Purification and biochemical characterization of a lysosomal α-fucosidase from the deuterostomia Asterias rubens

In vertebrates, mannose 6-phosphate receptors [MPR300 (Mr 300 kDa) and MPR46 (Mr 46 kDa)] are highly conserved transmembrane glycoproteins that mediate transport of lysosomal enzymes to lysosomes. Our studies have revealed the appearance of these putative receptors in invertebrates such as the molluscs and deuterostomes. Starfish tissue extracts contain several lysosomal enzyme activities and here we describe the affinity purification of α-fucosidase. The purified enzyme is a glycoprotein that exhibited a molecular mass of ∼56 kDa in SDS-PAGE under reducing conditions. It has also cross-reacted with an antiserum to the mollusc enzyme suggesting antigenic similarities among the two invertebrate enzymes. LC–MS/MS analysis of the proteolytic peptides of the purified enzyme in combination with de novo sequencing allowed us to do partial amino acid sequence determination of the enzyme. These data suggest that this invertebrate enzyme is homologous to the known mammalian enzyme. The purified enzyme exhibited a mannose 6-phosphate dependent interaction with the immobilized starfish MPR300 protein. Our results demonstrate that the lysosomal enzyme targeting pathway is conserved even among the invertebrates.     

Biochemical and functional characterization of cation dependent (Mr 46,000) goat mannose 6-phosphate receptor

The Mannose 6-phosphate receptor (MPR’s) proteins are important for transporting lysosomal enzymes from trans-golgi to the pre-lysosomal compartment. These are conserved in the vertebrates from fish to mammals. We have cloned the full length cDNA for the goat MPR 46 protein and compared its sequences to the other known vertebrate MPR 46 proteins. In the present study the full-length cDNA for the goat MPR 46 protein was expressed in MPR deficient cells. The expressed protein was purified on the multivalent phosphomannan gel in the presence of divalent metal ions. The apparent molecular mass of the expressed protein was found to be ∼46 kDa and also exhibits oligomeric nature as observed in the other species, by using an MSC1 antibody (that recognizes the MPR 46 from molluscs to mammals) as well as with a peptide specific antibody corresponding to amino acid residues (218–237) of the cytoplasmic tail of human MPR 46 protein. Furthermore the distribution of the expressed protein was visualized by immunofluorescence using MSC1 and LAMP1 antibody. Additionally in the goat MPR 46 expressing cells, the sorting function of the expressed protein to sort cathepsin D to lysosomes was studied by confocal microscopy using cathepsin D antiserum and LAMP1 antibody. The binding of goat MPR 46 to cathepsin D was shown in far Western blotting and the mannose 6-phosphate dependent binding was shown by co-immunoprecipitation.     

Biochemical and immunological characterization of a glycosylated alpha-fucosidase from the invertebrate Unio: interaction of the enzyme with its in vivo binding partners

Mammalian alpha-fucosidase (EC 3.2.1.51) is a lysosomal enzyme that catalyzes the removal of fucose residues from glycosphingolipids and its absence in humans results in a rare metabolic disorder called fucosidosis. Among the invertebrates in the molluscs (Unio) two forms of the enzyme have been reported, a 68 kDa non-glycosylated form and a 56 kDa glycosylated form. The glycosylated form has been purified from the seminal fluid of Unio [Biochem. Biophys. Res. Commun. 234 (1997) 54]. In the present study, the 56 kDa glycosylated form has been purified to homogeneity from the whole body tissue of Unio using a series of chromatographic steps. The purified enzyme migrated as a single protein species in 10% SDS-PAGE. Antibodies to the purified enzyme were raised in a rabbit in order to study its biochemical and immunological properties. The purified enzyme is a glycoprotein that exhibits strong binding to Con A-Sepharose gel and can be deglycosylated by PNGase F enzyme suggesting it to be N-glycosylated. The enzyme has been shown to specifically interact with the mannose 6-phosphate receptor protein (MPR 300) purified from goat and Unio. This specific interaction is discussed in view of its possible in vivo binding partners.     

Mannose-6-phosphate receptors (MPR 300 and 46) from the highly evolved invertebrate <Emphasis Type="Italic">Asterias rubens</Emphasis> (Echinodermate): biochemical and functional characterization of MPR 46 protein

Mammalian mannose 6-phosphate receptors (MPR 300 and 46) mediate transport of lysosomal enzymes to lysosomes. Recent studies established that the receptors are conserved throughout vertebrates. Although we purified the mollusc receptors and identified only a lysosomal enzyme receptor protein (LERP) in the Drosophila melanogaster, little is known about their structure and functional roles in the invertebrates. In the present study, we purified the putative receptors from the highly evolved invertebrate, starfish, cloned the cDNA for the MPR 46, and expressed it in mpr^(−/−) mouse embryonic fibroblast cells. Structural comparison of starfish receptor sequences with other vertebrate receptors gave valuable information on its extensive structural homology with the vertebrate MPR 46 proteins. The expressed protein efficiently sorts lysosomal enzymes within the cells establishing a functional role for this protein. This first report on the invertebrate MPR 46 further confirms the structural and functional conservation of the receptor not only in the vertebrates but also in the invertebrates.     

Molecular cloning, expression and functional characterization of the chicken cation dependent mannose 6-phosphate receptor protein

Mammalian mannose 6-phosphate (M6P) receptors function in transport of lysosomal enzymes. To understand the structural and functional significance of the chicken cation dependent mannose 6-phosphate receptor (MPR) (Mr 46kDa), a full-length cDNA for the chicken protein was cloned and expressed in mpr((-/-)) MEF cells devoid of both the receptors. The stably transfected cells express the receptor that could be affinity purified by phosphomannan chromatography. The authenticity of the receptor was confirmed by its immuno-reactivity with mammalian MPR 46 antibodies and its ability to sort cathepsin D in transfected cells (92.3%) as compared to mock transfected cells (50.2%), establishing a functional role for the chicken receptor.     

Identification of the putative mannose 6-phosphate receptor (MPR 46) protein in the invertebrate mollusc

Mannose 6-phosphate receptor (MPR 300) protein was earlier affinity purified on phosphomannan gel from the membrane extracts of whole animal acetone powder of a mollusc, unio, in the presence of EDTA (Udaya Lakshmi, Y., Radha, Y., Hille-Rehfeld, A., von Figura, K., and Siva Kumar, N. (1999) Biosci. Rep. 19:403–409). In the present study we demonstrate that the unio also contains the putative mannose 6-phosphate receptor (MPR 46) that can be purified on the same gel in presence of divalent metal ions (10 mM each of calcium, manganese, and magnesium), and in the absence of sodium chloride and at pH 6.5. Chicken and Fish cell MPR 46 proteins were purified under these conditions (Siva Kumar, N., Udaya Lakshmi, Y., Hille-Rehfeld, A., and von Figura, K. (1999) Comp. Biochem. & Physiol. 123B:261–265). The authenticity of the receptor is further confirmed by its ability to react with the MSC1 antibody that is specific for MPR 46 protein. Additional evidence for the presence of MPR 46 in molluscs could be obtained by metabolic labeling of mollusc cells Biomphalaria glabrata (Bg cells) with [³⁵S] methionine and cysteine, and passing the labeled membrane extract on phosphomannan gel (at pH 6.5 and 7.0). On elution with mannose 6-phosphate, followed by immunoprecipitation of the column fractions, we identified the putative MPR 46 protein in the Bg cells. When Bg cell MPR 46 was deglycosylated along with chicken MPR 46 (control) both species yielded a single polypeptide corresponding to molecular mass of 26 kDa, suggesting that both contain the same receptor protein.     

Proteomics analysis of serum from mutant mice reveals lysosomal proteins selectively transported by each of the two mannose 6-phosphate receptors

Most mammalian cells contain two types of mannose 6-phosphate (Man-6-P) receptors (MPRs): the 300 kDa cation-independent (CI) MPR and 46 kDa cation-dependent (CD) MPR. The two MPRs have overlapping function in intracellular targeting of newly synthesized lysosomal proteins, but both are required for efficient targeting. Despite extensive investigation, the relative roles and specialized functions of each MPR in targeting of specific proteins remain questions of fundamental interest. One possibility is that most Man-6-P glycoproteins are transported by both MPRs, but there may be subsets that are preferentially transported by each. To investigate this, we have conducted a proteomics analysis of serum from mice lacking either MPR with the reasoning that lysosomal proteins that are selectively transported by a given MPR should be preferentially secreted into the bloodstream in its absence. We purified and identified Man-6-P glycoproteins and glycopeptides from wild-type, CDMPR-deficient, and CIMPR-deficient mouse serum and found both lysosomal proteins and proteins not currently thought to have lysosomal function. Different mass spectrometric approaches (spectral count analysis of nanospray LC-MS/MS experiments on unlabeled samples and LC-MALDI/TOF/TOF experiments on iTRAQ-labeled samples) revealed a number of proteins that appear specifically elevated in serum from each MPR-deficient mouse. Man-6-P glycoforms of cellular repressor of E1A-stimulated genes 1, tripeptidyl peptidase I, and heparanase were elevated in absence of the CDMPR and Man-6-P glycoforms of alpha-mannosidase B1, cathepsin D, and prosaposin were elevated in the absence of the CIMPR. Results were confirmed by Western blot analyses for select proteins. This study provides a comparison of different quantitative mass spectrometric approaches and provides the first report of proteins whose cellular targeting appears to be MPR-selective under physiological conditions.     

Identification and characterization of cathepsin D in a highly purified sialidase from starfish A. pectinifera

A sialidase [EC 3.2.1.18] from the ovary of starfish Asterina pectinifera was isolated and highly purified by preparative PAGE. The SDS-PAGE separation of the purified enzyme revealed two natures of protein bands, upper (50 kDa) and a lower (47 kDa). To identify the protein, N-terminal amino acid sequence of the upper band was done. The sequence matched with the N-terminal amino acid sequence of human lysosomal mature cathepsin D and cathepsin D activity was also found in all the preparation steps. Protease inhibitor pepstatin A inhibited the proteolysis activity of cathepsin D against a synthetic substrate. The two enzymes sialidase and cathepsin D were separated from each other by using high-performance gel-filtration chromatography. The Western blot analysis and isoelectric focusing showed the co-purified cathepsin D is a 50 kDa protein with a PI value of 4.2.     

Biochemical Characterization of a Lysosomal α-Mannosidase from the Starfish <Emphasis Type="Italic">Asterias rubens</Emphasis>

Acidic α-mannosidase is an important enzyme and is reported from many different plants and animals. Lysosomal α-mannosidase helps in the catabolism of glycoproteins in the lysosomes thereby playing a major role in cellular homeostasis. In the present study lysosomal α-mannosidase from the gonads of echinoderm Asterias rubens was isolated and purified. The crude protein sample from ammonium sulfate precipitate contained two isoforms of mannosidase as tested by the MAN2B1 antibody, which were separated by anion exchange chromatography. Enzyme with 75 kDa molecular weight was purified and biochemically characterized. Optimum pH of the enzyme was found to be in the range of 4.5–5 and optimum temperature was 37 °C. The activity of the enzyme was inhibited completely by swainsonine but not by 1-deoxymannojirimycin. Ligand blot assays showed that the enzyme can interact with both the lysosomal enzyme sorting receptors indicating the presence of mannose 6-phosphate in the glycan surface of the enzyme. This is the first report of lysosomal α-mannosidase in an active monomeric form. Its interaction with the receptors suggest that the lysosomal enzyme targeting in echinoderms might follow a mannose 6-phosphate mediated pathway similar to that in the vertebrates.     

Mannose 6-phosphate-independent membrane association of cathepsin D, glucocerebrosidase, and sphingolipid-activating protein in HepG2 cells.

The membrane association of the lysosomal enzymes cathepsin D and glucocerebrosidase and its naturally occurring sphingolipid activating protein was studied in HepG2 cells. We differentially permeabilized cells with low concentrations of saponin, at which secretory proteins rinsed out completely, whereas integral membrane proteins were not released. All relevant intracellular compartments were shown to be permeabilized by saponin. Metabolic labeling showed that early precursors of cathepsin D, sphingolipid activating protein, and glucocerebrosidase were completely released from the cells, whereas more than 80% of the high molecular mass intermediates were retained by the cells. Treatment of permeabilized cells with 10 mM mannose 6-phosphate released only 50% of the cell-associated cathepsin D. Glucocerebrosidase remained membrane-associated, but cathepsin D and sphingolipid activating protein were released from the cells after proteolytic processing. Sphingolipid activating proteins and cathepsin D behaved similarly during biosynthesis and showed similar sensitivity to mannose 6-phosphate. The membrane association of the intermediate form of cathepsin D was independent of the presence of N-linked oligosaccharides. Subcellular fractionation on sucrose gradients showed that the lysosomal proteins became membrane-associated probably in the Golgi complex, and that both mannose 6-phosphate-dependent and mannose 6-phosphate-independent membrane association occur in the same compartments. We conclude that, in HepG2 cells, cathepsin D, sphingolipid activating protein, and glucocerebrosidase exhibit MPR-independent membrane association which is acquired in the same compartments beyond the rough endoplasmic reticulum.     

Purification and characterization of recombinant human alpha-N-acetylglucosaminidase secreted by Chinese hamster ovary cells

alpha-N-Acetylglucosaminidase (EC 3.2.1.50) is a lysosomal enzyme that is deficient in the genetic disorder Sanfilippo syndrome type B. To study the human enzyme, we expressed its cDNA in Lec1 mutant Chinese hamster ovary (CHO) cells, which do not synthesize complex oligosaccharides. The enzyme was purified to apparent homogeneity from culture medium by chromatography on concanavalin A-Sepharose, Poros 20-heparin, and aminooctyl-agarose. The purified enzyme migrated as a single band of 83 kDa on SDS-PAGE and as two peaks corresponding to monomeric and dimeric forms on Sephacryl-300. It had an apparent K(m) of 0.22 mM toward 4-methylumbelliferyl-alpha-N-acetylglucosaminide and was competitively inhibited by two potential transition analogs, 2-acetamido-1,2-dideoxynojirimycin (K(i) = 0.45 microM) and 6-acetamido-6-deoxycastanospermine (K(i) = 0.087 microM). Activity was also inhibited by mercurials but not by N-ethylmaleimide or iodoacetamide, suggesting the presence of essential sulfhydryl residues that are buried. The purified enzyme preparation corrected the abnormal [(35)S]glycosaminoglycan catabolism of Sanfilippo B fibroblasts in a mannose 6-phosphate-inhibitable manner, but its effectiveness was surprisingly low. Metabolic labeling experiments showed that the recombinant alpha-N-acetylglucosaminidase secreted by CHO cells had only a trace of mannose 6-phosphate, probably derived from contaminating endogenous CHO enzyme. This contrasts with the presence of mannose 6-phosphate on naturally occurring alpha-N-acetylglucosaminidase secreted by diploid human fibroblasts and on recombinant human alpha-l-iduronidase secreted by the same CHO cells. Thus contrary to current belief, overexpressing CHO cells do not necessarily secrete recombinant lysosomal enzyme with the mannose 6-phosphate-targeting signal; this finding has implications for the preparation of such enzymes for therapeutic purposes.     

Human and hamster procathepsin D, although equally tagged with mannose-6-phosphate, are differentially targeted to lysosomes in transfected BHK cells

BHK cells transfected with human cathepsin D (CD) cDNA normally segregate the autologous hamster cathepsin D while secreting a large proportion of the human proenzyme. In the present work, we have utilized these transfectants to examine to what extent the mannose-6-phosphate-dependent pathway for lysosomal enzyme segregation contributes to the differential sorting of human and hamster CD. We report that, in recipient control BHK cells, the rate of mannose-6-phosphate-dependent endocytosis of human procathepsin D secreted by transfected BHK cells is lower than that of hamster procathepsin D and much lower than that of human arylsulphatase A. The missorted human enzyme bears phosphorylated oligosaccharides and most of its phosphate residues are “uncovered”, like the autologous enzyme. Thus, despite both the Golgi-associated modifications of oligosaccharides, i.e. the phosphorylation of mannose and the uncovering of mannose-6-phosphate residues, which proceed on human and hamster procathepsin D with comparable efficiency, only the latter is accurately packaged into lysosomes. Ammonium chloride partially affects the lysosomal targeting of cathepsin D in control BHK cells, whereas in transfected cells, this drug strongly inhibits the maturation of human procathepsin D and slightly enhances its secretion. These data indicate that: (1) over-expression of a lysosomal protein does not saturate the Golgi-associated reactions leading to the synthesis of mannose-6-phosphate; (2) a portion of cathepsin D is targeted independently of mannose-6-phosphate receptors in the transfected BHK cells; and (3) whichever mechanism for lysosomal delivery of autologous procathepsin D is involved, this is not saturated by the high rate of expression of human cathepsin D.     

A His-Leu-Leu sequence near the carboxyl terminus of the cytoplasmic domain of the cation-dependent mannose 6-phosphate receptor is necessary for the lysosomal enzyme sorting function.

The determinants on the cytoplasmic tail of the cation-dependent mannose 6-phosphate receptor (CD-MPR) required for lysosomal enzyme sorting have been analyzed. Mouse L cells deficient in the mannose 6-phosphate/insulin-like growth factor-II receptor were transfected with normal bovine CD-MPR cDNA or cDNAs containing mutations in the 67-amino acid cytoplasmic tail and assayed for their ability to target the lysosomal enzyme cathepsin D to lysosomes. Cells expressing the wild-type bovine CD-MPR sorted 67 +/- 2% of newly synthesized cathepsin D compared with the base-line value of 47 +/- 1%. The presence of mannose 6-phosphate in the medium did not affect the efficiency of cathepsin D sorting, indicating that the routing of the ligand-receptor complex is completely intracellular. Mutant receptors with the carboxyl-terminal His-Leu-Leu-Pro-Met67 residues deleted or replaced with alanines sorted cathepsin D below the base-line value. A mutant receptor with the outermost Pro-Met residues replaced with alanines sorted cathepsin D better than the wild-type receptor, indicating that the essential residues for sorting are the His-Leu-Leu sequence. Disruption of a putative casein kinase II phosphorylation site at Ser57 had no detectable effect on sorting. The mutant receptor with the five-amino acid deletion was able to bind to a phosphopentamannose affinity column, proving that its ligand binding site was grossly intact. Resialylation experiments showed that this mutant receptor recycled from the cell surface to the Golgi at a rate similar to the normal CD-MPR, indicating that the defect in sorting is at the level of the Golgi.     

Identification of novel lysosomal matrix proteins by proteome analysis

The lysosomal matrix is estimated to contain about 50 different proteins. Most of the matrix proteins are acid hydrolases that depend on mannose 6-phosphate receptors (MPR) for targeting to lysosomes. Here, we describe a comprehensive proteome analysis of MPR-binding proteins from mouse. Mouse embryonic fibroblasts defective in both MPR (MPR 46-/- and MPR 300-/-) are known to secrete the lysosomal matrix proteins. Secretions of these cells were affinity purified using an affinity matrix derivatized with MPR46 and MPR300. In the protein fraction bound to the affinity matrix and eluted with mannose 6-phosphate, 34 known lysosomal matrix proteins, 4 candidate proteins of the lysosomal matrix and 4 non-lysosomal contaminants were identified by mass spectrometry after separation by two-dimensional gel electrophoresis or by multidimensional protein identification technology. For 3 of the candidate proteins, mammalian ependymin-related protein-2 (MERP-2), retinoid-inducible serine carboxypeptidase (RISC) and the hypothetical 66.3-kDa protein we could verify that C-terminally tagged forms bound in an M6P-dependent manner to an MPR-affinity matrix and were internalized via MPR-mediated endocytosis. Hence these 3 proteins are likely to represent hitherto unrecognized lysosomal matrix proteins.     

Recombinant expression, localization and in vitro inhibition of midgut cysteine peptidase (Sl-CathL) from sugarcane weevil, Sphenophorus levis

A cDNA coding for a digestive cathepsin L, denominated Sl-CathL, was isolated from a cDNA library of Sphenophorus levis larvae, representing the most abundant EST (10.49%) responsible for proteolysis in the midgut. The open reading frame of 972 bp encodes a preproenzyme similar to midgut cathepsin L-like enzymes in other coleopterans. Recombinant Sl-CathL was expressed in Pichia pastoris, with molecular mass of about 42 kDa. The recombinant protein was catalytically activated at low pH and the mature enzyme of 39 kDa displayed thermal instability and maximal activity at 37 °C and pH 6.0. Immunocytochemical analysis revealed Sl-CathL production in the midgut epithelium and secretion from vesicles containing the enzyme into the gut lumen, confirming an important role for this enzyme in the digestion of the insect larvae. The expression profile identified by RT-PCR through the biological cycle indicates that Sl-CathL is mainly produced in larval stages, with peak expression in 30-day-old larvae. At this stage, the enzyme is 1250-fold more expressed than in the pupal fase, in which the lowest expression level is detected. This enzyme is also produced in the adult stage, albeit in lesser abundance, assuming the presence of a different array of enzymes in the digestive system of adults. Tissue-specific analysis revealed that Sl-CathL mRNA synthesis occurs fundamentally in the larval midgut, thereby confirming its function as a digestive enzyme, as detected in immunolocalization assays. The catalytic efficiency of the purified recombinant enzyme was calculated using different substrates (Z-Leu-Arg-AMC, Z-Arg-Arg-AMC and Z-Phe-Arg-AMC) and rSl-CathL exhibited hydrolysis preference for Z-Leu-Arg-AMC (k_cat/K_m = 37.53 mM S⁻¹), which is similar to other insect cathepsin L-like enzymes. rSl-CathL activity inhibition assays were performed using four recombinant sugarcane cystatins. rSl-CathL was strongly inhibited by recombinant cystatin CaneCPI-4 (K_i = 0.196 nM), indicating that this protease is a potential target for pest control.     

A cathepsin B-like enzyme from mackerel white muscle is a precursor of cathepsin B

A cathepsin B-like enzyme from the white muscle of common mackerel Scomber japonicus was a cysteine protease that hydrolyzed Z-Arg-Arg-MCA, the substrate for cathepsin B. In a partial purified cathepsin B-like enzyme preparation at 4 degrees C left over time, a converted enzyme that hydrolyzes Z-Arg-Arg-MCA and Z-Phe-Arg-MCA appeared in the preparation. The converted enzyme was purified from the cathepsin B-like enzyme, characterized and was identified as mackerel cathepsin B. These results suggested that the mackerel cathepsin B-like enzyme was a precursor of cathepsin B. Mackerel cathepsin B formed in the purified cathepsin B-like enzyme preparation by adding of a small amount of the purified cathepsin B to the preparation. Therefore, mackerel cathepsin B-like enzyme was converted to the mature form of cathepsin B by autoactivation. The conversion of the cathepsin B-like enzyme (molecular mass 60 kDa) to cathepsin B (molecular mass 23 kDa) was detected by immunoblotting by using human anti-(cathepsin B) antibody. The intermediate forms of 40 kDa and 38 kDa were also detected during the conversion.     

Fibroblast chemotaxis and prolidase activity modulation by insulin-like growth factor II and mannose 6-phosphate

Chemotactic locomotion of fibroblasts requires extensive degradation of extracellular matrix components. The degradation is provided by a variety of proteases, including lysosomal enzymes. The process is regulated by cytokines. The present study shows that mannose 6-phosphate and insulin-like growth factor II (IGF-II) enhance fibroblast chemotaxis toward platelet-derived growth factor (PDGF). It is suggested that lysosomal enzymes (bearing mannose 6-phosphate molecules) are involved in chemotactic activity of the cells. The suggestion is supported by the observation that a-mannosidase and cathepsin D inhibitor - pepstatin are very potent inhibitors of fibroblast chemotaxis. Simultaneously, mannose 6-phosphate stimulates extracellular collagen degradation. The final step in collagen degradation is catalyzed by the cytosolic enzyme - prolidase. It has been found that mannose 6-phosphate stimulates also fibroblast prolidase activity with a concomitant increase in lysosomal enzymes activity. The present study demonstrates that the prolidase activity in fibroblasts may reflect the chemotactic activity of the cells and suggests that the mechanism of cell locomotion may involve lysosomal enzyme targeting, probably through IGF-II/mannose 6-phosphate receptor.     

Purification and characterization of a lysosomal aspartic protease with cathepsin D activity from the mosquito

A lysosomal aspartic protease with cathepsin D activity, from the mosquito, Aedes aegypti, was purified and characterized. Its isolation involved ammonium sulfate (30–50%) and acid (pH 2.5) precipitations of protein extracts from whole previtellogenic mosquitoes followed by cation exchange chromatography. Purity of the enzyme was monitored by SDS-PAGE and silver staining of the gels. The native molecular weight of the purified enzyme as determined by polyacrylamide gel electrophoresis under nondenaturing conditions was 80,000. SDS-PAGE resolved the enzyme into a single polypeptide with M_r = 40,000 suggesting that it exists as a homodimer in its non-denatured state. The pI of the purified enzyme was 5.4 as determined by isoelectric focusing gel electrophoresis. The purified enzyme exhibits properties characteristic of cathepsin D. It utilizes hemoglobin as a substrate and its activity is completely inhibited by pepstatin-A and 6M urea but not by 10 mM KCN. Optimal activity of the purified mosquito aspartic protease was obtained at pH 3.0 and 45°C. With hemoglobin as a substrate the enzyme had an apparent K_m of 4.2 μ M. Polyclonal antibodies to the purified enzyme were raised in rabbits. The specificity of the antibodies to the enzyme was verified by immunoblot analysis of crude mosquito extracts and the enzyme separated by both non-denaturing and SDS-PAGE. Density gradient centrifugation of organelles followed by enzymatic and immunoblot analyses demonstrated the lysosomal nature of the purified enzyme. The N-terminal amino acid sequence of the purified mosquito lysosomal protease (19 amino acids) has 74% identity with N-terminal amino acid sequence of porcine and human cathepsins D.     

Drug-induced phospholipidosis is caused by blockade of mannose 6-phosphate receptor-mediated targeting of lysosomal enzymes

Cationic amphiphilic drugs (CADs) cause massive intracellular accumulation of phospholipids, thereby resulting in phospholipidosis (PLD); however, the molecular mechanism underlying CAD-induced PLD remains to be resolved. Here, we found that treatment of normal rat kidney cells with CADs known to induce PLD caused redistribution of a mannose 6-phosphate/IGF-II receptor (MPR300) from the TGN to endosomes and concomitantly increased the secretion of lysosomal enzymes, resulting in a decline of intracellular lysosomal enzyme levels. These results enable the interpretation of why CADs cause excessive accumulation of undegraded substrates, including phospholipids in lysosomes, and led to the conclusion that the impaired MPR300-mediated sorting system of lysosomal enzymes reflects the general mechanism of CAD-induced PLD. In addition, our findings suggest that the measurement of lysosomal enzyme activity secreted into culture medium is useful as a rapid and convenient in vitro early screening system to predict drugs that can induce PLD.     

Biochemical characterization of pea ornithine-δ-aminotransferase: Substrate specificity and inhibition by di- and polyamines

Ornithine-δ-aminotransferase (OAT, EC 2.6.1.13) catalyzes the transamination of l-ornithine to l-glutamate-γ-semialdehyde. The physiological role of OAT in plants is not yet well understood. It is probably related to arginine catabolism resulting in glutamate but the enzyme has also been associated with stress-induced proline biosynthesis. We investigated the enzyme from pea (PsOAT) to assess whether diamines and polyamines may serve as substrates or they show inhibitory properties. First, a cDNA coding for PsOAT was cloned and expressed in Escherichia coli to obtain a recombinant protein with a C-terminal 6xHis tag. Recombinant PsOAT was purified under native conditions by immobilized metal affinity chromatography and its molecular and kinetic properties were characterized. Protein identity was confirmed by peptide mass fingerprinting after proteolytic digestion. The purified PsOAT existed as a monomer of 50 kDa and showed typical spectral properties of enzymes containing pyridoxal-5′-phosphate as a prosthetic group. The cofactor content of PsOAT was estimated to be 0.9 mol per mol of the monomer by a spectrophotometric analysis with phenylhydrazine. l-Ornithine was the best substrate (K_m = 15 mM) but PsOAT also slowly converted N_α-acetyl-l-ornithine. In these reactions, 2-oxoglutarate was the exclusive amino group acceptor (K_m = 2 mM). The enzyme had a basic optimal pH of 8.8 and displayed relatively high temperature optimum. Diamines and polyamines were not accepted as substrates. On the other hand, putrescine, spermidine and others represented weak non-competitive inhibitors. A model of the molecular structure of PsOAT was obtained using the crystal structure of human OAT as a template.