Purification and characterization of a hyaluronidase from venom of the spider Vitalius dubius (Araneae, Theraphosidae)

Sutti, Rafael; Tamascia, Mariana Leite; Hyslop, Stephen; Rocha-e-Silva, Thomaz Augusto Alves

doi:10.1186/1678-9199-20-2

Abstract

Background

Venom hyaluronidase (Hyase) contributes to the diffusion of venom from the inoculation site. In this work, we purified and characterized Hyase from the venom of Vitalius dubius (Araneae, Theraphosidae), a large theraphosid found in southeastern Brazil. Venom obtained by electrical stimulation of adult male and female V. dubius was initially fractionated by gel filtration on a Superdex® 75 column. Active fractions were pooled and applied to a heparin-sepharose affinity column. The proteins were eluted with a linear NaCl gradient.

Results

Active fractions were pooled and assessed for purity by SDS-PAGE and RP-HPLC. The physicochemical tests included optimum pH, heat stability, presence of isoforms, neutralization by flavonoids and assessment of commercial antivenoms. Hyase was purified and presented a specific activity of 148 turbidity-reducing units (TRU)/mg (venom: 36 TRU/mg; purification factor of ~4). Hyase displayed a molecular mass of 43 kDa by SDS-PAGE. Zymography in hyaluronic-acid-containing gels indicated an absence of enzyme isoforms. The optimum pH was 4-5, with highest activity at 37°C. Hyase was stable up to 60°C; but its activity was lost at higher temperatures and maintained after several freeze-thaw cycles. The NaCl concentration (up to 1 M) did not influence activity. Hyase had greater action towards hyaluronic acid compared to chondroitin sulfate, and was completely neutralized by polyvalent antiarachnid sera, but not by caterpillar, scorpion or snakes antivenoms.

Conclusion

The neutralization by arachnid but not scorpion antivenom indicates that this enzyme shares antigenic epitopes with similar enzymes in other spider venoms. The biochemical properties of this Hyase are comparable to others described.

Hyaluronidase; Venom; Purification; Vitalius dubius

Background

Spider venoms comprise complex mixtures of components of low molecular weight, peptides and proteins [ ¹1 . Rash LD, Hodgson WC: Pharmacology and biochemistry of spider venoms. Toxicon 2002, 40(3):225-254. ]. Among the enzymatic activities, collagenase and hyaluronidase (Hyase) are often found and were formerly attributed to matrix degradation [ ¹1 . Rash LD, Hodgson WC: Pharmacology and biochemistry of spider venoms. Toxicon 2002, 40(3):225-254.].

Hyase activity is found in several spider species, such as Cupiennius salei, Lycosa godeffroy, Lampona cylin-drata/murina, Loxosceles recluse, Loxosceles rufescens, Loxosceles deserta, Loxosceles gaucho, Loxosceles laeta, Loxosceles recluse, and Loxosceles intermedia [ ¹1 . Rash LD, Hodgson WC: Pharmacology and biochemistry of spider venoms. Toxicon 2002, 40(3):225-254.

2 . Kuhn-Nentwig L, Schaller J, Nentwig W: Purification of toxic peptides and the amino acid sequence of CSTX-1 from the multicomponent venom ofCupiennius salei (Areneae: Ctenidae).Toxicon 1994, 32(3):287-302.

3 . Wright RP, Elgert KD, Campbell BJ, Barrett JT: Hyaluronidase and esterase activities of the venom of the poisonous brown recluse spider.Arch Biochem Biophys 1973, 159(1):415-426.

4 . Young AR, Pincus SJ: Comparison of enzymatic activity from three species of necrotizing arachnids in Australia: Loxosceles rufescens, Badumma insignis and Lampona cylindrata .Toxicon 2001, 39(2-3):391-400.

5 . Barbaro KC, Knysak I, Martins R, Hogan C, Winkel K: Enzymatic characterization, antigenic cross-reactivity and neutralization of dermonecrotic activity of five Loxosceles spider venoms of medical importance in the Americas. Toxicon 2005,45(4):489-499. - ⁶6 . da Silveira RB, Chaim OM, Mangili OC, Gremski W, Dietrich CP, Nader HB, Veiga SS: Hyaluronidases in Loxosceles intermedia(Brown spider) venom are endo - β-N-acetyl-d-hexosaminidases hydrolases. Toxicon 2007, 49(6):758-768. ]. The first report of hyaluronidasic activity was in venoms of the Brazilian spidersLycosa raptorial and Phoneutria nigriventer [ ⁷7 . Kaiser E: The enzymatic activity of spider venom on the influence of sulfonated polysaccharides on the proteolytic and hyaluronic acid splitting activity of spider venom. Mem Inst Butantan 1953, 25(1):35-39. , ⁸8 . Kaiser E: Enzymatic activity of spider venoms. InVenoms. Edited by Buckley EE, Porges N. Washington, DC: American Association for the Advancement of Science; 1956:91 -93.]. The first Hyase to be purified from a Theraphosidae spider was the one from the tarantula Dugesiella hentzi (Girard), which was characterized and identified as the major venom component [ ⁹9 . Schanbacher FL, Lee CK, Wilson IB, Howell DE, Odell GV: Purification and characterization of tarantula, Dugesiella hentzi (girard) venom hyaluronidase. Comp Biochem Physiol B 1973, 44(2):389-396.].

The clinical relevance of Hyases is not confined to a toxin-spreading factor, since it acts as an allergen in a manner similar to hymenoptera venoms. Hyase, phospho-lipase A2 and melitin were identified as the tree major causes of allergic reactions involved in bee stings, and phospholipase A1 and antigen 5 are the major allergens in wasp venoms [ ¹⁰10 . Lu G, Kochoumian L, King TP: Sequence identity and antigenic cross-reactivity of white face hornet venom allergen, also a hyaluronidase, with other proteins. J Biol Chem 1995, 270(9):4457-4465. , ¹¹11 . Kolarich D, Leonard R, Hemmer W, Altmann F: The N-glycans of yellow jacket venom hyaluronidases and the protein sequence of its major iso-form in Vespula vulgaris . FEBS J 2005, 272(20):5182-5190. ].

Although tarantula bites to humans are relatively rare [ ¹²12 . Lucas S: Spiders in Brazil. Toxicon 1988, 26(9):759-772.

13 . Lucas SM, Da Silva PI Jr, Bertani R, Costa Cardoso JL: Mygalomorph spider bites: a report on 91 cases in the state of Sao Paulo. Brazil Toxicon 1994, 32(10):1211-1215. - ¹⁴14 . Isbister GK, Seymour JE, Gray MR, Raven RJ: Bites by spiders of the family Theraphosidae in humans and canines. Toxicon 2003, 41(4):519-524. ], these spider venoms represent a rich source of bioactive molecules for scientific interest, basic research and possible therapeutic applications [ ¹⁵15 . Escoubas P, Rash L: Tarantulas: eight-legged pharmacists and combinatorial chemists. Toxicon 2004, 43(5):555-574.

16 . Windley MJ, Escoubas P, Valenzuela SM, Nicholson GM: A novel family of insect-selective peptide neurotoxins targeting insect BKCa channels isolated from the venom of the theraphosid spider: eucratoscelus constrictus.Mol Pharmacol 2011, 80(1):1 -13.

17 . Edgerton GB, Blumenthal KM, Hanck DA: Inhibition of the activation pathway of the T-type calcium channel CaV3.1 by ProTxII.Toxicon 2010, 56(4):624-636. - ¹⁸18 . Escoubas P: Molecular diversification in spider venoms: a web of combinatorial peptide libraries. Mol Divers 2006, 10(4):545-554. ].

The tarantula Vitalius dubius (Mello-Leitão, 1923) is characterized as nonaggressive and is found in the very populous area of southeastern Brazil [¹⁹19 . Bertani R: Revision, cladistic analysis, and zoogeography ofVitalius, Nhandu, and Proshapalopus; with notes on other theraphosine genera (Araneae, Theraphosidae). Arq Zool S Paulo 2001, 36(3):266-350. ]. Recent studies have shown thatV. dubius venom has a complex biochemical and pharmacological composition, with different biological activities [ ²⁰20 . Rocha-e-Silva TAA, Sutti R, Hyslop S: Milking and partial characterization of venom from the Brazilian spider Vitalius dubius (Theraphosidae). Toxicon 2009, 53(1):153-161. , ²¹21 . Rocha-E-Silva TAA, Rostelato-Ferreira S, Leite GB, da Silva PI, Jr HS, Rodrigues-Simioni L: VdTX-1, a reversible nicotinic receptor antagonist isolated from venom of the spider Vitalius dubius(Theraphosidae). Toxicon 2013, 70:135-141. ]. In the present work we describe the purification and characterization of the hy-aluronidase present in its venom.

Methods

Reagents

Refined chemicals were purchased from Sigma Chemical Co. (USA) whereas heparin was purchased from Labora-tório Cristália (Brazil). Molecular mass markers for SDS-PAGE were acquired from BioRad (USA). The resins for column chromatography were purchased from GE Healthcare Life Sciences (Sweden). The HPLC column was a Jupiter C18 (4.6 mm χ 250 mm χ 12 μm) acquired from Phenomenex (USA).

Spiders and venom extraction

Specimens of V. dubius and Phoneutria nigriventer were provided by the Centers for Zoonosis Control for the cities in the region of Campinas, Sao Paulo state. The spiders were identified and kept in captivity, where they were fed cockroaches and water ad libitum. The tarantula venom was extracted as described by Rocha-e-Silvaet al. [ ²⁰20 . Rocha-e-Silva TAA, Sutti R, Hyslop S: Milking and partial characterization of venom from the Brazilian spider Vitalius dubius (Theraphosidae). Toxicon 2009, 53(1):153-161. ] then lyophilized and stored at-80°C until use.

Antisera

We used six antivenom sera produced by the Butantan Institute in Sao Paulo: (1) antiarachnid (Phoneutria nigriventer, Loxosceles gaucho andTityus serrulatus); (2) antiscorpionic (T. serrulatus); (3) antilonomic (Lonomia obliqua); (4) antibothropic (Bothrops alternatus, B. jararaca, B. jararacussu, B. moojeni and B. neuwiedi); (5) anticrotalic(Crotalus durissus terrificus and Crotalus durissus collilineatus); and (6) antielapidic (Micrurus frontalis and M. corallinus).

Enzymatic activity

Hyaluronidase activity was determined by a turbidimet-ric method [ ²²22 . Di Ferrante N: Turbidimetric measurement of acid mucopolysaccharides and hyaluronidase activity. J Biol Chem1956, 220(1):303-306. ]. The working solution for this trial consisted of a 200 μL buffer (0.2 M sodium acetate, pH 6.0, containing 0.15 M NaCl), 200 μL of substrate (hyaluronic acid from human umbilical cord 1 mg/mL in acetate buffer) and 100 μL of enzyme (20 μg) to give a total reaction volume of 500 μL. This mixture was incubated for 15 minutes at 37°C after which the reaction was stopped by adding 2 mL of hexadecyltrimethylammonium bromide in 2.5% NaOH. The resulting turbidity was read at 400 nm in a SpectraMax® 340 microplate reader (Molecular Devices, USA) after 30 minutes of incubation at room temperature. One unit of activity corresponded to the amount of enzyme that produced a 50% reduction in turbidity caused by 200 μg of substrate under the conditions described above.

Purification of Hyaluronidase

The venom (10 mg) of V. dubius was dissolved in 0.1 M sodium acetate buffer, pH 6.0, containing 0.15 M NaCl, and fractionated by a Superdex® 75 gel filtration column (10 mm χ 30 cm) balanced and eluted with the same buffer. Fractions of 1.5 mL each were collected at a flow rate of 1 mL per minute using an ÄKTA-Purifier chromatographic system (Pharmacia, Sweden). The elution profile was determined by monitoring the absorbance at 280 nm.

The hyaluronidase-containing fractions eluted from the previous step were applied to a heparin-sepharose column equilibrated with 0.1 M sodium acetate buffer, pH 6.0. The fractions were washed and eluted under a gradient of NaCl (0 to 1.0 M). The elution profile was determined by monitoring the absorbance at 280 nm whereas fractions (1.5 mL) containing the enzyme were stored at 8°C

Hyase purity was evaluated by RP-HPLC chromatography using a resource RPC column (4.6 mm χ 250 mm χ 12 μm). The column was balanced with 0.1% trifluoracetic acid (TFA) and the enzyme was eluted with a linear gradient (0-100%) of 66% acetonitrile in 0.1% TFA. The elution profile was monitored at 280 nm.

SDS-polyacrylamide gel electrophoresis (SDS-PAGE) and zymography

Electrophoresis was performed using 12% acrylamide or 5-20% gradients gels [²³23 . Hames BD: One-dimensional polyacrylamide gel electrophoresis. InGel Electrophoresis of Proteins: a Practical Approach. 2nd edition. Edited by Hames BD, Rickwood D. New York: Oxford University Press; 1990:1-147. ]. The existence of isoforms of Hyase was investigated as described by Cevallos et al. [ ²⁴24 . Cevallos MA, Navarro-Duque C, Varela-Julia M, Alagon AC: Molecular mass determination and assay of venom hyaluronidases by sodium dodecyl sulfate-polyacrylamide gel electrophoresis. Toxicon 1992, 30(8):925-930. ]. The hyaluronic acid was mixed into the SDS-polyacrylamide gels to obtain a final concentration of 0.6 mg/mL of non-polymerized solution.

During zymography, the electrophoretic separation phase was performed under the same conditions previously described (gels, buffers etc.), except for the samples, that were not warmed, to conserve their enzymatic activities. After Stains all staining (Sigma-Aldrich Co.), the gel was washed with a buffer containing 0.015 M Tris-HCl, 5% formamide and 20% isopropyl alcohol, pH 7.9, and photo documented.

Physicochemical characterization of the enzyme

The optimum pH was determined by changing the buffers of the enzymatic turbidimetric assay as follows: 0.1 M sodium citrate, pH 3.0 to 6.0, 0.1 M sodium acetate, pH 4.0 to 6.0 and 0.1 M Tris-HCl, pH 5.5 to 8.0 (0.15 M NaCl was added to all buffers).

The optimal working temperature of the enzyme was evaluated by adjusting assay temperature between 10 and 70°C. The thermal stability of the enzyme was tested by pre-incubating enzyme solution for 15 minutes under a temperature ranging from 25 to 80°C.

To evaluate freezing longevity of the enzyme, separated aliquots were stored at-20°C and enzyme activity measured at the times 1, 2, 3, 6, 24, 72 hours and 7 and 15 days. Each aliquot was thawed once before the assay. To evaluate freezing cycles stability, a stock solution was stored, then thawed and refrozen for each enzyme assay, following same intervals in the freezing longevity test.

We investigated substrate specificity of the enzyme towards hyaluronic acid and chondroitin sulfate A. For this assay the Hyase activity was measured by quantifying the released sugars according to the colorimetric method of Reissiget al. [ ²⁵25 . Reissig JL, Strominger JL, Leloir LF: A modified colorimetric method for the estimation of N-acetylamino sugars. J Biol Chem1955, 217(2):959-966. ].

The maximum reaction velocity (V_max) and the substrate concentration that results in the half of the maximum velocity (K_m) were assessed with fixed amounts of enzyme and variable substrate concentrations. The N-acetylamine release was quantified by the method of Reissig et al. [ ²⁵25 . Reissig JL, Strominger JL, Leloir LF: A modified colorimetric method for the estimation of N-acetylamino sugars. J Biol Chem1955, 217(2):959-966. ]. The parameters were calculated using Lineweaver-Burk graphs, as previously described by Segel [ ²⁶26 . Segel I: Biochemical Calculations. New York: John Wiley & Sons; 1972:454. ].

Immunological comparisons

An ELISA test was used to assess cross-reactivity between the enzyme and the commercial sera against several venomous species of spiders, scorpions and snakes.

The ability of Instituto Butantan's commercial anti-venom to neutralize the enzymatic activity of V. dubius was assessed using the turbidimetric assay. The enzyme was pre-incubated with different volumes of each anti-venom for 30 minutes at 37°C before measuring the enzyme activity. Control assays were performed using venom only.

Statistics

The results were expressed as the mean ± SEM for the number of assays. Statistical comparisons were made using ANOVA followed by the Tukey test, with p < 0.05 indicating significance.

Results

The Hyase activity of V. dubius venom was lower than that ofP. nigriventer (with respective turbidities of 11.6 and 5.6%). The venom of P. nigriventer reached assay saturation at a concentration of 5 μg/mL, while V. dubius venom showed maximum activity at 15 μg/mL ( Figure 1 ).

Figure 1
Comparison of hyaluronidase activity present in the venom ofV. dubius and P. nigriventer. The values represent the mean ±S.E. (n = 6).

Hyase purification was initiated through a size exclusion chromatography, which provided three active fractions (fractions 7, 8 and 9), pooled for the second stage(Figure 2A ).Inthefollowing affinity chromatography, Hyase activity was detected in one fraction ( Figure 2B ) (fraction 5). Reversed-phase HPLC provided the purified Hyase( Figure 2C ). The enzyme purity was confirmed by a 12% SDS-PAGE and zymography, which showed only one band around 43 kDa ( Figure 2D ).

Figure 2
Hyaluronidase purification from the venom of V. dubius. (A) Gelfiltration chromatography on Superdex® G-75 showing three active fractions. (B) Positive fractions from the previous step were applied to an affinity column of heparin-Sepharose (5 mL). The enzyme was detected at peak 2 (arrow), not retained by column. (C) C-18 reversed phase chromatography for finalpurification, using ACN gradient. (D) Left: SDS-PAGE of crude venom (Vd) and purified Hyase (Hy), using polyacrylamide gel 12% stained with silver nitrate. The estimated mass for the enzyme was 43 kDa. Right: crude venom and purified enzyme zymography. M = molecular weight markers.

About 850 μg of purified Hyase was obtained from 18 mg of crude venom protein, with an activity corresponding to 19.5% of the venom. The total activity significantly dwindled in the second stage (from 615.3 TRU to 124.4), but the specific activity augmented gradually during the purification process (148 U/mg). The purification factor had also increased (4.1).

The investigation of the physicochemical characteristics of the purified enzyme showed maximum activity at pH between 4 and 5and temperature from35and 40°C. Lower activity was observed at 25°C, decreasing gradually from 45°C onwards with total loss above 60°C ( Figure 3 ).

Figure 3
Properties of hyaluronidase from V. dubius. The purified enzyme showed maximum activity at pH between 4 and 5 and temperature from 35 and 40°C. Lower activity was observed starting from 25°C, decreasing gradually from 45°C onwards with total loss above 60°C. The points represent the mean ± S.E. (n = 6).

Enzyme samples submitted to consecutive freeze-thaw cycles remained at maximum activity after the first three cycles (0, 1 and 3 hours), with a slight decrease after six hours, remaining stable until 15 days. Otherwise, individual frozen aliquots maintained their activity until the seventh day, losing activity after 15 days of freezing ( Figure 4 ).

Figure 4
Stability of purified Hyase after freeze-thaw cycles (−20°C): the activity remained at maximum after the first three freeze-thaw cycles (0, 1 and 3 hours), with a slight decrease after six hours, unchanged until 15 days. Aliquots maintained their activity until the seventh day, losing activity after 15 days of freezing. The points represent mean ± SEM (n = 6), * p < 0.05.

The substrate specificity was evaluated in both purified enzyme and crude venom; it was observed that the Hyase has a higher specificity to hyaluronic acid, but a lower activity in the presence of chondroitin ( Figure 5 ). The values obtained for V_max and K_m fromV. dubius- purified Hyase were 11.4 μg/min and 677.0 μg/mL, respectively, as shown in Figure 6 .

Figure 5
Enzymatic activity of V. dubius venom (10 μg) and purified Hyase (5 μg) on hyaluronic acid and chondroitin sulfate A. The points represent mean ± SEM (n = 6).

Figure 6
Lineweaver-Burk graphs (1/S vs. 1/V) to Hyase Vmax and Km determination using hyaluronic acid as substrate. The points represent mean ± SEM (n = 6).

Antiophidic, antiscorpionic and antilonomic serum were inefficient at neutralizing the enzymatic activity ( Figure 7A ). The antiarachnid serum against enzyme and crude venom neutralized Hyase activity in a dose-dependent manner ( Figure 7B ).

Figure 7
Immunological comparisons. (A) Dose-dependent neutralization of Hyase by anti-arachnidic serum. Antiscorpionic, antilonomic, antibothropic, anticrotalic and antielapidic sera were inefficient at neutralizing the enzymatic activity. (B) Reactivity of V. dubius venom (10 μg) and purified Hyase (5 μg) compared to anti-arachnidic serum on ELISA. The points represent mean ± SEM (n = 6).

Discussion

The hyaluronidases (Hyases) that have been isolated from various sources and extensively characterized comprise a group of enzymes described as 4-hyaluronate glu-canohydrolase (EC 3.2.1.35, hyaluronoglucosamidase), hyaluronate-3-glucanohydrolase (EC 3.2.1.36, hyalurono-glucuronidase) and hyaluronatelyase (EC 4.2.2.1) [ ²⁷27 . Pessini AC, Takao TT, Cavalheiro EC, Vichnewski W, Sampaio SV, Giglio JR, Arantes EC: A hyaluronidase from Tityus serrulatusscorpion venom: isolation, characterization and inhibition by flavonoids.Toxicon 2001, 39(10):1495-1504. ]. The presence of this enzyme has been described in several human tissues, animal venoms, pathogenic organisms and cancers. Animal venom Hyases are structurally similar to those from the acrosome membrane of sperm, which play a fundamental role in mammalian fertilization, and to Hyases Hyal-1 and Hyal-2 of mammalian lysosomes [²⁸28 . Gmachl M, Kreil G: Bee venom hyaluronidase is homologous to a membrane protein of mammalian sperm. Proc Natl Acad Sci USA1993, 90(8):3569-3573.

29 . Frost GI, Csóka TB, Wong T, Stern R: Purification, cloning, and expression of human plasma hyaluronidase. Biochem Biophys Res Commun 1997, 236(1):10-15. - ³⁰30 . Lepperdinger G, Stroble B, Kreil G: Hyal2, a human gene expressed in many cells, encodes a lysosomal hyaluronidase with a novel type of specificity. J Biol Chem 1998, 273(35):22466-22470. ]. Thus, venom Hyases are attributed the scattering function by facilitating the spread of toxins through glucosamine glycan hydrolysis in connective tissue, thereby yielding systemic poisoning [ ³¹31 . Morey SS, Kiran KM, Gadag JR: Purification and properties of hyaluronidase from Palamneus gravimanus (Indian black scorpion) venom. Toxicon 2006, 47(2):188-195. ].

As expected, the venom of P. nigriventer presents higher Hyase activity than that of V. dubius, due to the former's abundant high-molecular-weight molecules, thus requiring a higher permeability to promote the dissemination of such components [ ¹1 . Rash LD, Hodgson WC: Pharmacology and biochemistry of spider venoms. Toxicon 2002, 40(3):225-254. ]. Moreover, the venom of V. dubius has few components of high molecular weight, but rather a predominance of low-weight molecules, such as pep-tides, thus less need of Hyase [ ²⁰20 . Rocha-e-Silva TAA, Sutti R, Hyslop S: Milking and partial characterization of venom from the Brazilian spider Vitalius dubius (Theraphosidae). Toxicon 2009, 53(1):153-161.].

That molecular profile of V. dubius Hyase venom contributed to the enzyme purification process. In three chromatographic steps, we obtained the pure enzyme, while in the venoms from other animals-namely Tityus serrulatus, Buthus martensi, Apis mellifera, Vespula vulgaris, Synanceja horrida and Lonomia obliqua-more chromatographic steps were necessary for Hyase purification [ ¹¹11 . Kolarich D, Leonard R, Hemmer W, Altmann F: The N-glycans of yellow jacket venom hyaluronidases and the protein sequence of its major iso-form in Vespula vulgaris . FEBS J 2005, 272(20):5182-5190. , ²⁷27 . Pessini AC, Takao TT, Cavalheiro EC, Vichnewski W, Sampaio SV, Giglio JR, Arantes EC: A hyaluronidase from Tityus serrulatusscorpion venom: isolation, characterization and inhibition by flavonoids.Toxicon 2001, 39(10):1495-1504. , ²⁸28 . Gmachl M, Kreil G: Bee venom hyaluronidase is homologous to a membrane protein of mammalian sperm. Proc Natl Acad Sci USA1993, 90(8):3569-3573., ³²32 . Feng L, Gao R, Gopalakrishnakone P: Isolation and characterization ofahyaluronidase from the venom of Chinese red scorpion Buthus martensi . Comp Biochem Physiol C Toxicol Pharmacol 2008, 148(3):250-257.

33 . Poh CH, Yuen R, Chung MC, Khoo HE: Purification and partia characterization of hyaluronidase from stonefish (Synanceja horrida) venom. Comp Biochem Physiol B 1992, 101 (1-2):159-163. - ³⁴34 . Da CB Gouveia AI, Da Silveira RB, Nader HB, Dietrich CP, Gremski W, Veiga SS: Identification and partial characterization of hyaluronidases inLonomia obliqua venom. Toxicon 2005, 45(4):403-410. ].

The enzyme yield (4.8%) was considered low after purification, mainly because the enzyme is present at small concentrations in the total venom. Similar yields (4.9%) can be obtained during the Hyase purification of the scorpion venom ofTityus serrulatus [ ²⁷27 . Pessini AC, Takao TT, Cavalheiro EC, Vichnewski W, Sampaio SV, Giglio JR, Arantes EC: A hyaluronidase from Tityus serrulatusscorpion venom: isolation, characterization and inhibition by flavonoids.Toxicon 2001, 39(10):1495-1504.]. Otherwise, the purification from the venom of the scorpion Palamneus gravima-nus, provided a higher yield, about 40% [ ³¹31 . Morey SS, Kiran KM, Gadag JR: Purification and properties of hyaluronidase from Palamneus gravimanus (Indian black scorpion) venom. Toxicon 2006, 47(2):188-195. ].

The optimum working temperature of purified V. dubius Hyase is around 37°C, which matches the physiological range of some of its largest prey, such as small rodents [ ³⁵35 . Dias SC, Brescovit AD: Notes on the behavior ofPachistopelma rufonigru Pocock (Araneae, Theraphosidae, Aviculariinae). Rev Bras Zool 2003, 20(1):13-17. ]. The enzyme loses its activity at 60°C, perhaps due to losses in the molecular structure, thus compromising its activity. Same hyaluronidase temperature range can be found in the venom activity presented by Agkistrodon contortrix andTityus serrulatus [ ²⁷27 . Pessini AC, Takao TT, Cavalheiro EC, Vichnewski W, Sampaio SV, Giglio JR, Arantes EC: A hyaluronidase from Tityus serrulatusscorpion venom: isolation, characterization and inhibition by flavonoids.Toxicon 2001, 39(10):1495-1504., ³⁶36 . Kudo K, Tu AT: Characterization of hyaluronidase isolatedfrom Agkistrodon contortrix contortrix (Southern copperhead) venom. Arch Biochem Biophys 2001, 386(2):154-162. ].

The optimum pH found in V. dubius Hyase was between 4 and 5, the same described for Buthus martensi and Palamneus gravimanus enzymes [ ³¹31 . Morey SS, Kiran KM, Gadag JR: Purification and properties of hyaluronidase from Palamneus gravimanus (Indian black scorpion) venom. Toxicon 2006, 47(2):188-195. , ³²32 . Feng L, Gao R, Gopalakrishnakone P: Isolation and characterization ofahyaluronidase from the venom of Chinese red scorpion Buthus martensi . Comp Biochem Physiol C Toxicol Pharmacol 2008, 148(3):250-257. ]. In the Hyase of Hippasa partita, the best pH was observed to be 6 [ ³⁷37 . Nagaraju S, Devaraja S, Kemparaju K: Purification and properties of hyaluronidase from Hippasa partita (funnel web spider) venom gland extract. Toxicon 2007, 50(3):383-393. ]. The finding of a pH between 4 and 5 can be explained by the preferential degradation of an acid substrate by the enzyme.

The V. dubius Hyase has a K_m of 677.0 μg/mL, indicating a comparatively low affinity of the substrate for the enzyme catalytic site, in contrast to the Hyases of T. serrulatus (69.7 μg/mL) andP. gravimanus (47.61 μg/ mL) scorpions, but similar to the stonefish Synanceja horrida (709 μg/mL) [ ²⁷27 . Pessini AC, Takao TT, Cavalheiro EC, Vichnewski W, Sampaio SV, Giglio JR, Arantes EC: A hyaluronidase from Tityus serrulatusscorpion venom: isolation, characterization and inhibition by flavonoids.Toxicon 2001, 39(10):1495-1504. , ³¹31 . Morey SS, Kiran KM, Gadag JR: Purification and properties of hyaluronidase from Palamneus gravimanus (Indian black scorpion) venom. Toxicon 2006, 47(2):188-195. , ³³33 . Poh CH, Yuen R, Chung MC, Khoo HE: Purification and partia characterization of hyaluronidase from stonefish (Synanceja horrida) venom. Comp Biochem Physiol B 1992, 101 (1-2):159-163. ].

Testing the specificity of substrates, we observed that V. dubius Hyase exerts greater activity on hyaluronic acid compared to chondroitin, although still positive for the latter. The chondroitin test was positive for bovine hyaluronidase but negative for Hyases purified from the venoms of Hippasa partita and Agkistrodon contortrix [ ³⁶36 . Kudo K, Tu AT: Characterization of hyaluronidase isolatedfrom Agkistrodon contortrix contortrix (Southern copperhead) venom. Arch Biochem Biophys 2001, 386(2):154-162. , ³⁷37 . Nagaraju S, Devaraja S, Kemparaju K: Purification and properties of hyaluronidase from Hippasa partita (funnel web spider) venom gland extract. Toxicon 2007, 50(3):383-393.].

The neutralization of Hyase activity by antivenoms has not been widely studied. The experiments conducted in our laboratory showed that the venom Hyase of V. dubius was recognized by antiarachnid serum, in a dose-dependent manner. The lack of influence of the antiscor-pionic sera, obtained fromTytius venoms that are used for antiarachnid production, attest that the above neutralization is specifically due to antibodies raised against Loxosceles and Phoneutria sp., pooled for anti-venom preparation against the latter. Neutralization also failed with antilonomic and antisnake sera, reinforcing the reaction specificity of V. dubius Hyase against spider antivenoms. This indicates that immunological identities may differ between the Hyase of arachnids and those of snakes and caterpillars. This immunological relationship has also been reported for several other enzymes and toxins of venoms [ ³⁸38 . Elliott WB: Chemistry and immunology of reptilian venoms. InBiology of the reptilia: physiology B. 8th edition. Edited by Gans C, Gans K. London: Academic Press; 1978:163-436. ].

Conclusions

Based on these findings, we conclude that the venom of V. dubius contains a Hyase with physicochemical and biochemical characteristics similar to other Hyases of venoms, although less potent. Nevertheless, the studied Hyase shares immunological features specifically with other spiders' enzymes, rather than those of caterpillars and snakes.

Acknowledgements

The authors would like to thank the Center for Control of Zoonoses in Itu, Sao Paulo state, Brazil for providing the spiders for this study, Jose Ilton dos Santos for his support in the laboratory and CNPq and FAPESP for financial support and scholarships.

References

¹
Rash LD, Hodgson WC: Pharmacology and biochemistry of spider venoms. Toxicon 2002, 40(3):225-254.
²
Kuhn-Nentwig L, Schaller J, Nentwig W: Purification of toxic peptides and the amino acid sequence of CSTX-1 from the multicomponent venom ofCupiennius salei (Areneae: Ctenidae).Toxicon 1994, 32(3):287-302.
³
Wright RP, Elgert KD, Campbell BJ, Barrett JT: Hyaluronidase and esterase activities of the venom of the poisonous brown recluse spider.Arch Biochem Biophys 1973, 159(1):415-426.
⁴
Young AR, Pincus SJ: Comparison of enzymatic activity from three species of necrotizing arachnids in Australia: Loxosceles rufescens, Badumma insignis and Lampona cylindrata .Toxicon 2001, 39(2-3):391-400.
⁵
Barbaro KC, Knysak I, Martins R, Hogan C, Winkel K: Enzymatic characterization, antigenic cross-reactivity and neutralization of dermonecrotic activity of five Loxosceles spider venoms of medical importance in the Americas. Toxicon 2005,45(4):489-499.
⁶
da Silveira RB, Chaim OM, Mangili OC, Gremski W, Dietrich CP, Nader HB, Veiga SS: Hyaluronidases in Loxosceles intermedia(Brown spider) venom are endo - β-N-acetyl-d-hexosaminidases hydrolases. Toxicon 2007, 49(6):758-768.
⁷
Kaiser E: The enzymatic activity of spider venom on the influence of sulfonated polysaccharides on the proteolytic and hyaluronic acid splitting activity of spider venom. Mem Inst Butantan 1953, 25(1):35-39.
⁸
Kaiser E: Enzymatic activity of spider venoms. InVenoms. Edited by Buckley EE, Porges N. Washington, DC: American Association for the Advancement of Science; 1956:91 -93.
⁹
Schanbacher FL, Lee CK, Wilson IB, Howell DE, Odell GV: Purification and characterization of tarantula, Dugesiella hentzi (girard) venom hyaluronidase. Comp Biochem Physiol B 1973, 44(2):389-396.
¹⁰
Lu G, Kochoumian L, King TP: Sequence identity and antigenic cross-reactivity of white face hornet venom allergen, also a hyaluronidase, with other proteins. J Biol Chem 1995, 270(9):4457-4465.
¹¹
Kolarich D, Leonard R, Hemmer W, Altmann F: The N-glycans of yellow jacket venom hyaluronidases and the protein sequence of its major iso-form in Vespula vulgaris . FEBS J 2005, 272(20):5182-5190.
¹²
Lucas S: Spiders in Brazil. Toxicon 1988, 26(9):759-772.
¹³
Lucas SM, Da Silva PI Jr, Bertani R, Costa Cardoso JL: Mygalomorph spider bites: a report on 91 cases in the state of Sao Paulo. Brazil Toxicon 1994, 32(10):1211-1215.
¹⁴
Isbister GK, Seymour JE, Gray MR, Raven RJ: Bites by spiders of the family Theraphosidae in humans and canines. Toxicon 2003, 41(4):519-524.
¹⁵
Escoubas P, Rash L: Tarantulas: eight-legged pharmacists and combinatorial chemists. Toxicon 2004, 43(5):555-574.
¹⁶
Windley MJ, Escoubas P, Valenzuela SM, Nicholson GM: A novel family of insect-selective peptide neurotoxins targeting insect BKCa channels isolated from the venom of the theraphosid spider: eucratoscelus constrictus.Mol Pharmacol 2011, 80(1):1 -13.
¹⁷
Edgerton GB, Blumenthal KM, Hanck DA: Inhibition of the activation pathway of the T-type calcium channel CaV3.1 by ProTxII.Toxicon 2010, 56(4):624-636.
¹⁸
Escoubas P: Molecular diversification in spider venoms: a web of combinatorial peptide libraries. Mol Divers 2006, 10(4):545-554.
¹⁹
Bertani R: Revision, cladistic analysis, and zoogeography ofVitalius, Nhandu, and Proshapalopus; with notes on other theraphosine genera (Araneae, Theraphosidae). Arq Zool S Paulo 2001, 36(3):266-350.
²⁰
Rocha-e-Silva TAA, Sutti R, Hyslop S: Milking and partial characterization of venom from the Brazilian spider Vitalius dubius (Theraphosidae). Toxicon 2009, 53(1):153-161.
²¹
Rocha-E-Silva TAA, Rostelato-Ferreira S, Leite GB, da Silva PI, Jr HS, Rodrigues-Simioni L: VdTX-1, a reversible nicotinic receptor antagonist isolated from venom of the spider Vitalius dubius(Theraphosidae). Toxicon 2013, 70:135-141.
²²
Di Ferrante N: Turbidimetric measurement of acid mucopolysaccharides and hyaluronidase activity. J Biol Chem1956, 220(1):303-306.
²³
Hames BD: One-dimensional polyacrylamide gel electrophoresis. InGel Electrophoresis of Proteins: a Practical Approach. 2nd edition. Edited by Hames BD, Rickwood D. New York: Oxford University Press; 1990:1-147.
²⁴
Cevallos MA, Navarro-Duque C, Varela-Julia M, Alagon AC: Molecular mass determination and assay of venom hyaluronidases by sodium dodecyl sulfate-polyacrylamide gel electrophoresis. Toxicon 1992, 30(8):925-930.
²⁵
Reissig JL, Strominger JL, Leloir LF: A modified colorimetric method for the estimation of N-acetylamino sugars. J Biol Chem1955, 217(2):959-966.
²⁶
Segel I: Biochemical Calculations. New York: John Wiley & Sons; 1972:454.
²⁷
Pessini AC, Takao TT, Cavalheiro EC, Vichnewski W, Sampaio SV, Giglio JR, Arantes EC: A hyaluronidase from Tityus serrulatusscorpion venom: isolation, characterization and inhibition by flavonoids.Toxicon 2001, 39(10):1495-1504.
²⁸
Gmachl M, Kreil G: Bee venom hyaluronidase is homologous to a membrane protein of mammalian sperm. Proc Natl Acad Sci USA1993, 90(8):3569-3573.
²⁹
Frost GI, Csóka TB, Wong T, Stern R: Purification, cloning, and expression of human plasma hyaluronidase. Biochem Biophys Res Commun 1997, 236(1):10-15.
³⁰
Lepperdinger G, Stroble B, Kreil G: Hyal2, a human gene expressed in many cells, encodes a lysosomal hyaluronidase with a novel type of specificity. J Biol Chem 1998, 273(35):22466-22470.
³¹
Morey SS, Kiran KM, Gadag JR: Purification and properties of hyaluronidase from Palamneus gravimanus (Indian black scorpion) venom. Toxicon 2006, 47(2):188-195.
³²
Feng L, Gao R, Gopalakrishnakone P: Isolation and characterization ofahyaluronidase from the venom of Chinese red scorpion Buthus martensi . Comp Biochem Physiol C Toxicol Pharmacol 2008, 148(3):250-257.
³³
Poh CH, Yuen R, Chung MC, Khoo HE: Purification and partia characterization of hyaluronidase from stonefish (Synanceja horrida) venom. Comp Biochem Physiol B 1992, 101 (1-2):159-163.
³⁴
Da CB Gouveia AI, Da Silveira RB, Nader HB, Dietrich CP, Gremski W, Veiga SS: Identification and partial characterization of hyaluronidases inLonomia obliqua venom. Toxicon 2005, 45(4):403-410.
³⁵
Dias SC, Brescovit AD: Notes on the behavior ofPachistopelma rufonigru Pocock (Araneae, Theraphosidae, Aviculariinae). Rev Bras Zool 2003, 20(1):13-17.
³⁶
Kudo K, Tu AT: Characterization of hyaluronidase isolatedfrom Agkistrodon contortrix contortrix (Southern copperhead) venom. Arch Biochem Biophys 2001, 386(2):154-162.
³⁷
Nagaraju S, Devaraja S, Kemparaju K: Purification and properties of hyaluronidase from Hippasa partita (funnel web spider) venom gland extract. Toxicon 2007, 50(3):383-393.
³⁸
Elliott WB: Chemistry and immunology of reptilian venoms. InBiology of the reptilia: physiology B. 8th edition. Edited by Gans C, Gans K. London: Academic Press; 1978:163-436.

Ethics committee approval

The present study was approved by the Ethical Committee on Animal Research (UNICAMP) under the registration number 2167-1.

Publication Dates

Publication in this collection
2014

History

Received
13 Aug 2013
Accepted
31 Jan 2014

This is an Open Access article distributed under the terms of the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original work is properly cited.

[1] ¹
Rash LD, Hodgson WC: Pharmacology and biochemistry of spider venoms. Toxicon 2002, 40(3):225-254.

[2] ²
Kuhn-Nentwig L, Schaller J, Nentwig W: Purification of toxic peptides and the amino acid sequence of CSTX-1 from the multicomponent venom ofCupiennius salei (Areneae: Ctenidae).Toxicon 1994, 32(3):287-302.

[3] ³
Wright RP, Elgert KD, Campbell BJ, Barrett JT: Hyaluronidase and esterase activities of the venom of the poisonous brown recluse spider.Arch Biochem Biophys 1973, 159(1):415-426.

[4] ⁴
Young AR, Pincus SJ: Comparison of enzymatic activity from three species of necrotizing arachnids in Australia: Loxosceles rufescens, Badumma insignis and Lampona cylindrata .Toxicon 2001, 39(2-3):391-400.

[5] ⁵
Barbaro KC, Knysak I, Martins R, Hogan C, Winkel K: Enzymatic characterization, antigenic cross-reactivity and neutralization of dermonecrotic activity of five Loxosceles spider venoms of medical importance in the Americas. Toxicon 2005,45(4):489-499.

[6] ⁶
da Silveira RB, Chaim OM, Mangili OC, Gremski W, Dietrich CP, Nader HB, Veiga SS: Hyaluronidases in Loxosceles intermedia(Brown spider) venom are endo - β-N-acetyl-d-hexosaminidases hydrolases. Toxicon 2007, 49(6):758-768.

[7] ⁷
Kaiser E: The enzymatic activity of spider venom on the influence of sulfonated polysaccharides on the proteolytic and hyaluronic acid splitting activity of spider venom. Mem Inst Butantan 1953, 25(1):35-39.

[8] ⁸
Kaiser E: Enzymatic activity of spider venoms. InVenoms. Edited by Buckley EE, Porges N. Washington, DC: American Association for the Advancement of Science; 1956:91 -93.

[9] ⁹
Schanbacher FL, Lee CK, Wilson IB, Howell DE, Odell GV: Purification and characterization of tarantula, Dugesiella hentzi (girard) venom hyaluronidase. Comp Biochem Physiol B 1973, 44(2):389-396.

[10] ¹⁰
Lu G, Kochoumian L, King TP: Sequence identity and antigenic cross-reactivity of white face hornet venom allergen, also a hyaluronidase, with other proteins. J Biol Chem 1995, 270(9):4457-4465.

[11] ¹¹
Kolarich D, Leonard R, Hemmer W, Altmann F: The N-glycans of yellow jacket venom hyaluronidases and the protein sequence of its major iso-form in Vespula vulgaris . FEBS J 2005, 272(20):5182-5190.

[12] ¹²
Lucas S: Spiders in Brazil. Toxicon 1988, 26(9):759-772.

[13] ¹³
Lucas SM, Da Silva PI Jr, Bertani R, Costa Cardoso JL: Mygalomorph spider bites: a report on 91 cases in the state of Sao Paulo. Brazil Toxicon 1994, 32(10):1211-1215.

[14] ¹⁴
Isbister GK, Seymour JE, Gray MR, Raven RJ: Bites by spiders of the family Theraphosidae in humans and canines. Toxicon 2003, 41(4):519-524.

[15] ¹⁵
Escoubas P, Rash L: Tarantulas: eight-legged pharmacists and combinatorial chemists. Toxicon 2004, 43(5):555-574.

[16] ¹⁶
Windley MJ, Escoubas P, Valenzuela SM, Nicholson GM: A novel family of insect-selective peptide neurotoxins targeting insect BKCa channels isolated from the venom of the theraphosid spider: eucratoscelus constrictus.Mol Pharmacol 2011, 80(1):1 -13.

[17] ¹⁷
Edgerton GB, Blumenthal KM, Hanck DA: Inhibition of the activation pathway of the T-type calcium channel CaV3.1 by ProTxII.Toxicon 2010, 56(4):624-636.

[18] ¹⁸
Escoubas P: Molecular diversification in spider venoms: a web of combinatorial peptide libraries. Mol Divers 2006, 10(4):545-554.

[19] ¹⁹
Bertani R: Revision, cladistic analysis, and zoogeography ofVitalius, Nhandu, and Proshapalopus; with notes on other theraphosine genera (Araneae, Theraphosidae). Arq Zool S Paulo 2001, 36(3):266-350.

[20] ²⁰
Rocha-e-Silva TAA, Sutti R, Hyslop S: Milking and partial characterization of venom from the Brazilian spider Vitalius dubius (Theraphosidae). Toxicon 2009, 53(1):153-161.

[21] ²¹
Rocha-E-Silva TAA, Rostelato-Ferreira S, Leite GB, da Silva PI, Jr HS, Rodrigues-Simioni L: VdTX-1, a reversible nicotinic receptor antagonist isolated from venom of the spider Vitalius dubius(Theraphosidae). Toxicon 2013, 70:135-141.

[22] ²²
Di Ferrante N: Turbidimetric measurement of acid mucopolysaccharides and hyaluronidase activity. J Biol Chem1956, 220(1):303-306.

[23] ²³
Hames BD: One-dimensional polyacrylamide gel electrophoresis. InGel Electrophoresis of Proteins: a Practical Approach. 2nd edition. Edited by Hames BD, Rickwood D. New York: Oxford University Press; 1990:1-147.

[24] ²⁴
Cevallos MA, Navarro-Duque C, Varela-Julia M, Alagon AC: Molecular mass determination and assay of venom hyaluronidases by sodium dodecyl sulfate-polyacrylamide gel electrophoresis. Toxicon 1992, 30(8):925-930.

[25] ²⁵
Reissig JL, Strominger JL, Leloir LF: A modified colorimetric method for the estimation of N-acetylamino sugars. J Biol Chem1955, 217(2):959-966.

[26] ²⁶
Segel I: Biochemical Calculations. New York: John Wiley & Sons; 1972:454.

[27] ²⁷
Pessini AC, Takao TT, Cavalheiro EC, Vichnewski W, Sampaio SV, Giglio JR, Arantes EC: A hyaluronidase from Tityus serrulatusscorpion venom: isolation, characterization and inhibition by flavonoids.Toxicon 2001, 39(10):1495-1504.

[28] ²⁸
Gmachl M, Kreil G: Bee venom hyaluronidase is homologous to a membrane protein of mammalian sperm. Proc Natl Acad Sci USA1993, 90(8):3569-3573.

[29] ²⁹
Frost GI, Csóka TB, Wong T, Stern R: Purification, cloning, and expression of human plasma hyaluronidase. Biochem Biophys Res Commun 1997, 236(1):10-15.

[30] ³⁰
Lepperdinger G, Stroble B, Kreil G: Hyal2, a human gene expressed in many cells, encodes a lysosomal hyaluronidase with a novel type of specificity. J Biol Chem 1998, 273(35):22466-22470.

[31] ³¹
Morey SS, Kiran KM, Gadag JR: Purification and properties of hyaluronidase from Palamneus gravimanus (Indian black scorpion) venom. Toxicon 2006, 47(2):188-195.

[32] ³²
Feng L, Gao R, Gopalakrishnakone P: Isolation and characterization ofahyaluronidase from the venom of Chinese red scorpion Buthus martensi . Comp Biochem Physiol C Toxicol Pharmacol 2008, 148(3):250-257.

[33] ³³
Poh CH, Yuen R, Chung MC, Khoo HE: Purification and partia characterization of hyaluronidase from stonefish (Synanceja horrida) venom. Comp Biochem Physiol B 1992, 101 (1-2):159-163.

[34] ³⁴
Da CB Gouveia AI, Da Silveira RB, Nader HB, Dietrich CP, Gremski W, Veiga SS: Identification and partial characterization of hyaluronidases inLonomia obliqua venom. Toxicon 2005, 45(4):403-410.

[35] ³⁵
Dias SC, Brescovit AD: Notes on the behavior ofPachistopelma rufonigru Pocock (Araneae, Theraphosidae, Aviculariinae). Rev Bras Zool 2003, 20(1):13-17.

[36] ³⁶
Kudo K, Tu AT: Characterization of hyaluronidase isolatedfrom Agkistrodon contortrix contortrix (Southern copperhead) venom. Arch Biochem Biophys 2001, 386(2):154-162.

[37] ³⁷
Nagaraju S, Devaraja S, Kemparaju K: Purification and properties of hyaluronidase from Hippasa partita (funnel web spider) venom gland extract. Toxicon 2007, 50(3):383-393.

[38] ³⁸
Elliott WB: Chemistry and immunology of reptilian venoms. InBiology of the reptilia: physiology B. 8th edition. Edited by Gans C, Gans K. London: Academic Press; 1978:163-436.

Brasil

Brasil

Purification and characterization of a hyaluronidase from venom of the spider Vitalius dubius (Araneae, Theraphosidae)

Abstract

Background

Results

Conclusion

Background

Methods

Reagents

Spiders and venom extraction

Antisera

Enzymatic activity

Purification of Hyaluronidase

SDS-polyacrylamide gel electrophoresis (SDS-PAGE) and zymography

Physicochemical characterization of the enzyme

Immunological comparisons

Statistics

Results

Discussion

Conclusions

Acknowledgements

References

Ethics committee approval

Publication Dates

History