Joseph L. Carlos scite author profile

Type I signal peptidase (SPase I) catalyzes the cleavage of the amino-terminal signal sequences from preproteins destined for cell export. Preproteins contain a signal sequence with a positively charged n-region, a hydrophobic h-region, and a neutral but polar c-region. Despite having no distinct consensus sequence other than a commonly found c-region "Ala-X-Ala" motif preceding the cleavage site, signal sequences are recognized by SPase I with high fidelity. Remarkably, other potential Ala-X-Ala sites are not cleaved within the preprotein. One hypothesis is that the source of this fidelity is due to the anchoring of both the SPase I enzyme (by way of its transmembrane segment) and the preprotein substrate (by the h-region in the signal sequence) in the membrane. This limits the enzyme-substrate interactions such that cleavage occurs at only one site. In this work we have, for the first time, successfully isolated Bacillus subtilis type I signal peptidase (SipS) and a truncated version lacking the transmembrane domain (SipS-P2). With purified full-length as well as truncated constructs of both B. subtilis and Escherichia coli (Lep) SPase I, in vitro specificity studies indicate that the transmembrane domains of either enzyme are not important determinants of in vitro cleavage fidelity, since enzyme constructs lacking them reveal no alternate site processing of pro-OmpA nuclease A substrate. In addition, experiments with mutant pro-OmpA nuclease A substrate constructs indicate that the h-region of the signal peptide is also not critical for substrate specificity. In contrast, certain mutants in the c-region of the signal peptide result in alternate site cleavage by both Lep and SipS enzymes.

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The Role of the Conserved Box E Residues in the Active Site of the Escherichia coli Type I Signal Peptidase

Klenotic¹,

Carlos²,

Schuenemann³

et al. 2000

Journal of Biological Chemistry

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Type I signal peptidases are integral membrane proteins that function to remove signal peptides from secreted and membrane proteins. These enzymes carry out catalysis using a serine/lysine dyad instead of the prototypical serine/histidine/aspartic acid triad found in most serine proteases. Site-directed scanning mutagenesis was used to obtain a qualitative assessment of which residues in the fifth conserved region, Box E, of the Escherichia coli signal peptidase I are critical for maintaining a functional enzyme. First, we find that there is no requirement for activity for a salt bridge between the invariant Asp-273 and the Arg-146 residues. In addition, we show that the conserved Ser-278 is required for optimal activity as well as conserved salt bridge partners Asp-280 and Arg-282. Finally, Gly-272 is essential for signal peptidase I activity, consistent with it being located within van der Waals proximity to Ser-278 and general base Lys-145 side-chain atoms. We propose that replacement of the hydrogen side chain of Gly-272 with a methyl group results in steric crowding, perturbation of the active site conformation, and specifically, disruption of the Ser-90/Lys-145 hydrogen bond. A refined model is proposed for the catalytic dyad mechanism of signal peptidase I in which the general base Lys-145 is positioned by Ser-278, which in turn is held in place by Asp-280.The majority of proteins exported from a cell are made with a signal or leader peptide. These peptides are responsible for targeting proteins to the cytoplasmic membrane in prokaryotes and the endoplasmic reticulum membrane in eukaryotes (1-3). The protein is then translocated across the membrane, and the N-terminal peptide is removed from the pre-protein by a type I signal peptidase.SPase I 1 has been isolated from Gram-negative (4 -6) and Gram-positive (7, 8) bacteria as well as from several eukaryotic organisms (9 -12). These endopeptidases are membrane-bound and specific for the region within the signal peptide immediately preceding the cleavage site. The substrate protein is cleaved during or after the protein is transported across the membrane bilayer. Cleavage occurs by way of nucleophilic attack by a catalytic serine O␥ on the peptide bond between the presequence and the mature region of the pre-protein.The best-studied enzyme of this family is SPase I, or leader peptidase, of Escherichia coli. It has been cloned (13), sequenced (14), and purified (15, 16). Its substrate specificity has been characterized; small-uncharged residues at the P1 (Ϫ1) and P3 (Ϫ3) positions of the substrate are required for cleavage (17)(18)(19). SPase I utilizes a serine/lysine dyad mechanism to perform its enzymatic function rather than the canonical catalytic triad found in most serine proteases (20 -23). To date, only a few other enzymes, such as LexA (24), UmuD (25), and the Tsp protease (26) have been identified with this unusual active site mechanism. Additional analysis is required to provide insight into other residues near this dyad in the SPase family and th...

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Mutational Evidence of Transition State Stabilization by Serine 88 in Escherichia coli Type I Signal Peptidase^,

et al. 2000

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Type I signal peptidase (SPase I) catalyzes the hydrolytic cleavage of the N-terminal signal peptide from translocated preproteins. SPase I belongs to a novel class of Ser proteases that utilize a Ser/Lys dyad catalytic mechanism instead of the classical Ser/His/Asp triad found in most Ser proteases. Recent X-ray crystallographic studies indicate that the backbone amide nitrogen of the catalytic Ser 90 and the hydroxyl side chain of Ser 88 might participate as H-bond donors in the transition-state oxyanion hole. In this work, contribution of the side-chain Ser 88 in Escherichia coli SPase I to the stabilization of the transition state was investigated through in vivo and in vitro characterizations of Ala-, Cys-, and Thr-substituted mutants. The S88T mutant maintains near-wild-type activity with the substrate pro-OmpA nuclease A. In contrast, substitution with Cys at position 88 results in more than a 740-fold reduction in activity (k(cat)) whereas S88A retains much less activity (>2440-fold decrease). Measurements of the kinetic constants of the individual mutant enzymes indicate that these decreases in activity are attributed mainly to decreases in k(cat) while effects on K(m) are minimal. Thermal inactivation and CD spectroscopic analyses indicate no global conformational perturbations of the Ser 88 mutants relative to the wild-type E. coli SPase I enzyme. These results provide strong evidence for the stabilization by Ser 88 of the oxyanion intermediate during catalysis by E. coli SPase I.

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Bacterial Type I Signal Peptidases

Carlos

Paetzel

Klenotic

et al. 2002

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Joseph L. Carlos

The Role of the Membrane-spanning Domain of Type I Signal Peptidases in Substrate Cleavage Site Selection

The Role of the Conserved Box E Residues in the Active Site of the Escherichia coli Type I Signal Peptidase

Mutational Evidence of Transition State Stabilization by Serine 88 in Escherichia coli Type I Signal Peptidase^,

Bacterial Type I Signal Peptidases

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Joseph L. Carlos

The Role of the Membrane-spanning Domain of Type I Signal Peptidases in Substrate Cleavage Site Selection

The Role of the Conserved Box E Residues in the Active Site of the Escherichia coli Type I Signal Peptidase

Mutational Evidence of Transition State Stabilization by Serine 88 in Escherichia coli Type I Signal Peptidase,

Bacterial Type I Signal Peptidases

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Product

Resources

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Mutational Evidence of Transition State Stabilization by Serine 88 in Escherichia coli Type I Signal Peptidase^,