Processing of predicted substrates of fungal Kex2 proteinases from Candida albicans, C. glabrata, Saccharomyces cerevisiae and Pichia pastoris
© Bader et al; licensee BioMed Central Ltd. 2008
Received: 13 March 2008
Accepted: 14 July 2008
Published: 14 July 2008
Kexin-like proteinases are a subfamily of the subtilisin-like serine proteinases with multiple regulatory functions in eukaryotes. In the yeast Saccharomyces cerevisiae the Kex2 protein is biochemically well investigated, however, with the exception of a few well known proteins such as the α-pheromone precursors, killer toxin precursors and aspartic proteinase propeptides, very few substrates are known. Fungal kex2 deletion mutants display pleiotropic phenotypes that are thought to result from the failure to proteolytically activate such substrates.
In this study we have aimed at providing an improved assembly of Kex2 target proteins to explain the phenotypes observed in fungal kex2 deletion mutants by in vitro digestion of recombinant substrates from Candida albicans and C. glabrata. We identified CaEce1, CA0365, one member of the Pry protein family and CaOps4-homolog proteins as novel Kex2 substrates.
Statistical analysis of the cleavage sites revealed extended subsite recognition of negatively charged residues in the P1', P2' and P4' positions, which is also reflected in construction of the respective binding pockets in the ScKex2 enzyme. Additionally, we provide evidence for the existence of structural constrains in potential substrates prohibiting proteolysis. Furthermore, by using purified Kex2 proteinases from S. cerevisiae, P. pastoris, C. albicans and C. glabrata, we show that while the substrate specificity is generally conserved between organisms, the proteinases are still distinct from each other and are likely to have additional unique substrate recognition.
Site specific proteolysis is a common feature in protein maturation and plays a crucial role in activation of many enzymes and in the generation of peptide hormones. In the late secretory pathway of eukaryotic cells this mechanism is mainly mediated by kexin-like proteinases, a subfamily of the subtilisin-like serine proteinases. Multicellular eukaryotes possess a large family of these regulatory proteinases, termed prohormone or proprotein convertases. While in mammals this family consists of at least seven members with tissue-specific expression patterns (most recently reviewed in ), fungi harbour only a single gene coding for a subtilisin-like serine proteinase with this activity. Originally identified in kex2 mutants of Saccharomyces cerevisiae lacking the ability to process the virally encoded killer toxin (killer expression)  the fungal Kex2 protein has since been implicated in several other proteolytic activation events, e.g. pheromone maturation at lysine-arginine motifs . The S. cerevisiae Kex2 protein has been the target of substantial biochemical [4–6] and crystallographic (reviewed in ) research. Apart from S. cerevisiae, a diverse spectrum of phenotypic descriptions has been published for a range of kex2 deletion mutants from other yeasts, such as Candida albicans [8, 9], C. glabrata , Pichia pastoris , Schizosaccharomyces pombe , or Yarrowia lipolytica  and moulds such as Aspergillus niger , A. oryzae  or Trichoderma reesei . The phenotypes of these deletion mutants include morphological changes that are thought to result from the lack of activity from cell-wall modifying enzymes, reduced virulence in the case of C. albicans , hypersensitivity to antimycotic drugs that target cell wall or plasma membrane integrity in C. glabrata  and inviability in S. pombe . In theory, the phenotypes of kex2 deletion mutants can be explained by the lack of processing events in substrate proteins rendering these dysfunctional, as in the case of the α-pheromone, where the lack of processing renders the kex2 mutant of S. cerevisiae mating deficient . Because of the localization of the Kex2 protein in the late trans Golgi network  and an endocytic, prevacuolar compartment , it can be concluded that the target spectrum is limited to proteins attached to the cell surface, those proteins which are secreted into the environment or to the luminal domains of integral membrane proteins passing through these compartments. Accordingly, the phenotypes of kex2 mutants include the secretion of unprocessed protein precursors into the environment, e.g. the secretory xylanase of T. reesei . However, these effects are blurred as the phenotypes observed from kex2 mutants may only be secondary effects themselves. Furthermore, missing Kex2-processing events may well be covered up by processing through other proteinases, such as the yapsins, a family of glycosylphosphatidylinositol (GPI) anchored aspartic proteinases [19, 20]. In the case of proteinase pro-peptides these events may also occur autocatalytically, as proposed for CaSap2 . While there is a fair number of proteins that have been annotated as potential Kex2 targets and two earlier studies have predicted Kex2 targets [9, 10], the number of proteins for which experimental proof of cleavage by Kex2 exists, remains low.
Knowing the substrates of this proteinase would not only help to explain the phenotypes observed in fungal kex2 deletion mutants, but also provide insights into essential cellular regulatory mechanisms. We have aimed at providing an improved assembly of Kex2 target proteins and present first biochemical evidence for the processing of selected substrates, in particular from the human pathogenic yeasts C. albicans and C. glabrata. Furthermore, we provide evidence for extended subsite recognition in the P1'–P4' region. By using recombinant Kex2 proteinases and potential substrate proteins from pathogenic and non-pathogenic yeasts, we show that the substrate specificity is generally conserved between organisms. However, our data also suggest that some Kex2 proteinases have additional unique substrates.
Heterologous expression and purification of Kex2 proteinases
For the expression of the soluble forms of S. cerevisiae, C. glabrata and P. pastoris Kex2 enzymes the P. pastoris expression system (Invitrogen) was used. The strain expressing S. cerevisiae Kex2 was a kind gift of Guy Boileau . For the expression of C. glabrata and P. pastoris Kex2 enzymes the 5' part of the gene coding for the luminal domain of the enzyme, including the native signal- and pro-peptide, plus a C-terminal 6 × His-tag were cloned into the pic3.5 vector (Figure 1B and 1C) and transformed into P. pastoris strain GS115. The transformants displaying the strongest extracellular proteolytic activity (ppCgKex2#12 and ppPpKex2#5) in test expressions were used for large-scale production of the enzymes.
Attempts to purify the C. glabrata and P. pastoris Kex2 enzymes via 6 × His-affinity chromatography were not successful, possibly due to burial of the epitope inside the protein. Thus, all three enzymes, including the one from S. cerevisiae, were purified to near homogeneity by a combination of anion exchange and size exclusion chromatography (Additional file 1).
Because several attempts to produce the intact, soluble form of Kex2 of C. albicans in the Pichia system failed, ultimately the native host C. albicans was used for production of this enzyme: the 5' part of the C. albicans KEX2 gene coding for the luminal domain of the enzyme, again including the native signal- and pro-peptide as well as a C-terminal 6 × His tag was put under the control of the constitutive and strong promoter of the ACT1 gene, as described under Methods (Figure 1D). The linearized plasmid was transformed into C. albicans strain CAI4 and the transformant giving the strongest Kex2-like activity in the supernatant (CaAct1-Kex2#7) was used for further large scale production of the enzyme, as above.
While we were able to produce the high Kex2 activity in supernatants, the efficiency of its purification remained low. Highest yields of enzyme were achieved using complex media including yeast extract and peptone, but this resulted in only impure enzyme preparations. However, the parental strain did not produce this activity (Additional file 1, Figure 1B). To avoid low-weight impurities in the enzyme preparations, which would have disguised product bands in further analytical experiments, the medium was passed over a 10 kDa size-exclusion column prior to the expression. In combination with the purification methods as outlined above this resulted in an enzyme preparation that contained only few other proteins and was devoid of low molecular weight contaminants.
Activity testing of the enzyme preparations
Prior to use, enzyme preparations were adjusted to a common activity of one nmol/min per μl proteinase added in a standard reaction setup with the chromogenic substrate Z-Tyr-Lys-Arg-pNA. Neither preparations from a P. pastoris negative control strain nor from the C. albicans parental CAI4 strain displayed this activity (data not shown). In addition we performed controls with the C. albicans enzyme preparation to ascertain that the proteolytic activity was Kex2-dependent: The activity was indeed inhibited by PMSF, EDTA and ZnCl2, but not by pepstatin A (Additional file 1, Figure 1C).
To test whether the enzymes had similar properties we first tested the enzymes for optimal pH and temperature with the chromogenic substrate Z-Tyr-Lys-Arg-pNA. The optimal pH for all enzymes was between 7.2 and 7.4 (data not shown), as described earlier for the S. cerevisiae enzyme  and this pH was therefore used throughout all further experiments. In contrast, the result for the optimal temperature was surprising: all enzymes showed an elevated activity at unphysiological temperatures from 40°C to 50°C (data not shown), at which none of the source organisms display optimal growth, if any. Nevertheless, all following experiments were carried out at 37°C, reflecting human body temperature, as our main focus lay on the enzymes of the human pathogenic fungi C. albicans and C. glabrata.
Prediction of potential Kex2 substrates
Next, we developed a prediction method for potential Kex2 cleavage sites in substrate proteins to identify proteins from C. albicans, C. glabrata or S. cerevisiae for testing with the proteinases. Earlier studies [9, 10] used very stringent search parameters and only looked in the N-terminal region of protein sequences. However, there is biochemical and biological evidence for processing of sites containing other amino acids in the P2 position [4, 24] as well as activity on C-terminal motifs in other organisms such as the chloroperoxidase CPO of A. niger  and on membrane proteins such as Kex2 itself. Therefore we included Golgi-luminal portions of transmembrane proteins as well as full-length sequences of soluble proteins into our search. ER-retained proteins were excluded, as they should not come into contact with Kex2.
A position specific scoring matrix for identification of potential Kex2 substrate proteins.
Expression of substrate proteins
In vitro proteolytic processing of substrate proteins by Kex2 from C. albicans, C. glabrata, S. cerevisiae and P. pastoris
Proteins that were cleaved into fragments of the expected sizes were CA0365, CaEce1 (CA1402), CA1873, CA2974, CaPga17(CA4679), CaTos1 (CA2303), CaSun41 (CA0883), CgScw4 (CAGL0M13805g), CgSUN4 (CAGL0L05434g), CgPir1 (CAGL0M08492g), CgPry1 (CAGL0F05137g) and CgPry2 (CAGL0G07667g). Proteins that remained fully uncleaved were CaCcw14 (CA2942), CaPho11 (CA5147), CaRbt4 (CA0104), CaCrh1 (CA0375), the Plb-homolog CAGL0J11770g and the three proteins of unknown function CA1394, CAGL0H08910g and CAGL0A02277g.
Reflection of substrate recognition in proteinase structure
Next, we asked whether the apparent preference for negatively charged residues in the P1'–P4' region of substrates digested by Kex2 proteins is reflected by the structure of the proteinases in the substrate binding cleft.
The neighbouring S1' and S3' pockets are characterized by positive charges in ScKex2 (H213, H381) as well as in furin (R193, H194, H364), and both pockets may well accommodate aspartate or glutamate residues in the substrate. In furin, the excess charge possibly results in a stronger selection for negatively charged residues in the P1' position, but as the S2 pocket is directly adjacent to the S1' pocket, the lack of a positively charged P2 residue in furin substrates may compensate this effect. The S2' pocket, located on the opposite side of the cleft, as well contains a terminal positive charge (R318 in ScKex2, R298 in furin) which would favour negatively charged residues in the P2' position.
A potential P4' pocket was also identified (Figure 6B and 6C). The P4' residue aligns between S363 and Q350 and extends towards E362 in the furin model (Figure 6C). The alignment with ScKex2 is of lesser quality in this region, but nevertheless a similarly built potential binding pocket is seen in the ScKex2 enzyme bordered by S380 and Y367 (Figure 6B). However, the equivalent to the negative terminal charge of E362 in furin would be the positive charge of H369 in ScKex2.
In summary, the structure of the enzymes explains the increased preference for negatively charged P1'–P4' residues in the substrates.
Conservation of residues involved in substrate recognition
Compilation of residues relevant for substrate recognition in S. cerevisiae and M. musculus furin.
 This work
The S1 pocket (composed of positions p, t, u, x, y and C) is fully conserved and among fungi this is also true for the four negative charges of the S2 pocket (positions a, b, c and d). Interestingly, we observed for the S4 and the S1' position that the enzymes from Ascomycetales combine the charge-selective properties of the S. cerevisiae Kex2 enzyme with those from the furin enzymes, and thus probably display the most discrete substrate recognition. Among the Saccharomycetales the residues are conserved for the major subsites S4, S2, S1 and S1' with minor exceptions only. Differences are visible in subsites where there is no strong selection to or discrimination against substrate residues, such as the S5 pocket (positions q and r). The S2' pocket is generally positively charged, however, this charge is mediated by one histidine in either the v or the w position.
In summary, it is seen, that the substrate selectivity among Saccharomycetales Kex2 enzymes is very conserved, and that there are no substitutions that would explain the differential processing of substrate CA0365 between the four proteinases. Therefore, the enzymes must discriminate their substrates either through further subsites or through processes independent of the primary sequence surrounding the cleavage site.
Relevance of substrate structural features for cleavage
Also, we did not observe cleavage for all proteins with potentially good sites. Therefore, we tested if this was due to an uncleavable primary sequence or if there were structural constraints preventing cleavage: site 3 of CaCcw14 and site 1 of CA0365, were each fused between a GST and a GFP domain and so exposed to the solvent. The GST-CA0365 -GFP fusion protein was not cleaved (Figure 8B, lane 2), indicating that this sequence is not a substrate of ScKex2 and the non-cleavage of the full length protein is not due to structural constraints, as was expected due to the cleavage by the other three Kex2 enzymes. In contrast, the GST-CaCcw14 -GFP fusion protein was readily cleaved by ScKex2 (Figure 8B, lane 5), demonstrating that this primary sequence reflects a good substrate and the non-cleavage in the full length protein must be due to structural constraints. This gives further evidence that accessibility and/or secondary structure of the cleavage site are essential for processing.
The pleiotropic phenotype of fungal Kex2 deletion mutants is attributed to the lack of posttranslational, proteolytic activation of substrate proteins. Besides biochemical data describing the P4-P1 substrate recognition towards short peptides of the Saccharomyces cerevisiae enzyme, only very few data exist of substrate preferences of fungal Kex2 proteins. Several proteins have been discussed as "potential Kex2 substrates", however there is no experimental data confirming actual cleavage by Kex2, except for a few cases, e.g. killer toxin, α-mating pheromones and proteinase propeptides. In the present study, we have investigated cleavage of recombinant Kex2 proteinases on recombinant, potential Kex2 substrates in order to get a first insight into the possible substrate repertoire of these regulatory proteases.
For heterologous production of soluble Kex2 enzymes, we selected the proteins from the two pathogenic fungi C. albicans and C. glabrata, as the phenotypes of the respective deletion mutants include avirulence  and increased susceptibility to antifungal compounds . In addition, we selected the well characterized S. cerevisiae enzyme and the ortholog from Pichia pastoris, as this enzyme is often involved in the heterologous production of secretory proteins. The Golgi-luminal domains of these four enzymes were expressed in the host P. pastoris and purified from culture supernatant, except for Kex2 from C. albicans, which was produced in C. albicans itself, as it was not expressible in Pichia. The purified enzymes showed similar pH- and temperature dependencies: the optimal pH was found at pH 7.2, as reported for S. cerevisiae Kex2 , but surprisingly maximum cleavage of the artificial substrate Z-TKR-pNA was observed at unphysiological temperatures ranging from 40°C to 55°C. The fact that the enzymes retain their catalytic activities at theses temperatures could reflect a stabilizing effect on the protein structure proposed for the P-domain of Kex2 .
To identify new substrates of Kex2, we have searched the genomes of C. albicans, C. glabrata and S. cerevisiae, for secretory proteins containing potential cleavage sites. These were grouped into clusters by sequence similarity and based on the conservation of such sites selected for heterologous expression and in vitro cleavage testing by Kex2 enzymes (Additional file 2).
All four proteinases cleaved the S. cerevisiae α-mating pheromone precursor in the same expected pattern, confirming the orthologous enzymatic activities of the proteins. As it is known, that the C. albicans and S. pombe Kex2 proteins can complement the S. cerevisiae Kex2 protein in vivo (30, 38), it was not surprising that almost all substrates were cleaved (or not cleaved) in an identical manner. However, one substrate (CA0365, Figure 4) was differentially processed. This demonstrates that even though the proteins have very high sequence similarity they still have partially different substrate preferences.
Statistical sequence analysis of processed vs. non-processed sites reveals an overrepresentation of negatively charged (aspartic/glutamic acid) or small residues in the P1', P2' and P4' positions, which has also been reported for substrates of the mammalian furin/PC proteinase family  (Figure 5). This finding is strengthened by the fact that a mutant of ScPir4, where the Kex2 cleavage site was changed from KR/D to KR/A failed to undergo processing . Previous biochemical analyses of substrate preference have focussed on the S1–S4 regions of the enzymes [4–6], due to the nature of the substrates used in those studies. However, the solved three dimensional structures of S. cerevisiae and Mus musculus furin in complex with proteinaceous inhibitors such as Eglin-c have lead to the postulation of binding pockets also in the S1' and S2' regions . In order to identify further residues involved in substrate recognition in the S1'–S4' region, we have produced a structural alignment of S. cerevisiae Kex2, M. musculus furin and the bacterial Subtilisin-like proteinase kumamolisin of Bacillus novospec MN-32 . The latter structure was solved for an active-site mutated form of the protein, which still retained its propeptide. Due to the autocatalytic nature of the maturation process of subtilisin-like proteinases , the propeptide is the first substrate cleaved by the enzyme and should reflect an optimal substrate. Indeed, the P1' residue of the Kumamolisin propeptide aligned with the predicted S1' binding pocket of the kexins (Figure 6). In addition, we identified a potential S4 binding pocket, which in Kex2 terminates with the positively charged H369 (Figure 6B).
A sequence alignment of residues involved in substrate recognition shows that these residues are generally very highly conserved among the enzymes investigated here (Figure 7). Accordingly, there is no single residue that could explain the strong difference between ScKex2 and CaKex2 in cleavage of substrate CA0365. However, it is possible that a combination of such amino acid exchanges could generate such an effect. In accordance with the experimental data, it is likely that the Kex2-ortholog enzymes of the Saccharomycetales exhibit a similar activity and the cleaved substrate pattern is comparable within these. However, for the enzymes from Ascomycetales it would be expected that they are more stringently selective for charged residues in the P4 and P1' position.
In addition to the very important direct enzyme-substrate interactions outlined here, other parameters must influence substrate recognition by Kex2 proteinases: the reduced cleavage of heat denatured protein shows that a site must be properly folded to be accessible. This view is strongly supported by the fact, that a potentially preferred substrate (CaCcw14) remains uncleaved in its native context but becomes cleavable, when exposed to the proteinase in a fusion protein (Figure 8). In our experiments 1/3 of the selected proteins remained uncleaved. Hence, to properly identify proteinase substrates, it is essential to include further parameters such as substrate structure in addition to primary sequence into the prediction algorithm.
Our data provide information beyond those previous data based on in silico predictions or assays with small peptides only. By using heterologous expressed proteases and substrates we were able to show the potential of each of the investigated Kex2 enzymes to digest selected putative substrates. However, further in vivo experiments are necessary in future studies to undoubtedly infer proteolytic maturation of these substrates.
Aside from α-mating pheromone- and killer toxin precursors, the only previously experimentally proven Kex2 substrates are the glycolytic enzymes Exg1 of S. cerevisiae  and Xylanases of T. reesei , the aspartic proteinase CaSap2 , the structural cell wall Pir protein family  and the hydrophobin Rep1 of Ustilago maydis . In our experiments we were able to confirm processing by Kex2 for the cell wall modulating enzymes CaSun41 (CA0883), CgScw4 (CAGL0M13805g) and CgSun4 (CAGL0L05434g) and for CgPir1, which had been predicted to be Kex2 substrates in earlier in silico searches [9, 10]. Additionally, we observed in vitro cleavage for several proteins which have not previously been discussed as Kex2 substrates such as CaEce1, a group of Ops4-like proteins and two members of the Pry-protein family.
In our tests three proteins of the "plant pathogenicity related" Pry-protein family (CaRbt4, CgPry1 and CgPry2) were included. The proteins of this family contain a strongly conserved KR-motif (see Additional file 2), but the proteins are not cleaved in a similar pattern: While CgPry1 is cleaved efficiently, CaRbt4 is not cleaved at all and CgPry2 only very slowly. It is therefore likely, that the conserved site of the Pry proteins is not cleaved in the fully native protein, and that processing of CgPry1 only takes place in the additional sites not present in the other two proteins.
The major phenotype described for kex2 deletion mutants in Candida revolves around morphological defects of the cell wall  and the resulting hypersensitivity to compounds interfering with the surface integrity . Several Kex2 target proteins directly interact with the fungal cell wall or are structural components thereof: the Pir proteins, glucanases such as Exg1, or proteins of the Sun/Scw family. While the direct consequence of failure to mature is not known for these proteins, the phenotypes of the respective deletion strains resemble those of kex2 deletion strains: mutants lacking cell wall localized glucanases such as ScExg1  or CaBgl2  and mutants lacking members of the Pir  or the SUN-family [41, 42] show similar increased sensitivities towards several cell wall or membrane perturbing compounds [8, 10]. Here it is interesting, that the Kex2 cleavage site is found in several but not in all glucanases.
Additionally, Pir deletions result in the formation of cell aggregates , which is also be seen in the S. cerevisiae sun4 and C. albicans sun41 deletion strains [41–43] and are also observed in C. glabrata kex2 deletion strains (data not shown). Furthermore, a S. cerevisiae scw4/scw10 double mutant  and a C. albicans sun41 strain showed enlarged cells , a phenotype which can also be observed in the C. glabrata kex2 mutant (data not shown). Furthermore, calcofluor white stained C. albicans kex2 cells show an abberant staining pattern , which would be in agreement with the potential changes in chitin deposition as seen from the abberant septum processing in C. albicans sun41 strains . The Kex2 cleavage site in Sun4- and Scw10-like proteins is preceded by an N-terminal stretch of positively charged amino acids, mainly histidines (see Additional file 2). This feature, which we termed "His-Box", is also found in Tos1 proteins, only here it is located further inside the protein and is additionally preceded by another Kex2 cleavage site. It can be speculated that, if this motif was involved in cell wall attachment, processing would lead to differential localization of the mature protein, e.g. secretion as observed in C. albicans for Sun41 and Tos1 .
A second group of proteins without assigned function identified as Kex2 substrates is the family of C. albicans Ops4-like proteins, whose members are differentially regulated in white-opaque switching  and mating . This family consists of CaOps4, CA2974, CA6162, CA1873 and CaPga17 (Figure 9). The C. albicans and S. cerevisiae kex2 deletion mutants are mating deficient [3, 48]. This has been attributed to the lack of processed α-mating pheromone, but if the above proteins are indeed involved in the mating process, the kex2 mating deficiency could be more severe than thought.
In summary, our data show that fungal Kex2 proteinases are similar in their substrate activities but these substrates may have different functions according to the different biological backgrounds of the investigated fungi, including pathogenicity in humans. In addition, the preferred processing sites of these substrates do not only depend on the amino acids surrounding the processing site, but also on other features such as three dimensional structure. Furthermore, Kex2 proteinases may have unique substrates whose processing sites are adapted to individual proteinases in each organism.
Oligonucleotides (TIBMolBiol, Germany) used for cloning of expression vectors in this study are given in Additional file 4.
Heterologous proteinase expression in Pichia pastoris
Candida glabrata and Pichia pastoris Kex2 enzymes were expressed using the Pichia expression system (Invitrogen) according to manufacturer's instructions. Briefly, the DNA coding for the Golgi-luminal part of the protein was PCR-amplified from genomic DNA with oligonucleotides containing terminal restriction sites (BamHI/NotI and SnaBI/NotI, respectively) and a sequence for a C-terminal 6 × His-tag, cloned into the pic3.5 vector and transformed into Pichia strain GS115 using an optimized electroporation protocol . Transformants were screened by testing of enzymatic activity against the chromogenic substrate Z-Tyr-Lys-Arg-pNA (see below) in the supernatant of pilot expressions and the clone exhibiting maximum activity used for scale-up. For large-scale production, cells were grown in 500 ml buffered minimal glycerol medium at 30°C over night, harvested by centrifugation, washed and resuspended in 50 ml buffered minimal methanol medium. Maximum activity was detected after 16 h of growth, after which the culture supernatants were harvested and the recombinant enzymes purified as described below.
Heterologous proteinase expression in Candida albicans
The soluble form of C. albicans Kex2 was expressed in the native host, as several attempts of heterologous expression in P. pastoris failed. The KEX2 gene was PCR-amplified from genomic DNA of C. albicans with primers containing restriction sites (HinDIII/NheI) and the sequence for a 6 × His-tag, cloned into pCIp10  and thus put under control of the mainly constitutive C. albicans ACT1 promoter. The plasmid was linearized with NcoI and transformed into C. albicans strain CAI4 using the same protocol as above for Pichia transformation. Transformants were selected on minimal medium and screened using the supernatant of 5 ml YPD (1% yeast extract, 2% peptone, 1% glucose) over night cultures for testing of enzymatic activity as above. For preparative expression, a 500 ml YPD culture was grown over night, the cells harvested, washed twice with 50 ml YPD, resuspended in 50 ml YPD and further cultivated at 30°C. Maximum Kex2 activity in the supernatant was observed after 12 h of growth at 30°C, after which the supernatant was collected and the recombinant protein purified as described below. YPD medium used for expression was previously freed from low molecular weight impurities by passing over a 10 kDa size exclusion Centricon-20 column (Millipore),
Purification of secreted soluble Kex2 proteins
To purify the recombinant enzymes, 50 ml sterile filtered expression culture supernatant were concentrated on a 30 kDa size-exclusion Centricon-20 column (Millipore) to a volume of approximately 1–2 ml, desalted using a PD-10 column (Amersham Biosciences) and eluent diluted to a volume of 20 ml into IAEX buffer (50 mM BisTris pH 4.5, 10 mM NaCl). This was loaded onto an HiTrap ANX FF anion exchange column (Amersham Biosciences), washed, and eluted with IAEX buffer containing 100 mM NaCl. The eluent was then again concentrated, the buffer changed into storage buffer (50 mM BisTris, pH 7.2 50% w/v glycerol) and the enzymes kept at -20°C.
Proteinase activity quantification
Proteolytic activity of the purified enzymes was assayed using the chromogenic substrate Z-Tyr-Lys-Arg-pNA (Bachem, Switzerland) as described previously . Assays were done in buffer containing 50 mM BisTris (pH 7.2), 1 mM CaCl2, 0.5 mM substrate in a total volume of 100 μl at 37°C. For the measurement of time kinetic data, the reaction was started by mixing 50 μl of solution containing the proteinase with 50 μl containing the substrate. The temperature gradient for optimal reaction temperature measurement was generated in a thermocycler (Biometra) and the reaction terminated by the addition of EDTA to a final concentration of 10 mM. Liberation of p-nitroannilide (pNA) was measured at 405 nm in a spectrophotometer (Tecan). All measurements were calibrated against negative controls without proteinase and repeated at least three times.
In silicoidentification and analysis of substrate sequences
The protein sequence sets analysed here were downloaded from the Genolevures Website [51, 52], from CandidaDB [53, 54] and from the Stanford Genomic Resources FTP server . Sequence analysis on genome-scale was done using custom perl scripts within the bioperl framework, incorporated into a local database, as described in the results section. Entry into the secretory pathway and membrane topology were predicted with the Phobius algorithm . Sequence logos were created using the Weblogo website . All programs were run under SUSE Linux 10.1.
Heterologous expression, renaturation and purification of substrate proteins
Heterologous expression of substrate proteins was done using the pET100-D TOPO vector system (Invitrogen) in E. coli, strain Rosetta (Novagen). Either, exponentially growing cells were induced with IPTG and grown for 3 h in a volume of 50 ml or autoinduced by growth in 50 ml LB containing 0.05% glucose and 0.2% lactose . Harvested cells were lysed in 5 ml BugBuster (Novagen) with Benzonase nuclease (Novagen) and lysosyme (Sigma) added according to the manufacturers' description. Proteins expressed in a soluble form were purified using 6 × His chelating chromatography and analyzed by SDS-PAGE. Proteins expressed in form of inclusion bodies were refolded using β-cyclodextrin . Inclusion body pellets were dissolved in solubilization buffer (100 mM Na2HPO4, 100 mM NaCl and 8 M urea) at 60°C. The denatured protein was bound to Ni-Agarose and washed with 20 bed volumes of solubilization buffer. The urea was thoroughly removed with buffer A (100 mM Na2HPO4) containing 0.1% Triton X-100 (Sigma). Excess Triton X-100 was removed by washing with 10 bed volumes of buffer A and the bound protein refolded over night in buffer A containing 5 mM β-cyclodextrin (Sigma). The refolded, bound protein was then again washed with 20 bed volumes buffer A and eluted with 200 mM imidazole and 0.001% Triton X-100. The eluent was passed through a 20 μm sterile filter to remove aggregates and then analyzed via SDS-PAGE.
To confirm proper folding by this method we tested one of the proteins, a putative acid phosphatase, for activity. One μl each of the refolded protein solution was assayed in 100 mM NaAcetate buffered from pH 3 to 6 at room temperature towards its activity against 0.5 mM para-nitrophenol phosphate (pNPP). Liberation of p-nitrophenol was measured in a spectrophotometer (Tecan) at 405 nm and the experiment repeated three times.
Proteolytic digestion of substrate proteins and detection of digestion products
Proteolytic digests of Kex2 substrates were performed in Kex2 buffer (20 mM Tris-HCl, 1 mM CaCl2, pH 7.2, modified from ) at 37°C. To observe intermediate products in the case of proteins with several potential cleavage sites, time series of the reactions were conducted by stopping the reaction of aliquots by fast heating to 95°C. Depending on the expected product sizes, the proteolytic digests were resolved either on Tris-glycine or Tris-tricine  polyacrylamide gels and visualized by silver staining and/or western blotting using an antibody against the N-terminal Xpress epitope (Invitrogen).
Alignment of proteinase structures and sequences
Sequences were aligned locally with the ClustalW algorithm  and edited with the BioEdit software . Coordinate sets for proteinase structures were downloaded from the Protein Data Bank , superimposed using the MASS algorithm  and visualized with RasMol .
The authors would like to thank Stefan Bentink, Sascha Brunke and Stefan Biere for help with setting up the substrate prediction and Maram Bader for critically reading the manuscript. The Pichia strain secreting soluble ScKex2 enzyme was a kind gift of Guy Boileau, Université Laval, Québec.
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