Determination of N-acetylhexosamines in the presence of -SH compounds

The procedure of Reissig et al. [Reissig, J. L., Strominger, J. L., and Leloir, L. F. (1955) J. Biol. Chem.217, 959–966] for the determination of N-acetylhexosamines has been modified for use in the presence of -SH compounds by alkylation of -SH groups with iodoacetate.     

Activation and inhibition of human cancer cell hyaluronidase by proteins

Results regarding hyaluronidase activity in tumor extracts or cell lines are subject to variations according to the method used for the assay and, sometimes, within an assay. Hyaluronidase was assayed at pH 3.8 in the culture medium of the human cancer-derived cell lines SA87 and H460M by several techniques: HPLC, Reissig technique, ELSA technique, and zymographic analysis. The optimal pH was between 3.3 and 4 in solutions at constant 150 mM sodium concentration. The enzyme was reversibly inhibited by sodium concentration over 200 mM. The activity of purified hyaluronidase increased in the presence of low concentrations of the specific HA-binding glycoprotein hyaluronectin, or of bovine serum albumin or immunoglobulins, or of human albumin, transferrin, or hemoglobin, showing that proteins cooperate in enzyme activity. The ELSA technique showed that optimal pH was slightly lower in the presence of HN than that with BSA. The optimal BSA concentration was determined with the ELSA technique at 0.1 g/liter, and excess of either protein inhibited hyaluronidase. When measured with the Reissig technique, the activity of purified enzyme in the presence of 0.1 g/liter BSA was up to fourfold that without BSA. The cooperative effect of BSA was visualized by zymography. We conclude that the total protein content of hyaluronidase solutions must be considered to correctly interpret quantitation of the enzyme in sera or tissue extracts because protein concentrations above 200 microg/liter lead to underestimation of the enzyme.     

A convenient plate assay for the quantitation of hyaluronidase in hymenoptera venoms

A simple plate assay for hyaluronidase activity in biological samples is described. Hyaluronic acid is incorporated into agarose gels and the enzyme is allowed to diffuse from punched wells. The undigested hyaluronic acid is then precipitated with cetylpyridinium chloride and the diameters of the clear circles are proportional to the logarithm of the enzyme concentration applied to the well. The assay was utilized to examine commercially available hymenoptera venoms, manufactured for use in allergy diagnosis and treatment, for their content of hyaluronidase as a measure of lot-to-lot consistency. The assay permits the analyses of a large number of samples with good reproducibility, without the need for any special instrumentation. Based on the quantity of purified hyaluronidase reported in honey bee venom (T. P. King, A. K. Sobotka, L. Kochoumian, and L. M. Lichtenstein, 1976, Arch. Biochem. Biophys.172, 661–671) we estimate that the assay should detect 70 ng/ml of purified honey bee venom hyaluronidase.     

Investigation of the pH dependence of proton uptake by porcine heart mitochondrial malate dehydrogenase upon binding of NADH

The pH dependence of proton uptake upon binding of NADH to porcine heart mitochondrial malate dehydrogenase (l-malate: NAD⁺ oxidoreductase, EC 1.1.1.37) has been investigated. The enzyme has been shown to exhibit a pH-dependent uptake of protons upon binding NADH at pH values from 6.0 to 8.5. Enzyme in which one histidine residue has been modified per subunit by the reagent iodoacetamide (E. M. Gregory, M. S. Rohrbach, and J. H. Harrison, 1971, Biochim. Biophys. Acta253, 489–497) was used to establish that this specific histidine residue was responsible for the uptake of a proton upon binding of NADH to the native enzyme. It has also been established that while there is no enhancement of the nucleotide fluorescence upon addition of NADH to the iodoacetamide-modified enzyme, NADH is nevertheless binding to the modified enzyme with the same stoichiometry as with native enzyme. The data are discussed in relation to the involvement of the essential histidine residue in the catalytic mechanism of “histidine dehydrogenases” recently proposed by Lodola et al. (A. Lodola, D. M. Parker, R. Jeck, and J. J. Holbrook, 1978, Biochem. J.173, 597–605) and the catalytic mechanism of “malate dehydrogenases” recently proposed by L. H. Bernstein and J. Everse (1978, J. Biol. Chem.253, 8702–8707).     

Hyaluronidase in sera of tumour-bearing nude mice

Cancer cell lines often secrete hyaluronidase, suggesting that this enzyme could be used as a marker of growing tumours. We have measured hyaluronidase in the sera of non-grafted mice and mice grafted with human tumour-derived hyaluronidase-secreting H460M and SA87 cells or non-secreting CB 193 cells. Mouse serum hyaluronidase was measured at pH 3.8 using the enzyme-linked sorbent assay (ELSA) technique by reference to human serum whose activity at pH 3.8 was determined by the Reissig technique. The serum hyaluronidase in non-grafted mice ranged from 310-520 mU l^?1 (mean±SD 432±70 mU l^?1, median 440 mU l^?1). Hyaluronidase increased in the sera of tumour-bearing mice grafted with H460M cells or with SA87 cells, but not in the sera of mice grafted with CB 193 cells. Serum hyaluronidase activity in H460M or SA87 tumour-bearing mice correlated with the tumour mass, increased with time, and decreased after tumour removal. Zymography detected two different hyaluronidase forms in the sera of non-grafted mice: type 1 had only one hyaluronidase band and type 2 had five different bands. In both types, enzyme augmentation in tumour-bearing mice correlated with the presence of an additional enzyme band that was not seen in normal sera and that migrated as the cancer cell enzyme did; there was no augmentation of the normal isoform(s). These results show that serum hyaluronidase can be used to follow the development of tumours in mice grafted with hyaluronidase-secreting cells.     

Purification and properties of protein methylase II

Protein methylase II (S-adenosyl-methionine:protein-carboxyl methyltransferase) from calf thymus was purified approximately 2400-fold with a yield of 7% by incorporating the pH 5.1 treatment and QAE (triethylaminoethyl)-Sephadex column chromatography to the published purification steps (Kim and Paik (1970) J. Biol. Chem., 245, 1806). The enzyme is found stable at pH 10.2, but loses 50% of its activity in 60 min at pH 5. The enzyme activity disappeared in 8 m urea 2.5 m guanidine hydrochloride at pH 8.0. However, about 80% of the activity returned upon dialysis of the mixture. The highly purified enzyme is stable for at least 2 yr in the presence of 50% glycerol at pH 8.0 or in the form of lyophilized powder. Protein methylase II from different tissues exhibits different pI values, determined by isoelectrofocusing; 4.85 with the enzyme preparation isolated from calf thymus, 5.8 from calf spleen, and 5.08 from rat testis. Reinvestigation of the methanol-forming enzyme system from calf posterior pituitary gland by Axelrod and Daly [Science 150, 892 (1965)] indicated that this enzyme is identical with protein methylase II.     

The carbon dioxide hydration activity of brush-border carbonic anhydrase from the dog kidney

The steady-state kinetic parameters for the hydration of CO₂ catalyzed by membrane-bound carbonic anhydrase from the renal brush-border of the dog are compared with the same parameters for water-soluble bovine erythrocyte carbonic anhydrase. For the membrane-bound enzyme, the turnover number k_cat is 6.5 × 10⁵ s^?1 and the Michaelis constant is 7.5 mm for CO₂ hydration at pH 7.4 and 25 °C. The corresponding constants for bovine carbonic anhydrase under these conditions are 6.3 × 10⁵ s^?1 and 15 mm (Y. Pocker and D.W. Bjorkquist (1977)Biochemistry16, 5698–5707). The rate constant for the transfer of a proton between carbonic anhydrase and buffer was determined from the dependence of the catalytic rate on the concentration of the buffers imidazole and N-2-hydroxyethylpiperazine-N′-2-ethanesulfonic acid (Hepes); the value of 2 × 10⁸m^?1s^?1 describes this constant for both forms of carbonic anhydrase at pH 7.4. Furthermore, the pH dependence of the initial velocity of hydration of CO₂ in the range of pH 6.5 to 8.0 is identical for the membrane-bound and soluble enzyme at low buffer concentration (1–2 mm imidazole). We conclude that the membrane plays no detectable role in affecting the CO₂ hydration activity and that the active site of the renal, membrane-bound carbonic anhydrase is exposed to the aqueous phase.     

Designed Human Serum Hyaluronidase 1 Variant, HYAL1��L, Exhibits Activity up to pH 5.9

Hyaluronidases from diverse species and sources have different pH optima. Distinct mechanisms with regard to dynamic structural changes, which control hyaluronidase activity at varying pH, are unknown. Human serum hyaluronidase 1 (HYAL1) is active solely below pH 5.1. Here we report the design of a HYAL1 variant that degrades hyaluronan up to pH 5.9. Besides highly conserved residues in close proximity of the active site of most hyaluronidases, we identified a bulky loop formation located at the end of the substrate binding crevice of HYAL1 to be crucial for substrate hydrolysis. The stretch between cysteine residues 207 and 221, which normally contains 13 amino acids, could be replaced by a tetrapeptide sequence of alternating glycine serine residues, thereby yielding an active enzyme with an extended binding cleft. This variant exhibited hyaluronan degradation at elevated pH. This is indicative for appropriate substrate binding and proper positioning being decisively affected by sites far off from the active center.Hyaluronan (HA),³ a linear polysaccharide found in the extracellular matrix of most tissues and body fluids of vertebrates, is enzymatically degraded by hyaluronidases (1). Mammalian-type hyaluronidases are grouped into EC 3.2.1.35 (2, 3) or the glycoside hydrolase family 56 (4). Members of this enzyme family hydrolyze the 1,4-β-glycosidic linkage between N-acetyl-d-glucosamine and d-glucuronate within HA polymers (5). In mammalians, hyaluronidases have been found in testis, liver lysosomes, and serum. They are involved in controlling HA levels and are thus implicated in various diseases related to defects of HA metabolism (6).The crystal structures of hyaluronidase from bee (7), wasp (8), and only recently that of human serum hyaluronidase 1 (HYAL1) (9) have been deciphered. In addition to the N-terminal catalytic domain of the insect enzymes, which resembles a distorted (β/α)₈ barrel, HYAL1 contains yet another domain. HA hydrolysis is achieved by a pair of acidic amino acids via a retaining double displacement mechanism and a substrate-assisted catalysis, in which the carbonyl oxygen of the N-acetyl group of the cleaved HA subunit acts as the catalytic nucleophile (7).Mammalian-type hyaluronidases display different pH optima. HYAL1 (10) and hyaluronidase 2 (HYAL2) (11) exhibit highest activities at acidic conditions, whereas the hyaluronidase found in Xenopus laevis kidney is only active at neutral pH (12). Bee venom hyaluronidase (13), as well as sperm hyaluronidase, PH20 (SPAM1) (14), are capable of degrading HA over a broad pH range. Up to three PH20 isoforms with greatly different pH optima could be found in protein preparations from bovine testis (15). Extensive analysis of hyaluronidase structures did not bring forward any insights as to what residues or regions of the enzymes specify a specific pH optimum.Profiles of pH-dependent activities can be assigned by computing the electrostatic interactions of the enzyme, which are primarily determined by the ionization states of its amino acid side chains. The pK_a values of titratable groups of the enzyme reflect pH-dependent properties such as stability, enzymatic interaction, and substrate interactions (16). Here we present computational and experimental data on the replacement of a loop region located at the end of the substrate binding groove yielding a variant hyaluronidase with an altered pH profile.     

Pigeon liver malic enzyme: Involvement of an arginyl residue at the binding site for malate and its analogs

Treatment of malic enzyme with arginine-specific reagents phenylglyoxal or 2,3-butanedione results in pseudo-first-order loss of oxidative decarboxylase activity. Inactivation by phenylglyoxal is completely prevented by saturating concentrations of NADP⁺, Mn²⁺, and substrate analog hydroxymalonate. Double log plots of pseudo-first-order rate constant versus concentration yield straight lines with identical slopes of unity for both reagents, suggesting that reaction of one molecule of reagent per active site is associated with activity loss. In parallel experiments, complete inactivation is accompanied by the incorporation of four [¹⁴C]phenylglyoxal molecules, and the loss of two arginyl residues per enzyme subunit, as determined by the colorimetric method of Yamasaki et al (R. B. Yamasaki, D. A. Shimer, and R. E. Feeney (1981) Anal. Biochem., 14, 220–226). These results confirm a 2:1 ratio for the reaction between phenylglyoxal and arginine (K. Takahashi (1968) J. Biol. Chem., 243, 6171–6179) and yield a stoichiometry of two arginine residues reacted per subunit for complete inactivation, of which one is essential for enzyme activity as determined by the statistical method of Tsou (C. L. Tsou (1962) Acta Biochim. Biophys. Sinica, 2, 203–211) and the Ray and Koshland analysis (W. J. Ray and D. E. Koshland (1961) J. Biol. Chem., 236, 1973–1979). Amino acid analysis of butanedione-modified enzyme also shows loss of arginyl residues, without significant decrease in other amino acids. Modification by phenylglyoxal does not significantly affect the affinity of this enzyme for NADPH. Binding of l-malate and its dicarboxylic acid analogs oxalate and tartronate is abolished upon modification, as is binding of the monocarboxylic acid α-hydroxybutyrate. The latter result indicates binding of the C-1 carboxyl group of the substrate to an arginyl residue on the enzyme.     

Catalytic properties of testicular hyaluronidase after gamma-irradiation

The effect of gamma-irradiation on ovine testicular hyaluronidase was studied in aqueous solution. Following irradiation, hyaluronidase is inhibited, and the kinetics of inhibition follow a pattern in which Km and Vmax decline as radiation dose is increased. It was indicated that the binding affinity of the residual activity of hyaluronidase with substrate is enhanced and depends upon radiation damage. Effects of various agents such as pH, salts, PCMB and glutathione on irradiated hyaluronidase have been compared with non-irradiated enzyme. The irradiated hyaluronidase was more sensitive to inhibition by CuSO4 than the non-irradiated enzyme. The residual activity after irradiation is less refractory to FeCl3 inhibition and less sensitive to NaCl stimulation compared to non-irradiated hyaluronidase. pH response curves of ovine testicular hyaluronidase show two maxima which become more evident after irradiation.     

Purification and characterization of an extremely dimethylsulfoxide tolerant esterase from a salt-tolerant Bacillus species isolated from the marine environment of the Sundarbans

A Bacillus sp. isolated from the Sundarbans region of the Bay of Bengal (NCBI GenBank Accession no. AY723697) which can tolerate 10% (w/v) NaCl, produces esterase optimally in Marine Broth 2216 medium containing 1% (w/v) NaCl. The enzyme was purified 42.7-fold with 6.4% recovery, (specific activity 569.2 U/mg protein) by ammonium sulphate precipitation followed by anion and cation exchange chromatography. The serine type esterolytic enzyme has a molecular weight of 35.0 kDa and is denatured into polypeptides of molecular weights 20 kDa and 15 kDa. The esterase was most active at pH 8.0, the pH of the seawater at the site of collection and is stable in the pH range 6.0–9.0. The optimum temperature of activity of this esterase is 45 °C and the enzyme is very stable after 1 h pre-incubation at 50 °C. Our esterase shows about 100% activity when incubated with 1 M NaCl, the activity drops to about 50% when incubated with 2.5 M sodium chloride and the enzyme is completely inactivated when 4 M NaCl is present during reaction. The esterase is almost inactivated by Ca²⁺, Hg²⁺ and Fe³⁺ ions, reducing agents and detergent. Interestingly, Co²⁺, a known inhibitor of many enzymes, preserved 70% of the activity of this esterase. Specific activity of the esterase increases more than twofold in the presence of water-miscible organic solvents as compared to that in aqueous buffer. When incubated for a period of 10 days in the presence of 30–70% dimethylsufoxide (DMSO), the specific activity increased by approximately two–threefold compared to the enzyme in aqueous buffer throughout the period of study. Specific activity between 1283 and 525 U/mg was maintained by our enzyme when incubated with 50% DMSO for 10 days. The enzyme was most active on p-nitrophenyl acetate, ethyl acetate, alpha isomer of naphthyl acetate but shows relatively lesser activity towards triglycerides of fatty acids. Certain characteristics, such as molecular weight, effects of NaCl, metal ions (Zn²⁺ and Mg²⁺) and reactivity towards para-nitrophenyl and aliphatic esters were strikingly similar to already described marine bacterial derived esterases. Extreme stability in DMSO could make this enzyme a potential immobilized biocatalyst for application in non-aqueous based continuous bioprocesses. Higher specific activity and purification factor, better thermo tolerance and solvent stability would make our enzyme more attractive for biotechnological applications than the marine microbial derived esterases described so far.     

Interfacial behaviour of bovine testis hyaluronidase

The interfacial properties of bovine testicular hyaluronidase were investigated by demonstrating the association of hyaluronidase activity with membranes prepared from bovine testis. Protein adsorption to the air/water interface was investigated using surface pressure-area isotherms. In whichever way the interfacial films were obtained (protein injection or deposition), the hyaluronidase exhibited a significant affinity for the air/water interface. The isotherm obtained 180 min after protein injection into a pH 5.3 subphase was similar to the isotherm obtained after spreading the same amount of protein onto the same subphase, indicating that bovine testicular hyaluronidase molecules adopted a similar arrangement and/or conformation at the interface. Increasing the subphase pH from 5.3 to 8 resulted in changes of the protein isotherms. These modifications, which could correspond to the small pH-induced conformational changes observed by Fourier-transform IR spectroscopy, were discussed in relation to the pH influence on the hyaluronidase activity. Adding hyaluronic acid, the enzyme substrate, to the subphase tested the stability of the interfacial properties of hyaluronidase. The presence of hyaluronic acid in the subphase did not modify the protein adsorption and allowed substrate binding to a preformed film of hyaluronidase at pH 5.3, the optimal pH for the enzyme activity. Such effects of hyaluronic acid were not observed when the subphase was constituted of pure water, a medium where the enzyme activity was negligible. These influences of hyaluronic acid were discussed in relation to the modelled structure of bovine testis hyaluronidase where a hydrophobic region was proposed to be opposite of the catalytic site.     

Optimization of Folin-Ciocalteu reagent concentration in an automated Lowry protein assay

The Lowry method (G. H. Lowry, N. J. Rosebrough, A. L. Farr, and R. J. Randall, 1951, J. Biol. Chem.193, 265–275) for protein concentration measurement has been automated to permit assay of samples with concentrations from 1 to 400 μg/ml. Calibration with solutions of bovine serum albumin resulted in a nonlinear (quadratic) curve. The quantity of color developed in the assay was found to be strongly dependent on the concentration of the Folin-Ciocalteu phenol reagent. Color yield peaked sharply at a reagent concentration 40% lower than that used in the Lowry procedure. Optimization of the reagent concentration is necessary to obtain maximum sensitivity from the Lowry assay.     

Purification and properties of a β-1,4-xylanase from a cellulolytic extreme thermophile expressed in Escherichia coli

• 1.1. An endoxylanase (EC 3.2.1.8) was purified from an Escherichia coli strain carrying a xylanase gene from the extreme thermophile “Caldocellum saccharolyticum strain Tp8T6.3.3.1. It was found to have an M_r of 42,000 and an isoelectric point of approx. 5.0.
• 2.2. The enzyme showed optimum activity at pH 5.0–7.7 and had an activation energy of 44 kJ mol⁻¹. It was stable at room temperature at pH 4.5–11.5 in the presence of 0.5 mg ml⁻¹ bovine serum albumin. The half-life of the enzyme at 75°C was 20 min at pH 6.0 in the presence of 0.5 mg ml⁻¹ bovine serum albumin.
• 3.3. The xylanase had highest activity on oat spelts xylan, releasing xylobiose and some xylotriose. The K_m for oat spelts xylan was 0.021% (w/v) at pH6.0.
• 4.4. The enzyme had high activity on sugar cane bagasse hemicelluloses A and B, lower activity on larchwood xylan and also hydrolysed carboxymethylcellulose, 4-methylumbelliferyl β-D-cellobioside and p-nitrophenyl β-D-cellobioside, but could not hydrolyse xylobiose.
• 5.5. It showed transferase activity on p-nitrophenyl β-D-xylopyranoside. Xylose did not inhibit the enzyme.

     

Further evidence for hyaluronidase activity of Treponema pallidum

The presence of hyaluronidase in preparations of Treponema pallidum was previously shown using acidified bovine serum albumin reactions and Ouchterlony immunodiffusion. To expand on these preliminary findings more sensitive techniques of viscometry, additional immunologic reactions, and altered capillary permeability were used to characterize treponemal-associated hyaluronidase. The pathogens T. pallidum and T. pertenue degraded hyaluronic acid, whereas the nonpathogens T. denticola and T. vincentii did not. As syphilitic infection progressed, hyaluronidase activity decreased; organisms harvested from 14-day testicular infections degraded hyaluronic acid less rapidly than organisms from 4-day infections. Uninfected rabbit testicular extract also exhibited significant enzyme activity. The neutralizing activity of immune sera was decreased by prior adsorption with bovine hyaluronidase, suggesting that some of the neutralizing factors are associated with this enzyme. Radioimmunoassay was used to quantitate antibodies to hyaluronidase in immune sera. Antihyaluronidase sera were isolated from rabbits immunized with bovine hyaluronidase. Treponema pallidum, as well as uninfected rabbit testicular extract, cross-reacted with these antisera. Immunofluorescence indicated that the hyaluronidase was uniformly distributed along the treponemal surface. As a final indicator of hyaluronidase activity, alterations in capillary permeability were detected 1 h after intradermal injection of T. pallidum.     

Hyaluronidase in sera of tumour-bearing nude mice

Cancer cell lines often secrete hyaluronidase, suggesting that this enzyme could be used as a marker of growing tumours. We have measured hyaluronidase in the sera of non-grafted mice and mice grafted with human tumour-derived hyaluronidase-secreting H460M and SA87 cells or non-secreting CB 193 cells. Mouse serum hyaluronidase was measured at pH 3.8 using the enzyme-linked sorbent assay (ELSA) technique by reference to human serum whose activity at pH 3.8 was determined by the Reissig technique. The serum hyaluronidase in non-grafted mice ranged from 310-520 mU l^-1 (mean±SD 432±70 mU l^-1, median 440 mU l^-1). Hyaluronidase increased in the sera of tumour-bearing mice grafted with H460M cells or with SA87 cells, but not in the sera of mice grafted with CB 193 cells. Serum hyaluronidase activity in H460M or SA87 tumour-bearing mice correlated with the tumour mass, increased with time, and decreased after tumour removal. Zymography detected two different hyaluronidase forms in the sera of non-grafted mice: type 1 had only one hyaluronidase band and type 2 had five different bands. In both types, enzyme augmentation in tumour-bearing mice correlated with the presence of an additional enzyme band that was not seen in normal sera and that migrated as the cancer cell enzyme did; there was no augmentation of the normal isoform(s). These results show that serum hyaluronidase can be used to follow the development of tumours in mice grafted with hyaluronidase-secreting cells.     

Novel products in hyaluronan digested by bovine testicular hyaluronidase

When the products of hyaluronan (HA) digested by bovine testicular hyaluronidase (BTH) were analyzed by high-performance liquid chromatography (HPLC), minor peaks were detected just before the main even-numbered oligosaccharide peaks. The amount of each minor peak was dependent on the reaction conditions for transglycosylation, rather than hydrolysis, by the BTH. Mainly based on HPLC and MS analysis, each minor peak was found to correspond to its oligosaccharide with one N-acetyl group removed from the reducing terminal N-acetylglucosamine. Enzymatic studies showed that the N-deacetylation activity was closely related to reaction temperature, pH, and the concentration of NaCl contained in the buffer, and glycosaminoglycan types and chain lengths of substrates. These findings strongly suggest that the N-deacetylation reaction in minor peaks was due to a novel enzyme contaminant in the BTH, N-deacetylase, that carries out N-deacetylation at the reducing terminal N-acetylglucosamine of oligosaccharides and is dependent on HA hydrolysis by BTH.     

Hyaluronidase in sera of tumour-bearing nude mice.

Cancer cell lines often secrete hyaluronidase, suggesting that this enzyme could be used as a marker of growing tumours. We have measured hyaluronidase in the sera of non-grafted mice and mice grafted with human tumour-derived hyaluronidase-secreting H460M and SA87 cells or non-secreting CB 193 cells. Mouse serum hyaluronidase was measured at pH 3.8 using the enzyme-linked sorbent assay (ELSA) technique by reference to human serum whose activity at pH 3.8 was determined by the Reissig technique. The serum hyaluronidase in non-grafted mice ranged from 310-520 mU l(-1) (mean+/-SD 432+/-70 mU l(-1), median 440 mU l(-1)). Hyaluronidase increased in the sera of tumour-bearing mice grafted with H460M cells or with SA87 cells, but not in the sera of mice grafted with CB 193 cells. Serum hyaluronidase activity in H460M or SA87 tumour-bearing mice correlated with the tumour mass, increased with time, and decreased after tumour removal. Zymography detected two different hyaluronidase forms in the sera of non-grafted mice: type 1 had only one hyaluronidase band and type 2 had five different bands. In both types, enzyme augmentation in tumour-bearing mice correlated with the presence of an additional enzyme band that was not seen in normal sera and that migrated as the cancer cell enzyme did; there was no augmentation of the normal isoform(s). These results show that serum hyaluronidase can be used to follow the development of tumours in mice grafted with hyaluronidase-secreting cells.     

Isolation,enzymatic characterization and antiedematogenic activity of the first reported rattlesnake hyaluronidase from Crotalus durissus terrificus venom

A hyaluronidase (CdtHya1) from Crotalus durissus terrificus snake venom (CdtV) was isolated and showed to exhibit a high activity on hyaluronan cleavage. However, surveys on this enzyme are still limited. This study aimed at its isolation, functional/structural characterization and the evaluation of its effect on the spreading of crotoxin and phospholipase A₂ (PLA₂). The enzyme was purified through cation exchange, gel filtration and hydrophobic chromatography. After that, it was submitted to a reverse-phase fast protein liquid chromatography (RP-FPLC) and Edman degradation sequencing, which showed the first N-terminal 44 amino acid residues whose sequence evidenced identity with other snake venom hyaluronidases. CdtHya1 is a monomeric glycoprotein of 64.5 kDa estimated by SDS-PAGE under reducing conditions. It exhibited maximum activity in the presence of 0.2 M NaCl, at 37 °C, pH 5.5 and a specificity to hyaluronan higher than that to chondroitin-4-sulphate, chondroitin-6-sulphate or dermatan. Divalent cations (Ca²⁺ and Mg²⁺) and 1 M NaCl significantly reduced the enzyme activity. The specific activity of CdtHya1 was 5066 turbidity reducing units (TRU)/mg, against 145 TRU/mg for the soluble venom, representing a 34.9-fold purification. The pure enzyme increased the diffusion of crotoxin and PLA₂ through mice tissues. CdtHya1 (32 TRU/40 μL) potentiated crotoxin action, as evidenced by mice death, and it decreased the oedema caused by subplantar injections of buffer, crotoxin or PLA₂, thus evidencing the relevance of hyaluronidase in the crotalic envenoming. This work yielded a highly active antiedematogenic hyaluronidase from CdtV, the first one isolated from rattlesnake venoms.     

Stimulation of bull sperm hyaluronidase by polycations.

The activity of bull sperm hyaluronidase (hyaluronate 3-glycanohydrolase, EC 3.2.1.36) is increased by the inclusion of polycations in the assay mixture. At pH 3.8, bovine serum albumin and histone give the greatest stimulation, while protamine sulfate, spermine, spermidine and hyamine 2389 stimulate to a lesser extent. Enzyme activity increases with serum albumin concentration to a nearly constant, high level at serum albumin concentrations greater than 1 mg/ml. Other stimulatory compounds show a similar concentration dependence except that inhibition of enzyme activity occurs at high concentrations of stimulator. The degree of stimulation depends on the pH, sample concentration and substrate concentration. Enzyme preparations with a low protein content give the greatest stimulation, while preparations with a high protein content show little stimulation. The concentration of serum albumin required for maximum stimulation increases with increased hyaluronic acid concentration. The results suggest that the stimulation of sperm hyaluronidase is nonspecific and results from an interaction of the polycation with hyaluronic acid. Since protein in the enzyme preparation substitutes for exogenous stimulator to a varying degree, serum albumin should be included in the assay mixture for sperm and testicular hyaluronidase to assure measurement of maximum enzyme activity.