Absolutely conserved tryptophan in M49 family of peptidases contributes to catalysis and binding of competitive inhibitors

The role of the unique fully conserved tryptophan in metallopeptidase family M49 (dipeptidyl peptidase III family) was investigated by site-directed mutagenesis on human dipeptidyl peptidase III (DPP III) where Trp300 was subjected to two substitutions (W300F and W300L). The mutant enzymes showed thermal stability equal to the wild-type DPP III. Conservative substitution of the Trp300 with phenylalanine decreased enzyme activity 2-4 fold, but did not significantly change the K_m values for two dipeptidyl 2-naphthylamide substrates. However, the K_m for the W300L mutant was elevated 5-fold and the k_cat value was reduced 16-fold with Arg-Arg-2-naphthylamide. Both substitutions had a negative effect on the binding of two competitive inhibitors designed to interact with S1 and S2 subsites.These results indicate the importance of the aromatic nature of W300 in DPP III ligand binding and catalysis, and contribution of this residue in maintaining the functional integrity of this enzyme’s S2 subsite.     

Human dipeptidyl peptidase III: insights into ligand binding from a combined experimental and computational approach

Human dipeptidyl peptidase III (DPP III) is a zinc-exopeptidase with implied roles in protein catabolism, pain modulation, and defense against oxidative stress. To understand the mode of ligand binding into its active site, we performed molecular modeling, site-directed mutagenesis, and biochemical analyses. Using the recently determined crystal structure of the human DPP III we built complexes between both, the wild-type (WT) protein and its mutant H568N with the preferred substrate Arg-Arg-2-naphthylamide (RRNA) and a competitive inhibitor Tyr-Phe-hydroxamate (Tyr-Phe-NHOH). The mutation of the conserved His568, structurally equivalent to catalytically important His231 in thermolysin, to Asn, resulted in a 1300-fold decrease of k(cat) for RRNA hydrolysis and in significantly lowered affinity for the inhibitor. Molecular dynamics simulations revealed the key protein-ligand interactions as well as the ligand-induced reorganization of the binding site and its partial closure. Simultaneously, the non-catalytic domain was observed to stretch and the opening at the wide side of the inter-domain cleft became enhanced. The driving force for these changes was the formation of the hydrogen bond between Asp372 and the bound ligand. The structural and dynamical differences, found for the ligand binding to the WT enzyme and the H568N mutant, and the calculated binding free energies, agree well with the measured affinities. On the basis of the obtained results we suggest a possible reaction mechanism. In addition, this work provides a foundation for further site-directed mutagenesis experiments, as well as for modeling the reaction itself.     

Identification of rate-limiting steps in yeast heme biosynthesis

The heme biosynthesis pathway in the yeast Saccharomyces cerevisiae is a highly regulated system, but the mechanisms accounting for this regulation remain unknown. In an attempt to identify rate-limiting steps in heme synthesis, which may constitute potential regulatory points, we constructed yeast strains overproducing two enzymes of the pathway: the porphobilinogen synthase (PBG-S) and deaminase (PBG-D). Biochemical analysis of the enzyme-overproducing strains revealed intracellular porphobilinogen and porphyrin accumulation. These results indicate that both enzymes play a rate-limiting role in yeast heme biosynthesis.     

Leishmania major metacaspase can replace yeast metacaspase in programmed cell death and has arginine-specific cysteine peptidase activity

The human protozoan parasite Leishmania major has been shown to exhibit several morphological and biochemical features characteristic of a cell death program when differentiating into infectious stages and under a variety of stress conditions. Although some caspase-like peptidase activity has been reported in dying parasites, no caspase gene is present in the genome. However, a single metacaspase gene is present in L. major whose encoded protein harbors the predicted secondary structure and the catalytic dyad histidine/cysteine described for caspases and other metacaspases identified in plants and yeast. The Saccharomyces cerevisiae metacaspase YCA1 has been implicated in the death of aging cells, cells defective in some biological functions, and cells exposed to different environmental stresses. In this study, we describe the functional heterologous complementation of a S. cerevisiae yca1 null mutant with the L. major metacaspase (LmjMCA) in cell death induced by oxidative stress. We show that LmjMCA is involved in yeast cell death, similar to YCA1, and that this function depends on its catalytic activity. LmjMCA was found to be auto-processed as occurs for caspases, however LmjMCA did not exhibit any activity with caspase substrates. In contrast and similarly to Arabidopsis thaliana metacaspases, LmjMCA was active towards substrates with arginine in the P1 position, with the activity being abolished following H147A and C202A catalytic site mutations. These results suggest that metacaspases are members of a family of peptidases with a role in cell death conserved in evolution notwithstanding possible differences in their catalytic activity.     

Synthesis, kinetic evaluation, and utilization of a biotinylated dipeptide proline diphenyl phosphonate for the disclosure of dipeptidyl peptidase IV-like serine proteases

In this study, we report on the synthesis, kinetic characterisation, and application of a novel biotinylated and active site-directed inactivator of dipeptidyl peptidase IV (DPP-IV). Thus, the dipeptide-derived proline diphenyl phosphonate NH(2)-Glu(biotinyl-PEG)-Pro(P)(OPh)(2) has been prepared by a combination of classical solution- and solid-phase methodologies and has been shown to be an irreversible inhibitor of porcine DPP-IV, exhibiting an over all second-order rate constant (k(i)/K(i)) for inhibition of 1.57 x 10(3) M(-1) min(-1). This value compares favourably with previously reported rates of inactivation of DPP-IV by dipeptides containing a P(1) proline diphenyl phosphonate grouping [B. Boduszek, J. Oleksyszyn, C.M. Kam, J. Selzler, R.E. Smith, J.C. Powers, Dipeptide phophonates as inhibitors of dipeptidyl peptidase IV, J. Med. Chem. 37 (1994) 3969-3976; B.F. Gilmore, J.F. Lynas, C.J. Scott, C. McGoohan, L. Martin, B. Walker, Dipeptide proline diphenyl phosphonates are potent, irreversible inhibitors of seprase (FAPalpha), Biochem, Biophys. Res. Commun. 346 (2006) 436-446.], thus demonstrating that the incorporation of the side-chain modified (N-biotinyl-3-(2-(2-(3-aminopropyloxy)-ethoxy)-ethoxy)-propyl) glutamic acid residue at the P(2) position is compatible with inhibitor efficacy. The utilisation of this probe for the detection of both purified dipeptidyl peptidase IV and the disclosure of a dipeptidyl peptidase IV-like activity from a clinical isolate of Porphyromonas gingivalis, using established electrophoretic and Western blotting techniques previously developed by our group, is also demonstrated.     

Identification of the dipeptidyl aminopeptidase responsible for N-terminal clipping of recombinant Exendin-4 precursor expressed in Pichia pastoris

Exendin-4 is a naturally occurring 39 amino acid peptide that is useful for the control of Type 2 diabetes. Recombinant Exendin-4, with an extra glycine at the carboxy-terminus (Exdgly), was expressed in the methylotropic yeast Pichia pastoris. A high proportion of the Exdgly molecules secreted into medium were found to be clipped, lacking the first two amino acids (His–Gly) from the N-terminus. Disruption of the P. pastoris homolog of the Saccharomyces cerevisiae dipeptidyl aminopeptidase (STE13) gene in Pichia genome resulted in a clone that expressed N-terminally intact Exdgly. Elimination of N-terminal clipping enhanced the yield and simplified the purification of Exdgly from P. pastoris culture supernatant.     

Monitoring of the effects of transfection with baculovirus on Sf9 cell line and expression of human dipeptidyl peptidase IV

Human dipeptidylpeptidase IV (hDPPIV) is an enzyme that is in hydrolase class and has various roles in different parts of human body. Its deficiency may cause some disorders in the gastrointestinal, neurologic, endocrinological and immunological systems of humans. In the present study, hDPPIV enzyme was expressed on Spodoptera frugiperda (Sf9) cell lines as a host cell, and the expression of hDPPIV was obtained by a baculoviral expression system. The enzyme production, optimum multiplicity of infection, optimum transfection time, infected and uninfected cell size and cell behavior during transfection were also determined. For maximum hDPPIV (269 mU mL⁻¹) enzyme, optimum multiplicity of infection (MOI) and time were 0.1 and 72 h, respectively. The size of infected cells increased significantly (P < 0.001) after 24 h post infection. The results indicated that Sf9 cell line was applicable to the large scale for hDPPIV expression by using optimized parameters (infection time and MOI) because of its high productivity (4.03 mU m L⁻¹ h⁻¹).     

Mating type-dependent constraints on the mobility of the left arm of yeast chromosome III

Mating-type gene (MAT) switching in budding yeast exhibits donor preference. MATa preferentially recombines with HML near the left telomere of chromosome III, whereas MATalpha prefers HMR near the right telomere. Donor preference is controlled by the recombination enhancer (RE) located proximal to HML. To test if HML is constrained in pairing with MATalpha, we examined live-cell mobility of LacI-GFP-bound lactose operator (lacO) arrays inserted at different chromosomal sites. Without induction of recombination, lacO sequences adjacent to HML are strongly constrained in both MATalpha and RE-deleted MATa strains, compared with MATa. In contrast, chromosome movement at HMR or near a telomere of chromosome V is mating-type independent. HML is more constrained in MATa Deltare and less constrained in MATa RE+ compared with other sites. Although HML and MATa are not prealigned before inducing recombination, the three-dimensional configuration of MAT, HML, and HMR is mating-type dependent. These data suggest there is constitutive tethering of HML, which is relieved in MATa cells through the action of RE.     

Identification of the reactive cysteine residues in oligopeptidase B from Trypanosoma brucei

Oligopeptidase B (OpdB) from Trypanosoma brucei is a candidate therapeutic target in African trypanosomiasis. OpdB is an atypical serine peptidase, since activity is inhibited by thiol-blocking reagents and enhanced by reducing agents. We have identified C256 as the reactive cysteine residue that mediates OpdB inhibition by N-ethylmaleimide and iodoacetic acid. Modeling studies suggest that C256 adducts occlude the P(1) substrate-binding site, preventing substrate binding. We further demonstrate that C559 and C597 are responsible for the thiol-enhancement of OpdB activity. These studies may facilitate the development of specific OpdB inhibitors with therapeutic potential, by exploiting these unique properties of this enzyme.     

Influence of compartmental localization on the function of yeast NADP+-specific isocitrate dehydrogenases

Three differentially compartmentalized isozymes of isocitrate dehydrogenase (mitochondrial IDP1, cytosolic IDP2, and peroxisomal IDP3) in the yeast Saccharomyces cerevisiae catalyze the NADP(+)-dependent oxidative decarboxylation of isocitrate to form alpha-ketoglutarate. These enzymes are highly homologous but exhibit some significant differences in physical and kinetic properties. To examine the impact of these differences on physiological function, we exchanged promoters and altered organellar targeting information to obtain expression of IDP2 and IDP3 in mitochondria and of IDP1 and IDP3 in the cytosol. Physiological function was assessed as complementation by mislocalized isozymes of defined growth defects of isocitrate dehydrogenase mutant strains. These studies revealed that the IDP isozymes are functionally interchangeable for glutamate synthesis, although mitochondrial localization has a positive impact on this function during fermentative growth. However, IDP2, whether located in mitochondria or in the cytosol, provided the highest level of defense against endogenous or exogenous oxidative stress.     

Replicative aging of the yeast does not require DNA replication

Glucose addition to a stationary culture of wild-type Saccharomyces cerevisiae BY4742 cells with zero activity of MDR pumps resuspended in a fresh medium causes pump resynthesis (measured as pump-effected diS-C3(3) efflux). In a stationary culture in its original growth medium, this glucose-induced pump resynthesis fails to occur due to depletion of essential nutrients or to extracellular metabolites produced by cells during growth. Direct pump inactivation by metabolites is excluded since exponential cells with high MDR pump activity cultured in a medium with high concentration of extracellular metabolites retain this activity for at least 2 h. The metabolites also do not affect pump synthesis on the level of gene expression as addition of concentrated growth medium or an amino acid mixture to stationary cells in spent growth medium restores glucose-induced pump synthesis. The block of MDR pump synthesis is therefore due to the lack of essential nutrients in spent medium.     

Functional significance of some particular amino acid residues in Bombyx mori pyridoxal kinase

Pyridoxal kinase (PLK; EC 2.7.1.35) is a key enzyme for vitamin B₆ metabolism in animals. It catalyzes the ATP-dependent phosphorylation of pyridoxal, generating pyridoxal 5′-phosphate, an important cofactor for many enzymatic reactions. Bombyx mori PLK (BmPLK) is 10 or more residues shorter than mammalian PLKs, and some amino acid residues conserved in the PLKs from mammals are not maintained in the protein. Multiple sequence alignment suggested that amino acid residues Thr⁴⁷, Ile⁵⁴, Arg⁸⁸, Asn¹²¹ and Glu²³⁰ might play important roles in BmPLK. In this study, we used a site-directed specific mutagenesis approach to determine the functional significance of these particular amino acid residues in BmPLK. Our results demonstrated that the mutation of Asn¹²¹ to Glu did not affect the catalytic function of BmPLK. The corresponding site-directed mutants of Thr⁴⁷ to Asn, Ile⁵⁴ to Phe, and Arg⁸⁸ to Ile displayed a decreased catalytic efficiency and an elevated Km value for substrate relative to the wild-type value, and no enzyme activity could be detected in mutant of Trp²³⁰ to Glu. Circular dichroism analysis revealed that the mutation of Trp²³⁰ to Glu resulted in mis-folding of the protein. Our results provided direct evidence that residue Trp²³⁰ is crucial to maintain the structural and functional integrity of BmPLK. This study will add to the existing understanding of the characteristic of structure and function of BmPLK.     

A mathematical model of ageing in yeast

Budding yeast, Saccharomyces cerevisiae, is commonly used as a system to study cellular ageing. Yeast mother cells are capable of only a limited number of divisions before they undergo senescence, whereas newly formed daughters usually have their replicative age "reset" to zero. Accumulation of extrachromosomal ribosomal DNA circles (ERCs) appears to be an important contributor to ageing in yeast, and we describe a mathematical model that we developed to examine this process. We show that an age-related accumulation of ERCs readily explains the observed features of yeast ageing but that in order to match the experimental survival curves quantitatively, it is necessary that the probability of ERC formation increases with the age of the cell. This implies that some other mechanism(s), in addition to ERC accumulation, must underlie yeast ageing. We also demonstrate that the model can be used to gain insight into how an extra copy of the Sir2 gene might extend lifespan and we show how the model makes novel, testable predictions about patterns of age-specific mortality in yeast populations.     

Biogenesis of yeast mitochondrial cytochrome c: a unique relationship to the TOM machinery

The import of cytochrome c into the mitochondrial intermembrane space is not understood at a mechanistic level. While the precursor apocytochrome c can insert into protein-free lipid bilayers, the purified translocase of the outer membrane (TOM) complex supports the translocation of apocytochrome c into proteoliposomes. We report an in organello analysis of cytochrome c import into yeast mitochondria from wild-type cells and different mutants cells, each defective in one of the seven Tom proteins. The import of cytochrome c is not affected by removal of the receptor Tom20 or Tom70. Moreover, neither the transfer protein Tom5 nor the assembly factors Tom6 and Tom7 are needed for import of cytochrome c. When the general import pore (GIP)-protein Tom40 is blocked, the import of cytochrome c is moderately affected. Mitochondria lacking the central receptor and organizing protein Tom22 contain greatly reduced levels of cytochrome c. We conclude that up to two components of the TOM complex, Tom22 and possibly the GIP, are involved in the biogenesis of cytochrome c.     

5'-end formation of yeast 5.8SL rRNA is an endonucleolytic event

Like most eukaryotes, Saccharomyces cerevisiae cells contain a minor 5.8SL rRNA that, relative to the major 5.8SS species, carries several extra nucleotides at the 5'-end. The two species are produced by alternative pathways that differ in the events removing the 3'-terminal region of Internal Transcribed Spacer 1 from the 27SA2 pre-rRNA. Whereas the pathway leading to 5.8SS rRNA is well established, that producing the 5'-end of 5.8SL (called B1L) is poorly understood. Northern analysis of two different mutants of S. cerevisiae that overproduce 5.8SL rRNA revealed the presence of a fragment corresponding to the 3'-terminal region of Internal Transcribed Spacer 1 (ITS1) directly upstream from site B1L. Immunoprecipitation experiments showed this fragment to be associated with the trans-acting factor Rrp5p required for processing at the early sites A0-A3. Together these data clearly support that the 5'-end of 5.8SL rRNA is an endonucleolytic event. In vivo mutational analysis demonstrated the lack of any cis-acting sequence elements directing this cleavage within ITS1.     

Membrane tension regulates water transport in yeast

Evidence that membrane surface tension regulates water fluxes in intact cells of a Saccharomyces cerevisiae strain overexpressing aquaporin AQY1 was obtained by assessing the osmotic water transport parameters in cells equilibrated in different osmolarities. The osmotic water permeability coefficients (P_f) obtained for yeast cells overexpressing AQY1 incubated in low osmolarity buffers were similar to those obtained for a double mutant aqy1aqy2 and approximately three times lower (with higher activation energy, E_a) than values obtained for cells incubated in higher osmolarities (with lower E_a). Moreover, the initial inner volumes attained a maximum value for cells equilibrated in lower osmolarities (below 0.75 M) suggesting a pre-swollen state with the membrane under tension, independent of aquaporin expression. In this situation, the impairment of water channel activity suggested by lower P_f and higher E_a could probably be the first available volume regulatory tool that, in cooperation with other osmosensitive solute transporters, aims to maintain cell volume. The results presented point to the regulation of yeast water channels by membrane tension, as previously described in other cell systems.     

A novel cis-acting element required for DNA damage-inducible expression of yeast DIN7

Din7 is a DNA damage-inducible mitochondrial nuclease that modulates the stability of mitochondrial DNA (mtDNA) in Saccharomyces cerevisiae. How DIN7 gene expression is regulated, however, has remained largely unclear. Using promoter sequence alignment, we found a highly conserved 19-bp sequence in the promoter regions of DIN7 and NTG1, which encodes an oxidative stress-inducible base-excision-repair enzyme. Deletion of the 19-bp sequence markedly reduced the hydroxyurea (HU)-enhanced DIN7 promoter activity. In addition, nuclear fractions prepared from HU-treated cells were used in in vitro band shift assays to reveal the presence of currently unidentified trans-acting factor(s) that preferentially bound to the 19-bp region. These results suggest that the 19-bp sequence is a novel cis-acting element that is required for the regulation of DIN7 expression in response to HU-induced DNA damage.