Kiyonobu Karata

Dissecting the Role of a Conserved Motif (the Second Region of Homology) in the AAA Family of ATPases SITE-DIRECTED MUTAGENESIS OF THE ATP-DEPENDENT PROTEASE FtsH

Escherichia coli FtsH is an ATP-dependent protease that belongs to the AAA protein family. The second region of homology (SRH) is a highly conserved motif among AAA family members and distinguishes these proteins in part from the wider family of Walker-type ATPases. Despite its conservation across the AAA family of proteins, very little is known concerning the function of the SRH. To address this question, we introduced point mutations systematically into the SRH of FtsH and studied the activities of the mutant proteins. Highly conserved amino acid residues within the SRH were found to be critical for the function of FtsH, with mutations at these positions leading to decreased or abolished ATPase activity. The effects of the mutations on the protease activity of FtsH correlated strikingly with their effects on the ATPase activity. The ATPase-deficient SRH mutants underwent an ATP-induced conformational change similar to wild type FtsH, suggesting an important role for the SRH in ATP hydrolysis but not ATP binding. Analysis of the data in the light of the crystal structure of the hexamerization domain ofN-ethylmaleimide-sensitive fusion protein suggests a plausible mechanism of ATP hydrolysis by the AAA ATPases, which invokes an intermolecular catalytic role for the SRH.

Balanced biosynthesis of major membrane components through regulated degradation of the committed enzyme of lipid A biosynthesis by the AAA protease FtsH (HflB) in Escherichia coli

The suppressor mutation, named sfhC21, that allows Escherichia coli ftsH null mutant cells to survive was found to be an allele of fabZ encoding R‐3‐hydroxyacyl‐ACP dehydrase, involved in a key step of fatty acid biosynthesis, and appears to upregulate the dehydrase. The ftsH1(Ts) mutation increased the amount of lipopolysaccharide at 42°C. This was accompanied by a dramatic increase in the amount of UDP‐3‐O‐(R‐3‐hydroxymyristoyl)‐N‐acetylglucosamine deacetylase [the lpxC (envA) gene product] involved in the committed step of lipid A biosynthesis. Pulse‐chase experiments and in vitro assays with purified components showed that FtsH, the AAA‐type membrane‐bound metalloprotease, degrades the deacetylase. Genetic evidence also indicated that the FtsH protease activity for the deacetylase might be affected when acyl‐ACP pools were altered. The biosynthesis of phospholipids and the lipid A moiety of lipopolysaccharide, both of which derive their fatty acyl chains from the same R‐3‐hydroxyacyl‐ACP pool, is regulated by FtsH.

Conserved Pore Residues in the AAA Protease FtsH Are Important for Proteolysis and its Coupling to ATP Hydrolysis

Like other AAA proteins, Escherichia coli FtsH, a membrane-bound AAA protease, contains highly conserved aromatic and glycine residues (Phe228 and Gly230) that are predicted to lie in the central pore region of the hexamer. The functions of Phe228 and Gly230 were probed by site-directed mutagenesis. The results of both in vivo and in vitro assays indicate that these conserved pore residues are important for FtsH function and that bulkier, uncharged/apolar residues are essential at position 228. None of the point mutants, F228A, F228E, F228K, or G230A, was able to degrade σ32, a physiological substrate. The F228A mutant was able to degrade casein, an unfolded substrate, although the other three mutants were not. Mutation of these two pore residues also affected the ATPase activity of FtsH. The F228K and G230A mutations markedly reduced ATPase activity, whereas the F228A mutation caused a more modest decrease in this activity. The F228E mutant was actually more active ATPase. The substrates, σ32 and casein, stimulated the ATPase activity of wild type FtsH. The ATPase activity of the mutants was no longer stimulated by casein, whereas that of the three Phe228 mutants, but not the G230A mutant, remained σ32-stimulatable. These results suggest that Phe228 and Gly230 in the predicted pore region of the FtsH hexamer have important roles in proteolysis and its coupling to ATP hydrolysis.

The crystal structure of the AAA domain of the ATP-dependent protease FtsH of Escherichia coli at 1.5 Å resolution

Eubacteria and eukaryotic cellular organelles have membrane-bound ATP-dependent proteases, which degrade misassembled membrane protein complexes and play a vital role in membrane quality control. The bacterial protease FtsH also degrades an interesting subset of cytoplasmic regulatory proteins, including sigma(32), LpxC, and lambda CII. The crystal structure of the ATPase module of FtsH has been solved, revealing an alpha/beta nucleotide binding domain connected to a four-helix bundle, similar to the AAA modules of proteins involved in DNA replication and membrane fusion. A sulfate anion in the ATP binding pocket mimics the beta-phosphate group of an adenine nucleotide. A hexamer form of FtsH has been modeled, providing insights into possible modes of nucleotide binding and intersubunit catalysis.

Heat shock regulation in the ftsH null mutant of Escherichia coli: dissection of stability and activity control mechanisms of sigma32 in vivo.

The heat shock response of Escherichia coli is regulated by the cellular level and the activity of σ32, an alternative sigma factor for heat shock promoters. FtsH, a membrane‐bound AAA‐type metalloprotease, degrades σ32 and has a central role in the control of the σ32 level. The ftsH null mutant was isolated, and establishment of the ΔftsH mutant allowed us to investigate control mechanisms of the stability and the activity of σ32 separately in vivo. Loss of the FtsH function caused marked stabilization and consequent accumulation of σ32 (≈20‐fold of the wild type), leading to the impaired downregulation of the level of σ32. Surprisingly, however, ΔftsH cells express heat shock proteins only two‐ to threefold higher than wild‐type cells, and they also show almost normal heat shock response upon temperature upshift. These results indicate the presence of a control mechanism that downregulates the activity of σ32 when it is accumulated. Overproduction of DnaK/J reduces the activity of σ32 in ΔftsH cells without any detectable changes in the level of σ32, indicating that the DnaK chaperone system is responsible for the activity control of σ32in vivo. In addition, CbpA, an analogue of DnaJ, was demonstrated to have overlapping functions with DnaJ in both the activity and the stability control of σ32.

The active form of DNA polymerase V is UmuD′ 2 C–RecA–ATP

DNA-damage-induced SOS mutations arise when Escherichia coli DNA polymerase (pol) V, activated by a RecA nucleoprotein filament (RecA*), catalyses translesion DNA synthesis. Here we address two longstanding enigmatic aspects of SOS mutagenesis, the molecular composition of mutagenically active pol V and the role of RecA*. We show that RecA* transfers a single RecA–ATP stoichiometrically from its DNA 3′-end to free pol V (UmuD′2C) to form an active mutasome (pol V Mut) with the composition UmuD′2C–RecA–ATP. Pol V Mut catalyses TLS in the absence of RecA* and deactivates rapidly upon dissociation from DNA. Deactivation occurs more slowly in the absence of DNA synthesis, while retaining RecA–ATP in the complex. Reactivation of pol V Mut is triggered by replacement of RecA–ATP from RecA*. Thus, the principal role of RecA* in SOS mutagenesis is to transfer RecA–ATP to pol V, and thus generate active mutasomal complex for translesion synthesis.

YdiV: a dual function protein that targets FlhDC for ClpXP‐dependent degradation by promoting release of DNA‐bound FlhDC complex

YdiV is an EAL‐like protein that acts as a post‐transcriptional, negative regulator of the flagellar master transcriptional activator complex, FlhD4C2, in Salmonella enterica to couple flagellar gene expression to nutrient availability. Mutants defective in ClpXP protease no longer exhibit YdiV‐dependent inhibition of FlhD4C2‐dependent transcription under moderate YdiV expression conditions. ClpXP protease degrades FlhD4C2, and this degradation is accelerated in the presence of YdiV. YdiV complexed with both free and DNA‐bound FlhD4C2; and stripped FlhD4C2 from DNA. A L22H substitution in FlhD was isolated as insensitive to YdiV inhibition. The FlhD L22H substitution prevented the interaction of YdiV with free FlhD4C2 and the ability of YdiV to release FlhD4C2 bound to DNA. These results demonstrate that YdiV prevents FlhD4C2‐dependent flagellar gene transcription and acts as a putative adaptor to target FlhD4C2 for ClpXP‐dependent proteolysis. Our results suggest that YdiV is an EAL‐like protein that has evolved from a dicyclic‐GMP phosphodiesterase into a dual‐function regulatory protein that connects flagellar gene expression to nutrient starvation.

Probing the mechanism of ATP hydrolysis and substrate translocation in the AAA protease FtsH by modelling and mutagenesis

We have built a homology model of the AAA domain of the ATP‐dependent protease FtsH of Escherichia coli based on the crystal structure of the hexamerization domain of N‐ethylmaleimide‐sensitive fusion protein. The resulting model of the hexameric ring of the ATP‐bound form of the AAA ATPase suggests a plausible mechanism of ATP binding and hydrolysis, in which invariant residues of Walker motifs A and B and the second region of homology, characteristic of the AAA ATPases, play key roles. The importance of these invariant residues was confirmed by site‐directed mutagenesis. Further modelling suggested a mechanism by which ATP hydrolysis alters the conformation of the loop forming the central hole of the hexameric ring. It is proposed that unfolded polypeptides are translocated through the central hole into the protease chamber upon cycles of ATP hydrolysis. Degradation of polypeptides by FtsH is tightly coupled to ATP hydrolysis, whereas ATP binding alone is sufficient to support the degradation of short peptides. Furthermore, comparative structural analysis of FtsH and a related ATPase, HslU, reveals interesting similarities and differences in mechanism.

Critical amino acids in Escherichia coli UmuC responsible for sugar discrimination and base-substitution fidelity

The active form of Escherichia coli DNA polymerase V responsible for damage-induced mutagenesis is a multiprotein complex (UmuD′2C-RecA-ATP), called pol V Mut. Optimal activity of pol V Mut in vitro is observed on an SSB-coated single-stranded circular DNA template in the presence of the β/γ complex and a transactivated RecA nucleoprotein filament, RecA*. Remarkably, under these conditions, wild-type pol V Mut efficiently incorporates ribonucleotides into DNA. A Y11A substitution in the ‘steric gate’ of UmuC further reduces pol V sugar selectivity and converts pol V Mut into a primer-dependent RNA polymerase that is capable of synthesizing long RNAs with a processivity comparable to that of DNA synthesis. Despite such properties, Y11A only promotes low levels of spontaneous mutagenesis in vivo. While the Y11F substitution has a minimal effect on sugar selectivity, it results in an increase in spontaneous mutagenesis. In comparison, an F10L substitution increases sugar selectivity and the overall fidelity of pol V Mut. Molecular modeling analysis reveals that the branched side-chain of L10 impinges on the benzene ring of Y11 so as to constrict its movement and as a consequence, firmly closes the steric gate, which in wild-type enzyme fails to guard against ribonucleoside triphosphates incorporation with sufficient stringency.

A strategy for the expression of recombinant proteins traditionally hard to purify.

We have developed a series of plasmid vectors for the soluble expression and subsequent purification of recombinant proteins that have historically proven to be extremely difficult to purify from Escherichia coli. Instead of dramatically overproducing the target protein, it is expressed at a low basal level that facilitates the correct folding of the recombinant protein and increases its solubility. Highly active recombinant proteins that are traditionally difficult to purify are readily purified using standard affinity tags and conventional chromatography. To demonstrate the utility of these vectors, we have expressed and purified full-length human DNA polymerases η, ι, and ν from E. coli and show that the purified DNA polymerases are catalytically active in vitro.