Substrate recognition and binding by RseP, an Escherichia coli intramembrane protease

Escherichia coli RseP belongs to the S2P family of intramembrane cleaving proteases. RseP catalyzes proteolytic cleavage of the membrane-bound anti-sigma(E) protein RseA as an essential step in transmembrane signal transduction in the sigma(E) extracytoplasmic stress response pathway. RseP cleaves transmembrane segments of membrane proteins, but the molecular mechanisms of its substrate recognition and proteolytic action remain largely unknown. Here we analyzed interaction between RseP and substrate membrane proteins. Co-immunoprecipitation assays showed that helix-destabilizing residues in a substrate transmembrane segment, which were previously shown to be required for efficient proteolysis of the substrate by RseP, stabilize the substrate-RseP interaction. Substitutions of certain amino acid residues, including those evolutionarily conserved, in the third transmembrane region (TM3) of RseP weakened the RseP-substrate interaction. Specific combinations of Cys substitutions in RseP TM3 and in the RseA transmembrane segment led to the formation of disulfide bonds upon oxidation, suggesting that TM3 of RseP directly binds the substrate. These results provide insights into the mechanism of membrane protein proteolysis by RseP.     

A pair of circularly permutated PDZ domains control RseP, the S2P family intramembrane protease of Escherichia coli

The sigma(E) pathway of extracytoplasmic stress responses in Escherichia coli is activated through sequential cleavages of the anti-sigma(E) protein, RseA, by membrane proteases DegS and RseP. Without the first cleavage by DegS, RseP is unable to cleave full-length RseA. We previously showed that a PDZ-like domain in the RseP periplasmic region is essential for this negative regulation of RseP. We now isolated additional deregulated RseP mutants. Many of the mutations affected a periplasmic region that is N-terminal to the previously defined PDZ domain. We expressed these regions and determined their crystal structures. Consistent with a recent prediction, our results indicate that RseP has tandem, circularly permutated PDZ domains (PDZ-N and PDZ-C). Strikingly, almost all the strong mutations have been mapped around the ligand binding cleft region in PDZ-N. These results together with those of an in vitro reaction reproducing the two-step RseA cleavage suggest that the proteolytic function of RseP is controlled by ligand binding to PDZ-N.     

RseP (YaeL), an Escherichia coli RIP protease, cleaves transmembrane sequences

Escherichia coli RseP (formerly YaeL) is believed to function as a 'regulated intramembrane proteolysis' (RIP) protease that introduces the second cleavage into anti-sigma(E) protein RseA at a position within or close to the transmembrane segment. However, neither its enzymatic activity nor the substrate cleavage position has been established. Here, we show that RseP-dependent cleavage indeed occurs within predicted transmembrane sequences of membrane proteins in vivo. Moreover, RseP catalyzed the same specificity proteolysis in an in vitro reaction system using purified components. Our in vivo and in vitro results show that RseP can cleave transmembrane sequences of some model membrane proteins that are unrelated to RseA, provided that the transmembrane region contains residues of low helical propensity. These results show that RseP has potential ability to cut a broad range of membrane protein sequences. Intriguingly, it is nevertheless recruited to the sigma(E) stress-response cascade as a specific player of RIP.     

Environment of the active site region of RseP, an Escherichia coli regulated intramembrane proteolysis protease, assessed by site-directed cysteine alkylation

Regulated intramembrane proteolysis (RIP) plays crucial roles in both prokaryotic and eukaryotic organisms. Proteases for RIP cleave transmembrane regions of substrate membrane proteins. However, the molecular mechanisms for the proteolysis of membrane-embedded transmembrane sequences are largely unknown. Here we studied the environment surrounding the active site region of RseP, an Escherichia coli S2P ortholog involved in the sigma(E) pathway of extracytoplasmic stress responses. RseP has two presumed active site motifs, HEXXH and LDG, located in membrane-cytoplasm boundary regions. We examined the reactivity of cysteine residues introduced within or in the vicinity of these two active site motifs with membrane-impermeable thiol-alkylating reagents under various conditions. The active site positions were inaccessible to the reagents in the native state, but many of them became partially modifiable in the presence of a chaotrope, while requiring simultaneous addition of a chaotrope and a detergent for full modification. These results suggest that the active site of RseP is not totally embedded in the lipid phase but located within a proteinaceous structure that is partially exposed to the aqueous milieu.     

Tyr-426 of the Escherichia coli asparaginyl-tRNA synthetase, an amino acid in a C-terminal conserved motif, is involved in ATP binding

Sequence comparisons of the E. coli asparaginyl-tRNA synthetase (NRSEC) with aminocyl-tRNA synthetase sequences of class II enzymes show significant homologies with aspartyl- and lysyl-tRNA synthetases. Three conserved regions were found, one of which is located in the C-terminal part of the NRSEC sequence. Site-directed mutagenesis was performed in this conserved region. A single point mutation Tyr-426----Ser results in a 15-fold increase in the Km for ATP, while all the other kinetic parameters remain unchanged. The replacement of this Tyr-426 by a Phe does not affect the kinetic behaviour of the enzyme. These data indicate that Tyr-426 is part of the ATP binding site.     

A conserved domain in Escherichia coli Lon protease is involved in substrate discriminator activity

Lon protease of Escherichia coli regulates a diverse set of physiological responses including cell division, capsule production, plasmid stability, and phage replication. Little is known about the mechanism of substrate recognition by Lon. To examine the interaction of Lon with two of its substrates, RcsA and SulA, we generated point mutations in lon which affected its substrate specificity. The most informative lon mutant overproduced capsular polysaccharide (RcsA stabilized) yet was resistant to DNA-damaging agents (SulA degraded). Immunoblots revealed that RcsA protein persisted in this mutant whereas SulA protein was rapidly degraded. The mutant contains a single-base change within lon leading to a single amino acid change of glutamate 240 to lysine. E240 is conserved among all Lon isolates and resides in a charged domain that has a high probability of adopting a coiled-coil conformation. This conformation, implicated in mediating protein-protein interactions, appears to confer substrate discriminator activity on Lon. We propose a model suggesting that this coiled-coil domain represents the discriminator site of Lon.     

Down-regulation of porins by a small RNA bypasses the essentiality of the regulated intramembrane proteolysis protease RseP in Escherichia coli

Adaptation to extracytoplasmic stress in Escherichia coli depends on the activation of sigmaE, normally sequestered by the membrane protein RseA. SigmaE is released in response to stress through the successive RseA cleavage by DegS and the RIP protease RseP. SigmaE and proteases that free it from RseA are essential. We isolated a multicopy suppressor that alleviated RseP and DegS requirement. The suppressor encodes a novel small RNA, RseX. Its activity required the RNA-binding protein Hfq. We used the property that small RNAs are often involved in RNA-RNA interactions to capture RseX putative partners; ompA and ompC mRNA, which encode two major outer membrane proteins, were identified. RseX activity was shown to confer an Hfq-dependent coordinate OmpA and OmpC down-regulation. Because RseP is shown to be no longer essential in a strain lacking OmpA and OmpC, we conclude that RseP, which is required for normal sigmaE activation, prevents toxicity due to the presence of two specific outer membrane proteins that are down-regulated by RseX.     

Structure of Escherichia coli tetrahydrodipicolinate N-succinyltransferase reveals the role of a conserved C-terminal helix in cooperative substrate binding

Tetrahydrodipicolinate N-succinyltransferase is an enzyme present in many bacteria that catalyzes the first step of the succinylase pathway for the synthesis of meso-diaminopimelate and the amino acid L-lysine. Inhibition of the synthesis of meso-diaminopimelate, a component of peptidoglycan present in the cell wall of bacteria, is a potential route for the development of novel anti-bacterial agents. Here, we report the crystal structure of the DapD tetrahydrodipicolinate N-succinyltransferase from Escherichia coli at 2.0 A resolution. Comparison of the structure with the homologous enzyme from Mycobacterium bovis reveals the C-terminal helix undergoes a large rearrangement upon substrate binding, which contributes to cooperativity in substrate binding.     

Characterization of a conserved alpha-helical, coiled-coil motif at the C-terminal domain of the ATP-dependent FtsH (HflB) protease of Escherichia coli

FtsH (HflB) is an ATP-dependent protease found in prokaryotic cells, mitochondria and chloroplasts. Here, we have identified, in the carboxy-terminal region of FtsH (HfIB), a short alpha helix predicted of forming a coiled-coil, leucine zipper, structure. This region appears to be structurally conserved. The presence of the coiled-coil motif in the Escherichia coli FtsH (HflB) was demonstrated by circular dichroism and cross-linking experiments. Mutational analysis showed that three highly conserved leucine residues are essential for FtsH (HfIB) activity in vivo and in vitro. Purified proteins mutated in the conserved leucine residues, were found to be defective in the degradation of E. coli sigma(32) and the bacteriophage lambda CII proteins. In addition, the mutant proteins were defective in the binding of CII The mutations did not interfere with the ATPase activity of FtsH (HflB). Finally, the mutant proteins were found to be more sensitive to trypsin degradation than the wild-type enzyme suggesting that the alpha helical region is an important structural element of FtsH (HflB).     

Changes in conserved region 2 of Escherichia coli sigma 70 affecting promoter recognition

We describe a mutation in rpoD, the gene encoding the sigma 70 subunit of RNA polymerase, which alters the promoter specificity of the holoenzyme in vivo. The mutant sigma causes a substantial and specific increase in the activity of mutant ant and lac promoters with a T.A to C.G substitution at position -12, the first position of the -10 hexamer. The rpoD mutation is a single base-pair substitution causing a Gln----His change at position 437, which is in a domain of conserved region 2.4 that is predicted to form an alpha-helix. Gln437 would lie one turn of the alpha-helix away from Thr440, which was previously implicated in recognition of position -12. The rpoD-QH437 mutation described here lends further support to the model that region 2.4 of sigma is involved in recognition of the 5' end of the -10 hexamer. In addition, two rpoD mutations with non-specific effects on promoter recognition are described.     

A conserved glutamate residue, Glu-257, is important for substrate binding and transport by the Escherichia coli mannitol permease.

The mannitol permease, or D-mannitol-specific enzyme II of the phosphoenolpyruvate-dependent carbohydrate phosphotransferase system (PTS) of Escherichia coli, both transports and phosphorylates its substrate. Previous analyses of the amino acid sequences of PTS permeases specific for various carbohydrates in different species of bacteria revealed several regions of similarity. The most highly conserved region includes a GIXE motif, in which the glutamate residue is completely conserved among the permeases that contain this motif. The corresponding residue in the E. coli mannitol permease is Glu-257, which is located in a large putative cytoplasmic loop of the transmembrane domain of the protein. We used site-directed mutagenesis to investigate the role of Glu-257. The properties of proteins with mutations at position 257 suggest that a carboxylate side chain at this position is essential for mannitol binding. E257A and E257Q mutant proteins did not bind mannitol detectably, while the E257D mutant could still bind this substrate. Kinetic studies with the E257D mutant protein also showed that a glutamate residue at position 257 of this permease is specifically required for efficient mannitol transport. While the E257D permease phosphorylated mannitol with kinetic parameters similar to those of the wild-type protein, the Vmax for mannitol uptake by this mutant protein is less than 5% that of the wild type. These results suggest that Glu-257 of the mannitol permease and the corresponding glutamate residues of other PTS permeases play important roles both in binding the substrate and in transporting it through the membrane.     

An antibiotic-binding motif of an RNA fragment derived from the A-site-related region of Escherichia coli 16S rRNA.

A small RNA derived from the decoding region of Escherichia coli 16S rRNA can bind to antibiotics of aminoglycosides (neomycin and paromomycin) that act on the small ribosomal subunit [Purohit,P. and Stern,S. (1994) Nature, 370, 659-662]. In the present study, the P-site subdomain was removed from this decoding region RNA to construct a 27mer RNA (designated as ASR-27), which includes the A-site-related region (positions 1402-1412 and 1488-1497) of 16S rRNA. Footprint experiments with dimethyl sulfate as a chemical probe indicated that the ASR-27 RNA can interact with the neomycin family in the same manner as the decoding region RNA. A mutagenesis analysis of the ASR-27 RNA revealed that paromomycin binding of ASR-27 involves the C1407.G1494 and C1409-G1491 base pairs, and the internal loop comprising A1408 and the nucleotides in positions 1492-1493, located between the two C.G base pairs. In addition, a G or U in position 1495, and base pairing between positions 1405 and 1496 are also involved. These structural features were found in a viral RNA element, the Rev-binding site of human immunodeficiency virus type-1, which may explain why neomycin can bind to this viral RNA.     

Structure and substrate binding properties of cobB, a Sir2 homolog protein deacetylase from Escherichia coli

Sirtuins are NAD+-dependent protein deacetylase enzymes that are broadly conserved from bacteria to human, and have been implicated to play important roles in gene regulation, metabolism and longevity. cobB is a bacterial sirtuin that deacetylates acetyl-CoA synthetase (Acs) at an active site lysine to stimulate its enzymatic activity. Here, we report the structure of cobB bound to an acetyl-lysine containing non-cognate histone H4 substrate. A comparison with the previously reported archaeal and eukaryotic sirtuin structures reveals the greatest variability in a small zinc-binding domain implicated to play a particularly important role in substrate-specific binding by the sirtuin proteins. Comparison of the cobB/histone H4 complex with other sirtuin proteins in complex with acetyl-lysine containing substrates, further suggests that contacts to the acetyl-lysine side-chain and beta-sheet interactions with residues directly C-terminal to the acetyl-lysine represent conserved features of sirtuin-substrate recognition. Isothermal titration calorimetry studies were used to compare the affinity of cobB for a variety of cognate and non-cognate acetyl-lysine-bearing peptides revealing an exothermic reaction with relatively little discrimination between substrates. In contrast, similar studies employing intact acetylated Acs protein as a substrate reveal a binding reaction that is endothermic, suggesting that cobB recognition of substrate involves a burial of hydrophobic surface and/or structural rearrangement involving substrate regions distal to the acetyl-lysine-binding site. Together, these studies suggest that substrate-specific binding by sirtuin proteins involves contributions from the zinc-binding domain of the enzyme and substrate regions distal to the acetyl-lysine-binding site.     

Spectrometric analysis of degradation of a physiological substrate sigma32 by Escherichia coli AAA protease FtsH

We have established a fluorescence polarization assay system by which degradation of sigma32, a physiological substrate, by FtsH can be monitored spectrometrically. Using the system, it was found that an FtsH hexamer degrades approximately 0.5 molecules of Cy3-sigma32 per min at 42 degrees C and hydrolyzes approximately 140 ATP molecules during the degradation of a single molecule of Cy3-sigma32. Evidence also suggests that degradation of sigma32 proceeds from the N-terminus to the C-terminus. Although FtsH does not have a robust enough unfoldase activity to unfold a tightly folded proteins such as green fluorescent protein, it can unfold proteins with lower [Formula: see text] s such as glutathione S-transferase (Tm = 52 degrees C).     

Ethidium-dependent uncoupling of substrate binding and cleavage by Escherichia coli ribonuclease III

Ethidium bromide (EB) is known to inhibit cleavage of bacterial rRNA precursors by Escherichia coli ribonuclease III, a dsRNA-specific nuclease. The mechanism of EB inhibition of RNase III is not known nor is there information on EB-binding sites in RNase III substrates. We show here that EB is a reversible, apparently competitive inhibitor of RNase III cleavage of small model substrates in vitro. Inhibition is due to intercalation, since (i) the inhibitory concentrations of EB are similar to measured EB intercalation affinities; (ii) substrate cleavage is not affected by actinomycin D, an intercalating agent that does not bind dsRNA; (iii) the EB concentration dependence of inhibition is a function of substrate structure. In contrast, EB does not strongly inhibit the ability of RNase III to bind substrate. EB also does not block substrate binding by the C-terminal dsRNA-binding domain (dsRBD) of RNase III, indicating that EB perturbs substrate recognition by the N-terminal catalytic domain. Laser photocleavage experiments revealed two ethidium-binding sites in the substrate R1.1 RNA. One site is in the internal loop, adjacent to the scissile bond, while the second site is in the lower stem. Both sites consist of an A-A pair stacked on a CG pair, a motif which apparently provides a particularly favorable environment for intercalation. These results indicate an inhibitory mechanism in which EB site-specifically binds substrate, creating a cleavage-resistant complex that can compete with free substrate for RNase III. This study also shows that RNase III recognition and cleavage of substrate can be uncoupled and supports an enzymatic mechanism of dsRNA cleavage involving cooperative but not obligatorily linked actions of the dsRBD and the catalytic domain.     

Role of CH/pi interactions in substrate binding by Escherichia coli beta-galactosidase

Interactions between carbohydrates and aromatic amino-acid residues are often observed in structures of carbohydrate-protein complexes. They are characterized by an orientation of the pyranose or furanose ring parallel with the aromatic ring of amino-acid residues. An important role in the formation of these complexes is supposed to be played by CH/pi interactions. This paper presents an ab initio quantum chemistry study of CH/pi interactions between beta-galactosidase from E. coli and its substrates and products. The energy stabilizing the interaction between Trp999 residue and substrate bound in the shallow binding mode was calculated at the MP2/6-31+G(d) level as 5.2kcalmol(-1) for the glucose moiety of allolactose, 2.4kcalmol(-1) for the galactose moiety of allolactose and 5.0kcalmol(-1) for the glucose moiety of lactose. The energy stabilizing the interaction between Trp568 residue and galactose in the deep binding mode was calculated as 2.7kcalmol(-1). Interaction energies at the HF/6-31+G(d) and B3LYP/6-31+G(d) levels were small or repulsive; therefore, highly correlated ab initio methods were necessary to study these interactions. These unexpectedly strong interactions give a rationale for allolactose formation and illustrate the role of the Trp999 residue. In addition, this illustrates the importance of CH/pi interactions for the function of carbohydrate-binding proteins and carbohydrate-processing enzymes.     

Crystal structure of hemoglobin protease, a heme binding autotransporter protein from pathogenic Escherichia coli

The acquisition of iron is essential for the survival of pathogenic bacteria, which have consequently evolved a wide variety of uptake systems to extract iron and heme from host proteins such as hemoglobin. Hemoglobin protease (Hbp) was discovered as a factor involved in the symbiosis of pathogenic Escherichia coli and Bacteroides fragilis, which cause intra-abdominal abscesses. Released from E. coli, this serine protease autotransporter degrades hemoglobin and delivers heme to both bacterial species. The crystal structure of the complete passenger domain of Hbp (110 kDa) is presented, which is the first structure from this class of serine proteases and the largest parallel beta-helical structure yet solved.     

Escherichia coli initiation factor 3 protein binding to 30S ribosomal subunits alters the accessibility of nucleotides within the conserved central region of 16S rRNA

Translational initiation factor 3 (IF3) is an RNA helix destabilizing protein which interacts with strongly conserved sequences in 16S rRNA, one at the 3' terminus and one in the central domain. It was therefore of interest to identify particular residues whose exposure changes upon IF3 binding. Chemical and enzymatic probing of central domain nucleotides of 16S rRNA in 30S ribosomal subunits was carried out in the presence and absence of IF3. Bases were probed with dimethyl sulfate (DMS), at A(N-1), C(N-3), and G(N-7), and with N-cyclohexyl-N'-[2-(N-methyl-4-morpholinio)ethyl] carbodiimide p-toluenesulfonate (CMCT), at G(N-1) and U(N-3). RNase T1 and nuclease S1 were used to probe unpaired nucleotides, and RNase V1 was used to monitor base-paired or stacked nucleotides. 30S subunits in physiological buffers were probed in the presence and absence of IF3. The sites of cleavage and modification were detected by primer extension. IF3 binding to 30S subunits was found to reduce the chemical reactivity and enzymatic accessibility of some sites and to enhance attack at other sites in the conserved central domain of 16S rRNA, residues 690-850. IF3 decreased CMCT attack at U701 and U793 and V1 attack at G722, G737, and C764; IF3 enhanced DMS attack at A814 and V1 attack at U697, G833, G847, and G849. Many of these central domain sites are strongly conserved and with the conserved 3'-terminal site define a binding domain for IF3 which correlates with a predicted cleft in two independent models of the 30S ribosomal subunit.