Most of the propeptide is dispensable for stability and autoprocessing of the zymogen of the germination protease of spores of Bacillus species

Structural insights into the psychrophilic germinal protease PaGPR and its autoinhibitory loop

In spore forming microbes, germination protease (GPR) plays a key role in the initiation of the germination process. A critical step during germination is the degradation of small acid-soluble proteins (SASPs), which protect spore DNA from external stresses (UV, heat, low temperature, etc.). Inactive zymogen GPR can be activated by autoprocessing of the N-terminal pro-sequence domain. Activated GPR initiates the degradation of SASPs; however, the detailed mechanisms underlying the activation, catalysis, regulation, and substrate recognition of GPR remain elusive. In this study, we determined the crystal structure of GPR from Paenisporosarcina sp. TG-20 (PaGPR) in its inactive form at a resolution of 2.5 A. Structural analysis showed that the active site of PaGPR is sterically occluded by an inhibitory loop region (residues 202-216). The N-terminal region interacts directly with the self-inhibitory loop region, suggesting that the removal of the N-terminal pro-sequence induces conformational changes, which lead to the release of the self-inhibitory loop region from the active site. In addition, comparative sequence and structural analyses revealed that PaGPR contains two highly conserved Asp residues (D123 and D182) in the active site, similar to the putative aspartic acid protease GPR from Bacillus megaterium. The catalytic domain structure of PaGPR also shares similarities with the sequentially non-homologous proteins HycI and HybD. HycI and HybD are metal-loproteases that also contain two Asp (or Glu) residues in their active site, playing a role in metal binding. In summary, our results provide useful insights into the activation process of PaGPR and its active conformation.

Small acid-soluble spore proteins of Clostridium acetobutylicum are able to protect DNA in vitro and are specifically cleaved by germination protease GPR and spore protease YyaC

Small acid-soluble proteins (SASPs) play an important role in protection of DNA in dormant bacterial endospores against damage by heat, UV radiation or enzymic degradation. In the genome of the strict anaerobe Clostridium acetobutylicum, five genes encoding SASPs have been annotated and here a further sixth candidate is suggested. The ssp genes are expressed in parallel dependent upon Spo0A, a master regulator of sporulation. Analysis of the transcription start points revealed a σG or a σF consensus promoter upstream of each ssp gene, confirming a forespore-specific gene expression. SASPs were termed SspA (Cac2365), SspB (Cac1522), SspD (Cac1620), SspF (Cac2372), SspH (Cac1663) and Tlp (Cac1487). Here it is shown that with the exception of Tlp, every purified recombinant SASP is able to bind DNA in vitro thereby protecting it against enzymic degradation by DNase I. Moreover, SspB and SspD were specifically cleaved by the two germination-specific proteases GPR (Cac1275) and YyaC (Cac2857), which were overexpressed in Escherichia coli and activated by an autocleavage reaction. Thus, for the first time to our knowledge, GPR-like activity and SASP specificity could be demonstrated for a YyaC-like protein. Collectively, the results assign SspA, SspB, SspD, SspF and SspH of C. acetobutylicum as members of α/β-type SASPs, whereas Tlp seems to be a non-DNA-binding spore protein of unknown function. In acetic acid-extracted proteins of dormant spores of C. acetobutylicum, SspA was identified almost exclusively, indicating its dominant biological role as a major α/β-type SASP in vivo.

Site-directed mutagenesis and structural studies suggest that the germination protease, GPR, in spores of Bacillus species is an atypical aspartic acid protease

Germination protease (GPR) initiates the degradation of small, acid-soluble spore proteins (SASP) during germination of spores of Bacillus and Clostridium species. The GPR amino acid sequence is not homologous to members of the major protease families, and previous work has not identified residues involved in GPR catalysis. The current work has focused on identifying catalytically essential amino acids by mutagenesis of Bacillus megaterium gpr. A residue was selected for alteration if it (i) was conserved among spore-forming bacteria, (ii) was a potential nucleophile, and (iii) had not been ruled out as inessential for catalysis. GPR variants were overexpressed in Escherichia coli, and the active form (P41) was assayed for activity against SASP and the zymogen form (P46) was assayed for the ability to autoprocess to P41. Variants inactive against SASP and unable to autoprocess were analyzed by circular dichroism spectroscopy and multi-angle laser light scattering to determine whether the variant's inactivity was due to loss of secondary or quaternary structure, respectively. Variation of D127 and D193, but no other residues, resulted in inactive P46 and P41, while variants of each form were well structured and tetrameric, suggesting that D127 and D193 are essential for activity and autoprocessing. Mapping these two aspartate residues and a highly conserved lysine onto the B. megaterium P46 crystal structure revealed a striking similarity to the catalytic residues and propeptide lysine of aspartic acid proteases. These data indicate that GPR is an atypical aspartic acid protease.

Analysis of the function of a putative 2,3-diphosphoglyceric acid-dependent phosphoglycerate mutase from Bacillus subtilis

A Bacillus subtilis gene termed yhfR encodes the only B. subtilis protein with significant sequence similarity to 2, 3-diphosphoglycerate-dependent phosphoglycerate mutases (dPGM). This gene is expressed at a low level during growth and sporulation, but deletion of yhfR had no effect on growth, sporulation, or spore germination and outgrowth. YhfR was expressed in and partially purified from Escherichia coli but had little if any PGM activity and gave no detectable PGM activity in B. subtilis. These data indicate that B. subtilis does not require YhfR and most likely does not require a dPGM.

Crystal structure of a novel germination protease from spores of Bacillus megaterium: structural arrangement and zymogen activation

The DNA in the core of spores of Bacillus species is saturated with a group of small, acid-soluble proteins (SASP) that protect DNA from a variety of harsh treatments and play a major role in spore resistance and long-term spore survival. During spore germination, SASPs are rapidly degraded to amino acids and this degradation is initiated by a sequence-specific protease called germination protease (GPR), which exhibits no obvious mechanistic or amino acid sequence similarity to any known class of proteases. GPR is synthesized during sporulation as an inactive tetrameric zymogen termed P(46), which later autoprocesses to a smaller form termed P(41), which is active only during spore germination. Here, we report the crystal structure of P(46) from Bacillus megaterium at 3.0 A resolution and the fact that P(46) monomer adopts a novel fold. The asymmetric unit contains two P(46) monomers and the functional tetramer is a dimer of dimers, with an approximately 9 A channel in the center of the tetramer. Analysis of the P(46) structure and site-directed mutagenesis studies have provided some insight into the mechanism of zymogen activation as well as the zymogen's lack of activity and the inactivity of P(41) in the mature spore.

Structural studies of a novel germination protease from spores of Bacillus megaterium

The amino acid sequence-specific protease (termed GPR) in the bacterium Bacillus megaterium initiates the rapid degradation of small, acid-soluble spore proteins during the germination of spores of this organism. GPR is synthesized during spore formation as an inactive zymogen termed P46, which later autoprocesses to a smaller active form termed P41, which acts during spore germination. However, GPR exhibits no obvious mechanistic or amino acid sequence similarity to any of the known classes of proteases. To initiate the determination of the mechanisms of P46 to P41 conversion, P46 inactivity, and P41 catalysis, B. megaterium GPR has been overexpressed in Escherichia coli and purified to homogeneity by anion-exchange and size exclusion chromatography, and crystals of both P46 and P41 have been obtained by the vapor diffusion method. P46 crystals diffracted x rays to 3.5 A but the crystals of P41 diffracted x rays to only 6.5 A. A native x-ray diffraction data set of P46 has been collected; the unit cell parameters are a = b = 76.8, c = 313.1 A, alpha = beta = gamma = 90 degrees; the space group is tetragonal P41212 or P43212. The asymmetric unit contains two monomeric molecules with a crystal volume per unit protein mass of 2. 85 A3/Da and a solvent content of about 57%. An isomorphous heavy atom derivative data set has also been obtained for P46 crystals with potassium dicyanoaurate (I).

Structure and mechanism of action of the protease that degrades small, acid-soluble spore proteins during germination of spores of Bacillus species

The germination protease (GPR) of Bacillus megaterium initiates the degradation of small, acid-soluble proteins during spore germination. Trypsin treatment of the 46-kDa GPR zymogen (termed P46) removes an approximately 15-kDa C-terminal domain generating a 30-kDa species (P30) which is stable against further digestion. While P30 is not active, it does autoprocess to a smaller form by cleavage of the same bond cleaved in conversion of P46 to the active 41-kDa form of GPR (P41). Trypsin treatment of P41 cleaves the same bond in the C-terminal part of the protein as is cleaved in the P46-->P30 conversion. While the approximately 29-kDa species generated by trypsin treatment of P41 is active, it is rapidly degraded further by trypsin to small inactive fragments. These results, as well as a thermal melting temperature for P41 which is 13 degreesC lower than that for P46 and the unfolding of P41 at significantly lower concentrations of guanidine hydrochloride than for P46, are further evidence for a difference in tertiary structure between P46 and P41, with P46 presumably having a more compact stable structure. However, circular dichroism spectroscopy revealed no significant difference in the secondary structure content of P46 and P41. The removal of approximately 30% of P46 or P41 without significant loss in enzyme activity localized GPR's catalytic residues to the N-terminal two-thirds of the molecule. This finding, as well as comparison of the amino acid sequences of GPR from three different species, analysis of several site-directed GPR mutants, determination of the metal ion content of purified GPR, and lack of inhibition of P41 by a number of protease inhibitors, suggests that GPR is not a member of a previously described class of protease.