Revista Electrónica:

Depósito Legal: ppi 201502ZU4665 / / ISSN electrónico: 2477-944X

Revista Impresa:

Depósito Legal: pp 199102ZU46 / ISSN 0798-2259

MARACAIBO, ESTADO ZULIA, VENEZUELA

Vol. XXX (3) 2020

UNIVERSIDAD DEL ZULIA

REVISTA CIENTÍFICA

FACULTAD DE CIENCIAS VETERINARIAS

DIVISIÓN DE INVESTIGACIÓN

142

Description of hutmannin-1 a new piii-metalloprotease from the venom / Pineda, M. y col.

ABSTRACT

The objective was to characterise hutmannin-1 (hut-1), a new ~

62 kDa P-III-class metalloprotease from Porthidium lansbergii

hutmanni (P.l.h) (Margarita Island, Venezuela). To characterise

this protein, the crude venom of P.l.h was fractionated by size

exclusion chromatography, anion exchange chromatography and

High Performance Liquid Chromatography (HPLC). Hutmannin-1

was identied by MALDI-TOF/TOF mass spectrometry, and the

venom was analysed by SDS-PAGE. The lethality, minimum

haemorrhagic dose (MHD), eect of temperature on the activity,

procoagulant activity on human plasma, and anticoagulant,

debrinating, gelatinolytic brinolytic, and brinogenolytic and

platelet aggregation activities of hut-1 were determined. Antigenic

recognition assays were performed on P.l.h crude venom and

hut-1 by a venezuelan polyvalent anti-ophidic serum (PAOS)

Hut-1 had strong brinogenolytic and moderate brinolytic

activity. These activities and the haemorrhagic activity of hut-

1 were completely inhibited by EDTA. P.l.h crude venom had

potent anticoagulant activity on recalcied plasma and inhibited

the platelet aggregation induced by thrombin, ADP, collagen and

ristocetin. In contrast, the anticoagulant, coagulant and platelet

aggregation inhibition of hut-1 were not observed with any of the

agonists. This result suggests that other proteins in the crude

venom, markedly impact platelet functions and/or coagulation

factors. Commercial venezuelan antivenin showed limited ability

to neutralise the haemorrhagic activity of hut-1.

Key words: A n t i c o a g u l a n t ; a n t i v e n i n ; c o a g u l a t i o n ; h a e m o s t a s i s ;

haemorrhage; snake venom

RESUMEN

El objetivo de este trabajo fue caracterizar hutmannin-1 (hut-

1), una nueva metaloproteasa de clase P-III de ~ 62 kDa de la

serpiente Porthidium lansbergii hutmanni (P.l.h) (Isla Margarita,

Venezuela). Para caracterizar esta proteína, el veneno crudo de

P.l.h se fraccionó mediante cromatografía de exclusión molecular,

cromatografía de intercambio aniónico y cromatografía líquida

del alto rendimiento (HPLC). Hutmannin-1 se identicó por

espectrometría de masas MALDI-TOF / TOF, y el veneno se

analizó por SDS-PAGE. Se determinó la letalidad, la dosis

hemorrágica mínima (MHD), el efecto de la temperatura sobre

la actividad, la actividad procoagulante en el plasma humano

y las actividades anticoagulantes, desbrinantes, brinolíticos

gelatinolíticos y brinogenolíticos y de agregación plaquetaria de

hut-1. Se realizaron ensayos de reconocimiento antigénico en

P.l.h veneno crudo y hut-1 mediante suero anti-ofídico polivalente

(PAOS) venezolano. Hut-1 tuvo una fuerte actividad brinolítica

y brinolítica moderada. Estas actividades y la actividad

hemorrágica de hut-1 fueron completamente inhibidas por

ethylenediaminetetraacetic acid (EDTA). El veneno crudo de P.l.h

tuvo una potente actividad anticoagulante en plasma recalcicado

e inhibió la agregación plaquetaria inducida por trombina, ADP,

colágeno y ristocetina. En contraste, la inhibición de la agregación

plaquetaria, actividad anticoagulante y coagulante de hut-1 no

se observó con ninguno de los agonistas. Este resultado sugiere

que otras proteínas en el veneno crudo, afectan notablemente

las funciones plaquetarias y / o los factores de coagulación. El

antiveneno comercial venezolano mostró una capacidad limitada

para neutralizar la actividad hemorrágica de la hut-1.

Palabras clave: A n t i c o a g u l a n t e ; a n t i t o x i n a ; c o a g u l a c i ó n ;

hemostasia; hemorragia; veneno de serpiente

Recibido: 24/01/2020 Aceptado: 12/08/2020

DESCRIPTION OF HUTMANNIN-1, A NEW PIII-METALLOPROTEASE

FROM THE VENOM OF THE NEOTROPICAL LANSBERG’S HOGNOSE

VIPER (Porthidium lansbergii hutmanni) WITH FIBRINO(GENO)LYTIC

AND HAEMORRHAGIC ACTIVITIES

DESCRIPCIÓN DE HUTMANNIN-1, UNA NUEVA METALOPROTEASA PIII DEL VENENO

DE LA SERPIENTE NEOTROPICAL MAPANARE DE LANSBERG (Porthidium lansbergii

hutmanni) CON ACTIVIDADES FIBRINO (GENO) LÍTICAS Y HEMORRÁGICAS

María Eugenia Pineda

, Jonás Perales

, Elda Eliza Sánchez

, Tomas Hermoso

, María Narvaez

Alexander Chapeaurouge

, Alba Marlene Vargas

and Alexis Rodríguez-Acosta

Biotechnology Unit of the Pharmacy Faculty, Universidad Central de Venezuela, Caracas, Venezuela.

Laboratory of Toxinology, Oswaldo Cruz Institute, Fiocruz, Rio de Janeiro, Brazil.

National Natural Toxins Research Center, Department of Chemistry, Texas A&M University-Kingsville, Kingsville, Texas, USA.

⁴Parasite Biochemistry Section, Tropical Medicine Institute of the Universidad Central de Venezuela, Caracas, Venezuela.

Immunochemistry and Ultrastructural Laboratory, Anatomical Institute, Universidad Central de Venezuela, Caracas, Venezuela.

E-Mail: rodriguezacosta1946@yahoo.es jonasperales@gmail.com

143

Revista Cientíca, FVC-LUZ / Vol. XXX, N° 3, 142 - 156, 2020

INTRODUCTION

Snake bite is a signicant work-related and countryside

menace in the tropical and sub-tropical Countries. Precise

statistics of the occurrence of snakebite and its morbidity and

mortality throughout dierent geographical areas does not exist;

nevertheless, it is sure that it is higher than what is ocially

reported. Clinical and toxinologically, description of snake

envenomations are considered into haemotoxic, neurotoxic, and

myotoxic pathological conditions.

Haemorrhagic signs are the characteristic symptoms associated

with Viperidae snake bites. This activity has been attributed to

haemorrhagic enzymes, usually metalloproteases. Several

studies have investigated the haemostatic eects of Viperidae

snake venoms and their isolated protein components [10, 16,

37, 40, 41]. Proteolytic enzymes and myotoxins are the central

components in the venom of members of the Viperidae family,

among which snake venom metalloproteases (SVMPs) induce

symptoms such as haemorrhages [36, 45]. These proteases

interact with dierent targets to regulate haemostasis or with

important tissues associated with vital physiological functions

in prey and predators, causing the most palpable eect:

haemorrhages [3]. The dierent actions of these proteases

involve dierent targets, such as the activation of coagulation

factors [43], brinogen [14], and the endothelial extracellular

matrix of capillary vessels [21].

The taxonomic classication of species in the Porthidium genus

has been controversial over the past several years. Species of

this genus were previously included in the literature as members

of the Bothrops genus [29] however, based on taxonomic

criteria and molecular studies, phylogenetic relationships

have been established among Viperidae family members in

the Porthidium, Atropoides and Cerrophidion genera in the so-

called “Central American Lineage», which is widely distributed in

Central America [2, 6, 23]. In this lineage, the Porthidium genus is

the only genus found in Venezuela [4, 11, 44]; this lineage forms

a paraphyletic group of «South American Lineage» genera and

comprises Bothrocophias, Bothrops and Bothriopsis [4, 11, 31].

The main objective of this work was the purication and the

biological-biochemical characterisation of a haemorrhagic

component found in the venom of the snake Porthidium lansbergii

hutmanni (P.l.h).

MATERIALS AND METHODS

Reagents

The next materials were used for electrophoresis: reagents

(Bio-Rad, USA) and immobilized pH gradient (IPG) strips, pH

3-10, 11 centimetres (cm) (Bio-Rad, USA). The following materials

were used for haemostasis: human brinogen (Sigma, MO, USA)

and bovine thrombin (Sigma, MO, USA). These materials were

used for immunoblotting: equine peroxidase-coupled-equine IgG

antibody (Santa Cruz Biotechnology, CA, USA); nitrocellulose

membrane (Bio-Rad, USA); and SuperSignal West Pico®

chemiluminescence development kit (ThermoScientic, USA).

These materials were used for MALDI-TOF/TOF: α-cyano-4-

hydroxycinnamic acid matrix (α-CHCA) (Sigma, MO, USA); ACN;

triuoroacetic acid (TFA); and diethyl ether (Sigma, MO, USA). The

next materials were used for LC-MS/MS: OFFGEL RoomTemp

HighRes® Kit (Agilent Technologies, USA); IPG strips, pH 3-10,

24 cm strips (GE Healthcare, USA); swine trypsin (PROMEGA);

electro spray calibrant solution 63606; and Calibration Tune Mix

ESI (Sigma-Fluka, USA). Working solutions were composed

of reagents of high purity (≥98%, Merck and Riedel de Haen,

Germany). Polyvalent antiophidic serum (PAOS) was obtained

from Biotecfar C.A., Caracas, Venezuela.

Software

Prism® (GraphPad, Software) [51] was used for statistical

analyses. For one dimension gels analysis and two-dimensional

gels electrophoresis analysis QuantityOne® (Bio-Rad, USA)(54)

and PDQuest® (Bio-Rad) [48], respectively, were used. For the

MALDI/TOF experiment, the Compass 1.2 SR1 for Flex Analysis

(BrukerDaltonics)[30} software was employed.

The liquid chromatography (LC)-MS/MS analysis was done

with the Compass 1.2 SR1 program for Microtof/Maxis® (Bruker-

Daltonics).

Experimental animals

The animals were purchased from the National Institute of

Hygiene “Rafael Rangel” (Caracas, Venezuela) animal facility. The

mice were kept in cages at room temperature with 12 hours (h) of

natural light and ad libitum water and food until experimentation.

Male mice (Mus musculus) of the National Institute of Health

(NIH) strain weighing 20 to 22 grams (g) and 25 to 27 g were used

to determine lethality and haemorrhagic activity, respectively.

Venom

The pooled P.l.h venom was obtained by manually milking

11 adult specimens of both sexes that were captured at 3

metres above sea level (m.a.s.l) in the at regions of Margarita

Island, Nueva Esparta State (Venezuela),The animals were

captured in Macanao peninsula, geographically located at

Longitude: “O64°16’59.99” and Latitude: “N11°1’0.01”). The

area these specimens originate from has a climate favourable

to xerophytes; the climate is inuenced by northeast trade

winds (“vientos aliseos”), the tropical oor as an average

annual temperature of 28°C and an annual rainfall less than

800 millimetres (mm), and the vegetation is very similar to the

Venezuelan coastal inland vegetation. The majority of this area

comprises at terrain, and common vegetation is the arborescent

cacti group known as “Cardonal”, which is mainly characterised

by columnar cacti (“cardones”) and spiny Mimosaceae with a

squat appearance (“cujíes”). The prevailing vegetation near

144

Description of hutmannin-1 a new piii-metalloprotease from the venom / Pineda, M. y col.

the seashore is these “Cardonales”; however, spine bushes or

“Espinares” (“cujíes”) are common inland [38].

On the other hand, the Bothrops colombiensis venom originated

from the pooled venom of 12 adult specimens of both sexes,

which were captured in dierent Venezuelan regions. All snakes

were maintained in captivity in the Serpentarium of the Pharmacy

School Faculty, Universidad Central de Venezuela (Caracas,

Venezuela). Once obtained, the venom was crystallized under

vacuum in a desiccator (Pyrex

, 2.4L Small Knob Top Desiccator

Corning, USA) containing CaCl

as a desiccant and maintained

at 4°C (Frigidaire FGVU21F8QF Vertical Freezer, USA) until use.

Fractionation of P.l.hcrudevenombygelltration

The fractionation of the P.l.h crude venom was initiated with

a Sephadex

G-100 molecular sieve chromatography column

(90 x 2.5 centimetres (cm) following the method by Grillo and

Scannone [18]. Venom samples were dissolved in 5 millilitres (mL)

of mobile phase, composed of 0.2 Molar (M) ammonium acetate

buer at pH 6.8 (four runs were performed, for a total of 1000

milligrams (mg of venom). Protein elution was achieved by mobile

phase at a ow rate of 7 mL/h. The eluates were monitored at

280 nanometres (nm). Fractions were lyophilised, weighed, and

stored at -20°C (Frigidaire FGVU21F8QF Vertical Freezer, USA)

until used to evaluate haemorrhagic action. To determine which of

the fractions (FI to FIV) obtained from P.l.h venom by molecular

exclusion had the highest haemorrhagic activity, a single dose

of 1 microgram (μg) in 0.1 mL of the FI and FII fractions diluted

in 0.85% saline solution was inoculated in experimental animals,

and four animals were used per group. The haemorrhagic

area was established as described for the determination of the

Minimum Haemorrhagic Dose (MHD). FI had the highest activity

and was selected for further purication with anionic exchange

chromatography.

Anion exchange chromatography

The fractionation was carried out in an automated work station

(Bio-rad, USA) by means of an anion exchange column [1] in

several stages. Briey, FI was dissolved in a 20 millimolar (mM)

acetic acid/sodium acetate buer at pH 5.4 (“A” solution). Then,

a gradient between solution “A” and an elution buer solution “B”

(20 mM acetic acid/sodium acetate, pH 3.0) was established, with

the percentage of the “B” solution increasing by 10% at each step.

Finally, the proteins that failed to be eluted under these conditions

were subjected to a linear gradient of NaCl at a nal concentration

of 2 M.

Throughout this process, the ow rate of the mobile phase

was 1 mL/minute (min), and protein detection was carried out at

280 nm. A total of 20 runs (100 mg) were performed to obtain a

batch of each fraction. Each individual batch was concentrated

and desalted by centrifugation at 2,500 x G), using concentrator

tubes, with a 3 kilodaltons (kDa) cut-o, until 90% of the volume

was reduced. Then, the samples were resuspended in deionised

water. This process was repeated three times for each fraction

until an aqueous solution with a neutral pH was obtained at an

appropriate protein concentration. The fractions obtained at the

end of this process were stored at -20 °C (Frigidaire FGVU21F8QF

Vertical Freezer, USA) until use.

Selection of the anion exchange fraction of interest

A single dose of 1 µg of protein from each ion exchange

fraction was intradermically injected into experimental animals,

and four animals were used per group. The fraction with the

highest haemorrhagic activity, protein content, and purity as

evidenced by one-dimensional electrophoresis was selected for

toxicological characterization and proteomic identication.

Protein determination

The protein content in the fractions obtained by anion exchange

chromatography was determined [32] using bovine serum albumin

as a standard for the calibration curve.

High-performance liquid chromatography of hutmannin-1

The puried fraction (100 μg) was dissolved in 200 μL of 1%

TFA in deionised water and subjected to a reverse phase C-18

column on an High Performance Liquid Chromatography (HPLC)

(Waters Alliance,) instrument.

A linear gradient from 0 to 100% acetonitrile (ACN) in 0.1%

TFA was established over one h at a ow rate of 1 mL/min. The

eluates were detected at 280 nm. The appearance of a single,

acute and symmetric peak was considered the purity criterion of

the component named hut-1.

Identicationofhutmannin-1withMALDI-TOF/TOFmass

spectrometry

The identication of hut-1 was carried out at the Toxicology

Laboratory, Department of Physiology and Pharmacodynamics,

Oswaldo Cruz Institute, Rio de Janeiro, Brazil. For this method,

band fragments from SDS-PAGE were treated with 65 mM DL-

Dithiothreitol (DTT) (Sigma-Aldrich, USA) for 30 min at 56°C to

reduce the protein disulphide bonds, and then the samples were

subjected to alkylation with 100 μL of 200 mM iodoacetamide

for 30 min. Later, the gel fragments were decolourised with 50%

ACN in 25 mM ammonium bicarbonate at pH 8.0, dehydrated

with 200 μL of ACN and trypsinised with 15 μL of a (20 ng/μL)

trypsin solution, prepared in 40 mM ammonium bicarbonate.

The obtained peptides were analysed by MALDI-TOF/TOF mass

spectrometry [14, 39]. The mass spectrum was obtained, and de

novo sequencing of the analysed peptides was carried out. The

obtained sequence was compared with the protein sequences

deposited in the NCBI (National Center for Biotechnology

Information, USA) with the BLAST program.

Assessment of FI and hutmannin-1 haemorrhagic potency

145

Revista Cientíca, FVC-LUZ / Vol. XXX, N° 3, 142 - 156, 2020

ateachpuricationstep

The performance of FI and hut-1 was dened as the per-cent

increase in haemorrhagic potency at each purication step.

SDS-PAGE analysis of venom

SDS-PAGE (12% gel) was carried out [28]. Briey,

samples were dissolved at a concentration of 5 μg/μL in a

protease inhibitor cocktail composed of 4-(2-aminoethyl)-

benzene-sulphonyl uoride (AEBSF), E-64, bestatin, leupeptin,

aprotinin and disodium

EthylendiamineTetraacetic acid (EDTA), and then the samples

were diluted to the optimum concentration for visualisation in 0.5

M Tris-HCl buer at pH 6.8, 10% SDS, 1% glycerol and 0.02%

bromophenol blue. For hut-1, a sample under reduced conditions

was also prepared. Once loaded in their respective gel wells, the

samples were run at 100 V for approximately 120 min. Afterward,

the appropriate gels were selected for Blue Silver staining [5],

which has a sensitivity of 1 ng per band. Next, the gels were

washed with deionised water to remove excess dye and digitised.

Each experiment was performed in triplicate.

Hutmannin-1 lethality

Venom lethality (deaths and signs of toxicity) was determined

in mice intravenously injected with 50 μg or 25 μg of hut-1

samples, corresponding to doses of 2.5 mg/kg and 1.25 mg/kg,

respectively. These doses were selected on basis of the lethality

of the crude venom and FI. The animals were autopsied, and the

macroscopic observations of the haemorrhages were performed.

Determination of the minimum haemorrhagic dose (MHD)

To determine the MHD of the P.l.h hut-1, a modied

method [27] was used. Serial doses of hut-1 in the range of 0.0088

μg to 0.044 μg were intradermally injected into the depilated

backs of mice (Mus musculus). The mice were sacriced, and the

skin was removed after 2 h. The diameter of the haemorrhage on

the skin was measured, and the MHD was dened as the amount

of venom protein required to induce a 10 mm haemorrhage.

With the experimental data, a dose response graph was

constructed. Linear regression analysis was performed to estimate

the MHD from the equation line with Prism® (GraphPad). This

procedure was repeated in triplicate, and the mean and standard

deviation of the MHD were calculated.

Eectoftemperatureonhutmannin-1activity

Hutmanin-1 was prepared in 0.1 mL of 0.85% saline solution

such that the amount of protein corresponded to 10x MHD. From

this solution, 2 mL aliquots were incubated for 30 min at dierent

temperatures: 40, 50, 60, 70, 80, and 90°C. After the incubation

period, 0.1 mL of each sample was injected into groups of four

mice. The diameter of the produced haemorrhagic area was

calculated as indicated for the determination of the MHD. The per-

cent haemorrhagic activity was calculated relative to the activity

of the control, which was a sample incubated for 30 min at 30°C.

Determination of procoagulant activity on human plasma

The ability of P.l.h crude venom and hut-1 to induce blood

coagulation was determined through the physical observation

of clot formation [47] Briey, dierent venom or fraction dilutions

were prepared in a coagulation solution composed of 0.02

M phosphate-saline buered solution (PBS) at pH 7.4. Aliquots

of 50 μL of crude venom and hut-1 dilutions were added to 200

μL of citrated human plasma from healthy laboratory donors. In

the case of crude venom, concentrations ranging from 0.1 μg to

100 μg per 50 μL were used. For hut-1, the concentration ranged

from 5 to 40 μg. The coagulation time was recorded, and the

samples that induced plasma coagulation in less than 30 min

were considered procoagulants.

Four replicates were carried out for each dilution. Additionally,

four tubes of the coagulation control solution without P.l.h crude

venom were prepared. A sample 5 μg of B. colombiensis venom

and 200 μL of plasma as a positive control was also carried out, in

which the coagulation time should not exceed 60 seconds (sec).

Anticoagulant activity determination

In addition to the previous experiment, whether the P.l.h crude

venom or hut-1 inhibited or promoted plasma coagulation when

recalcied was determined [13]. The procedure consisted of

making dilutions of venom or hut-1 preparation in coagulation

solution to contain the required dose in 50 μL of solution. With

crude venom, doses ranging from 0.1 μg to 100 μg were used.

For hut-1 doses from 5 μg to 40 μg, 50 μL of each dilution was

added to 200 μL of citrated plasma and incubated at 37°C for 10

min. During this interval, it was observed if plasma coagulation

occurred. If not, 100 μL of 1 M CaCl

was supplemented to the tube

and again incubated, recording the coagulation time for another

30 min. Four replicates were made for each trial. The experimental

control consisted of 50 μL of 0.85% saline solution and incubated

with plasma in the absence of venom or hut-1.

Determinationofdebrinatingactivity

The ability of venom or fractions to degrade brinogen in

vivo was assessed [13]. Briey, groups of ve (20-22 g) mice were

intravenously injected with dierent dilutions of P.l.h crude venom

(7.5 μg to 120 μg) or a single dose of 25 μg of hut-1, prepared in

0.2 mL 0.85% saline solution. One hour after the injection, blood

was drawn from the axillary plexus of each experimental animal

under anaesthesia. Samples were stored in glass tubes for two

h at room temperature, and clot formation was observed. The

minimal debrinating dose (MDD) was dened as the minimum

amount of venom that induced incoagulability in all inoculated

mice. In addition, a control group was inoculated with 0.85%

saline solution and developed a rm clot one h after collection.

146

Description of hutmannin-1 a new piii-metalloprotease from the venom / Pineda, M. y col.

Determination of the brinogenolytic activity of P.l.h crude

venom and hutmannin-1

To evaluate the proteolytic activity of P.l.h crude venom and hut-

1 on the α, β, and γ chains of brinogen, we proceeded according

to a modied protocol [34]. In brief, a stock solution of puried

human brinogen was prepared at a concentration of 2 mg/mL in

a 0.1 M Tris-HCl buer solution at pH 7.4. Dierent concentrations

of P.l.h crude venom (0.03 μg to 2 μg) and hut-1 (0.5 μg to 32 μg)

were incubated at 37°C for 30 min with pre-prepared aliquots of

brinogen solution (50 μL/100 μg). After incubation, each sample

was diluted 1:1 with reducing solution containing 0.5 M Tris at pH

6.8, 10% SDS, 1% glycerol, 0.02% bromophenol blue, and 3%

2-β-mercaptoethanol. Then, the samples were placed in a water

bath (Whip Mix, WPM-05350, USA) at 100°C for 5 min. An aliquot

of 15 μL of each sample was electrophoresed as indicated.

The degradation of dierent brinogen chains was observed.

A brinogen sample was run under the same conditions in the

absence of P.l.h crude venom or hut-1.

Determinationofbrinogenolyticactivityasafunctionof

time

After establishing the lowest amount of crude venom (0.25

μg) and hut-1 (1 μg) capable of completely degrading the α chain

of human brinogen under the conditions described above, the

appropriate concentrations of venom and hut-1 were incubated

with 100 μg of brinogen at 37°C for the following incubation

periods: 30 seconds, 1 min, 5 min, 15 min, 30 min, 60 min, 3 h

and 24 h. Subsequently, to determine the brinogenolytic activity,

these samples were electrophoresed (SDS-PAGE) as indicated

and compared to the electrophoretic pattern of a control sample

consisting of the corresponding dose of crude venom or fraction,

incubated with 100 μg of brinogen and immediately subjected to

the reducing action of the reducing solution (time 0).

Eectofproteaseinhibitorsonbrinogenolyticactivity

Constant amounts of P.l.h crude venom (1 μg) and hut-1 (2 μg)

were incubated at 37°C for 30 min with 100 μg of human brinogen

in a 0.02 M Tris-HCl buer solution at pH 7.5. To evaluate the

brinogenolytic serine protease activity, 2 mM benzamidine

was added to the incubation mixture, whereas to evaluate the

metalloprotease activity, EDTA was added to the samples. As

controls, samples without protease inhibitors were used. After the

incubation period, the samples were evaluated by SDS-PAGE as

indicated to determine brinogenolytic activity.

EectofthepHonbrinogenolyticactivity

A constant dose of hut-1 (50 µL/3 μg) was prepared in the

following buer solutions at dierent pH values: citric acid/0.1

MNa2HPO4 (pH 3, pH 4, pH 5 and pH 6) and 0.1 M Tris-HCl (pH

7, pH 8, pH 9 and pH 10). The mixtures were incubated at 37°C for

30 min with (50 µL/100 μg) human brinogen, and then SDS-

PAGE was performed as indicated to determine brinogenolytic

activity.

Determinationofbrinolyticactivity

The ability of P.l.h crude venom and hut-1 to degrade brin

was determined [34]. Briey, 1.5 mL of 0.1% brinogen solution

in imidazole-buered 0.85% saline solution at pH 7.4 was added

to Petri dishes (3 cm). Then, 75 μL of 10 U/mL bovine thrombin

containing 0.025 M CaCl

was added to form a uniform brin

layer. Afterward, 10 μL (1 μg/μL) of crude venom or 10 μL of (1

μg/μL) hut-1 in 0.85% saline solution was placed in the centre of

the brin layer and incubated for 24 h at 37°C. After the incubation

period, the diameter of the lysis area on the brin surface was

determined. Fibrinolytic activity was expressed as the diameter

(mm

) of the lysis area per microgram of venom or fraction.

Determination of proteolytic activity on gelatine

The modied methodology proposed by Terra et al. [46] was

followed for this step. Discontinuous 12.5% polyacrylamide gels

copolymerised with 1% gelatine were run. Then, 3 mL of each

sample of P.l.h crude venom and hut-1 at a concentration of 2 μg/

μL in 0.5 M Tris buer at pH 6.8, 10% SDS, 1% glycerol and 0.02%

bromophenol blue, was added to the gel. In addition, as a positive

control, 1 μL (2 μg/μL) of B. colombiensis venom was added to

the gel. After electrophoresis, the gel was equilibrated in a 2.5%

Triton X-100 solution, stirring for 1 h at room temperature, washed

with double distilled water (two washes of 10 min each) and

incubated at 37°C for 18 h in a buer solution of 20 mM Tris-HCl

at pH 7.4, 150 mM NaCl, and 5 mM CaCl2. The proteolytic activity

on gelatine was evidenced by the zones of degradation in the

gel, which were observed as translucent areas after Coomassie

R-250 blue staining. [5].

DeterminationoftheeectsofP.l.h crude venom and

hutmannin-1 on platelet aggregation

The eects of venom and hut-1 on platelet aggregation were

assessed by the turbidimetry method [7]. Briey, blood was

obtained from healthy laboratory donors and centrifuged at 190 x

G and 20°C for 15 min to obtain platelet-rich plasma (PRP). After

counting platelets, an aliquot was subjected to a second

centrifugation at 1700 x G for 15 min to obtain the platelet-poor

plasma (PPP). The plasma used during the trials consisted of the

PRP at a concentration of 1x10

platelets/mL adjusted with the

PPP.

Each measurement was obtained in an aggregometer (Crono-

Log

560, USA), and aliquot suspensions of 500 μL were

placed under agitation at 37°C in a silicon cuvette during the

determination. A total of 10 μL of dierent dilutions of crude venom

(0.6 μg to 16 μg), prepared in normal saline solution, were added to

each sample. For hut-1, an amount corresponding to ve times the

of crude venom value was used. After 4 min, the aggregation

agonists ADP (10 μM), ristocetin (1.25 mg/mL), collagen (8 μg/

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mL) and thrombin (1 U/mL) were added. The aggregation curve

was recorded over 8 min for all assays. As a reaction control, the

agonists were placed on the platelet suspension without venom

and instead adding 10 μL of 0.85% saline solution. In the case

of crude venom, a dose response curve was prepared with the

obtained results, and IC

of each agonist was determined. The

was dened as the amount of venom capable of reducing

platelet aggregation by 50% with respect to the control.

Neutralisation and antigenic recognition assays of P.l.h crude

venom and hutmannin-1 by the polyvalent anti-ophidic serum

Neutralisation of haemorrhagic activity

The antivenom used in the neutralisation experiments was

PAOS, produced by the Biotechnology Centre of the Faculty of

Pharmacy of the Universidad Central de Venezuela (Biotecfar C.

A), lot L-162. PAOS consists of F(ab)

fragments of hyperimmune

immunoglobulins obtained from horses. (Equus ferus caballus)

The species used for the immunisation were Crotalus durissus

cumanensis, Crotalus vegrandis, Crotalus pifanorum,

Crotalus ruruima, Bothrops atrox, B. colombiensis, Bothrops

venezuelensis, and P.l.h.

The capacity of PAOS neutralising the haemorrhages induced

by P.l.h crude venom, FI and hut-1 was determined. Briey,

crude venom, F1 or hut-1 was combined with dierent antivenom

dilutions, using as a reference value of the titre declared by the

PAOS manufacturer for Bothrops genus (1 mL of PAOS must

neutralise the activity of 2 mg of Bothrops venom).

The neutralising test was prepared to obtain 10 MHD in 0.1

mL of the mixture and dierent venom/antivenom proportions of

crude venom, F1 or hut-1. The mixtures were incubated for 30

min at 37°C and centrifuged at 2,500 x G for 10 min to eliminate

the antigen-antibody complexes that formed.

The experimental animals were assigned to groups of ve mice

each. Each mouse in the groups was injected with 0.1 mL of the

appropriate venom/antivenom mixture.

Additionally, there was a venom control group challenged with the

crude venom or fraction and a serum control group that received

the highest PAOS dose used in the experiments. Two h after the

injection, the haemorrhagic lesion as described for the MHD was

evaluated. The per-cent reduction in the haemorrhagic lesion

diameter induced by each dose was calculated with respect to the

control. The ED

was dened as the amount of PAOS capable of

reducing the diameter of the haemorrhagic lesion by 50%.

Immunoblotting assays

The PAOS reactivity against the epitopes present in

the P.l.h crude venom and hut-1 were evaluated using western

immunoblotting. In this determination, the selected gel was

incubated for 10 min in transfer solution (50 mM Tris-HCl at pH

8.0, containing 380 mM glycine, 0.1% SDS and 20% methanol).

Then, the gel was placed in a transfer chamber, allowing the

proteins to pass from the polyacrylamide matrix to a nitrocellulose

membrane. This process was carried out at 180 milliampers (mA)

for 2 h.

After the transfer, the nitrocellulose membrane was blocked for

2 h at room temperature with a 0.2 M PBS solution at pH 7.0, with

5% (w/v) skimmed milk and 0.1% (w/v) Tween 20. Later, three

washes were performed for 5 min, each with a solution of 0.05%

(w/v) Tween 20 and 0.2 M PBS at pH 7.0. The membrane was

incubated again at room temperature for another 90 min, with

PAOS diluted to 1:3000 in blocking solution. After the incubation

period, the membrane was washed three times with the washing

solution for ve min each wash. Immediately after the washes, the

secondary antibody anti-equine IgG (coupled to horseradish

peroxidase) diluted 1:7000 in blocking solution was added. Then,

the membrane was incubated at room temperature for another 90

min and washed, as indicated. The electrophoretic bands

recognised by PAOS were visualised using a chemiluminescence

development kit, and the image was analysed.

Eectofproteaseinhibitorsonthehaemorrhagicactivityof

hutmannin-1

The eect of protease inhibitors on the haemorrhagic activity of

hut-1 was tested using EDTA, a metalloprotease activity inhibitor,

and benzamidine, a trypsin or trypsin-like inhibitor. In each case,

the proteases were preincubated with the corresponding inhibitor

at 37°C for 30 min.

Six experimental groups, consisting of four mice each, were

used. Each mouse was inoculated with dose of hut-1 that

corresponded to 5 times the MHD. The rst group received hut-1

preincubated with 2 mM EDTA, the second group was inoculated

with hut-1 preincubated with benzamidine, and the third group

received a dose of hut-1 preincubated in 0.85% saline solution,

representing the haemorrhage control group. The remaining

groups were inoculated with the following vehicles: 0.85% saline

NaCl, 2mM EDTA and 2 mM benzamidine. Each animal was

injected and the haemorrhagic area was determined as indicated

to determine MHD. The arithmetic mean was calculated for the

results of each group. The per-cent reduction induced by the

protease inhibitors was calculated by considering the diameter

of the haemorrhagic area for the crude venom control group as

100%.

Statistical analysis

The MHD and neutralisation were analysed by linear regression.

The data were expressed as the mean ± standard deviation.

To determine dierences between experimental groups (three

replicates of each condition), one-way ANOVA with Dunnett’s post

hoc test was used to compare the experimental conditions to the

control conditions. Results with an error probability <0.01 were

148

Description of hutmannin-1 a new piii-metalloprotease from the venom / Pineda, M. y col.

considered signicant. Analysis was completed using SPSS

version 2.0 [35]

RESULTS AND DISCUSSION

The majority of snake venoms exert their actions on almost

all tissues, and their pharmacological activities are determined

by several biologically active fractions [21]. The most signicant

components of these bioactive fractions are SVMPs, the major

components of the venom produced by the Porthidium genus [23,

29]. SVMPs are enzymes considered to have the highest

haemorrhagic potential among the components of Viperidae

snake venoms. These proteins are capable of degrading

extracellular matrix proteins such as laminin, nidogen,

bronectin, type IV collagen (constituents of vessel walls) and

proteoglycans in the endothelial basement membrane, which

promotes the diusion of venom through the membranes and

weakens the capillary structure. Together with the hydrostatic

pressure generated inside the blood vessel, SVMPs can produce

blood extravasation [9]. Other toxic activities attributed to these

enzymes include brinogenolytic activity, prothrombin and Factor

X activation, apoptosis induction, platelet aggregation inhibition,

proinammatory activity, and inactivation of serine protease

blood inhibitors [26, 33]. Most Viperidae snake venoms alter

blood coagulation, but there are a few venoms, such as those

produced by Bothriechis lateralis and Porthidium nasutum, that

do not alter blood coagulation; however, these venoms do induce

haemorrhages due to other protease activities [19] According to

the current analysis of P.l.h crude venom, only high concentrations

of F1 showed procoagulant activity, indicating that the proportion

of proteins with procoagulant activity is low in this venom.

Other researchers [25, 37] have reported that mammalian

experimental models with disrupted platelet aggregation did not

present abnormalities in coagulation tests, despite showing signs

of systemic haemorrhaging.

In the size exclusion chromatography, four protein peaks

from the P.l.h venom were obtained (data not shown). Two

predominant fractions were isolated (FI and FII) and used for

further purication. These fractions presented the largest areas in

the chromatogram. FI (1 μg) produced the largest haemorrhagic

area (22.29 ± 2.79 mm) on mouse skin and was selected for the

next purication stage using anion exchange chromatography. FII

at this dose did not produce any haemorrhagic lesions, and it was

discarded.

After passing FI through an anion exchange chromatographic

column, seven well-dened peaks were obtained [FIG.1]. A total

of 20 runs were carried out, and the fractions (named according

to the percentage of buer “B” composing the mobile phase) were

grouped and homogenised as follows: rst, a fraction called F0%

(tubes 5 and 6), whose protein content did not interact with the

negatively charged resin. Second, a series of fractions were bound

to the resin with dierent anities, according to their isoelectric

point and that required a decreasing pH mobile phase for elution:

F20% eluted at pH ~ 5.0 (tubes 28 and 29); F30% eluted at pH ~

4.5 (tubes 37 and 38); F40% eluted at pH ~ 4.0 (tubes 46 and 47);

F60% eluted at pH ~ 3.5 (tubes 56 and 57); and F100% (tubes

66 and 67) eluted at pH ~ 3.0. The peak obtained with the salt

gradient was also collected and called FNaCl (tubes 81-82).

FIGURE 1. PURIFICATION OF HUT-1 BY ANION EXCHANGE

CHROMATOGRAPHY. Fraction I obtained from the crude venom

of P. lansbergii hutmanni was applied to a Q1 column (BioRad,

USA). Elution was performed by establishing a pH step gradient

with buer pH 3 in ve steps (20, 30, 40, 60 and 100%) during

rst 73 min of the run (showed on X axis), following with a NaCl

2M gradient, evidenced by an increasing of conductivity value

expressed in mS/cm. The fraction with the highest haemorrhagic

activity was called hut-1 and was selected to check its homogeneity

by means of HPLC.

Mice were intradermally injected with 1 μg of the protein

from the anion exchange fractions, and the haemorrhagic

lesions that resulted from these injections are shown in TABLE

I. The fractions F40%, F60%, F100% and FNaCl had a strong

haemorrhagic action. The fraction F100% was selected for further

biochemical and toxicological characterisation because it has the

highest haemorrhagic activity.

TABLE I

HAEMORRHAGIC LESIONS PRODUCED BY ANION

EXCHANGE FRACTIONS

Anion exchange

fraction

Haemorrhagic lesion (10 mm

diameter)

(μg protein/fraction)

F0% NH

F20% NH

F30% NH

F40% 20.7 ± 0.5µg

F60% 20.9 ± 0.6µg

F100% 22.5 ± 0.3µg

FNaCl 17.8 ± 0.8µg

NH: No haemorrhages were observed.

It was possible to purify a 62 kDa protein called hut-1 using a

combination of size exclusion chromatography and anion exchange

chromatography. Hut-1 showed a single protein peak that eluted

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during the acetonitrile (ACN) gradient under high-performance

liquid chromatography (HPLC). As shown in FIG.2, this peak was

symmetric, and no major peaks corresponding to protein sample

contaminants were observed. This protein was composed of a

single polypeptide chain, as evidenced by treatment with the

reducing agent B-mercaptoethanol. Hut-1 was identied as a

member of the SVMP family, with homology to class P-III of the

zinc-dependent metalloprotease domain family based on the

molecular mass determined by tandem mass spectrometry (MS/

MS). The toxic action of hut-1 demonstrated that, similar to other

SVMPs [45], its main toxicological targets were haemostasis

components.

symmetric, and no major peaks corresponding to protein

sample contaminants were observed. This protein was composed

of a single polypeptide chain, as evidenced by treatment with

the reducing agent B-mercaptoethanol. Hut-1 was identied as

a member of the SVMP family, with homology to class P-III of

the zinc-dependent metalloprotease domain family based on the

molecular mass determined by tandem mass spectrometry (MS/

MS). The toxic action of hut-1 demonstrated that, similar to other

SVMPs [45], its main toxicological targets were haemostasis

components.

FIGURE 2. HIGH PERFORMANCE LIQUID CHROMATOGRAPHY

(HPLC) OF HUT-1. Hutmannin-1 (100 μg) was dissolved in 0.1%

triuoroacetic acid (TFA) and run in a C-18 reverse phase column

(HPLC) with a linear gradient from 0 to 100% acetonitrile (ACN),

in one h at a ow rate of 1mL/min.

Exploring the lethality of P.l.h FI and hutmannin-1 was obtained

that the LD

of FI (1.45 ± 0.16 mg/kg) was lower than that of

the crude venom of P.l.h (2.51 ± 0.16 mg/kg), showing that this

fraction possessed the majority of the toxic components in the

venom. Hut-1 showed high toxicity. It was not feasible to determine

the LD

of hut-1 because it was not possible to obtain enough

sample for this test; however, when doses as low as 2.63 mg/kg

and 1.32 mg/kg were tested, all the animals died within 24 h after

the injection, which indicated that the hut-1 LD

was below 1.32

mg/kg. Before the animals injected with both doses of hut-1 died,

they all presented motor incoordination, accid paralysis in the

anterior and posterior limbs, cyanosis, respiratory insuciency,

tachycardia and haematemesis. Autopsies of mice revealed atrial

thrombosis and massive pulmonary and hepatic haemorrhages,

indicating the high toxicity of hut-1 (data not shown).

The acute toxicity of hut-1 was found to be more potent than

those of FI and crude venom. This toxicity is notable when

comparing hut-1 with a PI class metalloprotease (Porthidin-1),

previously isolated from P.l.h venom [15], which was found to be

non-lethal in experimental mice intravenously injected with a dose

of 6 mg/kg.

The results obtained in each purication step are shown

in TABLE II. Here, the performance and eciency of the

purication process of hutmannin-1 (hut-1) were determined,

and the minimum haemorrhagic dose (MHD, µg) was obtained at

each purication step.

The MHD of hut-1 was 83 times higher than that of crude venom,

showing that hut-1 is one of the most powerful haemorrhagic toxins

described to date; this conclusion becomes evident when hut-1 is

compared with similar toxins from the venoms of various Viperidae

snakes [49]. Moreover, the autopsies of mice treated with hut-

1 showed extensive systemic haemorrhages. The macroscopic

study of the lung tissue of treated mice revealed profuse

haemorrhages in the lung, and these lesions rapidly appeared

15 min after injection. Observations of the structural changes that

occur following exposure to P.l.h crude venom [49] revealed the

appearance of erythrocytes and glomerular kidney oedema,

as well as the detachment from the basement membrane and

plasma membrane rupture of endothelial cell. This result could

demonstrate the possible systemic haemorrhagic activity of hut-1,

the haemorrhagic fraction from this venom. Previous studies that

investigated other metalloproteases from Bothrops snakes, such

as jararagin, have shown that similar pulmonary haemorrhages

occur in mice [8, 36]. The MHD value is shown in TABLE II. At

nanogram (0.0088 to 0.044 μg) doses, hut-1 presented a

high haemorrhagic capacity, resulting in bleeding skin lesions in

the experimental animals (data not shown).

TABLE II

PERFORMANCE AND EFFICIENCY OF THE

PURIFICATION PROCESS OF HUT-1. THE MHD

ACTIVITY (µG) RESULTS OBTAINED AT EACH

PURIFICATION STEP

Sample Amount

obtained

MHD

activity

(µg)

Purication

factor

Crude

venom

1000 mg 1.475 1

Fraction I 697.2 mg 0.102 14.5

Hutmannin-1 39 mg 0.021 69.9

Hut-1 maintained its haemorrhagic activity when

incubated for 30 min at 40°C, but haemorrhagic activity of hut-

1 decreased by approximately 20% after incubation at 50°C for

the same period of time. After exposure to temperatures equal

to or higher than 60°C, hut-1 completely lost its haemorrhagic

capacity [FIG. 3A]. This temperature restriction is similar to the

temperature restriction of other viperid metalloproteases, such

as uracoin-1 [1], and elapid metalloproteases, such

as EpyHTI and EcoHTI, which presented a 50% reduction

in haemorrhagic activity at temperatures close to 50°C and

completely lost activity at 70°C [49].

150

Description of hutmannin-1 a new piii-metalloprotease from the venom / Pineda, M. y col.

The haemorrhagic activity of hut-1 was completely abolished

by preincubation with 2 mM EDTA, a metal chelator, whereas

preincubation with 2 mM benzamidine, a trypsin or trypsin-like

inhibitor, did not induce signicant dierences from untreated hut-

1 (n=4, FIG. 3B), demonstrating the dependence of the activity of

hut-1 on divalent ions, as previously reported for a large variety of

metalloproteases [7,15,16,19, 36, 46].

FIGURE 3. EFFECT OF TEMPERATURE AND PROTEASE

INHIBITORS ON THE HAEMORRHAGIC ACTIVITY OF HUT-1.

(A) 1: Control; 2: 40

C; 3: 50

C; 4: 60

C; 5: 70

C; 6: 80

C. The

bars represent the standard error. Dunett test one-way ANOVA

analysis = * α <0.05 ** α <0.01. (B) 1) control; 2) Hut-1 + 2 mM

EDTA; 3) Hut-1 + 2mM benzamidine. The bars represent the

standard error. Dunett test one-way ANOVA analysis = ** α <0.01

The haemorrhagic potential of high class

P-III metalloproteases has been attributed to two main facts: (1)

the inability of α2-macroglobulin to inhibit these toxins and (2)

the presence of domains with disintegrin-like activity that are rich

in cysteine residues and specically degrade extracellular matrix

components, especially type IV collagen [22].

The identication hutmannin-1 by tandem mass spectrometry

showed that the fragmentations with matrix assisted

laser desorption/ionization (MALDI) time-of-ight mass

spectrometry (TOF) resulted in two main signals: m/z 3182.95

and 2197.84. The defragmentation of these peptides and

their subsequent de novo sequencing led to the identication of

two peptide sequences, NLLVAVTMAHELGHNL (m/z: 3182.95)

and VECETGECC (m/z: 2197.84), which are sequences of zinc-

metalloprotease domains found in SVMPs.

FIGURE 4. NCBI/BLAST search comparison of arrangements de novo peptide NLLVAVTMAHELGHNL and VECETGECC sequenced

from MS/MS spectrometry, of Hutmannin-1 to partial amino acid sequences of two snake venom metalloproteases, atrolysin-A 17 and

metalloprotease-8 [18]. The sequence similarities are shown in the gure

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Revista Cientíca, FVC-LUZ / Vol. XXX, N° 3, 142 - 156, 2020

After analysing these sequences with the BLASTp program,

hut-1 was identied as an SVMP, showing similarity with

adamalisin-1 (Crotalus adamanteus), atrolysin-A (Crotalus

atrox) (E-value 9e-07) [23], metalloprotease-8 (C. adamanteus)

(E-value 5e-07) [41], and an additional 43 SVMPs [24], all with

E-value estimates that are considered signicant (≤1e -04). The

similarity of the sequences obtained with the sequences of these

proteins is shown (FIG. 4).

The electrophoretic analysis of FI [FIG.5] revealed that the

chromatographic process was ecient; primarily high molecular

weight proteins were detected in this fraction (8 bands between

36 kDa and 170 kDa). Moreover, the predominance of the 62 kDa

band was observed. The concentration of the 170 kDa and 36

kDa bands was increased in FI compared with the total venom,

whereas the concentration of the 54 kDa band was decreased

in FI. No bands of proteins less than 36 kDa in mass were

detected. Next, the electrophoretic analysis of hut-1 [FIG.5]

showed a single 62 kDa band that was observed both in the

crude venom and in FI.

FIGURE 5. Porthidium l. hutmanni SDS-PAGE. A) molecular

weight markers; B) crude venom; C) FI; D) hutmannin-1 under

native conditions; E) hutmannin-1 under reduction conditions. All

samples were run with 25µg of protein.

After hut-1 was reacted with the reducing agent 2-β-mercaptoethanol

and subsequently underwent electrophoresis, a single band with a

slightly higher molecular weight than the unreduced protein (~ 69

kDa) was observed. This result suggested that hut-1 is composed

of a single polypeptide chain.

In the procoagulant activity of FI and hutmannin-1 was

demonstrated that FI of the P.l.h venom dose-dependently induced

the coagulation of human plasma, as measured by physical clot

formation; all the tested FI doses were markedly more eective

than 5 μg of B. colombiensis venom, in which the plasma

coagulation time was 40 sec (data not shown). Hut-1 did not show

plasma procoagulant activity during 30 min of incubation (data

not shown). On the other hand, Hut-1 did not show anticoagulant

activity on human plasma. Compared to the control, hut-1 did

not signicantly aect the recalcied plasma coagulation times

at the highest doses tested 200 μg (data not shown). The

experimental results indicated that mice treated with FI or hut-

1 maintained their coagulant capacity 2 h after the intravenous

injection of each fraction. This result shows that FI and hut-1 lack

debrinating activity.

In the brinogenolytic activity assay, P.l.hutmanni crude venom

degraded the brinogen Aα chain at the concentration of 0.5

μg venom/100 μg brinogen (data not shown). Moreover, hut-1

proved to have potent proteolytic action on the brinogen α chain

at the same hut-1/brinogen ratio of 0.5 μg/100 μg. However, it

was not easy to determine whether the degradation of the A chain

was complete at this ratio; at the 0.5 μg/100 μg ratio, Coomassie

blue staining revealed that the hut-1 band was located at the

FIGURE 6. (I) FIBRINOGENOLYTIC ACTIVITY OF HUT-1/FIBRINOGEN (µG/µG). A) molecular weights; B) 0 μg/100μg; C) 0.5μg/100μg;

D) 1.0μg/100μg; E) 2.0μg/100μg; F) 4.0μg/100μg; G) 8.0μg/100μg; H) 16.0μg/100μg; I) 32.0μg/100μg; J) hut-1 (32μg) in the absence

of brinogen. (II) FIBRINOGENOLYTIC HUT-1 EFFECT AS A TIME FUNCTION. A) molecular weight markers; B) Control (time 0); C)

incubation for 30 sec; D) incubation for 1 min; E) incubation for 5 min; F) incubation for 15 min; G) incubation for 30 min; H) incubation

for 1 h; I) incubation for 3 h; J) incubation for 24 h. (III) EFFECT OF PH FOR THE ACTIVITY OF HUT-1 ON FIBRINOGEN AT 37°C

INCUBATED FOR 30 MIN. A) molecular weight markers; B) pH 3; C) pH 4; D) pH 5; E) pH 6; F) pH 7; G) pH8; H) pH 9; I) pH 10

152

Description of hutmannin-1 a new piii-metalloprotease from the venom / Pineda, M. y col.

same position as the Aα chain gel due to the similar molecular

weights of these proteins. The degradation of the B or y chain

was not observed at any of the tested doses [FIG. 6I]. The eect

of hut-1 on the brinogen α chain was incubation time-dependent.

After incubating 1 μg of hut-1 with 100 μg of brinogen for

dierent time intervals, the degradation of the brinogen α chain

was observed. After 30 min of incubation, the brinogen Aα chain

began to degrade, and it was undetectable after 3 h of incubation.

After 24 h, the Bβ chain was completely degraded [FIG. 6II].

Hut-1 lacks the procoagulant activity of other P-III class

metalloproteases, such as the Factor V activator RVV-X and

the prothrombin activators ecarin and carinactivase-1 [26],

and the debrinating activity associated with the exacerbated

activation of some Porthidium venom coagulation factors, such

as Porthidin-1 [14]. Additionally, the fraction from which hut-1 was

isolated FI showed a procoagulant eect at high concentrations,

suggesting the presence of other low potency procoagulant toxins.

The eect of hut-1 on human brinogen was similar to that of crude

venom on human brinogen, indicating the strong degradation

power of hut-1 on the α subunit of brinogen. In addition, the

β chain was completely degraded after 24 h of incubation. The

optimum pH of this activity was between 7 and 9, similar to that

of colombienases 1 and 2, as previously reported [17] [FIG.6III].

min; G) incubation for 30 min; H) incubation for 1 h; I) incubation

for 3 h; J) incubation for 24 h. (III) EFFECT OF PH FOR THE

ACTIVITY OF HUT-1 ON FIBRINOGEN AT 37°C INCUBATED

FOR 30 MIN. A) molecular weight markers; B) pH 3; C) pH 4; D)

pH 5; E) pH 6; F) pH 7; G) pH8; H) pH 9; I) pH 10.

Hut-1 was completely inhibited by EDTA, conrming that

the metalloprotease action of hut-1 depends on brinogen

degradation [FIG.7].

FIGURE 7. EFFECT OF PROTEASE INHIBITORS ON THE

FIBRINOGENOLYTIC ACTIVITY OF HUT-1. A) Fibrinogen (Fb)

(100µg); B) Fb + hut-1 (100 µg+ 32 µg) ; C) Fb + hut-1 (100 µg+

32 µg) + 2mM benzamidine ; D) Fb + hut- 1 (100 µg+ 32 µg) +

EDTA 2mM.

Alternatively, the degradation of brin mesh induced by hut-1

proved to be less eective than that induced by the zymogen. The

lysis area obtained in the brin plates was 3.5 times

smaller than that obtained with crude venom, wh

ich suggests that toxins other than hut-1 were involved in

the brinolytic activity of P.l.h venom [FIG.8]. Hut-1 showed

more activity against the brinogen molecule than against the

polymerised brin mesh.

FIGURE 8. FIBRINOLYTIC ACTIVITY OF HUT-1. A) Negative

control PBS; B) Positive control B. colombiensis crude venom;

C) P.l.hutmanni crude venom; D) Hut-1.

No proteolytic activity of hut-1 on the hydrolysed collagen

that forms gelatine was observed [FIG.9].

Similarly, several authors have correlated gelatinolytic activity

with the haemorrhagic action of SVMPs [8,39,41,42]; however,

some P-III metalloproteases, such as alsophinase [50] and

VLH2 [20], have high brinogenolytic and haemorrhagic activity

but have not been shown to have gelatinolytic activity [12]

[FIG.9]. In the case of hut-1, it was necessary to evaluate this

activity by using dierent forms of colparticularly type IV collagen,

as collagen is one of the main toxicological targets for these

enzymes. However, when the hut-1 precursor FI was tested,

two lysis areas corresponding to ~ 37 and 27 kDa were clearly

evident, but no activity was observed in the region corresponding

to the molecular weight of hut-1.

FIGURE 9. GELATINOLYTIC ACTIVITY OF FRACTIONS OF

P.L.H . A) molecular weight markers; B) 6 μg of P.l.h crude venom;

C) 6 μg of P.l.h FI; D) 6 μg of hut-1; E) 2 μg of B. colombiensis

crude venom.

153

Revista Cientíca, FVC-LUZ / Vol. XXX, N° 3, 142 - 156, 2020

In the platelet aggregation assay, hut-1 did not inhibit platelet

aggregation in response to the tested agonists (collagen, ADP,

ristocetin). This result contrasts with the potent inhibitory action

of P.l.h crude venom, suggesting that other proteins in this venom

induce platelet aggregation [52]

Compared to the titre, which is the volume of serum necessary

to neutralize the concentration of bothropic venom [47], as

determined by the manufacturer, PAOS had low ecacy at

neutralising the haemorrhages induced by the P.l.h crude venom,

nearly four times the amount recommended by the manufacturer

was required. PAOS was even less eective against hut.1 than

the crude venom; a concentration 11 times higher than the

recommended by the manufacturer was required to neutralise the

activity of hut-1 (1 mL of PAOS per 2 mg of venom).

To correlate these results with the antigenic recognition

evaluation by Western blot analysis, the antivenom exhibited

limited antigenic recognition of some protein bands,

specically, 54, 45 and 30 kDa [FIG.10]. These molecular weights

are within the range reported for PII and PI metalloproteases,

such as porthidin-1, a 23 kDa haemorrhagic metalloprotease that

was previously

isolated from this venom [14]. These observations could indicate

that additional metalloproteases exist in the P.l.h venom that are

not antigenically recognised by the immunoglobulins present in

the antivenom and, therefore, are not neutralised. These results

markedly contrast the results obtained for hut-1, which was

antigenically recognised by PAOS [FIG.10]; however, PAOS did

not eectively neutralise the haemorrhagic activity of hut-1, which

could be a consequence of the antigen binding at a site that does

not corresponding to the activity of hut-1. The ecological area of

the specimens whose venom were used corresponds, as detailed

in materials and methods, to the Macanao peninsula. It is known

that the manufacturer of antivenoms (Biotecfar CA) uses a pool of

venoms from specimens that are randomly collected throughout

the island, it is also known that venoms have intra-species

variability [42] and that geographic variability surely inuences the

synergistic strategies of predominant toxins components of snake

venoms [53].

FIGURE 10. WESTERN BLOT PA INTERACTION AGAINST

P.L.H FI AND HUT-1. A) molecular weight markers; B) SDS-

PAGE P.l.h FI (10 µg); C) Western blot PA against P.l.h FI; D)

SDS-PAGE hut-1 (10 µg); E) Western blot PA against hut-1.

CONCLUSIONS

P. lansbergii hutmanni is an epidemiologically important

venomous snake species located on Margarita Island (Venezuela).

Here, it has been shown that the P.l.h venom lacked the marked in

vitro procoagulant activity characteristic of bothropic venoms,

which could have implications in the diagnosis of envenomations

considered to be from bothropic snakes. The P.l.h crude venom

showed very high haemorrhagic and anticoagulant activities, and

hut-1, an ~ 62 kDa enzyme classied as a P-III metalloprotease,

was identied in this venom. Additionally, hut-1 had a strong

brinogenolytic and moderate brinolytic action and did not

exhibit anticoagulant activity. The antivenom PAOS was not

able to eectively neutralise the haemorrhagic activity of crude

venom, but PAOS did neutralise hut-1; therefore, treatment with

this antivenom could have reduced ecacy in the treatment of

envenomation by P.l.h.

Funding and Acknowledgments

The authors gratefully acknowledge the funding for the research

grant (PG: 09-8760-2013), from the Consejo de Desarrollo

Cientíco y Humanístico de la Universidad Central de Venezuela,

Bolivarian Republic of Venezuela and Conselho Nacional de

Desenvolvimento Cientíco e Tecnológico (CNPQ) y la Fundação

Carlos Chagas Filho de Amparo à Pesquisa do Estado do Rio de

Janeiro (FAPERJ-Dr. J. Perales).

154

Description of hutmannin-1 a new piii-metalloprotease from the venom / Pineda, M. y col.

Ethical statement

Qualied sta arranged all the experimental methods relating

to the use of live animals. These methods were approved by the

Institute of Anatomy Ethical Committee of the Universidad Central

de Venezuela on 7 March 2018 under assurance number 07-

03-18 and followed the norms obtained from the Guidelines for

the Care and Use of Laboratory Animals, published by the US

National Institute of Health (1985). The research questions asked,

the technical methods chosen, and the conclusions reached are

exclusively responsibility of the authors.

ConictsofInterest

The authors declare no conict of interest.

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