Comparative specificity of microbial acid proteinases for synthetic peptides. Primary specificity with Z-tetrapeptides

The substrates Z-X

Leu-(Ala)₂ and

Z-Phe X-(Ala)₂ (Z = benzyloxycarbonyl, X = various amino acid residues) were synthesized in order to investigate the primary specificity of acid proteinases from molds and yeasts. Since these peptides are mainly susceptible to cleavage by the enzymes at the peptide bonds shown by the arrows, it was possible to determine the specificity with respect to the amino acid residues on both sides of the splitting point. Pepsin was used for comparison. The results indicated that the microbial acid proteinases exhibit specificity for aromatic or hydrophobic amino acid residues on both sides of splitting point in peptide substrates, as does pepsin. However, the microbial enzymes showed somewhat broader specificity than pepsin. The former enzymes, which possess trypsinogen-activating ability, show specificity for a lysine residue, while pepsin or Mucor rennin-like enzyme does not. Although pepsin is very specific for a tyrosine residue on the imino side of the splitting point, the microbial enzymes do not show such stringency.     

Backbone and side-chain resonance assignments of <Emphasis Type="Italic">Plasmodium falciparum</Emphasis> SUMO

One of the most debilitating diseases Malaria, in its different forms, is caused by protozoan of Plasmodium species. Deadliest among these forms is the “cerebral malaria” which is afflicted upon by Plasmodium falciparum. Plasmodium adopts numerous strategies including various post-translational modifications (PTMs) to infect and survive in the human host. These PTMs have proven their critical requirement in the Plasmodium biology. Recently, sumoylation has been characterized as one of the important PTMs and many of its putative substrates have been identified in Plasmodium. Sumoylation is the covalent attachment of SUMO protein to the substrate protein, which is mediated by an enzyme cascade involving activating (E1), conjugating (E2), and ligating enzymes (E3). Here, we report resonance assignment for ¹H, ¹³C and ¹⁵N of Plasmodium falciparum SUMO (Pf-SUMO) protein determined by various 2D and 3D heteronuclear NMR experiments along with predicted secondary structures.     

Multi-spectroscopic studies on the interaction between traditional Chinese herb,helicid with pepsin

Study on the binding properties of helicid by pepsin systematically using multi-spectroscopic techniques and molecular docking method, and these interactions comprise biological recognition at molecular level and backbone of biological significance in medicine concerned with the uses, effects, and modes of action of drugs. We investigated the mechanism of interaction between helicid and pepsin by using various spectroscopic techniques viz., fluorescence spectra, UV–Vis absorption spectra, circular dichroism (CD), 3D spectra, synchronous fluorescence spectra and molecular docking methods. The quenching mechanism associated with the helicid–pepsin interaction was determined by performing fluorescence measurements at different temperatures. From the experimental results show that helicid quenched the fluorescence intensity of pepsin via a combination of static and dynamic quenching process. The binding constants (K_a) at three temperatures (288, 298, and 308 K) were 7.940?×?10⁷, 2.082?×?10⁵ and 3.199?×?10⁵ L mol^?1, respectively, and the number of binding sites (n) were 1.44, 1.14, and 1.18, respectively. The n value is close to unity, which means that there is only one independent class of binding site on pepsin for helicid. Thermodynamic parameters at 298 K were calculated as follows: ΔH^o (??83.85 kJ mol^?1), ΔG^o (??33.279 kJ mol^?1), and ΔS^o (??169.72 J K^?1 mol^?1). Based on thermodynamic analysis, the interaction of helicid with pepsin is driven by enthalpy, and Van der Waals’ forces and hydrogen bonds are the main forces between helicid and pepsin. A molecular docking study further confirmed the binding mode obtained by the experimental studies. The conformational changes in the structure of pepsin was confirmed by 3D fluorescence spectra and circular dichroism.     

The Proteolytic Activity and Cleavage Specificity of Fibronectin-Gelatinase and Fibronectin-Lamininase

Human plasma fibronectin contains two latent aspartic proteinases, FN-gelatinase and FN-lamininase. Both enzymes can be generated and activated in the presence of Ca²⁺ from the purified cathepsin D-produced 190-kDa fibronectin fragment. We investigated the proteolytic activity and cleavage specificity of both enzymes in a range of pH from 3.5 to 9.0 using the B chain of oxidized bovine insulin and chromogenic peptides as substrates. The inhibition of the enzymes by several natural inhibitors from human plasma was also tested. The specificities of FN-gelatinase and FN-lamininase are similar to other major acidic proteinases, including pepsin, renin, cathepsin D, and HIV-proteinases. Both enzymes mainly hydrolyze three peptide bonds in the oxidized insulin B chain, namely Glu–Ala (residues 13–14), Tyr–Leu (residues 16–17), and Phe–Phe (residues 24–25). For the peptide substrates H-Pro-Thr-Glu-Phe-p-nitro-Phe-Arg-Leu-OH and H-Phe-Gly-His-p-nitro-Phe-Phe-Val-Leu-OMe that were cleaved the respective values of k _cat/K _M were 105.1 and 11.8 mM^–1 sec^–1 for cleavage by FN-gelatinase, and 123.2 and 15.5 mM^–1 sec^–1 for cleavage by FN-lamininase. The maximal activities of both enzymes were observed in a range between pH 5.6 and 6.3 and they became inactivated at a pH value above 8.4. Both FN-gelatinase and FN-lamininase were efficiently inhibited by ₂-macroglobulin.     

Properties of Probiotics <Emphasis Type="Italic">Kocuria</Emphasis> SM1 and <Emphasis Type="Italic">Rhodococcus</Emphasis> SM2 Isolated from Fish Guts

This study characterized probiotics Kocuria SM1 and Rhodococcus SM2, which were recovered from the intestinal microbiota of rainbow trout (Oncorhynchus mykiss, Walbaum). The cultures were Gram-positive, non-motile, catalase-positive and oxidase-negative cocci or rods. Cell multiplication of SM1 and SM2 was observed at 4–37 °C (45 °C for SM1), in 0–20% (w/v) NaCl and at pH 2–11. The viability was not affected when exposed to pepsin at pH 2.0 and 3.0, and pancreatin at pH 8.0. Neither isolates were chrome azurol S-positive for siderophore production. Of the 19 common enzymes analysed using the API-ZYM system, only 8 were evident in the culture of SM1 compared to 11 enzymes for SM2. The secondary metabolites of both probiotics were inhibitory to Acinetobacter baumannii, Vibrio anguillarum and V. ordalii; SM2 inhibited Escherichia coli, Klebsiella pneumoniae, Pseudomonas aeruginosa and Staphylococcus aureus. SM2 was resistant to penicillin and sulphatriad, out of six antimicrobial agents; SM1 was resistant to sulphatriad. These results suggest that Kocuria SM1 and Rhodococcus SM2 are able to grow over a wide range of temperature, salinity and pH, including in conditions that mimic the gastrointestinal environment of fish and produce extracellular enzymes that may have a role in the host digestive processes. Importantly, Rhodococcus SM2 displays a high degree of bacteriocinogenic potential against multi-drug-resistant human pathogens that have never been documented among the gut microbiota of fish.     

Nepenthesin from Monkey Cups for Hydrogen/Deuterium Exchange Mass Spectrometry

Studies of protein dynamics, structure and interactions using hydrogen/deuterium exchange mass spectrometry (HDX-MS) have sharply increased over the past 5–10 years. The predominant technology requires fast digestion at pH 2–3 to retain deuterium label. Pepsin is used almost exclusively, but it provides relatively low efficiency under the constraints of the experiment, and a selectivity profile that renders poor coverage of intrinsically disordered regions. In this study we present nepenthesin-containing secretions of the pitcher plant Nepenthes, commonly called monkey cups, for use in HDX-MS. We show that nepenthesin is at least 1400-fold more efficient than pepsin under HDX-competent conditions, with a selectivity profile that mimics pepsin in part, but also includes efficient cleavage C-terminal to “forbidden” residues K, R, H, and P. High efficiency permits a solution-based analysis with no detectable autolysis, avoiding the complication of immobilized enzyme reactors. Relaxed selectivity promotes high coverage of disordered regions and the ability to “tune” the mass map for regions of interest. Nepenthesin-enriched secretions were applied to an analysis of protein complexes in the nonhomologous end-joining DNA repair pathway. The analysis of XRCC4 binding to the BRCT domains of Ligase IV points to secondary interactions between the disordered C-terminal tail of XRCC4 and remote regions of the BRCT domains, which could only be identified with a nepenthesin-based workflow. HDX data suggest that stalk-binding to XRCC4 primes a BRCT conformation in these remote regions to support tail interaction, an event which may be phosphoregulated. We conclude that nepenthesin is an effective alternative to pepsin for all HDX-MS applications, and especially for the analysis of structural transitions among intrinsically disordered proteins and their binding partners.Mass spectrometry has served the biochemical and biological communities by providing the capacity for protein identification and characterization, but in the last several years it has also become a powerful tool for interrogating protein structure and dynamics (1, 2). Solution-phase hydrogen/deuterium exchange (HDX)¹, when coupled with mass spectrometry (MS), provides rich sets of data that can be mined to extract structural and dynamic parameters from proteins (3–7). In many cases, the technique is used in experimental situations in which x-ray diffraction analysis or other biophysical techniques (e.g. NMR, cryoEM) are difficult to apply, which is particularly true in the structure-function analysis of protein interactions (8). Most applications of the method involve deuteration of a protein in two or more states, and differential labeling data is extracted at the highest structural resolution possible. Although there have been some impressive developments in top-down protein analysis using newer ion fragmentation methods for label localization (9, 10), most studies continue to employ a bottom-up strategy, in which the protein is digested with an enzyme, and the label is quantified by mass analysis of the resulting peptides.The reasons for the prominence of the bottom-up approach to HDX-MS are shared with the corresponding proteomics method. Peptides may be detected with more sensitivity than proteins, and samples of considerably higher complexity can be interrogated (11). Analytically, this shifts the focus toward optimizing protein digestion, to cover 100% of the sequence and generate a high degree of overlapping fragments to increase opportunities for localizing the deuterium label at high resolution (12–14).The unique requirements of the HDX-MS workflow unfortunately place restrictions on the digestion enzymes that may be used. To avoid label loss through back-exchange to nondeuterated solvent, the kinetics of exchange must be dramatically slowed by pH and temperature reduction, and even under these conditions the digestion must be done rapidly. Conventional methods employ a pH of ∼2.5 and temperatures of 4–10 °C. The aspartic protease pepsin can function under such conditions, which has led to its prominence for HDX-MS applications. This does not mean the enzyme is ideal. Several laboratories have sought to identify other enzymes or develop analytical solutions that address its shortcomings, which include extensive autolysis, modest efficiency, and nonideal substrate specificity. Currently, most methods involve either enzyme microreactors presenting high concentrations of pepsin in a flow-through system (15), or solution-phase digestions using pepsin and protease XIII in separate experiments (16, 17). The latter enzyme is also an aspartic protease with a sequence specificity that partially overlaps pepsin, thus the two maps together tend to somewhat improve sequence coverage (18). A method that fuses the two strategies has recently been described, involving tandem pepsin and protease XIII microreactors (13).Neither strategy is likely to be ideal when applied to protein complexes of far greater complexity, to support of structure-building activities or dynamics analysis of multiprotein “machines.” The microreactor approach complicates the front-end fluidic system, and can lead to sample loss and carryover (19). The solution-phase method requires large amounts of enzyme resulting in contamination because of enzyme autolysis (18). More importantly, neither fully overcomes the low efficiency of these enzymes. In many cases, changing the presentation of substrate can change the sequence map considerably. For example, the sequence map of a protein can be distorted when bound to a second protein (20). A map dependent on the protein load complicates the comparison of deuteration levels for the protein in different states. This alteration suggests a level of substrate inhibition (21), and probably reflects a wide range of specificity constants (k_cat/K_m) across the many individual cleavage sites presented in a protein substrate (22). Similar issues have been noted with trypsin (23). Overall, the sequence maps generated using these methods are serviceable for samples of lower complexity, but low enzymatic efficiency of the available proteases remains an important limitation and a key driver in the search for novel proteases (24).In this study, we characterize the proteolytic activity of secretions from the Nepenthes genus (25), arising from the aspartic protease nepenthesin (26), and evaluate the enzyme for use within HDX applications. Nepenthesin displays remarkably high cleavage efficiency for a broad range of substrates at low pH and temperature, which promotes high sequence coverage for a collection of proteins selected from ongoing HDX projects in our laboratories. Globally, we demonstrate that it outperforms pepsin in sequence coverage and can be used in a simple workflow for broad sequence coverage, or targeted toward a desired area of protein sequence. This new tool was applied to an HDX-MS characterization of a protein complex involved in the nonhomologous end-joining (NHEJ) pathway of DNA damage repair, and the results support a model of the complex proposed from SAXS data (27).     

Comparative specificity of microbial acid proteinases for synthetic peptides. I. Primary specificity

The specificity of various acid proteinases from mold and yeast such as Aspergillus niger, Aspergillus saitoi, Rhizopus chinensis, Mucor miehei, Rhodotorula glutinis, and Cladosporium sp. were comparatively determined using with

(X = various amino acid residues) as substrates. Pepsin was used in a comparative study. Since the peptides were susceptible to these enzymes at the peptide bonds indicated by the arrows, except for the ones from both Aspergillus species and Rhodotorula, we could examine their specificity with respect to the amino acid residue on both sides of the splitting point. The results indicated that the microbial enzymes were specific for aromatic, or bulky and hydrophobic amino acid residues on both sides, as had been observed with pepsin. The specificity of the enzymes from Aspergillus and Rhodotorula was not determined because of lack of hydrolysis of the peptides.     

Organic and inorganic acids as the stimulus for exsheathment of infective juveniles of nematodes

Petronijevic T., Rogers W. P. and Sommerville R. I. 1986. Organic and inorganic acids as the stimulus for exsheathment of infective juveniles of nematodes. International Journal for Parasitology 16: 163–168. A variety of organic and inorganic acids stimulated exsheathment of infective juveniles of Nematospiroides dubius over the range pH 2–7. Activity, in relation to pK values, suggests that the undissociated form of the acid was the active agent. Under normal conditions of exposure, exsheathment of infective juveniles of Haemonchus contortus was not obtained below pH 6, and at higher pH values activity was low except in the presence of CO₂ at pressures >9-5 kPa in the gas phase. Brief exposure to HCl at concentrations up to 2N did not induce exsheathment but in the presence of CO₂ in the gas phase, 95.3 kPa, activity was obtained in 0-O1N HCl when the times of exposure were 3–25 min.The differences in the responses of N. dubius and H. contortus to a stimulus at low pH values may be attributed to the stability of the exsheathing enzyme of N. dubius in acid media as well as to the relative sensitivity of the two species to stimuli generally.     

Asteropsins B–D,sponge-derived knottins with potential utility as a novel scaffold for oral peptide drugs

Background

Known linear knottins are unsuitable as scaffolds for oral peptide drug due to their gastrointestinal instability. Herein, a new subclass of knottin peptides from Porifera is structurally described and characterized regarding their potential for oral peptide drug development.

Methods

Asteropsins B–D (ASPB, ASPC, and ASPD) were isolated from the marine sponge Asteropus sp. The tertiary structures of ASPB and ASPC were determined by solution NMR spectroscopy and that of ASPD by homology modeling.

Results

The isolated asteropsins B–D, together with the previously reported asteropsin A (ASPA), compose a new subclass of knottins that share a highly conserved structural framework and remarkable stability against the enzymes in gastrointestinal tract (chymotrypsin, elastase, pepsin, and trypsin) and human plasma.

Conclusion

Asteropsins can be considered as promising peptide scaffolds for oral bioavailability.

General significance

The structural details of asteropsins provide essential information for the engineering of orally bioavailable peptides.     

Limited proteolysis as a tool to study the kinetics of protein folding: Conformational rearrangements in acid-dissociated lactic dehydrogenase as determined by pepsin digestion

Noncovalent aggregation as a side reaction competing with the reconstitution of oligomeric enzymes is enhanced by slow conformational changes within the partially unfolded subunits. This has been shown for lactic dehydrogenase from pig muscle after acid dissociation [G., Zettlmeissl R. Rudolph, and R. Jaenicke (1981)Eur. J. Biochem.121, 169–175]. The present experiments confirm previous spectroscopic evidence (from circular dichroism) applying pepsin digestion and subsequent analysis of the fragments on sodium dodecyl sulfate-polyacrylamide gradient gels. The susceptibility of certain fragmentation sites toward pepsin digestion changes with increasing incubation at acid pH, in accordance with a slow M₁ → M₂ transition of the acid-dissociated monomers. Constant pulses of pepsin at varying times after transferring native enzyme to pH 2.3 yield distinct changes in the fragmentation pattern consisting of undigested monomers (M_r = 35,000) plus 12 fragments ranging from 31,000 to 5000. Short digestion of the M₂ species at low concentrations of pepsin preferentially yields 25,000 and 10,500 fragments (molar ratio pepsin:lactic dehydrogenase = 1:24). The time-dependent decrease of monomers upon incubation in 0.1 m sodium phosphate, pH 2.3, at 20 °C strictly parallels the formation of the two fragments. The quantitative kinetic analysis of the changes in peptide pattern yields a first-order rate constant K₁ = 8 ± 2 × 10^?4 s^?1. The observed increase in proteolytic susceptibility is in the time range of the above mentioned decrease in the far-ultraviolet circular dichroism, and the parallel decrease in the yield of reactivation. The results suggest that during the M₁ → M₂ transition at acid pH a specific interdomain cleavage site is becoming exposed. As taken from the molecular weight of the two main fragments the trp 225-lys 226 peptide bond is the most probable candidate for this cleavage site.     

Excystation of five digenean metacercariae in vitro and in the peritoneal cavity of the mouse

Excystation of metacercariae of Parorchis acanthus, Posthodiplostomum nanum, Posthodiplostomum sp., Posthodiplostomoides leonensis and Clinostomum tilapiae in mammalian saline at 39 degrees C was similar to their excystation in mouse peritoneal cavity. Extrinsic enzymes were not needed for C. tilapiae excystation but were an absolute necessity for P. acanthus excystation. Extrinsic pepsin enhanced P. nanum excystation but was not obligatory. Acid pepsin was an absolute requirement for Posthodiplostomum sp. and Posthodiplostomoides leonensis excystation. It was noted that acid saline could not be substituted for acid pepsin and that there was diversity in the condition involved in digenean excystation.     

Control of foreign polypeptide localization in specific layers of protein body type I in rice seed

Key message

Prolamin–GFP fusion proteins, expressed under the control of native prolamin promoters, were localized in specific layers of PB-Is. Prolamin–GFP fusion proteins were gradually digested from outside by pepsin digestion.

Abstract

In rice seed endosperm, protein body type I (PB-I) has a layered structure consisting of prolamin species and is the resistant to digestive juices in the intestinal tract. We propose the utilization of PB-Is as an oral vaccine carrier to induce mucosal immune response effectively. If vaccine antigens are localized in a specific layer within PB-Is, they could be protected from gastric juice and be delivered intact to the small intestine. We observed the localization of GFP fluorescence in transgenic rice endosperm expressing prolamin–GFP fusion proteins with native prolamin promoters, and we confirmed that the foreign proteins were located in specific layers of PB-Is artificially. Each prolamin–GFP fusion protein was localized in specific layers of PB-Is, such as the outer-most layer, middle layer, and core region. Furthermore, to investigate the resistance of prolamin–GFP fusion proteins against pepsin digestion, we performed in vitro pepsin treatment. Prolamin–GFP fusion proteins were gradually digested from the peripheral region and the contours of PB-Is were made rough by in vitro pepsin treatment. These findings suggested that prolamin–GFP fusion proteins accumulating specific layers of PB-Is were gradually digested and exposed from the outside by pepsin digestion.

     

Structure of the O-polysaccharide from the lipopolysaccharide of Providencia alcalifaciens O31 containing an ether of d-mannose with (2R,4R)-2,4-dihydroxypentanoic acid

Recently, ether-linked diastereomeric 2,4-dihydroxypentanoic acids have been reported as new components of bacterial glycans [Shashkov, A. S. et al.Nat. Prod. Commun.2008, 3, 1625-1630]. In this work, an ether of (2R,4R)-2,4-dihydroxypentanoic acid (Dhpa) with d-mannose was identified in the O-polysaccharide of Providencia alcalifaciens O31, and the polysaccharide structure was elucidated. Studies by NMR spectroscopy confirmed the ether linkage between O-2 of Dhpa and O-4 of Man, and the absolute configuration of Man was determined after ether cleavage with boron trichloride. In the polysaccharide, Dhpa was found to exist partially in the form of 1,4-lactone. Using sugar and methylation analyses along with ¹H and ¹³C NMR spectroscopy, including 2D ¹H,¹H COSY, TOCSY, ROESY, H-detected ¹H,¹³C HSQC, and gHMBC experiments, the following structure of the tetrasaccharide repeating unit of the polysaccharide was established:     

Versatile catechol dioxygenases in <Emphasis Type="Italic">Sphingobium scionense</Emphasis> WP01<Superscript>T</Superscript>

The objective was to understand the roles of multiple catechol dioxygenases in the type strain Sphingobium scionense WP01^T (Liang and Lloyd-Jones in Int J Syst Evol Microbiol 60:413–416, 2010a) that was isolated from severely contaminated sawmill soil. The dioxygenases were identified by sequencing, examined by determining the substrate specificities of the recombinant enzymes, and by quantifying gene expression following exposure to model priority pollutants. Catechol dioxygenase genes encoding an extradiol xylE and two intradiol dioxygenases catA and clcA that are highly similar to sequences described in other sphingomonads are described in S. scionense WP01^T. The distinct substrate specificities determined for the recombinant enzymes confirm the annotated gene functions and suggest different catabolic roles for each enzyme. The role of the three enzymes was evaluated by analysis of enzyme activity in crude cell extracts from cells grown on meta-toluate, benzoate, biphenyl, naphthalene and phenanthrene which revealed the co-induction of each enzyme by different substrates. This was corroborated by quantifying gene expression when cells were induced by biphenyl, naphthalene and pentachlorophenol. It is concluded that the ClcA and XylE enzymes are recruited in pathways that are involved in the degradation of chlorinated aromatic compounds such as pentachlorophenol, the XylE and ClcA enzymes will also play a role in degradation pathways that produce alkylcatechols, while the three enzymes ClcA, XylE and CatA will be simultaneously involved in pathways that generate catechol as a degradation pathway intermediate.     

Separation and partial characterization of two ribonucleic Acid polymerases from pea seedlings

Two DNA-dependent RNA polymerases (ribonucleoside triphosphate:RNA nucleotidyl transferase, EC 2.7.7.6) have been isolated from pea (Pisum sativum) seedlings. The enzymes were solubilized by sonication in high salt buffer and were separated by chromatography on diethylaminoethyl cellulose using a linear salt gradient. Polymerase I eluted at 0.10 m (NH₄)₂SO₄, accounted for about 10% of the recovered activity and was completely insensitive to α-amanitin. Polymerase II eluted at 0.14 m (NH₄)₂SO₄, accounted for the remaining 90% of recovered activity and was strongly inhibited by α-amanitin. Both enzymes preferred denatured to native DNA as template, both showed an absolute requirement of divalent cation, and both were sensitive to the ionic strength of the assay medium. The developing pea seedling seems a promising system for studies of possible changes in relative activities and roles of multiple RNA polymerases during eukaryotic development.     

<Emphasis Type="Italic">Diphyllobothrium dendriticum</Emphasis> (Cestoda: Diphyllobothriidae) in the intestinal tract of the herring gull <Emphasis Type="Italic">Larus argentatus</Emphasis>: Localization and trophic parameters

We studied the activities both of digestive enzymes in the small intestine of the herring gull (Larus argentatus) and a tapeworm Diphyllobothrium dendriticum (Cestoda: Diphyllobothriidae) residing in the intestine. It was found that D. dendriticum infects the medial section of the small intestine of the herring gull. Such localization of D. dendriticum is caused by the maximal activity of proteases and glycosidases and by the high rate of membrane and cavitary digestion in this section. The activity of protease and glycosidase in gulls infected with D. dendriticum is decreased. The activity of proteases in the fractions desorbed from the tegument surface of D. dendriticum is significantly higher than that of glycosidases.     

Screening and genetic identification of acidic and neutral protease-producing yeasts strains by 26S rRNA gene sequencing

Protease enzymes (proteases), particularly those produced by microorganisms, play very important roles in industry, due to their diverse applications. Considering the richness of microbial diversity in nature, a good chance always exists that proteases more suitable, with better properties for commercial application, may be discovered while screening novel microorganisms from local environments. In this study, 94 yeasts were isolated from different natural sources collected from the Abha region, Kingdom of Saudi Arabia, to determine extracellular protease production and activity. Among them, 23 isolates (24.46%) showed protease activity using a casein hydrolysis test. Of these, five isolates (21.74%) were selected and identified as the best protease producers by exhibiting the largest clearance zones around colonies. A 26S rRNA gene D1/D2 domain sequence alignment, comparison, and phylogenetic analysis of our study yeasts to published D1/D2 domain rRNA gene sequences from GenBank, identifies the isolates as Rhodotorula mucilaginosa KKU-M12c, Cryptococcus albidus KKU-M13c, Pichia membranifaciens KKU-M18c, Hanseniaspora uvarum KKU-M19c, and Candida californica KKU-M20c. The influence of varying pH (4.0–9.0) on the yield and activity of the proteases was investigated using 0.5% (w/v) casein as a substrate, to detect optimum pH values for yeast extracellular protease production. Enzyme activity was measured using qualitative and quantitative assays. Results show all of the study yeasts secreting protease enzyme at all tested pH levels, with the exception of pH 9.0. This indicates that none of the five yeasts are alkaline protease producers. Maximum protease activity (187 U/mL) was observed in strain H. uvarum KKU-M19c at pH 6.0 (only), indicating that strain KKU-M19c only produces neutral protease. The other four yeast isolates, R. mucilaginosa KKU-M12c, C. albidus KKU-M13c, P. membranifaciens KKU-M18c, and C. californica KKU-M20c, produced both acidic (at pH 4.0) and neutral (at pH 6.0 and 7.0) proteases. Strain C. californica KKU-M20c was found to be the best acidic and neutral protease producer (138 U/mL at pH 4.0, and 185 U/mL at pH 7.0). This is the first report of the discovery and isolation of local, powerful yeasts producing acidic and neutral protease enzymes from the Abha region, Kingdom of Saudi Arabia.