growth, since a null mutant could not be isolated.

Role of Clp protease subunits in degradation of carbon starvation proteins in Escherichia coli

When deprived of a carbon source, Escherichia coli induces the synthesis of a group of carbon starvation proteins. The degradation of proteins labeled during starvation was found to be an energy-dependent process which was inhibited by the addition of KCN and accelerated when cells were resupplied with a carbon source. The degradation of the starvation proteins did not require the ATP-dependent Lon protease or the energy-independent proteases protease I, protease IV, OmpT, and DegP. During starvation, mutants lacking either the ClpA or ClpP subunit of the ATP-dependent Clp protease showed a partial reduction in the degradation of starvation proteins. Strains lacking ClpP failed to increase degradation of starvation proteins when glucose was added to starving cells. The clpP mutants showed a competitive disadvantage compared with wild-type cells when exposed to repeated cycles of carbon starvation and growth. Surprisingly, the glucose-stimulated, ClpP-dependent degradation of starvation proteins did not require either the ClpA or ClpB protein. The patterns of synthesis of starvation proteins were similar in clpP+ and clpP cells. The clpP mutants had reduced rates of degradation of certain starvation proteins in the membrane fraction when a carbon source was resupplied to the starved cells.

Mutational analysis of the Escherichia coli serB promoter region reveals transcriptional linkage to a downstream gene

Genes encoding proteins with unrelated functions can be cotranscribed, and this may be used by cells to coordinate different metabolic pathways during growth. We describe a gene, designated sms, which is downstream from the serine biosynthetic gene serB in Escherichia coli but does not appear to be involved in amino acid (aa) biosynthesis. The sms gene is 1380 bp long. The Sms product migrates at 55 kDa on sodium dodecyl sulfate(SDS)-polyacrylamide gels and has a M(r) of 49472 (460 aa residues) calculated from the nucleotide sequence. The deduced Sms aa sequence shares regions of similarity with two ATP-dependent proteases, Lon and RecA, and contains two motifs: a C-x(2)-C-x(n)-C-x(2)-C motif, which is found in some nucleic acid binding proteins, and an ATP/GTP binding site motif. Insertional inactivation of sms led to increased sensitivity to the alkylating agent methylmethane sulfonate, but not to a requirement for serine or other metabolites. Several promoter mutations were isolated and characterized, which suggest that serB has a typical promoter recognized by sigma 70. After the serB coding sequence there is a 48-bp region with no obvious promoter sequence preceding the sms translation start codon. Analyses using sms'-lacZ fusions cloned downstream from wild-type and mutant serB promoters showed that sms is cotranscribed with serB.

Enhanced export of beta-galactosidase fusion proteins in prlF mutants is Lon dependent

We have used fusions of the outer membrane protein LamB to beta-galactosidase (encoded by lacZ) to study the protein export process. This LamB-LacZ hybrid protein blocks export when synthesized at high levels, as evidenced by inducer (maltose) sensitivity, a phenomenon termed LacZ hybrid jamming. The prlF1 mutation relieves LacZ hybrid jamming and allows localization of the fusion protein to a noncytoplasmic compartment. prlF1 and similar alleles are gain-of-function mutations. Null mutations in this gene confer no obvious phenotypes. Extragenic suppressors of a gain-of-function prlF allele have been isolated in order to understand how this gene product affects the export process. The suppressors are all lon null mutations, and they are epistatic to all prlF phenotypes tested. Lon protease activity has been measured in prlF1 cells and shown to be increased. However, the synthesis of Lon is not increased in a prlF1 background, suggesting a previously unidentified mechanism of Lon activation. Further analysis reveals that prlF1 activates degradation of cytoplasmically localized precursors in a Lon protease-dependent manner. It is proposed that accumulation of precursors during conditions of hybrid protein jamming titrates an essential export component(s), possibly a chaperone. Increased Lon-dependent precursor degradation would free this component, thus allowing increased protein export under jamming conditions.

Cloning, characterization, and inactivation of the Bacillus brevis lon gene

A gene of Bacillus brevis HPD31 analogous to the Escherichia coli lon gene has been cloned and characterized. The cloned gene (B. brevis lon gene) encodes a polypeptide of 779 amino acids with a molecular weight of 87,400 which resembles E. coli protease La, the lon gene product. Fifty-two percent of the amino acid residues of the two polypeptides were identical. The ATP-binding sequences found in E. coli protease La were highly conserved. The promoter of the B. brevis lon gene resembled that recognized by the major RNA polymerase of Bacillus subtilis and did not contain sequences homologous to the E. coli heat shock promoters. The B. brevis lon gene was inactivated by insertion of the neomycin resistance gene. A mutant B. brevis carrying the inactivated lon gene showed diminished ability for the degradation of abnormal polypeptides synthesized in the presence of puromycin.

Suppression of insertions in the complex pdxJ operon of Escherichia coli K-12 by lon and other mutations

Complementation analyses using minimal recombinant clones showed that all known pdx point mutations, which cause pyridoxine (vitamin B6) or pyridoxal auxotrophy, are located in the pdxA, pdxB, serC, pdxJ, and pdxH genes. Antibiotic enrichments for chromosomal transposon mutants that require pyridoxine (vitamin B6) or pyridoxal led to the isolation of insertions in pdxA, pdxB, and pdxH but not in pdxJ. This observation suggested that pdxJ, like pdxA, pdxB, and serC, might be in a complex operon. To test this hypothesis, we constructed stable insertion mutations in and around pdxJ in plasmids and forced them into the bacterial chromosome. Physiological properties of the resulting insertion mutants were characterized, and the DNA sequence of pdxJ and adjacent regions was determined. These combined approaches led to the following conclusions: (i) pdxJ is the first gene in a two-gene operon that contains a gene, temporarily designated dpj, essential for Escherichia coli growth; (ii) expression of the rnc-era-recO and pdxJ-dpj operons can occur independently, although the pdxJ-dpj promoter may lie within recO; (iii) pdxJ encodes a 26,384-Da polypeptide whose coding region is preceded by a PDX box, and dpj probably encodes a basic, 14,052-Da polypeptide; (iv) mini-Mud insertions in dpj and pdxJ, which are polar on dpj, severely limit E. coli growth; and (v) three classes of suppressors, including mutations in lon and suppressors of lon, that allow faster growth of pdxJ::mini-Mud mutants can be isolated. A model to account for the action of dpj suppressors is presented, and aspects of this genetic analysis are related to the pyridoxal 5'-phosphate biosynthetic pathway.

Involvement of the chaperonin dnaK in the rapid degradation of a mutant protein in Escherichia coli

The ability of Escherichia coli rapidly to degrade abnormal proteins is inhibited by mutations affecting any of several heat shock proteins (hsps). We therefore tested whether a short-lived mutant protein might become associated with hsps as part of its degradation. At 30 degrees C, the non-secreted mutant form of alkaline phosphatase, phoA61, is relatively stable, and very little phoA61 is found associated with the hsp dnaK. However, raising the temperature to 37 degrees C or 41 degrees C stimulated the degradation of this protein, and up to 30% of cellular phoA61 became associated with dnaK, as shown by immunoprecipitation and Western blot analysis. Also found in complexes with phoA61 were the hsps, protease La and grpE (but no groEL, or groES). The rapid degradation of phoA61 at 37 degrees C and 41 degrees C is in part by protease La, since it decreased by 50% in lon mutants. This process also requires dnaK, since deletion of this gene prevented phoA61 degradation almost completely (unless a wild-type dnaK gene was introduced). In contrast, the missense mutation, dnaK756, enhanced phoA61 degradation. The dnaK756 protein also was associated with phoA61, but this complex, unlike that containing wild-type dnaK could not be dissociated by ATP addition. Furthermore, in a grpE mutant, the degradation of phoA61 and the amount associated with dnaK increased, while in a dnaJ mutant, phoA61 degradation and its association with dnaK decreased. Thus, complex formation with dnaK appears essential for phoA61 degradation by protease La and some other cell proteases, and a failure of the dnaK to dissociate normally may accelerate proteolytic attack.(ABSTRACT TRUNCATED AT 250 WORDS)

Regulation of capsular polysaccharide synthesis in Escherichia coli K12

Synthesis of the capsular polysaccharide colanic acid in Escherichia coli K12 is regulated by a complex network of regulatory proteins. This regulation is expressed at the level of transcription of the cps (capsular polysaccharide synthesis) genes. Two positive regulators, RcsA and RcsB, are necessary for maximal capsule expression. The availability of RcsA is normally limited because the RcsA protein is rapidly degraded by the Lon ATP-dependent protease. Therefore Lon acts, indirectly, as a negative regulator of capsule synthesis. The sequence predicted for RcsB suggests that it is the effector component of a two-component system; a protein with homology to sensors, RcsC, also plays a role in capsule regulation. We propose a model for capsule synthesis in which RcsA interacts with RcsB to stimulate transcription of the cps genes. The mechanism of regulation of colanic acid synthesis in E. coli may apply to other capsules in a variety of Gram-negative bacteria.

Expression of ClpB, an analog of the ATP-dependent protease regulatory subunit in Escherichia coli, is controlled by a heat shock sigma factor (sigma 32)

Escherichia coli K-12 produces at least two ATP-dependent proteases, Lon (La) and Clp (Ti), the latter consisting of a regulatory subunit (ClpA) and a proteolytic subunit (ClpP). The gene clpB encoding an analog of ClpA had been found at 57 min on the E. coli chromosome. Cloning and examination of novel heat shock promoters led us to identify a major clpB promoter specifically controlled by a heat shock sigma factor, sigma 32 (the rpoH [= htpR] gene product). beta-Galactosidase synthesis from a PclpB-lacZ operon fusion was transiently induced upon temperature shift from 30 to 42 degrees C, and the induction depended on the rpoH function. Chromosomal clpB transcripts also increased upon temperature upshift and were totally absent in the rpoH deletion strain. In the in vitro transcription experiments, the clpB promoter was specifically recognized and transcribed by RNA polymerase-sigma 32. Nucleotide sequencing and determination of mRNA start sites permitted us to identify a major heat shock promoter located upstream of the clpB coding sequence. The results clearly indicate that clpB expression is under direct control of sigma 32. Since ClpP was recently shown to be a sigma 32-dependent heat shock protein, the present finding suggests the possibility that a potential ATP-dependent protease, ClpB-ClpP complex, plays an important role against thermal stress in E. coli.

Increased ATP-dependent proteolytic activity in lon-deficient Escherichia coli strains lacking the DnaK protein

Extracts made from Escherichia coli null dnaK strains contained elevated levels of ATP-dependent proteolytic activity compared with levels in extracts made from dnaK+ strains. This ATP-dependent proteolytic activity was not due to Lon, Clp, or Alp-associated protease. Comparison of the levels of ATP-dependent proteolytic activity present in lon rpoH dnaK mutants and in lon rpoH dnaK+ mutants showed that the level of ATP-dependent proteolytic activity was elevated in the lon rpoH dnaK mutant strain. These findings suggest that DnaK negatively regulates a new ATP-dependent proteolytic activity, independently of sigma 32. Other results indicate that an ATP-dependent proteolytic activity was increased in a lon alp strain after heat shock. It is not yet known whether the same protease is associated with the increased ATP-dependent proteolytic activity in the dnaK mutants and in the heat-shocked lon alph strain.

Saturation and specificity of the Lon protease of Escherichia coli

Lon is an ATP-dependent protease of Escherichia coli. The lon mutation has a pleiotropic phenotype: UV sensitivity, mucoidy, deficiency for lysogenization by bacteriophage lambda and P1, and lower efficiency in the degradation of abnormal proteins. All of these phenotypes are correlated with the loss of protease activity. Here we examine the effects of overproduction of one Lon substrate, SulA, and show that it protects two other substrates from degradation. To better understand this protection, we mutagenized the sulA gene and selected for mutants that have partially or totally lost their ability to saturate the Lon protease and thus can no longer protect another substrate. Some of the SulA mutants lost their ability to protect RcsA from degradation but could still protect the O thermosensitive mutant protein (Ots). All of the mutants retained their capacity to induce cell division inhibition. It was also found that deletion of the C-terminal end of SulA affected its activity but did not affect its susceptibility to Lon. We propose that Lon may have more than one specificity for peptide cleavage.

Proteolysis and modulation of the activity of the cell division inhibitor SulA in Escherichia coli lon mutants

Intracellular accumulation of the inducible cell division inhibitor SulA is modulated by proteases that ensure its degradation, namely, the Lon protease and another ATP-dependent protease(s). Lon- cells are UV sensitive because SulA is stable. We asked whether these ATP-dependent proteases are more active when lon cells are grown at high temperature or in synthetic medium since these conditions decrease the UV sensitivity of lon cells. We found that these growth conditions have no direct effect on Lon-independent degradation of SulA. They may, instead, decrease the SulA-FtsZ interaction.

Sequence and structure of Clp P, the proteolytic component of the ATP-dependent Clp protease of Escherichia coli

The ATP-dependent Clp protease of Escherichia coli contains two dissimilar components: the Clp A regulatory polypeptide, with two ATP binding sites and intrinsic ATPase activity, and the Clp P subunit, which contains the proteolytic active site. The DNA sequence of the clpP gene predicts a protein of 207 amino acids (Mr 21,679), which is in close agreement with the size determined by sodium dodecyl sulfate-gel electrophoresis of purified Clp P. Clp P has a native Mr of approximately 240,000, and electron micrographs of the protein show superimposed disk-like structures with a central cavity, similar in appearance to purified proteasomes from eukaryotic cells. Clp P is synthesized with a 14-amino acid leader which is rapidly cleaved in vivo to yield the 193-amino acid protein which has activity in vitro. The clpP gene is at 10 min on the E. coli map, close to that for the ATP-dependent Lon protease of E. coli and far from the gene for clpA. Primer extension experiments indicate that transcription initiates immediately upstream of the coding region for Clp P, with a major transcription start at 120 bases in front of the start of translation. Insertion mutations in clpP have been isolated and transferred to the chromosome; strains devoid of Clp P are viable in the presence or absence of Lon protease. Mutations in clpP stabilize the same Clp A-beta-galactosidase fusion protein specifically stabilized by clpA mutations, providing the first genetic evidence that Clp A and Clp P act together in vivo.

[Cloning, structure and expression of the full-size lon gene in Escherichia coli coding for ATP-dependent La-proteinase]

Assembly of the full Escherichia coli K-12 lon gene from the EcoRI--SphI fragment of the bacterial DNA ("modified" gene) cloned and sequenced earlier and the PstI fragment of the same DNA containing 3'-terminal region of the lon gene has been performed. Both "modified" and full genes showed all phenotype properties of lon gene. The complete nucleotide sequence of the gene (2770 bp) coding for the 784 amino acid sequence of protease La was determined. Location of catalytically active serine, histidine and aspartic acid residues was suggested, and ATP-binding site found. The lon gene and protease La structures we found are compared with those described independently and differences observed are discussed.

Regulation of activity of an ATP-dependent protease, Clp, by the amount of a subunit, ClpA, in the growth of Escherichia coli cells

The activity of an ATP-dependent protease, Clp, was examined in Escherichia coli SG1110 (lon-) in various growth phases. The ATP-dependent proteolytic activity (Clp activity) in a crude extract of the cells changed with the growth phase. Cells in the early exponential growth phase showed the lowest activity, but then the activity increased dramatically with cell growth. The highest Clp activity was found in the cells in the late exponential and early stationary phases, however, the activity returned to the original level on prolonged culturing. These changes in Clp activity were closely correlated to the amount of one of the components of Clp, Clp A, which was quantitated immunochemically with antibodies against the Clp A protein. However, the amount of the other component of Clp, Clp P, did not change with the growth phase. These results suggest that the activity of Clp in the cells is regulated by the amount of Clp A in various growth phases. We next examined the effect of the cellular ATP level on Clp activity, because ATP is a cofactor for Clp protease in vitro. The addition of dinitrophenol (DNP) and sodium azide reduced the intracellular concentration of ATP, but had no effect on the Clp activity or the level of the Clp A protein when these drugs were added to the culture at the stationary phase. On the other hand, these drugs elevated both the Clp activity and the Clp A amount in exponentially growing cells, whose cellular ATP level was also reduced.(ABSTRACT TRUNCATED AT 250 WORDS)

The ATP-dependent Clp protease of Escherichia coli. Sequence of clpA and identification of a Clp-specific substrate

The clpA gene, which codes for the ATP-binding subunit of the ATP-dependent Clp protease of Escherichia coli, has been sequenced. The coding region contains a single open reading frame for a protein of 758 amino acids; within the amino acid sequence are two consensus sequences for ATP-binding sites. The sequence of ClpA does not resemble that of other previously described ATPases or Lon, the other sequenced ATP-dependent protease of E. coli, except in the ATP-binding site consensus region. The clpA gene is expressed as a monocistronic message. Primer extension experiments define a major start point of transcription at -183 relative to the start of translation. A rho-independent terminator is located 23 bases beyond the end of the coding region. The ClpA protein is degraded in vivo in a Clp-dependent fashion (t1/2 approximately 60 min). A fusion protein containing the first 40 amino acids of ClpA fused in frame to beta-galactosidase is degraded very rapidly in a clpA+ host (t1/2 approximately 3 min) but not in a clpA- host. This fusion protein is the first Clp-specific substrate described.

Regulation of intracellular proteolysis in Escherichia coli cells by antisense mRNAs of the lon gene

To explore the possibility of regulating proteolytic processes in Escherichia coli cells, a series of plasmids directing the synthesis of antisense mRNAs complementary to different regions of the lon gene was constructed. The effect of these antisense mRNAs on the rate of degradation of abnormal proteins (14C-labelled polypeptides containing puromycin or canavanine) in the bacterial cells was studied. The greatest inhibitory effect occurred in the case of a mRNA complementary to the regulatory region at the 5' end of the lon gene. The reasons for the differences in the efficiency of lon gene antisense mRNAs in inhibiting proteolysis are considered.

Regulation of breakdown of canavanyl proteins in Escherichia coli by growth conditions in lon+ and lon- cells

In vivo rates of proteolysis of canavanyl proteins were compared in lon+ and lon- Escherichia coli strains following growth in a variety of media. Both lon+ and lon- cells grown rapidly in complex media possessed higher levels of constitutive degradative activity than when cultured in minimal media. Pre-growth of lon+ cells in the presence of canavanine induced proteolytic activity following growth in minimal media as did stress agents such as heat, alcohol and puromycin: the lon mutant did not show the increased activity following canavanine treatment. The results suggest the presence of a proteolytic activity which selectively degrades aberrant proteins which does not involve protease La, the product of the lon gene, and which furthermore is regulated in part by growth conditions independently of the stress response.

Lon-dependent regulation of the DNA binding protein HU in Escherichia coli

HU, the major DNA binding protein of Escherichia coli, exists in solution as a heterodimer composed of two highly homologous subunits: HU1, encoded by hupB; HU2, encoded by hupA. The purification of the HU protein from hupA- or hupB- bacteria showed that the hupB mutant strains synthesize normal amounts of the HU2 subunit (which corresponds to 60% of the total HU present in wild-type cells). On the contrary, the amount of HU1 present in hupA mutant strains corresponds to only 6% of the total HU present in wild-type cells. We showed by fusions of the hupB and hupA promoters to the malPQ operon that the absence of one subunit has no major effect on the transcription rate of the gene encoding the other subunit. Analysis of the stability of the HU1 and HU2 subunits, using pulse-chase labeling experiments, showed that the HU1 subunit is degraded specifically in the absence of the HU2 subunit and, moreover, that this degradation is dependent on the presence of the Lon protease.

Alp, a suppressor of lon protease mutants in Escherichia coli

Escherichia coli lon mutants lack a major ATP-dependent protease, are sensitive to UV light and methylmethane sulfonate (MMS), and overproduce capsular polysaccharide. Evidence is presented that an activity (Alp), cloned on a multicopy plasmid, can suppress the phenotypes of lon mutants. The sensitivity to UV and MMS is a reflection of the stabilization of the cell division inhibitor SulA, while the capsule overproduction arises through the stabilization of a transcriptional activator of capsule biosynthetic genes, RcsA. Multicopy alp (pAlp) suppressed capsule formation in delta lon cells, and delta lon cells containing the pAlp plasmid were resistant to MMS treatment. The MMS resistance of delta lon pAlp+ cells correlates with an increase in the degradation of SulA to that found in lon+ cells. Lon-directed degradation of SulA was energy dependent, as was the increase in degradation of SulA in delta lon pAlp+ cells. alp maps close to pheA, at 57 min on the E. coli chromosome. Although pAlp can substitute for Lon, cells lacking alp activity did not have the phenotype on a lon mutant. This study demonstrates that at least one activity, when overproduced in the cell, can substitute for Lon protease.

The two-component, ATP-dependent Clp protease of Escherichia coli. Purification, cloning, and mutational analysis of the ATP-binding component

The ATP-binding component (Component II, hereafter referred to as ClpA) of a two-component, ATP-dependent protease from Escherichia coli has been purified to homogeneity. ClpA is a protein with subunit Mr 81,000. It has an intrinsic ATPase activity and activates degradation of protein substrates only in the presence of a second component (Component I, hereafter referred to as ClpP), Mg2+, and ATP. The amount of ClpA varies by less than a factor of 2 in cells grown in different media and at temperatures from 30 to 42 degrees C. ClpA does not appear to be a heat-shock protein since its synthesis is not dependent on htpR. Antibodies against purified ClpA were used to identify lambda transducing phage bearing the clpA gene. The cloned gene contains a DNA sequence expected to code for the first 28 amino acids of ClpA, which were determined by protein sequencing of purified ClpA. The clpA gene in the phage was mutated by insertion of delta kan defective transposons and the mutations were transferred to E. coli by homologous recombination. The clpA gene was mapped to 19 min on the E. coli chromosome. Mutant cells with insertions early in the gene produce no ClpA protein detectable in Western blots, and extracts of such mutant cells have no detectable ClpA activity. clpA- mutants grow well under all conditions tested and are not defective in turnover of proteins during nitrogen starvation nor in the turnover of such highly unstable proteins as the lambda proteins O, N, and cII, or the E. coli proteins SulA, RcsA, and glutamate dehydrogenase. The degradation of abnormal canavanine-containing proteins is defective in clpA mutants especially in cells that also have a lon- mutation. Extracts of clpA- lon- cells have ATP-dependent casein degrading activity.

Sequence of the lon gene in Escherichia coli. A heat-shock gene which encodes the ATP-dependent protease La

To learn more about the mechanism and regulation of the ATP-dependent protease La in Escherichia coli, the lon gene was completely sequenced using the dideoxy method on fragments generated by Bal31 digestion. The predicted amino acid composition based on the DNA sequence agreed well with the composition of the acid-hydrolyzed protease. The predicted NH2-terminal amino acid sequence, tryptophan content, and the carboxyl terminus also agreed with experimental data. However, the molecular weight of 87,000 (783 amino acids) calculated from the DNA sequence was lower than prior estimates. The tetrameric enzyme contains four binding sites for ATP, a DNA-binding domain, a proteolytic site, and a regulatory site that binds unfolded polypeptides. An ATP-binding pocket exists on each subunit as shown by consensus sequences and elements of secondary structure resembling those on other nucleotide-binding proteins (e.g. adenylate kinase, RecA). For this purpose, improved consensus patterns for identifying ATP-binding domains were developed. Computer-assisted comparisons, however, failed to demonstrate any regions homologous to sequences in other polypeptides including proteases or DNA-binding proteins. This enzyme also contains an unusual highly acidic domain surrounded by very basic sequences. Protease La is the first ATP-dependent protease sequenced and seems to represent a new type of enzyme. The promoter sequence was similar to consensus sequences for other heat-shock promoters. Using site-directed mutagenesis, alterations were introduced into the putative promoter sequence. Mutations upstream of -35 had little effect, but alterations immediately upstream of -10 lowered basal transcription of a lon-lacZ operon fusion and reduced its response to inducers of the heat-shock response.

A bacteriophage T4 gene which functions to inhibit Escherichia coli Lon protease

A bacteriophage T4 gene which functions to inhibit Escherichia coli Lon protease has been identified. This pin (proteolysis inhibition) gene was selected for its ability to support plaque formation by a lambda Ots vector at 40 degrees C. Southern blot experiments indicated that this T4 gene is included within the 4.9-kilobase XbaI fragment which contains gene 49. Subcloning experiments showed that T4 gene 49.1 (designated pinA) is responsible for the ability of the Ots vector to form plaques at 40 degrees C. Deficiencies in Lon protease activity are the only changes known in E. coli that permit lambda Ots phage to form plaques efficiently at 40 degrees C. lon+ lysogens of the lambda Ots vector containing pinA permitted a lambda Ots phage to form plaques efficiently at 40 degrees C. Furthermore, these lysogens, upon comparison with similar lysogens lacking any T4 DNA, showed reduced levels of degradation of puromycyl polypeptides and of canavanyl proteins. The lon+ lysogens that contained pinA exhibited other phenotypic characteristics common to lon strains, such as filamentation and production of mucoid colonies. Levels of degradation of canavanyl proteins were essentially the same, however, in null lon lysogens which either contained or lacked pinA. We infer from these data that the T4 pinA gene functions to block Lon protease activity; pinA does not, however, appear to block the activity of proteases other than Lon that are involved in the degradation of abnormal proteins.

Construction and characterization of mutations in hupB, the gene encoding HU-beta (HU-1) in Escherichia coli K-12

Plasmid pJMC21 contains Escherichia coli chromosomal DNA encoding Lon protease, HU-beta (HU-1), and an unidentified 67,000-dalton protein. A kanamycin resistance cassette was used in the construction of insertion and deletion mutations in hupB, the gene encoding HU-beta on plasmid pJMC21. The reconstructed plasmids were linearized and used to introduce hupB chromosomal mutations into JC7623 (recBC sbcBC). These mutations, as expected, mapped in the 9.8-min region of the E. coli chromosome by P1 transduction (16% linkage to proC+). Southern blot hybridization of chromosomal fragments verified that hupB+ was replaced by the mutant allele, with no indication of gene duplication. All the mutant strains had growth rates identical to that of wild-type E. coli, were resistant to UV irradiation and nitrofurantoin, and supported the in vivo transposition-replication of bacteriophage Mu, Mu lysogenization, Tn10 transposition from lambda 1098, and lambda replication-lysogenization. The only observable phenotypic variation was a reduced Mu plaque size on the hupB mutant strains; however, the yield of bacteriophage Mu in liquid lysates prepared from the mutant strains was indistinguishable from the yield for the wild type.

The phenotypic suppression of a mutation in the gene rplX for ribosomal protein L24 by mutations affecting the lon gene product for protease LA in Escherichia coli K12

A suppressor mutation of a temperature-sensitive mutant of ribosomal protein L24 (rplX19) was mapped close to the lon gene by genetic analysis and was shown to affect protease LA. The degradation and the synthesis rates of individual ribosomal proteins were determined. Proteins L24, L14, L15 and L27 were found to be degraded faster in the original rplX19 mutant than in the rplX19 mutant containing the suppressor mutation. Other ribosomal proteins were either weakly or not at all degraded in both mutants. Temperature-sensitive growth was also suppressed by the overproduction of mutant protein L24 from a plasmid. Our results suggest that (1) either free ribosomal proteins or proteins bound to abortive assembly precursors are highly susceptible to the lon gene product and (2) the mutationally altered protein L24 can still function at the nonpermissive growth temperature of the mutant, if it is present in sufficient amounts.

[Stability of normal, abnormal and recombinant proteins in Escherichia coli strains deficient for intracellular proteinase La--the product of the lon gene]

Escherichia coli Lon-mutants deficient in intracellular protease La have been isolated. The rate of degradation of normal cellular proteins was 1.5-2-fold lower in Lon-mutants as compared with that of the wild type strain. The rate of degradation of canavanine-containing abnormal proteins, as well as foreign proteins was significantly higher in E. coli than that of normal proteins. Lon-mutants possessed 2-2.5-fold lower rates of degradation of abnormal proteins as compared with Lon+-strains. The rate of degradation of human interferon alpha-2 was 10-fold higher in E. coli than that of abnormal proteins. B. amyloliquefaciens alpha-amylase degraded in E. coli with the rate comparable with that of abnormal proteins, since chloramphenicolacetyltransferase from Tn9 was stable in E. coli. The rate of degradation of interferon alpha-2 was 2-fold lower in Lon-mutants (half-life 23-26 min) than in the initial strain (11-12 min). Lon-mutants were effectively used as recipient strains for constructing strains-producers of several human alpha- and beta-interferons.

Binding of nucleotides to the ATP-dependent protease La from Escherichia coli

A critical enzyme in protein breakdown in Escherichia coli is the ATP-hydrolyzing protease La, the lon gene product. In order to clarify the role of ATP in proteolysis, we studied ATP and ADP binding to this enzyme using rapid gel filtration to separate free from bound ligands. In the presence of Mg2+ or Mn2+ and 10 microM ATP, two molecules of ATP were bound to the tetrameric enzyme, while at 100 microM ATP (or higher), four ATP molecules were bound, both at 0 and 37 degrees C. Protease La thus has two high affinity sites (S0.5 less than 10(-7) M) for ATP and two lower affinity sites (S0.5 = 12-15 microM). Binding was reversible. In the absence of a divalent ion, ATP bound to only two sites. However, much lower Mg2+ concentrations (50 microM) were required for maximal ATPase binding than for maximal proteolytic and ATPase activity (2 mM). Decavanadate, which is a potent inhibitor of proteolysis, also blocked ATP binding, but orthovanadate had neither effect. Different ATP analogs bind to these sites in distinct ways. Adenyl-5'-yl imidodiphosphate binds to only one high affinity site, while adenyl-5'-yl methylene monophosphonate binds to two. Nevertheless, both non-metabolizable analogs can activate oligopeptide hydrolysis as well as ATP. Although binding of a single nucleotide can activate peptide hydrolysis, occupancy of all four sites appears necessary for maximal protein breakdown. The ATP molecules on all four sites are hydrolyzed rapidly. The Pi is released, but ADP remains on the enzyme. ADP binds to the same four sites, but this process does not require divalent ions. Protease La shows higher affinity for ADP than for ATP. Therefore, in vivo, ADP should inhibit ATP binding and protease La function.

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.

Regulation of cell division in Escherichia coli K-12: probable interactions among proteins FtsQ, FtsA, and FtsZ

In Escherichia coli, the FtsQ, FtsA, and FtsZ proteins are believed to play essential roles in the regulation of cell division. Of the three proteins, FtsZ has received the most attention, particularly because of its interactions with SfiA. Double mutants which carry mutations located in the ftsQ, ftsA, or ftsZ gene in combination with the lon-1 mutation were constructed. In the presence of the lon-1 mutation, which is known to stabilize SfiA, the ftsQ1 mutant cells were not capable of forming colonies on a rich agar medium, whereas mutant cells harboring either one of the mutations grew well on this medium. Examination of lon-1 fts double-mutant cells for sensitivity to UV light revealed that those carrying the ftsA10 allele were resistant. It was also observed that in the presence of a multicopy plasmid containing a wild-type ftsZ gene, the ftsQ1 mutant filamented markedly following a nutritional shift-up and that the division rate of ftsZ84 mutant cells was slightly reduced when they harbored a wild-type ftsQ-containing plasmid. The possibility that the Fts proteins are interacting with one another and forming a molecular complex is discussed.

A multiple-component, ATP-dependent protease from Escherichia coli

A new ATP-dependent, casein-degrading proteolytic complex has been identified and partially purified from Escherichia coli. The proteolytic complex can be isolated from wild-type cells as well as from mutants in which the gene for the ATP-dependent Lon protease is deleted. The complex consists of at least two components (components I and II) that can be separated from each other (and from wild-type Lon protease) by phosphocellulose chromatography. Neither component has casein-degrading activity when added separately to assay solutions with or without ATP. Both components must be present simultaneously for casein degradation to occur. Of the nucleotides tested, only ATP activates the proteolytic complex, and the ATP must be present continuously for degradation to occur. Component II copurifies with an ATPase activity and binds to a Type 4 ATP affinity column. ATP protects component II from heat inactivation, suggesting that component II interacts with ATP. Proteolysis was not inhibited by any serine protease inhibitors but was inhibited by reagents such as the organomercurial Neohydrin and N-ethylmaleimide, which react with sulfhydryl groups. Our data provide convincing evidence that E. coli possesses a previously undescribed proteolytic system composed of at least two complementary components and absolutely dependent on ATP.

An increased content of protease La, the lon gene product, increases protein degradation and blocks growth in Escherichia coli

The lon gene product in Escherichia coli is an ATP-dependent protease (La) that plays an important role in the breakdown of abnormal proteins and certain normal polypeptides. Since transcription of the lon gene rises as part of the heat-shock response, we studied the physiological effects of increased levels of protease La. In cells carrying additional copies of the lon gene under the control of the lac or tac promoter, induction of the protease resulted in a rapid cessation of cell growth and in a loss of viability at stationary phase. Similarly, cells carrying a multicopy plasmid encoding the lon gene contained 2-5-fold more protease La and grew much more slowly than did control cells. In such cells, insertion sequences appeared spontaneously in the lon gene on the plasmid and prevented the excess protease production and allowed more rapid growth. The cells with increased content of protease La (due to the lon plasmid or induction of the lon gene) exhibited severalfold higher rates of degradation of abnormal proteins containing amino acid analogs and of incomplete polypeptides containing puromycin. Also, a beta-galactosidase fusion protein with enzymatic activity was relatively stable in control cells but unstable in the cells with high protease La content. In these cells, the overall degradation of normal proteins increased 2-fold, and certain cellular polypeptides appeared particularly sensitive to proteolysis. Thus, rates of protein degradation in vivo are limited in part by the cellular content of the ATP-dependent protease, and increases in transcription of the lon gene enhance proteolysis and can be deleterious to the cell.

Structural inhibition and reactivation of Escherichia coli septation by elements of the SOS and TER pathways

The inhibition of cell division caused by induction of the SOS pathway in Escherichia coli structurally blocks septation, as deduced from two sets of results. Potential septation sites active at the time of SOS induction became inactivated, while those initiated during the following doubling time were active. Penicillin resistance increased in wild-type UV light-irradiated cells, a behavior similar to that observed in mutants in which structural blocks were introduced by inactivation of FtsA. Potential septation sites that have been structurally blocked by either the SOS division inhibitor, furazlocillin inhibition of PBP3, or inactivation of a TER pathway component, FtsA3, could be reactivated one doubling time after removal of the inhibitory agent in the presence of an active lon gene product. Reactivation of potential septation sites blocked by the presence of an inactivated FtsA3 was significantly lower when the lon protease was not active, suggesting that Lon plays a role in the removal of inactivated TER pathway products from the blocked potential septation sites.