ORIGINAL PAPER

Expression of matrix metalloproteinase-2 and metalloproteinase-9
in the skin of dogs with visceral leishmaniasis

Ana Paula Prudente Jacintho1
& Guilherme D. Melo2

& Gisele F. Machado3
& Paulo Henrique Leal Bertolo4

&

Pamela Rodrigues Reina Moreira4,5
& Claudia Momo6

& Thiago A. Souza4 & Rosemeri de Oliveira Vasconcelos4

Received: 6 September 2017 /Accepted: 6 April 2018 /Published online: 18 April 2018
# Springer-Verlag GmbH Germany, part of Springer Nature 2018

Abstract
The skin is the first organ to be infected by the parasite in canine visceral leishmaniasis. The enzyme matrix metalloproteinase
(MMP) acts towards degradation of the extracellular matrix (ECM) and modulation of the inflammatory response against many
kinds of injuries. The aims of this study were to evaluate the expression of MMP-2 and MMP-9 through immunohistochemistry
and zymography on the skin (muzzle, ears, and abdomen) of dogs that were naturally infected by Leishmania spp. and to compare
these results with immunodetection of the parasite and with alterations to the dermal ECM. Picrosirius red staining was used to
differentiate collagen types I and III in three regions of the skin. The parasite load, intensity of inflammation, and production of
MMP-2 (latent) and MMP-9 (active and latent) were higher in the ear and muzzle regions. MMP-9 (active) predominated in the
infected group of dogs and its production was significantly different to that of the control group. Macrophages, lymphocytes, and
plasma cells predominated in the dermal inflammation and formed granulomas in association with degradation of mature
collagen (type I) and with discrete deposition of young collagen (type III). This dermal change was more pronounced in dogs
with high parasite load in the skin. Therefore, it was concluded that the greater parasite load and intensity of inflammation in the
skin led consequently to increased degradation of mature collagen, caused by increased production of MMPs, particularly active
MMP-9, in dogs with visceral leishmaniasis. This host response profile possibly favors systemic dissemination of the parasite.

Keywords Gelatinases A and B . Immunohistochemistry . Leishmania infantum . Skin . Dog . Zymography

Introduction

In visceral leishmaniasis (VL), the skin is the first target of
the vector (Lutzomyia longipalpis) of Leishmania infantum
in dogs and humans (Brasil 2014). In dogs, one of the main
findings is skin lesions. However, in dogs without macro-
scopic cutaneous lesions (asymptomatic dogs), high para-
site loads have also been reported (Solano-Gallego et al.
2004; Madeira et al. 2009).

The microscopic lesions observed in the skin of dogs with
VL are due to inflammation of the superficial dermis. These
lesions are composed of parasitized or non-parasitized macro-
phages, followed by plasmocytes, lymphocytes, and rare neu-
trophils (Solano-Gallego et al. 2004; Reis et al. 2009).
Likewise, type I collagen reduction and type III collagen in-
crease, due to the deleterious effects of the inflammatory pro-
cess, have also been described (Giunchetti et al. 2006).

Matrix metalloproteinases (MMPs) are zinc-dependent en-
dopeptidases. They are associated with physiological and with
acute and chronic pathological processes. MMPs have

Section Editor: Tobili Sam-Yellowe

* Pamela Rodrigues Reina Moreira
pamela_rreina@yahoo.com.br

1 Department of Veterinary Medicine, Rio Preto University Center
(UNIRP), São José do Rio Preto, São Paulo, Brazil

2 Department of Infection and Epidemiology (IE), Pasteur Institute,
Paris, France

3 Department of ClinicalMedicine, Surgery andAnimal Reproduction,
Araçatuba School of Veterinary Medicine (FMVA), São Paulo State
University (UNESP), Araçatuba, São Paulo, Brazil

4 Department of Veterinary Pathology, School of Veterinary and
Agrarian Sciences (FCAV), São Paulo State University (UNESP),
Jaboticabal, São Paulo, Brazil

5 Departamento de Patologia Veterinária, FCAV - Universidade
Estadual Paulista (UNESP), Via de Acesso Prof. Paulo Donato
Castellane, s/n, Jaboticabal, São Paulo 14884-900, Brazil

6 Department of Pathology, School of VeterinaryMedicine andAnimal
Science (FMVZ), University of São Paulo (USP), São Paulo, São
Paulo, Brazil

Parasitology Research (2018) 117:1819–1827
https://doi.org/10.1007/s00436-018-5868-9

http://crossmark.crossref.org/dialog/?doi=10.1007/s00436-018-5868-9&domain=pdf
mailto:pamela_rreina@yahoo.com.br


importance in relation to dissemination of neoplasia because
of their capacity to degrade the extracellular matrix (ECM)
(Cawston and Wilson 2006; Kupai et al. 2010).

The gelatinases MMP-2 andMMP-9 degrade the basement
membrane and collagen fibers and allow carcinoma cells to
migrate to blood vessels (Nagase and Woessner Jr 1999;
Gutierrez et al. 2008; Kupai et al. 2010). MMP-2 arises
through constitutive expression in healthy tissues and is unre-
sponsive to the majority of stimuli. However, MMP-9 is in-
ducible and is considered to be a systemic inflammationmark-
er in animals (Opdenakker et al. 2001a).

In cases of infection with Leishmania mexicana, loosening
or detachment of the connective tissue matrix of the dermis,
allowing establishment of infection, has been reported. The
parasite has receptors for type I collagen, which facilitates
penetration of the parasite in the connective tissue of the der-
mis, before being phagocytosed by macrophages, thus en-
abling migration to other organs of the host (Lira et al.
1997). However, the pathogeny of this interaction with the
ECM remains unclear and the role of MMPs in this has been
little studied.

The aim of the present study was to evaluate MMP-2
and MMP-9 enzyme expression in different areas of canine
cutaneous tissue (muzzle, ears, and abdomen), in order to
determine which cells produce these gelatinases and to
quantify their active and inactive isoforms. These findings
were compared with the parasite load and dermal changes
in infected dogs.

Material and methods

Animals

Thirty-six dogs infected with Leishmania infantum (infected
group) were used, without preference for age, breed, or gen-
der. They were obtained from the Zoonosis Control Center of
the municipality of Araçatuba, São Paulo State, Brazil, a re-
gion that is endemic for VL. The animals were euthanized
using an intravenous (IV) overdose of barbiturate, followed
by IV administration of potassium chloride (decree number
51.838 of the Brazilian Ministry of Health and Resolution
number 714, of June 20, 2002, of the Federal Veterinary
Medicine Council). The necropsy on the dogs was performed
immediately after euthanasia.

A control group composed of four dogs was recruited from
within routine care at the Department of Veterinary Pathology,
Jaboticabal-SP, Brazil, which is in an area that is non-endemic
for VL (Oliveira et al. 2008). The infected and control dogs
were selected for presence or absence of disease, respectively,
bymeans of the ELISA test (Lima et al. 2005). The dogs of the
infected and control groups were further selected through

obtaining a negative result for Ehrlichia canis, through cyto-
logical analysis on bone marrow.

Histopathological and collagen fiber analysis

For histopathological analysis, skin samples measuring ap-
proximately 2 × 2 cm were collected from the muzzle (transi-
tion area between the muzzle and the skin), ear (middle third
of the auricular pavilion), and abdomen (glabrous ventral ab-
dominal area, next to the linea alba). These are regions in
which there is greater probability of contact with the vector
insect of VL. These samples were analyzed regardless of the
presence of cutaneous lesions (ulcers, scabs, or scaling). The
skin fragments were fixed in 10% phosphate-buffered forma-
lin solution (pH 7.2), for 12 h. They were then processed,
embedded in paraffin, sectioned at 5 μm, and stained with
hematoxylin and eosin. The cutaneous inflammatory re-
sponse, and its distribution and intensity, was evaluated in
the dogs with VL.

The dermal collagen fiber composition was analyzed using
skin samples that had been embedded in paraffin and stained
with Sirius red dissolved in saturated solution of picric acid. A
polarization filter was used, thus allowing differentiation be-
tween collagen fiber type I (mature) and type III (neoformed).
The proportion of each type of collagen fiber per animal was
evaluated. This proportion was determined through scores in
three categories: mild (1), moderate (2), and severe (3) colla-
gen formation.

Parasite load andMMP-2 andMMP-9 immunolabeling

The immunohistochemical analysis to determine the parasite
load in the three skin areas was performed using the
streptavidin-biotin-peroxidase complex (LSAB kit; code
K0690, Dako Cytomation, CA, USA).

For immunolabeling of the amastigote forms, hyperim-
mune serum from a leishmaniasis-positive dog (titer of
1:40,000, by means of the ELISA test) was used at a dilu-
tion of 1:1.000 (Moreira et al. 2010, modified from Tafuri
et al. 2004). For metalloproteinase immunolabeling, poly-
clonal antibodies for detection of MMP-2 (ABCAM, code
AB79781, dilution 1:250) and MMP-9 (ABCAM, code
AB38899, dilution 1:4500) were used. The cell types in
the dermal inflammatory infiltrate were identified using
the antibodies CD138 (plasma cells, Spring code E4564,
dilution 1:25), CD3 (T lymphocytes, Dako code M7254,
dilution 1:200), and MCA387 (macrophages, AbD Serotec
code batch 1209, dilution 1:3500).

Antigen retrieval was performed in a water bath at 95 °C
for 30 min. Peroxidase blocking was performed by using a
12%methanol and hydrogen peroxide solution, for 10min. To
block nonspecific sites, a commercial product was used
(Protein Block; code X0909, Dako Cytomation, CA, USA)

1820 Parasitol Res (2018) 117:1819–1827



for 20 min. The chromogen was diaminobenzidine (DAB;
code K3468, Dako Cytomation, CA, USA). Negative controls
were produced using the antibody diluent (Dako Cytomation,
reference S302283-2) to replace the primary antibody.

Expression of MMP-2 and MMP-9
through zymography

To investigate the presence of the MMP-2 and MMP-9 en-
zymes in the skin samples, a pool of subcutaneous tissue mea-
suring about 1.5 × 1 cm, including the three areas analyzed
(muzzle, ears, and abdomen), was subjected to zymographic
analysis. The skin fragments were frozen in liquid nitrogen
and stored in a freezer at − 80 °C for further analysis of enzy-
matic activity.

During the analysis, the skin samples were macerated to-
gether with a lysis buffer (50 mM of Tris-HCl (pH 7.6),
150 mM of NaCl, 5 mM of CaCl2, 0.05% Brij-35®, and dis-
tilled water qsp to complete up to 1000 mL). Afterwards, this
homogenized mix was centrifuged (12,000×g) for 15 min at
4 °C and the supernatant was stored in 50 uL aliquots at −
20 °C for further analysis. All the steps of this procedure were
performed with the samples immersed in ice (4 °C).

Skin total protein was quantified by means of the
bicinchoninic acid method (BCA, 23225, Pierce
Biotechnology, Rockford, IL, USA). This analysis was
performed to standardize the protein concentration used
in the zymogram gels.

The enzymatic activity of these samples was detected by
means of SDS-PAGE (sodium dodecy l su l fa te -
polyacrylamide gel electrophoresis) zymography, as described
by Ihara et al. (2001) and modified by Machado et al. (2010).
The polyacrylamide gels (10%) were used together with gel-
atin (G8150-100G, Sigma-Aldrich). Samples with previously
standardized protein concentration (10 μL) were put together
with a buffer solution (10 μL), containing 125 mM of Tris-
HCl (pH 6.8), glycerol 20% (v/v), SDS 4% (w/v), and
bromophenol blue 0.2% (w/v). The samples were subjected
to electrophoresis at 4 °C for 3 h. Subsequently, the gels were
placed in Triton X-100 (2.5% v/v) for 30 min, for SDS remov-
al, and were incubated with enzymatic activation buffer con-
taining 50 mM of Tris, 200 mM of NaCl, 5 mM of CaCl2 and
Brij-35 (0.2% w/v), at pH 7.5, for 20 h at 37 °C, under gentle
agitation. After the incubation, the gels were stained with
Coomassie brilliant blue R-250 (0.5% w/v), methanol (45%
v/v), and glacial acetic acid (10% v/v) for 30 min. The mixture
was subsequently destained using 45% methanol and glacial
acetic acid (10% v/v) for 30 min. The MMP gelatinolytic
activity in the samples was shown by the appearance of
light bands highlighted in a dark blue background. The
positive control for the zymography was a sample of
female dog mammary adenocarcinoma, as previously
standardized (Machado et al. 2010).

The gel images were captured bymeans of optical densitom-
etry (ImageQuant LAS 4000; GE Healthcare Bio-Sciences,
Uppsala, Sweden) and the results were analyzed through the
public-domain ImageJ 1.45 s software (Wayne Rasband,
National Institutes of Health; http://rsb.info.nih.gov/ij).

Statistical analysis

The number of cells immunolabeled by antibodies (MMP-2,
MMP-9 and parasite load) was determined from five high-
power fields (× 40 objective lens), thus finding the average
number of immunolabeled cells per animal.

The ana lys is on the average number of ce l l s
immunolabeled by MMP-2 and MMP-9 per animal was per-
formed through the Kruskal-Wallis nonparametric test. The
comparison between groups (infected and control), in each
area (muzzle, ear, and abdomen), was performed through
Dunn’s multiple comparison test. The same test was used to
show the predominance of latent versus active forms ofMMP-
2 andMMP-9 in the same groups. The gelatinolytic activity in
the pool from the skin regions (muzzle, ear, and abdomen) in
the infected and control groups was determined through the
Mann-Whitney nonparametric test. The comparison between
parasite load in skin areas (muzzle, ear, and abdomen) of the
infected group was performed through Dunn’s multiple com-
parison test. The statistical software used was GraphPad Prism
(version 5.00; 2007) and differences were considered signifi-
cant at p < 0.05.

Results

In the histopathological analysis, the infected group showed
cutaneous inflammation distributed diffusely (Fig. 1a) or
multifocally, predominantly around cutaneous adnexa (Fig.
1b) in the dermis from the ear, muzzle, and abdomen areas.
In the infected dogs, the inflammation and parasite load were
observed to present lower intensity in the abdominal region.
This infiltrate was composed of plasmocytes (Fig. 1c), lym-
phocytes (Fig. 1d), parasitized or non-parasitized macro-
phages (Fig. 1e), and mast cells (detail, Fig. 1b), forming
granulomas with poorly defined edges. Macrophages were
the predominant cell type in the inflammatory infiltrate.
When the inflammation was composed of highly parasitized
macrophages, there was severe dissociation of the dermal col-
lagen fibers, due to the diffuse distribution of the granuloma-
tous inflammatory infiltrate.

It was noted that the greatest intensity of inflammation was
in the ear area (Fig. 1a), followed by the muzzle. Additionally,
acanthosis, hyperkeratosis, ulceration, and crusts in the epi-
dermis were observed.

In cases of diffuse inflammation that were rich in parasitized
macrophages, the infiltrate extended to deeper layers of the

Parasitol Res (2018) 117:1819–1827 1821

http://rsb.info.nih.gov/ij


skin, such as adipose tissue. In these situations, it was common
to observe complete degradation of the dermal collagen.

Dermal mature collagen degradation was observed at the
same intensity and in the same locations as the cutaneous
inflammatory infiltrate (Fig. 1f). The dogs infected with gross
skin lesions (n = 26) had higher intensity of inflammation, and

consequently, the destruction of mature collagen was severe
(Fig. 2b). This degradation was characterized by absence of
mature collagen fibers in the areas where the inflammatory
infiltrate was located (Fig. 1g). The proportion of young col-
lagen (type III) was low in all infected dogs. The dogs infected
without gross skin lesions (n = 10) showed dermal

Fig. 1 Photomicrograph of skin from dogs with visceral leishmaniasis. a
Ear: diffuse inflammatory infiltrate (*; × 10 obj. lens). Detail:
predominant macrophage infiltrate (black arrow) followed by plasma
cells (yellow arrow) and lymphocytes (blue arrow; × 40 obj. lens);
hematoxylin and eosin. b Multifocal inflammation around the
cutaneous adnexa (*; × 10 obj. lens), hematoxylin and eosin. Detail:
note mast cells (red arrow) in association with parasitized macrophages
(black arrow; × 40 obj. lens), toluidine blue. c Immunostaining of plasma
cells (CD138) in inflammatory infiltrate around cutaneous adnexa (* red;
× 40 obj. lens); in detail, note immunostaining cytoplasmic membrane of
the cell (× 100 obj. lens); peroxidase-linked polymer complex. d

Immunostaining of T cells (CD3) in inflammatory infiltrate around
cutaneous adnexa (* red); in detail, note immunodetection of the
lymphocytes among parasitized macrophages (× 40 obj. lens);
peroxidase-linked polymer complex. e Immunostaining of macrophages
(MCA387) in cutaneous inflammatory infiltrate without parasites (black
arrow) among parasitized macrophages (red arrow) (× 40 obj. lens);
peroxidase-linked polymer complex. f Sirius red staining with halogen
light. g Sirius red staining with polarized light. Note intense collagen
degradation associated with the inflammatory infiltrate around annexes
(*; × 10 obj. lens)

1822 Parasitol Res (2018) 117:1819–1827



inflammation and presence of parasitized macrophages in the
inflammatory infiltrate (2/10).

In dogs with high density of parasitized macrophages,
the dermal mature collagen degradation was intense. In
these areas of the skin, the proportion of young collagen
fibers (type III collagen), which are thinner and slightly
birefringent, was lower.

The immunohistochemical technique showed that
immunodetection of the parasite was restricted to
intracytoplasmic amastigote forms in macrophages (Fig. 2a, b)

and in fibroblasts of the superficial dermis. In the infected
group, it was observed that the ears and muzzle were the
areas that presented the highest parasite density. The abdo-
men was the region that presented the lowest intensities of
inflammation and parasitized macrophages (Fig. 3).

Immunolabeling for MMP-2 (Fig. 2c) and MMP-9 (Fig. 2e)
was observed in the cytoplasm of macrophages, lymphocytes,
mast cells, and plasmocytes of the inflammatory infiltrate.
Likewise, lower intensity of immunolabeling was seen in fibro-
blasts, collagen fibers, epidermis, hair follicle, and

*
*

**

*

*
*

*
*

Fig. 2 Photomicrographs of
muzzle skin from dogs infected
with Leishmania infantum or the
control group. a Macrophages
immunostained for Leishmania
infantum (arrow) and detail
(yellow arrow) in the
inflammatory infiltrate of the
superficial dermis (infected
group, × 20. obj. lens; detail × 40.
obj. lens). b Note the higher
parasitized macrophage density
(arrow and detail) and evident
dissociation of the collagen fibers
in the deep dermis (infected
group, × 20 obj. lens and × 40.
obj. lens). c Immunostaining for
MMP-2 (*) in the inflammatory
infiltrate of the superficial dermis
(infected group, × 20 obj. lens). d
Absence of immunostaining for
MMP-2 in dermis (*; control
group, × 20 obj. lens). e
Immunostaining for MMP-9 in
granulomatous inflammation
around adnexa (*; infected group,
× 20. obj. lens). Detail: note
macrophages positive for MMP-9
(arrow; × 40 obj. lens). f Absence
of immunostaining for MMP-9 in
dermis (*; control group, × 20
obj. lens). Polymer complex
linked to peroxidase

Parasitol Res (2018) 117:1819–1827 1823



chondrocytes of the ear cartilage. In the control group, immu-
nostaining of MMP-2 (Fig. 2d) and MMP-9 (Fig. 2f) was ab-
sent or rare and located near the cutaneous adnexa.

The highest proportion of parasitized cells occurred in the
ears and muzzle. However, there were no significant differ-
ences between the areas (p = 0.1798; Fig. 3).

The zymographic analysis revealed gelatinolytic activity
relating to enzymes with molecular weight of 92 kDa (pro-
MMP-9), 86 (active MMP-9), 72 (pro-MMP-2), and 66 (ac-
tive MMP-2), which were detected in the pool of skin areas
from the infected dogs and control dogs (Fig. 4).

The gelatinolytic activity was evaluated in the three
skin areas of the infected group, in which a significant
difference in the expression of active MMP-9 (p =
0.0122) was observed in comparison with the control an-
imals (Fig. 5a). When these areas were analyzed separate-
ly, greater expression of latent MMP-9 (p = 0.0409), active
MMP-9 (p = 0.0067), and active MMP-2 (p = 0.0384) was
observed in the ears of the infected group, in comparison
with the control group (Fig. 5b). Greater expression of
latent MMP-9 (p = 0.0106), active MMP-9 (p = 0.0115),
and active MMP-2 (p = 0.0249; Fig. 5c) was also seen in
the muzzle. In the abdomen, there was no significant

difference in the expression of MMPs between the infect-
ed dogs and the control group (Fig. 5d).

Discussion

In the present study, the cutaneous inflammatory process was
predominantly around the adnexa, with multifocal to coalescent
distribution. In the cases with greater numbers of parasitized
cells, this distribution was diffuse, extending as far as the sub-
cutaneous tissue. The inflammatory infiltrate was distributed
diffusely and sometimes only around the hair follicles
(Giunchetti et al. 2006; Xavier et al. 2006; Moreira et al. 2013).

Macrophages were the predominant cell type in the inflam-
matory infiltrate that was observed in the three skin areas,
similar to what had been observed in other studies (Xavier
et al. 2006; Moreira et al. 2013). Giunchetti et al. (2006) found
predominance of plasma cells in the dermal infiltrate of dogs
with VL.

Plasma cells were also evident in the cutaneous inflamma-
tory infiltrate, with a proportion similar to that of the macro-
phages in the infected group of dogs. These cells may reflect
the humoral response profile, given that the presence of plas-
ma cells with Russell bodies (Mott cells) was a common find-
ing. Dogs with severe VL lesions may present elevated anti-
body titers, and this may worsen the disease through deposi-
tion of immunocomplexes in several tissues, such as the kid-
neys (Feitosa et al. 2000; Barbiéri 2006).

The structural profile of the dermal granulomas of the
infected dogs was characterized by poorly defined edges,
with predominance of macrophages with variable parasite
load. Classically, granulomas are divided into Th1 or Th2,
according to the predominant cytokine profile and the mac-
rophage activation pathway through CD4 T cells, such as
the Arg-1 pathway (L-arginine, Th2) or the iNOS pathway
(Th1) (Ackermann 2011). In dogs with high numbers of
parasitized macrophages, the diffuse granulomas suggest
a Th2 cytokine profile.

Fig. 3 Median of the parasitized cell density in the skin areas of the group
infected with visceral leishmaniasis. Note that ear and muzzle had high
numbers of parasitized macrophages. Kruskal-Wallis test (p = 0.1798)

proMMP-9

active MMP-9 

proMMP-2

active MMP-2 

Fig. 4 Representative zymogram
of the skin from dogs with
visceral leishmaniasis presenting
gelatinolytic bands corresponding
to pro-MMP-9 (92 kDa), active
MMP-9 (86 kDa), pro-MMP-2
(72 kDa), and active MMP-2
(66 kDa). a Molecular weight
(mammary adenocarcinoma used
as positive control). b Infected
dogs. c Non-infected dogs
(control group)

1824 Parasitol Res (2018) 117:1819–1827



In this study, the areas with greater lesion intensity (ears and
muzzle) coincided with the findings from other studies
(Giunchetti et al. 2006; Moreira et al. 2013). The predominance
of cutaneous lesions on the head is because this is the preferential
access site for the vector of the protozoon (Giunchetti et al. 2006).
This hypothesis is supported by the finding of lesions of greater
severity in the cervical lymph nodes of dogs with spontaneous
VL. These lymph nodes drain the head area (Lima et al. 2004).

In cases of diffuse inflammation that was rich in parasitized
macrophages, the infiltrate extended to the adipose tissue.
This suggested that parasitized macrophages could invade
the vascular bed in order to reach the peripheral lymph nodes.
Moreira et al. (2010) found severe lesions in the popliteal
lymph nodes of dogs that were symptomatic for VL, with
predominance of parasitized macrophages and lymphoid atro-
phy. Similar to what was observed by Xavier et al. (2006),
dogs without macroscopic cutaneous lesions also presented
inflammation of the dermis and some of them showed

presence of parasitized macrophages. Animals with no clini-
cally visible signs of VL are also important sources of con-
tamination for humans and dogs.

Immunostaining of Leishmania sp. was observed in mac-
rophages and also in fibroblasts in the three skin areas (ears,
muzzle, and abdomen) of the infected dogs. Macrophages are
the parasite target cells. However, fibroblasts produce proteins
for the ECM, cytokines, MMPs, and chemokines that regulate
the extracellular microenvironment composition under physi-
ological and pathological conditions (Ackermann 2011). In
the present study, the parasitized fibroblasts or fibroblasts that
were stimulated bymediators released at the inflammation site
may also have contributed towards the dermal alterations, es-
pecially through release of gelatinolytic enzymes (MMPs).

In the current study, the presence of accentuated degrada-
tion of mature collagen in the dermis was associated with
inflammatory infiltrate. Therefore, the production of
collagenolytic enzymes (MMPs) by macrophages, fibroblasts,

Fig. 5 Gelatinolytic activity of skin from dogs with visceral
leishmaniasis. a Significant difference in expression of active MMP-9
(p = 0.0122) was observed in the three areas of the skin from dogs with
VL, compared with the control group. b Skin from ear area: significant
differences in latent MMP-9 (p = 0.0409), active MMP-9 (p = 0.0067),
and active MMP-2 (p = 0.0384), in comparison with the control animals.
c Skin from muzzle area: significant difference in latent MMP-9 (p =

0.0106), active MMP-9 (p = 0.0115), and active MMP-2 (p = 0.0249),
in comparison with the control animals. d Skin from abdomen area.
There was no significant difference in MMP expression in the animals
with VL, in comparison with the control animals (p > 0.05). The results
are shown as means and standard errors, from Mann-Whitney test. The
values were expressed as arbitrary units (AU)

Parasitol Res (2018) 117:1819–1827 1825



and mast cells in the dermis may contribute towards ECM
degradation in VL (Cawston and Wilson 2006).

The formation of young collagen was low in relation to the
proportion of it that was degraded in the infected group. Dermal
collagen evaluations in dogs with VL in other studies showed
that in dogs with intense inflammatory infiltrate and presence of
high numbers of parasitized macrophages, type III collagen
(young) predominated. These changes may be related to delete-
rious effects in the inflammatory infiltrate (Giunchetti et al. 2006)
or to mechanisms for evasion of the host’s immune response that
the parasite induces (Lira et al. 1997). On the other hand, Kondo
et al. (2009) found that type I collagen was gradually replaced by
type III collagen in the popliteal lymph nodes of dogs with VL.

In the present study, greater degradation of type I collagen was
confirmed by detection of MMP-2 and MMP-9 in the skin (in-
flammatory infiltrate, fibroblasts, and collagen), which was seen
in the groups of infected dogs. Similar results were described by
Cardoso et al. (2017),who observed greater degradation ofmature
collagen (type I) and lower deposition of young collagen (type III)
in symptomatic dogs, possibly through these dogs’ loss of capac-
ity to remodel the extracellular matrix within the chronic inflam-
matory process.However, these authors highlighted that therewas
greater deposition of young collagen in the oligosymptomatic
dogs. That result differed fromwhat was seen in the present study,
since the infected dogs always presented a lower proportion of
young collagen. The reduction in mature collagen probably fa-
voredmigration of the parasitized macrophages, thus contributing
towards systemic dissemination of the infection.

In canine VL, there have not been any reports ofMMP-2 and
MMP-9 immunolabeling in the skin of dogs naturally infected
with Leishmania infantum. However, these MMPs were evalu-
ated in the brain (Machado et al. 2010) and cerebrospinal fluid
(CSF) (Marangoni et al. 2011) of dogs with VL. The authors
concluded, respectively, that there was positive latent MMP-2
and MMP-9 immunolabeling in resident cells and in inflamma-
tory infiltrate cells in the brain and that there were high levels of
MMP-9 in the CSF, which could participate in disruption of the
blood-brain barrier. A previous study with methodology similar
to the latter study was conducted on dogs with mammary tu-
mors and showed high detection ofMMP-2 andMMP-9, which
correlated with the malignant behavior of these tumors
(Loukopoulos et al. 2003). In human mucosal leishmaniasis,
neutrophils were found to contribute towards lesion expansion
throughMMP-9 production (Boaventura et al. 2010). Similarly,
in human cutaneous leishmaniosis, high levels of MMP-9 were
observed in skin lesions, compared with healthy patients.
Monocytes andMMP-9may play key roles in tissue destruction
through L. braziliensis infection (Campos et al. 2014).

In the present study, the collagen degradation was possibly
induced by macrophages, fibroblasts, and active mast cells,
which contributed towards MMP-2 and MMP-9 production.
In the same way, the proportion of the active form of MMP-9
was greater in the infected group, thus suggesting that this

enzyme is a good marker for active inflammation. On the other
hand, MMP-2 showed greater expression in the latent form in
the same group. This gelatinase (MMP-2) has constitutive ex-
pression in tissues, whereas MMP-9 is inducible (Opdenakker
et al. 2001b). In the present study, MMP-9 production was
induced by cells of the dermal inflammatory infiltrate in dogs
with VL. It is possible that fibroblasts activated by the parasite
also contributed towards higher expression of this enzyme.

It can be hypothesized that MMP-2 is released in greater
concentrations in the initial phase of the infection and that
MMP-9 becomes predominant through chronic evolution of
the disease. This hypothesis could not be confirmed under the
conditions of the present study, because dogs with spontane-
ous disease were used. TIMPs are considered to be the main
tissue regulators of MMPs (Dzwonek et al. 2004). In the fu-
ture, it would be interesting to evaluate the role of these MMP
regulators in the infected groups.

In summary, the infected dogs showed that the intensity of
gross lesions in the skin was proportional to the intensity of
inflammation, the parasite load, and the degradation of mature
collagen fibers. Changes to the dermal collagen composition
were induced by MMP enzymes, especially active MMP-9,
and these changes favored the spread of parasitized macro-
phages to the blood vessels, thus also favoring systemic dis-
semination of the parasite and maintenance of persistent
infection.

Conclusions

Active MMP-9 was significantly present in the dogs of the
infected group, in the ear and muzzle regions, coinciding with
areas of higher parasite load and cutaneous inflammatory infil-
trate. The intensity of degradation of mature collagen fibers was
associated with the inflammation and this was perhaps one of
the factors that favoredmigration of parasitizedmacrophages to
the vascular bed and led to systemic dissemination.

Acknowledgements The authors wish to acknowledge the assistance giv-
en by the Zoonosis Control Center of Araçatuba, which provided animals
for this study.

Funding information Financial assistance was provided by FAPESP
(Fundação de Amparo à Pesquisa do Estado de São Paulo; procedural
number 2009/07815-4). Ana Paula Prudente Jacintho was a FAPESP
grantee (2009/11687-1).

Compliance with ethical standards

Ethical standards The design for this study was approved by the Ethics
and Animal Welfare Committee (CEBEA no. 020373/09) of
FCAV/UNESP, Jaboticabal, state of São Paulo, Brazil.

Conflict of interest The authors declare that they have no conflict of
interest.

1826 Parasitol Res (2018) 117:1819–1827



References

Ackermann MR (2011) Chronic inflammation and wound healing. In:
McGavin MD, Zachary JF (eds) Pathologic basis of veterinary dis-
ease, 5th edn. Elsevier, St Louis, pp 153–191

Barbiéri CL (2006) Immunology of canine leishmaniasis. Parasite
Immunol 28:329–337. https://doi.org/10.1111/j.1365-3024.2006.
00840.x

Boaventura VS, Santos CS, Cardoso CR, Andrade J, Santos WLC,
Clarêncio J, Silva JS, Borges VM, Barral-Netto M, Brodskyn CI,
Barral A (2010) Humanmucosal leishmaniasis: neutrophils infiltrate
areas of tissue damage that express high levels of Th17-related cy-
tokines. Eur J Immunol 40:2830–2836. https://doi.org/10.1002/eji.
200940115

Brasil (2014) Ministério da Saúde. Secretaria de Vigilância em Saúde.
Departamento de Vigilância Epidemiológica. Manual de vigilância e
controle da leishmaniose visceral. Ministério da Saúde, Brasília, pp 120

Campos TM, Passos ST, Novais FO, Beiting DP, Costa RS, Queiroz A,
Mosser D, Scott P, Carvalho EM, Carvalho LP (2014) Matrix me-
talloproteinase 9 production by monocytes is enhanced by TNF and
participates in the pathology of human cutaneous leishmaniasis.
PLoS Negl Trop Dis 8(11):e3282. https://doi.org/10.1371/journal.
pntd.0003282

Cardoso JMO, Ker HG, Aguiar-Soares RDO,Moreira ND,Mathias FAZ,
Reis LES, Roatt BM, Vieira PMA, Coura-Vital W, Carneiro CM,
Reis AB (2017) Association betweenmast cells, tissue remodelation
and parasite burden in the skin of dogs with visceral leishmaniasis.
Vet Parasitol 243:260–266. https://doi.org/10.1016/j.vetpar.2017.
05.028

Cawston TE, Wilson AJ (2006) Understanding the role of tissue
degrading enzymes and their inhibitors in development and disease.
Best Pract Res Clin Rheumatol 20:983–1002. https://doi.org/10.
1016/j.berh.2006.06.007

Dzwonek J, Rylski M, Kaczmarek L (2004) Matrix metalloproteinases
and their endogenous inhibitors in neuronal physiology of the adult
brain. FEBS Lett 567:129–135. https://doi.org/10.1016/j.febslet.
2004.03.070

Feitosa MM, Ikeda FA, Luvizotto MCR, Perri SHV (2000) Aspectos
clínicos de cães com leishmaniose visceral no município de
Araçatuba—São Paulo (Brasil). Clin Vet 5:36–44

Giunchetti RC, Mayrink W, Genaro O, Carneiro CM, Corrêa-Oliveira R,
Martins-Filho OA, Marques MJ, Tafuri WL, Reis AB (2006)
Relationship between canine visceral leishmaniosis and the
Leishmania (Leishmania) chagasi burden in dermal foci. J Comp
Pathol 135:100–107

Gutierrez FRS, Lalu MM, Mariano FS, Milanezi CM, Cena J, Gerlach
RF, Santos JET, Torres-Dueñas D, Cunha FQ, Schulz R, Silva JS
(2008) Increased activities of cardiac matrix metalloproteinases
MMP-2 and MMP-9 are associated with mortality during the acute
phase of experimental Trypanosoma cruzi infection. J Infect Dis
197:1468–1476

Ihara M, Tomimoto H, Kinoshita M, Oh J, Noda M,Wakita H, Akiguchi I,
Shibasaki H (2001) Chronic cerebral hypoperfusion induces MMP-2
but not MMP-9 expression in the microglia and vascular endothelium
of white matter. J Cereb Blood Flow Metab 21:828–834

Kondo KRJ, Fonseca CC, Matta SLP, Viloria MIV (2009) Análise
histomorfométrica da matriz extracelular do linfonodo poplíteo de
cães naturalmente infectados por Leishmania (L.) chagasi. Pesq Vet
Bras 29:610–616

Kupai K, Szucs G, Cseh S, Hajdu I, Csonka C, Csont T, Ferdinandy P
(2010) Matrix metalloproteinases activity assays: importance of
zymography. J Pharmacol Toxicol Methods 65:205–209

Lima WG, Michalick MSM, Melo MN, Tafuri WL, Tafuri WL (2004)
Canine visceral leishmaniasis: a histopathological study of lymph
nodes. Acta Trop 92:43–53

LimaVMF, Biazzono L, Silva AC, Correa APFL, LuvizottoMCR (2005)
Serological diagnosis of visceral leishmaniasis by an enzyme immu-
noassay using protein A in naturally infected dogs. Pesq Vet Bras
25(4):215–218

Lira R, Rosales-Encina JL, Arguelos C (1997) Leishmania mexicana: bind-
ing of promastigotes to type I collagen. Exp Parasitol 85:149–157

Loukopoulos P, Mungall BA, Straw RC, Thornton JR, Robinson WF
(2003) Matrix metalloproteinase-2 and -9 involvement in canine
tumors. Vet Pathol 40:382–394

Machado GF, Melo GD, Moraes OC, Souza MS, Marcondes M, Perri
SHV, Vasconcelos RO (2010) Differential alterations in the activity
of matrix metalloproteinases within the nervous tissue of dogs in
distinct manifestations of visceral leishmaniasis. Vet Immunol
Immunopathol 136:340–345

Madeira MF, Figueiredo FB, Pinto AG, Nascimento LD, Furtado M,
Mouta-Confort E, Paula CC, Bogio A, Gomes MCA, Bessa AMS,
Passos SRL (2009) Parasitological diagnosis of canine visceral
leishmaniasis: is intact skin a good target? Res Vet Sci 87:260–262

Marangoni NR, Melo GD, Moraes OC, Souza MS, Perri SHV, Machado
GF (2011) Levels of matr ix metal loproteinase-2 and
metalloproteinase-9 in the cerebrospinal fluid of dogs with visceral
leishmaniasis. Parasite Immunol 11(33):330–334

Moreira PRR, Vieira LM, Andrade MMC, Bandarra MB, Machado GF,
Munari DP, Vasconcelos RO (2010) Immune response pattern of the
popliteal lymph nodes of dogs with visceral leishmaniasis. Parasitol
Res 107:605–613. https://doi.org/10.1007/s00436-010-1902-2

Moreira PRR, Bandarra MB, Magalhães GM, Munari DP, Machado GF,
Prandini MM, Alessi AC, Vasconcelos RO (2013) Influence of ap-
optosis on the cutaneous and peripheral lymph node inflammatory
response in dogs with visceral leishmaniasis. Vet Parasitol 192:149–
157. https://doi.org/10.1016/j.vetpar.2012.09.029

Nagase H,Woessner Jr JF (1999)Matrix metalloproteinases. J Biol Chem
274:21491–21494

Oliveira TMFS, Furuta PI, Carvalho D, Machado RZ (2008) A study of
cross-reactivity in serum samples from dogs positive for Leishmania
sp, Babesia canis and Ehrlichia canis in enzyme-linked immunosor-
bent assay and indirect fluorescent antibody test. Ver Bras Parasitol
Vet 17:7–11

Opdenakker G, Van den Steen PE, Dubois B, Nelissen I, Coillie EV,
Masure S, Proost P, Van Damme J (2001a) Gelatinase B functions
as regulator and effector in leukocyte biology. J Leukoc Biol 69:
851–859

Opdenakker G, Van den Steen PE, Van Damme J (2001b) Gelatinase B: a
tuner and amplifier of immune functions. Trends Immunol 22:571–579

Reis AB, Martins-Filho OA, Teixeira-Carvalho A, Giunchetti RC,
Carneiro CM, Mayrink W, Tafuri WL, Corrêa-Oliveira R (2009)
Systemic and compartmentalized immune response in canine viscer-
al leishmaniasis. Vet Immunol Immunopathol 128:87–95

Solano-Gallego L, Fernández-BellonH,Morrell P, Fondevila D, Alberola
J, Ramis A, Ferrer L (2004) Histological and immunohistochemical
study of clinically normal skin of Leishmania infantum-infected
dogs. J Comp Pathol 130:7–12

Tafuri WL, Santos RL, Arantes RME, Gonçalves R, Melo MN,
Michalick MSM, Tafuri WL (2004) An alternative immunohisto-
chemical method for detecting Leishmania amastigotes in paraffin-
embedded canine tissues. J Immunol Methods 292:17–23

Xavier SC, Chiarelli IM, Lima WG, Gonçalves R, Tafuri WL (2006)
Canine visceral leishmaniasis: a remarkable histopathological pic-
ture of one asymptomatic animal reported from Belo Horizonte,
Minas Gerais, Brazil. Arq Bras Med Vet Zootec 58(6):994–1000

Parasitol Res (2018) 117:1819–1827 1827

https://doi.org/10.1111/j.1365-3024.2006.00840.x
https://doi.org/10.1111/j.1365-3024.2006.00840.x
https://doi.org/10.1002/eji.200940115
https://doi.org/10.1002/eji.200940115
https://doi.org/10.1371/journal.pntd.0003282
https://doi.org/10.1371/journal.pntd.0003282
https://doi.org/10.1016/j.vetpar.2017.05.028
https://doi.org/10.1016/j.vetpar.2017.05.028
https://doi.org/10.1016/j.berh.2006.06.007
https://doi.org/10.1016/j.berh.2006.06.007
https://doi.org/10.1016/j.febslet.2004.03.070
https://doi.org/10.1016/j.febslet.2004.03.070
https://doi.org/10.1007/s00436-010-1902-2
https://doi.org/10.1016/j.vetpar.2012.09.029

	Expression of matrix metalloproteinase-2 and metalloproteinase-9 �in the skin of dogs with visceral leishmaniasis
	Abstract
	Introduction
	Material and methods
	Animals
	Histopathological and collagen fiber analysis
	Parasite load and MMP-2 and MMP-9 immunolabeling
	Expression of MMP-2 and MMP-9 through zymography
	Statistical analysis

	Results
	Discussion
	Conclusions
	References