Isolation and characterization of a new aminopeptidase from bovine lens

Role of αA-crystallin-derived αA66-80 peptide in guinea pig lens crystallin aggregation and insolubilization

Earlier we reported that low molecular weight (LMW) peptides accumulate in aging human lens tissue and that among the LMW peptides, the chaperone inhibitor peptide αA66-80, derived from α-crystallin protein, is one of the predominant peptides. We showed that in vitro αA66-80 induces protein aggregation. The current study was undertaken to determine whether LMW peptides are also present in guinea pig lens tissue subjected to hyperbaric oxygen (HBO) in vivo. The nuclear opacity induced by HBO in guinea pig lens is the closest animal model for studying age-related cataract formation in humans. A LMW peptide profile by mass spectrometry showed the presence of an increased amount of LMW peptides in HBO-treated guinea pig lenses compared to age-matched controls. Interestingly, the mass spectrometric data also showed that the chaperone inhibitor peptide αA66-80 accumulates in HBO-treated guinea pig lens. Following incubation of synthetic chaperone inhibitor peptide αA66-80 with α-crystallin from guinea pig lens extracts, we observed a decreased ability of α-crystallin to inhibit the amorphous aggregation of the target protein alcohol dehydrogenase and the formation of large light scattering aggregates, similar to those we have observed with human α-crystallin and αA66-80 peptide. Further, time-lapse recordings showed that a preformed complex of α-crystallin and αA66-80 attracted additional crystallin molecules to form even larger aggregates. These results demonstrate that LMW peptide-mediated cataract development in aged human lens and in HBO-induced lens opacity in the guinea pig may have common molecular pathways.

Profiling of lens protease involved in generation of αA-66-80 crystallin peptide using an internally quenched protease substrate

Proteins of lens fiber cells are prone to accumulate extensive post-translational modifications because of very little protein turnover. Lens proteins are degraded via the lens proteolytic systems into peptides, which are subsequently hydrolyzed by downstream aminopeptidases. Inefficient degradation can lead to accumulation of protein fragments and subsequent aggregation. Previously we showed that αA-66-80 peptide and its truncated products accumulate in aging and cataract human lenses. These peptides interact with crystallins, causing crystallin aggregation and precipitation. N- and C-terminal-blocked peptides that have the cleavage sites to generate the αA-66-80 fragment were used to test lens extracts for sequence-specific proteases in lens extracts. An internally quenched fluorogenic peptide substrate containing the sequence-specific site for a lens protease to generate αA-66-80 peptide was designed, synthesized and used to characterize protease(s) that are capable of generating this peptide in bovine and human lenses. We show that proteases with the potential to generate αA-66-80 peptide are present in bovine and human lenses. We also show that the αA-66-80 peptides are resistant to hydrolysis by aminopeptidases present in the lenses and they can suppress the degradation of other peptides. Failure of complete hydrolysis of these peptides in vivo can lead to their accumulation in the lens and subsequent lens protein aggregation, which may ultimately lead to the formation of cataract.

Comparison of leucine aminopeptidase and aminopeptidase III activities in lens

PURPOSE

To evaluate the relative contribution of leucine aminopeptidase and aminopeptidase III activities to the total aminopeptidase activity in bovine and human lenses under in vivo pH conditions.

METHODS

Bovine and human lens extracts were fractionated on a Sephadex G-200 column at pH 6.9 and 8.5 and all the fractions were assayed with Leu-pNA and Arg-pNA as substrates at in vivo lens pH (6.9) and optimum pH for leucine aminopeptidase, (8. 5). The major peptidases were purified and their activities compared with that of LAP and AP III isolated from bovine lens. The ability of bovine and human lens extracts and purified bovine lens LAP and AP III to hydrolyze various peptide bonds in synthetic peptides, VHLPTVEK, bradykinin and Ile-Ser-bradykinin was determined by amino acid analysis of the reaction products.

RESULTS

Sephadex G-200 gel chromatography and assay of all the fractions at pH 6.9 showed that the elution volume for the predominant aminopeptidase present in bovine lens extract is the same as that of purified AP III from the same lenses. However, when the assays were done at pH 8.5, the major activity eluting from the Sephadex G-200 column was found in fractions having LAP. A similar study of human lens extracts at pH 6. 9 and 8.5 showed one major peak with elution volume corresponding to that of purified bovine lens AP III: The human lens extracts displayed a very low level of LAP activity. The hydrolysis pattern of peptide substrates by AP III paralleled that of bovine and human lens extract at pH 6.9. The X-Pro bond resistant to LAP in peptide substrate, VHLTPVEK was hydrolyzed by AP III as well as lens extracts.

CONCLUSION

Both bovine and human lenses have very low LAP activity compared to AP III activity at in vivo pH 6.9. AP III, by its higher activity, broad specificity and its ability to cleave peptide bonds that are resistant to LAP, is likely to play a major role in lens during epithelial cell differentiation into fiber cells and complete hydrolysis of peptides generated in vivo.

Peptide hydrolysis in lens: role of leucine aminopeptidase, aminopeptidase III, prolyloligopeptidase and acylpeptidehydrolase

The distribution of leucine aminopeptidase, aminopeptidase III, prolyloligopeptidase and acylpeptidehydrolase activities in different regions of a bovine lens was determined and correlated with the distribution of crystallin fragments (measured as < 18 kDa protein) and water-insoluble proteins in the same lens. A gradient of activity was observed for all the peptidases tested, with the highest specific activity present in the cortical fibers which decreased to one half or below in the inner cortical fibers and nucleus. An inverse correlation between peptidase activities and the amount of crystallin fragments was observed in different regions of the lens. However, a direct correlation between the water-insoluble protein content and the crystallin fragments was observed in all fibers of the same lens. The amount of crystallin fragments and the amount of water-insoluble proteins increased from 2.7% and 8% in the outer cortical fibers to 13% and 68% in the nucleus of the same lens. The water-insoluble fraction from both cortical and nuclear fibers however displayed 4-5 fold more crystallin fragments compared to that present in the water-soluble fraction of the same preparation. When the bovine lens cortical and nuclear extracts were tested for their ability to hydrolyze the peptide substrate, Ile-Ser-bradykinin, the cortical extract was found to be at least ten times superior to the nuclear extract. Prior inactivation of prolyloligopeptidase and other serine proteases by diisopropylfluorophosphate however diminished the ability of the cortical extract to hydrolyze peptide substrates. Bovine lens cortical extract was able to completely hydrolyze alpha-melanocyte stimulating hormone as well as N-Acetyl-Met-Asp-Arg-Val-Leu-Ser-Arg-Tyr showing the presence of active acylpeptidehydrolase facilitating the complete hydrolysis of N-terminally blocked peptides. The human lens extract was found to contain both diisopropylfluorophosphate sensitive and resistant enzymes capable of hydrolyzing peptide substrates.

Purification and characterization of an aminopeptidase from tuna (Thunnus albacares) pyloric caeca

An aminopeptidase was purified from a water soluble fraction of tuna pyloric caeca by heat treatment, Zn2+ fractionation, ion exchange on a DEAE cellulose column, gel filtration on Fractogel TSK-55, and immobilized metal ion affinity chromatography (IMAC) on IDA(Cu2+/Zn2+)-Sepharose 6B. The molecular mass of the enzyme was estimated to be 150,000 on Sephacryl S-300 HR, and was found to be near 72,000 by SDS-PAGE. The aminopeptidase, which is a glycoprotein rich in acidic amino acids, is optimally active at pH 8.8 and 65 degrees C. The enzyme activity was not affected by Mg2+, Zn2+, Ca2+, Mn2+, Co2+, PMSF, iPr2FP, 4-hydroxymercuribenzoic acid, iodoacetamide, puromycin, and cysteine but it was strongly inhibited by metal chelators (EDTA and o-phenanthroline), amastatin, Hg2+, Cd2+, and Cu2+. The enzyme was also inhibited by some L-amino acids. Kinetic parameters of the enzyme were determined with some aminoacyl-p-nitroanilides and aminoacyl-beta-naphthylamides. L-Alanine-p-nitroanilide and L-alanine-beta-naphthylamide were hydrolysed most rapidly while the highest hydrolytic coefficient (kcat/Km) value was obtained with L-methionine-p-nitroanilide. The apoaminopeptidase was prepared and reconstitution of an active enzyme was carried out using metal chelating interaction chromatography on an IDA-Sepharose 6B column charged with a metal ion. Full activity was restored with Zn2+, Co2+, Cu2+ and Al3+. Zn(2+)-Enzyme was the most thermostable form of the aminopeptidase. Reversal inhibition by Cu2+ and Cd2+ was also examined. When the aminopeptidase was partially deglycosylated by a treatment with N-glycosidase F some of its physical properties differed from that of the native enzyme: its electrophoretic mobility was reduced and its stability to denaturation by SDS and by ionic strength were lower than those of the untreated enzyme. All together, our results indicate that the tuna pyloric caeca aminopeptidase is distinct from the peptide hydrolases characterized in the literature.

Description of an acylpeptide hydrolase from lens

Acylpeptide hydrolase, which catalyses the hydrolysis of blocked N-terminal amino acids from peptide substrates, has been identified in the extracts from beef, human, rabbit and rat lens. In bovine lens sections, lower activity was observed in nuclear and inner cortical regions compared to the outer cortical region. The enzyme from bovine lens showed a high molecular weight nature, eluting between alpha and beta crystallins during Sephadex G-200 chromatography. The activity has a pH optimum around 7.8 when assayed with N-acetyl-Ala-p-NA as substrate. The enzyme was capable of hydrolyzing a variety of blocked peptides including N-acetyl-(Ala)2, Me-O-Suc-Ala-Ala-Pro-Val-p-NA, N-Acetyl-Met-Leu-Phe, Acetyl-Ser-Gln-Asn-Tyr and N-formyl-Met-p-NA. In each case the enzyme released an N-blocked amino acid and exposed a free amino group as judged by thin layer chromatography. Neither Ala-p-NA nor N-acetyl-Ala were hydrolysed by the same enzyme preparation. The enzyme activity from human and bovine lens was completely inhibited by DFP, and partially inhibited by PMSF, penicillin-G and ampicillin. These preliminary results show that lens tissue has an active acylpeptide hydrolase, however, a partially purified enzyme preparations was not able to cleave the acetyl-Met- from native alpha A-crystallin in vitro suggesting that the N-terminus of native crystallins is not accessible to the enzymes.

Use of azidobestatin as a photoaffinity label to identify the active site peptide of leucine aminopeptidase

Aminopeptidases catalyze the hydrolysis of amino acid residues from the amino terminus of peptide substrates. They are found in most cells and tissues, and their activity has been implicated in myriad fundamental biochemical and physiological processes. Nevertheless, little is known about the structure of the aminopeptidase active sites. Beef lens leucine aminopeptidase (blLAP) can be considered prototypical of many enzymes in this family of peptidases. Bestatin, [(2S,3R)-(3-amino-2-hydroxy-4-phenyl-butanoyl)-L-leucine] is a nonhydrolyzable substrate analogue of a peptide, PheLeu, which is rapidly cleaved by blLAP. Bestatin incorporates elements of the putative tetrahedral intermediate, and this results in a greater than 10(5)-fold enhancement of binding relative to analogous peptides. Bestatin is the most tightly bound inhibitor of many aminopeptidases. Bestatin was successively converted to nitrobestatin, p-aminobestatin, [3H]-p-aminobestatin, and finally [3H]-p-azidobestatin (pAB). Like bestatin, pAB is a slow binding inhibitor of LAP (Ki*, the dissociation constant for the final complex, = approximately 4 x 10(-9); Ki, the dissociation constant for the initial collision complex, = approximately 10(-8). The t1/2 for binding of 2 x 10(-8) M and 8 x 10(-8) M bestatin are approximately 60 min and approximately 38 min, respectively. pAB, nitrobestatin, bestatin, and physiological peptides appear to bind in the same site, the first three with similar avidity. In the dark, pAB and bestatin protect low concentrations of the enzyme against inactivation upon extensive dialysis. The t1/2 for photoactivation of pAB is approximately 3 s. Irradiation of blLAP for such short periods of time resulted in insignificant change in activity. blLAP which was placed in 254-nm light in the presence of pAB was inactivated significantly. Treatment of photolabeled blLAP with trypsin produces only two peptides. Autoradiography and scintillation counting indicate that the active site is in the peptide which includes residues 138-487. Treatment of the same blLAP with hydroxylamine produces two different peptides, with the active site in the peptide 323-487. This indicates that the active site is in the carboxyl-terminal one-third of the protomer. It is likely that this photoaffinity label will be useful in identifying active sites in other aminopeptidases as well.

Protein oxidation and proteolytic degradation. General aspects and relationship to cataract formation

1) Intracellular proteins are subject to oxidative and photooxidative denaturation. 2) Proteolytic systems recognize and selectively degrade oxidatively denatured, and photooxidatively denatured proteins. By degrading mildly denatured proteins these proteolytic systems prevent further oxidative/photooxidative damage which could otherwise result in the formation of cross-linked (undigestible) proteins, or protein fragments with toxic biological activities. Proteolytic systems also provide amino acids for the synthesis of new (replacement) proteins. 3) A 700,000 dalton neutral endoproteinase, which we have called macroxyproteinase or M.O.P., appears to be mostly responsible for the degradation of oxidatively denatured proteins. M.O.P. has been shown to function in red blood cells and in the eye lens, and appears to also exist in many other mammalian cell types. 4) Cataract is a disease associated with aging, and with photooxidative denaturation (and cross-linking) of lens crystallins and other proteins. 5) Both cataract and aging of lens cells are associated with declining proteolytic capacity and diminished antioxidant protection. 6) Lens aging and in vivo photooxidative stress can cause opacity ("cataract"), cross-linking of crystallins, and diminished proteolytic capacity. 7) High levels of dietary ascorbate increase ascorbate concentrations in lens tissue, and are associated with greater resistance of lens proteins and lens proteolytic enzymes to oxidative/photooxidative stress in vitro.

Protease activities in cultured beef lens epithelial cells peak and then decline upon progressive passage

Beef lens cells in culture are readily obtained and provide many opportunities to study phenomena related to cell differentiation and maturation, environmental stress, disease, and perhaps mechanisms of transformation. Although altered rates of proteolysis are known to accompany these phenomena, the proteolytic activities available in cultured beef lens epithelial cells have not been documented. In this work are documented the specific activities, based on protein and DNA content, of neutral exo- and endopeptidase, cathepsins B- and D-like enzymes and acid phosphatase in lens epithelial cortical and core tissue and in cultured epithelial cells at passages 1-43. Maximal activity of each protease occurs almost routinely at passage 5 or 9, reaching values of approx. 1400-, 0.77-, 4520-nmol min-1 per mg protein for neutral exopeptidase (passage 5), neutral endopeptidase (passage 5) and cathepsin B (passage 5) respectively, and 7.1 micrograms trichloroacetic acid soluble peptide min-1 per mg protein for cathepsin D (passage 15). On a microgram-1 DNA basis, the maximal specific activities for the same enzymes were 48 (passage 5), 0.03 (passage 5), 283 (passage 9), and 0.5 (passage 9) respectively. In subsequent passages, the specific activities declined to values which were similar to or lower than the specific activities observed for these proteases in lens epithelial tissue.

Purification and characterization of an aminopeptidase from bovine cornea

An aminopeptidase from bovine cornea has been extensively purified by gel filtration and ion-exchange chromatography. The purified enzyme with a molecular weight of 96,000 showed broad substrate specificity. All of the various aminoacyl bonds were hydrolyzed optimally at pH 6.5. The purified enzyme showed hydrolytic activity towards bioactive peptides such as enkephalins, bradykinin, and angiotensin-II. The enzyme was inhibited by bestatin, amastatin, puromycin, bacitracin, sulfhydryl reagents and metal chelators. Only Co2+ stimulated the enzyme whereas other heavy metal ions were toxic. The gross properties of the corneal enzyme resemble those of an aminopeptidase III isolated from bovine lens.

Protein oxidation and loss of protease activity may lead to cataract formation in the aged lens

Over 95% of the dry mass of the eye lens consists of specialized proteins called crystallins. Aged lenses are subject to cataract formation, in which damage, cross-linking, and precipitation of crystallins contribute to a loss of lens clarity. Cataract is one of the major causes of blindness, and it is estimated that over 50,000,000 people suffer from this disability. Damage to lens crystallins appears to be largely attributable to the effects of UV radiation and/or various active oxygen species (oxygen radicals, 1O2, H2O2, etc.). Photooxidative damage to lens crystallins is normally retarded by a series of antioxidant enzymes and compounds. Crystallins which experience mild oxidative damage are rapidly degraded by a system of lenticular proteases. However, extensive oxidation and cross-linking severely decrease proteolytic susceptibility of lens crystallins. Thus, in the young lens the combination of antioxidants and proteases serves to prevent crystallin damage and precipitation in cataract formation. The aged lens, however, exhibits diminished antioxidant capacity and decreased proteolytic capabilities. The loss of proteolytic activity may actually be partially attributable to oxidative damage which proteases (like any other protein) can sustain. We propose that the rate of crystallin damage increases as antioxidant capacity declines with age. The lower protease activity of aged lens cells may be insufficient to cope with such rates of crystallin damage, and denatured crystallins may begin to accumulate. As the concentration of oxidatively denatured crystallins rises, cross-linking reactions may produce insoluble aggregates which are refractive to protease digestion. Such a scheme could explain many events which are known to contribute to cataract formation, as well as several which have appeared to be unrelated.(ABSTRACT TRUNCATED AT 250 WORDS)

Aminopeptidase III activity in normal and cataractous lenses

Aminopeptidase III activity was demonstrated in extracts from several different mammalian lenses by the hydrolysis of Arg-MCA at pH 6.0. No more than a two-fold difference was seen in overall specific activity. Sections of bovine lenses were removed from the periphery to the center and assayed. A sharp decline in activity was observed in the inner cortical region, and little or no activity was observed in the lens nucleus. This correlated with an increase in the presence of low molecular weight peptides as determined by SDS polyacrylamide gel electrophoresis. The properties of the aminopeptidase from human lens tissue were the same as those previously reported for the purified enzyme from bovine lens. The aminopeptidase activity of normal and cataractous lenses was compared using 4 different substrates. The cataractous lenses had significantly less total aminopeptidase activity. However, little difference in specific activity was observed based on soluble lens protein content. Similarly, electrophoretic separations of normal and cataractous soluble proteins showed little or no differences in the content of low molecular weight peptides. Therefore, this major human lens aminopeptidase remains functional in the cataractous state.