Role of Calcium in Activity and Stability of the Lactococcus lactis Cell Envelope Proteinase

The mature lactococcal cell envelope proteinase (CEP) consists of an N-terminal subtilisin-like proteinase domain and a large C-terminal extension of unknown function whose far end anchors the molecule in the cell envelope. Different types of CEP can be distinguished on the basis of specificity and amino acid sequence. Removal of weakly bound Ca²⁺ from the native cell-bound CEP of Lactococcus lactis SK11 (type III specificity) is coupled with a significant reversible decrease in specific activity and a dramatic reversible reduction in thermal stability, as a result of which no activity at 25°C (pH 6.5) can be measured. The consequences of Ca²⁺ removal are less dramatic for the CEP of strain Wg2 (mixed type I-type III specificity). Autoproteolytic release of CEP from cells concerns this so-called “Ca-free” form only and occurs most efficiently in the case of the Wg2 CEP. The results of a study of the relationship between the Ca²⁺ concentration and the stability and activity of the cell-bound SK11 CEP at 25°C suggested that binding of at least two Ca²⁺ ions occurred. Similar studies performed with hybrid CEPs constructed from SK11 and Wg2 wild-type CEPs revealed that the C-terminal extension plays a determinative role with respect to the ultimate distinct Ca²⁺ dependence of the cell-bound CEP. The results are discussed in terms of predicted Ca²⁺ binding sites in the subtilisin-like proteinase domain and Ca-triggered structural rearrangements that influence both the conformational stability of the enzyme and the effectiveness of the catalytic site. We argue that distinctive primary folding of the proteinase domain is guided and maintained by the large C-terminal extension.     

Deletion of Various Carboxy-Terminal Domains of Lactococcus lactis SK11 Proteinase: Effects on Activity, Specificity, and Stability of the Truncated Enzyme

The Lactococcus lactis SK11 cell envelope proteinase is an extracellular, multidomain protein of nearly 2,000 residues consisting of an N-terminal serine protease domain, followed by various other domains of largely unknown function. Using a strategy of deletion mutagenesis, we have analyzed the function of several C-terminal domains of the SK11 proteinase which are absent in cell envelope proteinases of other lactic acid bacteria. The various deletion mutants were functionally expressed in L. lactis and analyzed for enzyme stability, activity, (auto)processing, and specificity toward several substrates. C-terminal deletions of first the cell envelope W (wall) and AN (anchor) domains and then the H (helix) domain leads to fully active, secreted proteinases of unaltered specificity. Gradually increasing the C-terminal deletion into the so-called B domain leads to increasing instability and autoproteolysis and progressively less proteolytic activity. However, the mutant with the largest deletion (838 residues) from the C terminus and lacking the entire B domain still retains proteolytic activity. All truncated enzymes show unaltered proteolytic specificity toward various substrates. This suggests that the main role played by these domains is providing stability or protection from autoproteolysis (B domain), spacing away from the cell (H domain), and anchoring to the cell envelope (W and AN domains). In addition, this study allowed us to more precisely map the main C-terminal autoprocessing site of the SK11 proteinase and the epitope for binding of group IV monoclonal antibodies.     

Deletion of various carboxy-terminal domains of Lactococcus lactis SK11 proteinase: effects on activity, specificity, and stability of the truncated enzyme

The Lactococcus lactis SK11 cell envelope proteinase is an extracellular, multidomain protein of nearly 2,000 residues consisting of an N-terminal serine protease domain, followed by various other domains of largely unknown function. Using a strategy of deletion mutagenesis, we have analyzed the function of several C-terminal domains of the SK11 proteinase which are absent in cell envelope proteinases of other lactic acid bacteria. The various deletion mutants were functionally expressed in L. lactis and analyzed for enzyme stability, activity, (auto)processing, and specificity toward several substrates. C-terminal deletions of first the cell envelope W (wall) and AN (anchor) domains and then the H (helix) domain leads to fully active, secreted proteinases of unaltered specificity. Gradually increasing the C-terminal deletion into the so-called B domain leads to increasing instability and autoproteolysis and progressively less proteolytic activity. However, the mutant with the largest deletion (838 residues) from the C terminus and lacking the entire B domain still retains proteolytic activity. All truncated enzymes show unaltered proteolytic specificity toward various substrates. This suggests that the main role played by these domains is providing stability or protection from autoproteolysis (B domain), spacing away from the cell (H domain), and anchoring to the cell envelope (W and AN domains). In addition, this study allowed us to more precisely map the main C-terminal autoprocessing site of the SK11 proteinase and the epitope for binding of group IV monoclonal antibodies.     

Engineering of the Lactococcus lactis serine proteinase by construction of hybrid enzymes

Plasmids containing wild-type and hybrid proteinase genes were constructed from DNA fragments of the prtP genes of Lactococcus lactis strains Wg2 and SK11. These plasmids were introduced into the plasmid-free strain L. lactis MG1363. The serine proteinases produced by these L. lactis strains were isolated, and their cleavage specificity and rate towards alpha s1- and beta-casein was investigated. The catalytic properties of both the SK11 and Wg2 proteinases, which differ in 44 out of 1902 amino acid residues, could be changed dramatically by the reciprocal exchange of specific fragments between the two enzymes. As a result, various L. lactis strains were constructed having new proteolytic properties that differ from those of the parental strains. Furthermore, two segments in the proteinase could be identified that contribute significantly to the cleavage specificity towards casein; within these two segments, several amino acid residues were identified that are important for substrate cleavage rate and specificity. The results also indicate that the lactococcal proteinase has an additional domain involved in substrate binding compared with the related subtilisins. This suggests that the 200 kd L. lactis proteinase may be the representative of a new subclass of subtilisin-like enzymes.     

Structural changes and interactions involved in the Ca(2+)-triggered stabilization of the cell-bound cell envelope proteinase in Lactococcus lactis subsp. cremoris SK11

The cell-bound cell envelope proteinase (CEP) of the mesophilic cheese-starter organism Lactococcus lactis subsp. cremoris SK11 is protected from rapid thermal inactivation at 25 degrees C by calcium bound to weak binding sites. The interactions with calcium are believed to trigger reversible structural rearrangements which are coupled with changes in specific activity (F. A. Exterkate and A. C. Alting, Appl. Env. Microbiol. 65:1390-1396, 1999). In order to determine the significance of the rearrangements for CEP stability and the nature of the interactions involved, the effects of the net charge present on the enzyme and of different neutral salts were studied with the stable Ca-loaded CEP, the unstable so-called "Ca-free" CEP and with the Ca-free CEP which was stabilized nonspecifically and essentially in its native conformation by the nonionic additive sucrose. The results suggest that strengthening of hydrophobic interactions is conducive to stabilization of the Ca-free CEP. On the other hand, a hydrophobic effect contributes significantly to the stability of the Ca-loaded CEP; a phased salting-in effect by a chaotropic salt suggests a complex inactivation process of this enzyme due to weakening of hydrophobic interactions and involving an intermediate enzyme species. Moreover, a Ca-triggered increase of a relatively significant hydrophobic effect in the sucrose-stabilized Ca-free CEP occurs. It is suggested that in the Ca-free CEP the absence of both local calcium-mediated backbone rigidification and neutralization of negative electrostatic potentials in the weak Ca-binding sites, and in addition the lack of significant hydrophobic stabilization, increase the relative effectiveness of electrostatic repulsive forces on the protein to an extent that causes the observed instability. The conditions in cheese seem to confer stability upon the cell-bound enzyme; its possible involvement in proteolysis throughout the ripening period is discussed.     

Structural Changes and Interactions Involved in the Ca2+-Triggered Stabilization of the Cell-Bound Cell Envelope Proteinase in Lactococcus lactis subsp. cremoris SK11

The cell-bound cell envelope proteinase (CEP) of the mesophilic cheese-starter organism Lactococcus lactis subsp. cremoris SK11 is protected from rapid thermal inactivation at 25°C by calcium bound to weak binding sites. The interactions with calcium are believed to trigger reversible structural rearrangements which are coupled with changes in specific activity (F. A. Exterkate and A. C. Alting, Appl. Env. Microbiol. 65:1390–1396, 1999). In order to determine the significance of the rearrangements for CEP stability and the nature of the interactions involved, the effects of the net charge present on the enzyme and of different neutral salts were studied with the stable Ca-loaded CEP, the unstable so-called “Ca-free” CEP and with the Ca-free CEP which was stabilized nonspecifically and essentially in its native conformation by the nonionic additive sucrose. The results suggest that strengthening of hydrophobic interactions is conducive to stabilization of the Ca-free CEP. On the other hand, a hydrophobic effect contributes significantly to the stability of the Ca-loaded CEP; a phased salting-in effect by a chaotropic salt suggests a complex inactivation process of this enzyme due to weakening of hydrophobic interactions and involving an intermediate enzyme species. Moreover, a Ca-triggered increase of a relatively significant hydrophobic effect in the sucrose-stabilized Ca-free CEP occurs. It is suggested that in the Ca-free CEP the absence of both local calcium-mediated backbone rigidification and neutralization of negative electrostatic potentials in the weak Ca-binding sites, and in addition the lack of significant hydrophobic stabilization, increase the relative effectiveness of electrostatic repulsive forces on the protein to an extent that causes the observed instability. The conditions in cheese seem to confer stability upon the cell-bound enzyme; its possible involvement in proteolysis throughout the ripening period is discussed.     

Variation in specificity of the PrtP extracellular proteinases in <Emphasis Type="Italic">Lactococcus lactis</Emphasis> and <Emphasis Type="Italic">Lactobacillus paracasei</Emphasis> subsp. <Emphasis Type="Italic">paracasei</Emphasis>

Comparison of cell-wall-bound extracellular proteinases (CEPs) from Lactobacillus paracasei (LBP) ssp. paracasei natural isolates BGHN14, BGAR75 and BGAR76 with Lactococcus lactis (LCL) ssp. cremoris Wg2, in their action on α_S1-, β- and κ-casein was done. The CEPs of LBP strains were able to degrade α_S1- and β-caseins and their caseinolytic specificity depended on the type of buffer used. These CEPs, compared with LCL Wg2, differ in four amino acid residues in small segments predicted to be involved in substrate binding. The most striking features of this comparison are the presence of Ala instead of Ser³²⁹ and the presence of Thr instead of Asn²⁵⁶ and Ala²⁹⁹, in the subtilisin-like region of the CEP in LBP natural isolates. Additional conservative amino acid substitution Leu to Ile³⁶⁴ was found.     

Cloning and partial sequencing of the proteinase gene complex from Lactococcus lactis subsp. lactis UC317.

The proteinase genes from Lactococcus lactis subsp. lactis UC317 were identified on a plasmid, pCI310, which is a deletion derivative of a cointegrate between pCI301, the 75 kb Lac Prt plasmid from UC317 and the 38.5 kb cryptic plasmid from that strain. The prt genes were cloned using a replacement cloning strategy whereby fragments from pCI310 were exchanged with the equivalent fragments in pNZ521, which contains the cloned proteinase genes from L. lactis subsp. lactis SK112. This generated two plasmids which encoded a cell-envelope-associated and a secreted proteinase, respectively. Specific regions of the UC317 structural prtP gene known to encode seven of the amino acids essential for substrate cleavage specificity were sequenced and compared with the known sequences of prt genes from L. lactis strains SK112, Wg2 and NCDO763. In spite of various differences that were detected in the nucleotide sequence of this region, it appears that these seven amino acids in strains UC317 and NCDO763 are identical, and represent a combination of three of the amino acids from SK112 and four from Wg2. These results indicate that the UC317 proteinase is a natural hybrid of the SK112 and Wg2 proteinases.     

The crystal structure of an oxidatively stable subtilisin-like alkaline serine protease, KP-43, with a C-terminal beta-barrel domain

The crystal structure of an oxidatively stable subtilisin-like alkaline serine protease, KP-43 from Bacillus sp. KSM-KP43, with a C-terminal extension domain, was determined by the multiple isomorphous replacements method with anomalous scattering. The native form was refined to a crystallographic R factor of 0.134 (Rfree of 0.169) at 1.30-A resolution. KP-43 consists of two domains, a subtilisin-like alpha/beta domain and a C-terminal jelly roll beta-barrel domain. The topological architecture of the molecule is similar to that of kexin and furin, which belong to the subtilisin-like proprotein convertases, whereas the amino acid sequence and the binding orientation of the C-terminal beta-barrel domain both differ in each case. Since the C-terminal domains of subtilisin-like proprotein convertases are essential for folding themselves, the domain of KP-43 is also thought to play such a role. KP-43 is known to be an oxidation-resistant protease among the general subtilisin-like proteases. To investigate how KP-43 resists oxidizing reagents, the structure of oxidized KP-43 was also determined and refined to a crystallographic R factor of 0.142 (Rfree of 0.212) at 1.73-A resolution. The structure analysis revealed that Met-256, adjacent to catalytic Ser-255, was oxidized similarly to an equivalent residue in subtilisin BPN'. Although KP-43, as well as proteinase K and subtilisin Carlsberg, lose their hydrolyzing activity against synthetic peptides after oxidation treatment, all of them retain 70-80% activity against proteinaceous substrates. These results, as well as the beta-casein digestion pattern analysis, have indicated that the oxidation of the methionine adjacent to the catalytic serine is not a dominant modification but might alter the substrate specificities.     

Primary structure and organization of the gene for a procaryotic, cell envelope-located serine proteinase

We have determined the complete nucleotide sequence of the gene for the cell envelope-located proteinase of Lactococcus lactis SK11. The gene contains a very AT-rich promoter region followed by the coding sequence of a protein of 1962 amino acids. Comparison of the NH2-terminal amino acid sequence of the mature proteinase and the expected primary translation product of the proteinase gene indicates that the enzyme is probably synthesized as a pre-pro-protein. This is confirmed by expression studies of the proteinase gene in Escherichia coli. The amino acid sequence of the proteinase shows significant homology to a number of serine proteinases of the subtilisin family. Compared with the related proteinase of L. lactis Wg2, the proteinase of L. lactis SK11 contains a 60-amino acids duplication and a total of 44-amino acid substitutions, some of which may account for the different cleavage specificity of both enzymes. Furthermore, a region was identified in the Lactococcus proteinase, which shows homology to the membrane-anchoring domains of a number of proteins from other Gram-positive bacteria.     

A new family of Cdc42 effector proteins, CEPs, function in fibroblast and epithelial cell shape changes

Cdc42, a Rho GTPase, regulates the organization of the actin cytoskeleton by its interaction with several distinct families of downstream effector proteins. Here, we report the identification of four new Cdc42-binding proteins that, along with MSE55, constitute a new family of effector proteins. These molecules, designated CEPs, contain three regions of homology, including a Cdc42 binding domain and two unique domains called CI and CII. Experimentally, we have verified that CEP2 and CEP5 bind Cdc42. Expression of CEP2, CEP3, CEP4, and CEP5 in NIH-3T3 fibroblasts induced pseudopodia formation. Fibroblasts coexpressing dominant negative Cdc42 with CEP2 or expressing a Cdc42/Rac interactive binding domain mutant of CEP2 did not induce pseudopodia formation. In primary keratinocytes, CEP2- and CEP5-expressing cells showed reduced F-actin localization at the adherens junctions with an increase in thin stress fibers that extended the length of the cell body. Keratinocytes expressing CEPs also showed an altered vinculin distribution and a loss of E-cadherin from adherens junctions. Similar effects were observed in keratinocytes expressing constitutively active Cdc42, but were not seen with a Cdc42/Rac interactive binding domain mutant of CEP2. These results suggest that CEPs act downstream of Cdc42 to induce actin filament assembly leading to cell shape changes.     

A novel isoform of SK2 assembles with other SK subunits in mouse brain

The SK2 subtype of small conductance Ca2+-activated K+ channels is widely distributed throughout the central nervous system and modulates neuronal excitability by contributing to the afterhyperpolarization that follows an action potential. Western blots of brain membrane proteins prepared from wild type and SK2-null mice reveal two isoforms of SK2, a 49-kDa band corresponding to the previously reported SK2 protein (SK2-S) and a novel 78-kDa form. Complementary DNA clones from brain and Western blots probed with an antibody specific for the longer form, SK2-L, identified the larger molecular weight isoform as an N-terminally extended SK2 protein. The N-terminal extension of SK2-L is cysteine-rich and mediates disulfide bond formation between SK2-L subunits or with heterologous proteins. Immunohistochemistry revealed that in brain SK2-L and SK2-S are expressed in similar but not identical patterns. Heterologous expression of SK2-L results in functional homomeric channels with Ca2+ sensitivity similar to that of SK2-S, consistent with their shared core and intracellular C-terminal domains. In contrast to the diffuse, uniform surface distribution of SK2-S, SK2-L channels cluster into sharply defined, distinct puncta suggesting that the extended cysteine-rich N-terminal domain mediates this process. Immunoprecipitations from transfected cells and mouse brain demonstrate that SK2-L co-assembles with the other SK subunits. Taken together, the results show that the SK2 gene encodes two subunit proteins and suggest that native SK2-L subunits may preferentially partition into heteromeric channel complexes with other SK subunits.     

Calcium- and cell cycle-dependent association of annexin 11 with the nuclear envelope

Annexin 11 is a widely expressed calcium- and phospholipid-binding protein that resides in the nucleoplasm in many cultured cell lines. This is in contrast to its most extensively characterized in vitro ligand, the small calcium-binding protein S100A6 (calcyclin), which is concentrated in the nuclear envelope. Here we have examined the significance of the association of annexin 11 and S100A6 by asking whether circumstances exist in which the two proteins occupy the same subcellular localization. First, we show that in both A431 and vascular smooth muscle cells, elevation of intracellular Ca2+ leads to translocation of annexin 11 from the nucleus to the nuclear envelope where it co-localizes with S100A6. We also demonstrate, using fusions of annexin 11 with green fluorescent protein, that whereas the C-terminal core domain of annexin 11 is essential for Ca2+ sensitivity, the N-terminal domain is required for targeting to the nuclear envelope. Second, we show that annexin 11 relocalizes to the nuclear envelope as A431 cells transit from early to mid-prophase. In late prophase, at the time of nuclear envelope breakdown, annexin 11 and S100A6 become intensely localized with lamina-associated polypeptide 2 to folds in the nuclear envelope. From metaphase to telophase S100A6 is degraded, but in late telophase annexin 11 associates with the reforming nuclear envelope before resuming a nucleoplasmic location in interphase. These results show that co-localization of annexin 11 and S100A6 at the nuclear envelope may be regulated either by elevation of intracellular Ca2+ or by cell cycle progression and provide the first evidence that these proteins may associate in vivo.     

The autoproteolysis of Lactococcus lactis lactocepin III affects its specificity towards beta-casein

The effect of autoproteolysis of Lactococcus lactis lactocepin III on its specificity towards beta-casein was investigated. beta-Casein degradation was performed by using either an autolysin-defective derivative of L. lactis MG1363 carrying the proteinase genes of L. lactis SK11, which was unable to transport oligopeptides, or autoproteolyzed enzyme purified from L. lactis SK11. Comparison of the peptide pools by high-performance liquid chromatography analysis revealed significant differences. To analyze these differences in more detail, the peptides released by the cell-anchored proteinase were identified by on-line coupling of liquid chromatography to mass spectrometry. More than 100 oligopeptides were released from beta-casein by the cell-anchored proteinase. Analysis of the cleavage sites indicated that the specificity of peptide bond cleavage by the cell-anchored proteinase differed significantly from that of the autoproteolyzed enzyme.     

Crystal structures of apocalmodulin and an apocalmodulin/SK potassium channel gating domain complex

Small conductance Ca2+-activated K+ channels (SK channels) are composed of the pore-forming alpha subunit and calmodulin (CaM). CaM binds to a region of the alpha subunit called the CaM binding domain (CaMBD), located intracellular and immediately C-terminal to the inner helix gate, in either the presence or absence of Ca2+. SK gating occurs when Ca2+ binds the N lobe of CaM thereby transmitting the signal to the attached inner helix gate to open. Here we present crystal structures of apoCaM and apoCaM/SK2 CaMBD complex. Several apoCaM crystal forms with multiple (12) packing environments reveal the same EF hand domain-swapped dimer providing potentially new insight into CaM regulation. The apoCaM/SK2 CaMBD structure, combined with our Ca2+/CaM/CaMBD structure suggests that Ca2+ binding induces folding and dimerization of the CaMBD, which causes large CaMBD-CaM C lobe conformational changes, including a >90 degrees rotation of the region of the CaMBD directly connected to the gate.     

Structure-function relationship of bifunctional scorpion toxin BmBKTx1

As the first identified scorpion toxin active on both big conductance Ca2+-activated K+ channels (BK) and small conductance Ca2+-activated K+ channels (SK), BmBKTx1 has been proposed to have two separate functional faces for two targets. To investigate this hypothesis, two double mutants, K21A-Y30A and R9A-K11A, together with wild-type toxin were expressed in Escherichia coli. The recombinant toxins were tested on cockroach BK and rat SK2 channel for functional assay. Mutant K21A-Y30A had a dramatic loss of function on BK but retained its function on SK. Mutant R9A-K11A did not lose function on BK or SK. These data support the two functional-face hypothesis and indicate that the BK face is on the C-terminal beta-sheet.     

The Autoproteolysis of Lactococcus lactis Lactocepin III Affects Its Specificity towards β-Casein

The effect of autoproteolysis of Lactococcus lactis lactocepin III on its specificity towards β-casein was investigated. β-Casein degradation was performed by using either an autolysin-defective derivative of L. lactis MG1363 carrying the proteinase genes of L. lactis SK11, which was unable to transport oligopeptides, or autoproteolyzed enzyme purified from L. lactis SK11. Comparison of the peptide pools by high-performance liquid chromatography analysis revealed significant differences. To analyze these differences in more detail, the peptides released by the cell-anchored proteinase were identified by on-line coupling of liquid chromatography to mass spectrometry. More than 100 oligopeptides were released from β-casein by the cell-anchored proteinase. Analysis of the cleavage sites indicated that the specificity of peptide bond cleavage by the cell-anchored proteinase differed significantly from that of the autoproteolyzed enzyme.