Hindawi Publishing Corporation
Experimental Diabetes Research
Volume 2012, Article ID 356841, 10 pages
doi:10.1155/2012/356841

Research Article

Spontaneous Periodontitis Development in Diabetic Rats
Involves an Unrestricted Expression of Inflammatory Cytokines
and Tissue Destructive Factors in the Absence of Major Changes
in Commensal Oral Microbiota

Marcela Claudino,1 Gabriela Gennaro,1 Tania Mary Cestari,1 César Tadeu Spadella,2

Gustavo Pompermaier Garlet,1 and Gerson Francisco Assis1

1 Department of Biological Sciences, School of Dentistry of Bauru, Sao Paulo University (FOB/USP),
Al. Dr Octávio Pinheiro Brisolla, 9-75, 17012-901 Bauru, SP, Brazil

2 Department of Surgery and Orthopedics, School of Medicine of Botucatu, Sao Paulo State University (UNESP),
18618-970 Botucatu, SP, Brazil

Correspondence should be addressed to Marcela Claudino, marcelaclaudino@hotmail.com

Received 5 January 2012; Accepted 14 February 2012

Academic Editor: Shi Fang Yan

Copyright © 2012 Marcela Claudino et al. This is an open access article distributed under the Creative Commons Attribution
License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original work is properly
cited.

Diabetes mellitus is a heterogeneous group of disorders, in which hyperglycemia is a main feature. The objective was to evaluate
the involvement of RAGE, inflammatory cytokines, and metalloproteinases in spontaneous periodontitis triggered by diabetes
induction. Immunohistochemical procedures for MMP-2, MMP-9, TNF-α, IL-1β, IL-6, RANKL, and RAGE were performed in
rats after 1, 3, 6, 9, and 12 months of diabetes induction. Total DNA was extracted from paraffin-embedded tissues and evaluated
by Real-TimePCR for 16S total bacterial load and specific periodontopathogens. Our data did not demonstrate differences in
microbiological patterns between groups. In diabetic groups, an increase in RAGE-positive cells was detected at 6, 9, and 12
months, while TNF-alpha-stained cells were more prevalent at 6 and 12 months. In experimental groups, IL-β-positive cells were
increased after 12 months, IL-6 stained cells were increased at 9 and 12 months, and RANKL-positive cells at 9 months. Diabetes
resulted in widespread expression of RAGE, followed by expression of proinflammatory mediators, without major alterations
in oral microbial profile. The pervasive expression of cytokines suggests that spontaneous periodontitis development may be
independent of microbial stimulation and may be triggered by diabetes-driven imbalance of homeostasis.

1. Introduction

Diabetes mellitus is a heterogeneous group of disorders
that affect the metabolism of carbohydrates, lipids, and
proteins, in which hyperglycemia is a main feature. The
subsequent hyperglycemia has wide-ranging molecular and
cellular effects, resulting in oxidative stress, upregulation
of proinflammatory responses, and vascular changes that
predispose individuals to the classic diabetes complications
of cardiovascular disease, nephropathy, retinopathy, neu-
ropathy, and atherosclerosis. Elevated blood glucose levels
have been associated with diabetic complications through-
out the acceleration of advanced glycation end products

(AGEs) formation [1, 2]. The interaction between AGEs and
their receptor RAGE generates reactive oxygen species and
activates inflammatory signaling cascades, demonstrating
the great influence of this interaction in the pathogenesis
of several chronic diseases such as Alzheimer’s disease,
nondiabetic nephropathy, and chronic kidney disease [3–5].
In addition, AGE-RAGE interaction is also associated with
diabetic complications [6, 7].

It also has been demonstrated that AGE-RAGE inter-
action results in increased levels of proinflammatory
mediators such as tumoral necrosis factor alpha (TNF-
alpha), interleukin-1beta (IL-1beta), interleukin-6 (IL-6),
and matrix metalloproteinases (MMPs) [8, 9]. In fact,



2 Experimental Diabetes Research

previous studies [5, 10, 11] revealed that higher levels of
inflammatory mediators are related to diabetic complica-
tions such as nephropathy, neuropathy, retinopathy, and
cardiovascular diseases. Then, the central role of AGEs
and RAGE in maintaining perpetuated cell activation is
demonstrated in various therapeutic attempts to block RAGE
or their ligands [12, 13].

Among the pathologies triggered or exacerbated by
diabetes, the effect of chronic hyperglycemic in periodontal
environment has been characterized by an increase in peri-
odontitis prevalence and severity. In this way, periodontal
disease has been termed the sixth complication of diabetes
[14–16]. Several mechanisms have been proposed to explain
the interactions between diabetes and periodontal diseases.
These potential mechanisms are strikingly similar to those
associated with the established complications of chronic
diabetes, suggesting that increased severity of periodontal
disease in presence of diabetes was due to an exacer-
bated inflammatory response triggered by AGEs [17, 18].
In fact, clinical and experimental studies [15, 19] have
been demonstrating an association between diabetes and
increased expression of inflammatory mediators, osteoclas-
togenic factors, and matrix metalloproteases. Some studies
[20, 21] also suggest that diabetes interfere in host defense
mechanisms such as chemotaxis, adherence, phagocytosis,
and apoptosis, contributing to tissue destruction.

These studies demonstrated that diabetes increases the
severity of periodontal disease previously induced by bac-
terial inoculation or by silk ligatures [22, 23]. However,
a previous study [24] demonstrated that a chronic hyper-
glycemic environment in periodontal tissue, even in absence
of external stimuli such as bacterial inoculation or silk
ligatures, results in the clear establishment and progression of
periodontal disease. In fact, previous reports suggested that
diabetes not only exacerbate the periodontitis severity but
also can trigger periodontal disease induction [25]. Interest-
ingly, it has been suggested that the inflammatory/immune
deregulation caused by diabetes could trigger periodontitis
development in response to the commensal subgingival
microflora [9, 16, 23]. However, the mechanisms involved
in the spontaneous onset of periodontitis after diabetes
induction remains unknown.

In this context, the purpose of this study was to
investigate the potential mechanisms involved in the spon-
taneous onset of diabetes-triggered periodontitis through
the quantitative and spatial evaluation of RAGE, TNF-alpha,
IL-1beta, IL-6, RANKL, MMP-2, MMP-9 immunostaining
patterns, and also the monitoring of oral microbiota load,
in periodontal tissue in rats after 1, 3, 6, 9, and 12 months of
diabetes induction.

2. Material and Methods

2.1. Induction of Diabetes and Collection of Samples. Adult
male Wistar rats, 10–12 weeks old, weighing approximately
250 g, were submitted to diabetes induction by intravenous
administration of alloxan (Sigma Chemical Co., St Louis,
EUA) in a single dose of 42 mg/kg of body weight into the

caudal vein. Only rats showing two successive determina-
tions of blood glucose levels (7 and 14 days after alloxan
injection) greater than 250 mg/dL were considered diabetic
and included in the experiment. The glucose levels during
the experiment were typically 400–450 mg/dL in diabetic
rats, while serum glucose levels of control rats ranged from
90 to 130 mg/dL. The animals were housed in metabolic
cages in groups of four per cage and fed a standard rat
chow and water ad libitum. Study protocol was approved by
the Experimental Committee of Bauru School of Dentistry,
São Paulo State University (033/2007). Each diabetic and
control group was composed of 25 animals, subdivided
into 5 subgroups with 5 rats each, analyzed at 1, 3, 6, 9,
and 12 months after diabetes induction. On their respective
dates, the animals were sacrificed with overdose of sodium
pentobarbital (Cristália Chemical Products-Itapira/SP) and
the hemimandibles were removed and fixed in 10% formalin
solution for 7 days.

2.2. Histological and Immunohistochemical Analyses. The
hemimandibles were demineralized for 8 weeks in 4.13%
EDTA, washed, dehydrated, and embedded in paraffin. Slides
of 5 μm thick serial sections of the each hemimandible were
obtained (3 semi-serial sections for each protein/antibody
studied) and submitted to immunohistochemical proce-
dures. Immunohistochemistry was performed using the
Streptavidin-Biotin/HRP Complex method.

Paraffin sections (3 semi-serial section of each animal)
were deparaffinized with xylol, dehydrated in decreasing
alcohol solutions, and the endogenous peroxidase was
blocked with 3% hydrogen peroxide solution in phosphate-
buffered saline (PBS) for 30 minutes at room temperature.
For antigen retrieval, sections were treated with 0.5%
pepsin (IL-1beta, TNF-alpha, IL-6 and RAGE antibodies)
and 0.4 mg/mL of proteinase K (RANKL antibody) for
20 minutes at room temperature. In MMP-2 and MMP-9
reactions, sections were submitted to sodium citrate (10 mM;
pH 6.0) for 20 minutes at 95◦C. After antigen retrieval,
sections were incubated in 7% free-fat milk for 40 minutes
at room temperature.

A specific primary antibodies for MMP-9 (sc-6840-Santa
Cruz Biotechnology, Inc., Santa Cruz, CA, USA) at 1 : 200
dilution; MMP-2 (sc-58386-Santa Cruz Biotechnology, Inc.),
at 1 : 100 dilution; RANKL (sc-7628-Santa Cruz Biotech-
nology, Inc.), at 1 : 50 dilution; RAGE (ab3611-Abcam Inc.,
Cambridge, USA), at 1 : 50 dilution; TNF-alpha (sc-1348-
Santa Cruz Biotechnology, Inc.), at 1 : 50 dilution; IL-1beta
(sc-7884-Santa Cruz Biotechnology, Inc.), at 1 : 50 dilution;
IL-6 (IL-6-Santa Cruz Biotechnology, Inc.), at 1 : 50 dilution
were applied and incubated for 2 hours at room temperature
in a humidified chamber.

After washing, the sections were incubated with biotin-
conjugated secondary antibody (sc-2774 and sc-2040-Santa
Cruz Biotechnology, Inc.) for 1 h at room temperature
followed by streptavidin/peroxidase complex (Dakocytoma-
tion, Glostrup, Denmark) for 20 minutes at room tem-
perature. Immunoreactivity was developed using 3,30-
diaminobenzidine, for 5 min (DakoCytomation, Glostrup,



Experimental Diabetes Research 3

Denmark), counterstained with Harris’s hematoxylin and
mounted. All rinses were performed three times in 0.1%
PBS/Triton-X. Negative controls were performed replacing
the primaries antibodies for the same PBS/BSA solution.
Periodontal disease tissue was used as a positive control for
TNF-alpha, IL-1beta, IL-6, and RANKL [26]. Accordingly to
fabricant instruction, rat lung tissue exposed to tobacco was
used as positive control for MMP-2, MMP-9, and RAGE.

All histological sections were identified with a ran-
dom numerical sequence in order to codify experimental
periods and groups during the analysis procedures. A
single calibrated investigator analyzed the sections with a
binocular microscope (Olympus Optical Co., Tokyo, Japan).
Morphometrical measurements were obtained using a 100x
immersion objective and a Zeiss kpl 8x eyepiece containing
a Zeiss II integration grid (Carl Zeiss Jena GmbH, Jena,
Germany) with 10 parallel lines and 100 points in a quadran-
gular area. The grid image was successively superimposed on
approximately 15 histological fields per histological section,
comprising all the periodontal area, from the junctional
epithelium to the root apex of mesial face of lower first molar
mesial root. In each field, immunostained cells are counted
and results were presented as number of immunolabeled cells
per mm2 of tissue in each examined group.

2.3. DNA Extraction and Real-Time PCR Reactions. In order
to allow the quantification of the bacteria, which potentially
invaded the host tissues, we performed the extraction of
bacterial DNA. Histological sections formalin-fixed (3 semi-
serial section of each animal), paraffin-embedded tissue
sections comprising the teeth and surrounding structures
were submitted to DNA extraction with QIAamp DNA FFPE
Tissue Kit (QUIAGEN) following manufacturer instructions.
Bacterial load (16S) was quantified by Real-Time-PCR
performed in a MiniOpticon system (BioRad, Hercules,
CA, USA), using SybrGreenMasterMix (Invitrogen), with
100 nM specific primers and 5 ng of DNA in each reaction,
as previously described [27].

2.4. Statistical Analyses. A two-way ANOVA was employed to
analyze data from all groups, followed by one-way ANOVA
and Tukey’s test to determine significant differences within
the same group related to time. The significance level was
always set at P < 0.05, and all calculations were performed
using GraphPad program Prism 3.0 (GraphPad Software Inc,
EUA).

3. Results

Our immunohistochemical results did not show significant
differences between control and experimental groups after
1 and 3 months of diabetes induction. However, differences
were detected after 6, 9, and 12 months regarding to RAGE,
TNF-alpha, IL-1beta, IL-6, and RANKL, as illustrated in
Figure 1. The immunoreactive cells were detected in different
regions of periodontal tissues with different morphologies.
Considering that we did not observe a focal distribution
of immunostained cells, we performed a quantification

comprising all regions of periodontium in order to quantify
the number of immunoreactive cells.

Regarding to RAGE, we initially detected increased
number of RAGE-positive cells in diabetic groups after 6
(P < 0.001), 9 (P < 0.01), and 12 (P < 0.01) months when
compared to control group (Figure 2). Evaluating different
periods of control group, we did not found any differences
in immunoreactivity patterns. Nevertheless, diabetic groups
revealed changes in the number of RAGE-positive cells
among periods of experimental design.

Our next step was to evaluate the number of positive
cells regarding to proinflammatory cytokines such as TNF-
alpha, IL-1beta, and IL-6 (Figure 3). Evaluating the number
of TNF-alpha-positive cells, we found a statistical significant
increase in experimental groups after 6 (P < 0.05) and 12
months (P < 0.001) when compared to their respective
control groups (Figure 3). Different time points of control
groups did not show any differences, while diabetic groups
revealed a trend of increase (P > 0.05) after 3 months. This
difference became more pronounced at later periods, being
statistically significant after 6 and 12 months.

Moreover, the number of IL-1beta-positive cells was
increased only after 12 months (P < 0.001) in diabetic
group (Figure 3). In control groups, few immunoreactive
cells were detected in all periods; however, experimental
groups revealed a trend of increase (P > 0.05) at 3, 6, and
9 months. In IL-6 experiments, we observed an increase in
the number of immunoreactive cells in diabetic groups at 9
(P < 0.001) and 12 (P < 0.01) months compared to control
groups (Figure 3).

Regarding to RANKL, diabetic groups presented the
same pattern as control groups in initial periods (1 and
3 months). However, a trend of increase (P > 0.05) was
observed in next periods, being statistically significant after
9 months of diabetes induction (P < 0.001) (Figure 3).

In addition, we did not observe significant statistical
differences between control and experimental groups in
MMP-2 and MMP-9 at any timepoints (Figure 4). We
observed few MMP-2-positive cells in initial periods with a
trend of increase (P > 0.05) in control groups after 9 and
12 months. In experimental group, it was detected a slight
increase in the number of MMP-2-positive cells, followed by
a trend to reduction in the period of 12 months. We also
detected a trend of increase (P > 0.05) in the number of
MMP-9-positive cells in diabetic group after 12 months of
diabetes induction.

These results are the mean value of 15 histological fields
per histological section, comprising all the periodontal area
from the gingival crest to the root apex. When the results
were individually analyzed by a subdivision of periodontal
area in cervical, medium, and apical regions (5 histological
fields in each region), no significant differences were found
in the distribution of immunoreactive cells (data not shown).

We also evaluated the overall microbial load in oral
cavity, and the results demonstrated that the levels of
16S bacterial DNA were similar in all the periods evalu-
ated in both diabetic and control groups (Figure 5). The
DNA samples extracted from periodontal tissue sections
were also investigated regarding the presence of classic



4 Experimental Diabetes Research

Cervical region Medium region Apical region

200 μm 50 μm

(a)

(b)

(c)

(d)

(e)

Figure 1: Increased number of immunoreactive cells after 9 months of diabetes induction in rats. Histological sections of periodontal tissues
were submitted to immunohistochemical analyses for RAGE (a), TNF-alpha (b), IL-1beta (c), IL-6 (d), and RANKL (e) after 9 months of
diabetes induction in rats. Observe the presence of immunoreactive cells in all regions of periodontium (cervical, medium, and apical
regions), being not limited to the gingival area.

periodontopathogens (Actinomyces actinomycetemcomitans,
Porphyromonas gingivalis, Prevotella nigrescens, Tannerella
forsythia, and Treponema denticola) but no positive samples
were observed in any period of both diabetic and control
groups (data not shown).

4. Discussion

It is well established that periodontal disease is more
severe and frequent in presence of diabetes [14–16], being

associated with higher levels of proinflammatory cytokines,
osteoclastogenic factors, and metalloproteases [19, 26, 28].
While the modulation of the established periodontal disease
by diabetes seems to be a consensus in the scientific literature,
the potential coinduction of periodontal disease by diabetes
recently demonstrated [14, 25] remains almost unknown.
In this context, the co-induction hypothesis proposed is
characterized by a “two-hit model,” where the “first hit”
is supposed to be provided by the oral microflora. In this
way, the “second hit” is represented by the exacerbated



Experimental Diabetes Research 5

RAGE

1 3 6 9 12
0

20

40

60

80

Diabetic
Control

Time (months)

∗
∗∗

N
u

m
be

r 
of

 im
m

u
n

or
ea

ct
iv

e 
ce

lls
/m

m
2

Figure 2: Increased number of RAGE-positive cells in diabetic
groups. Histological sections of periodontal tissues were submitted
to immunohistochemical analyses for RAGE after 1, 3, 6, 9, and 12
months of diabetes induction. The results are presented as mean ±
SD of immunoreactive cells per mm2 in 3 semiserial section of each
animal, ∗P < 0.05, one-way analysis of variance (ANOVA) followed
by Tukey’s test.

inflammatory response driven by systemic diseases such
diabetes [25].

In accordance with this coinduction hypothesis [25], our
previous results demonstrated that diabetes induction trigger
alterations, which are typical of periodontal diseases even in
the absence of periodontitis induction [24]. However, in our
initial report, no attempts to characterize possible changes
in the overall oral microbial profile as well to evaluate
potential mechanisms underlying spontaneous periodontitis
development were conducted. Then, the aim of this study
was to investigate the possible microbiological changes and
the spatial distribution and the number of immunostained
cells to RAGE, TNF-alpha, IL-1beta, IL-6, RANKL and
MMP-2, and MMP-9, in periodontal tissue after diabetes
induction.

Initially, we investigated the overall bacterial load in oral
cavity, represented by the 16S bacterial DNA levels, and our
results also did not show variations in periodontal bacterial
load, suggesting the absence of quantitative differences in
the biofilm in both groups. Also, we investigated the pres-
ence of classical periodontopathogens such as Actinomyces
actinomycetemcomitans, Porphyromonas gingivalis, Prevotella
nigrescens, Tannerella forsythia, and Treponema denticola,
but no positive samples were found along the disease
development in diabetic group nor in control animals. In this
way, our data suggest that the presence of diabetes did not
affect qualitative and quantitative pattern of dental biofilm.

Interestingly, previous studies showed that exacerbated
periodontal disease associated to diabetes is caused by clas-
sical periodontopathogens, but it is important to consider
that the aggravation of existing disease is distinct of the
coinduction situation, where classical periodontopathogens

were supposed to be absent in health conditions [29]. Then,
the establishment of periodontal disease seems to be a
result of an exacerbated response against a conventional
stimulus provided by the periodontopathogenic subgingival
microflora [25].

Thus, our next step was to investigate the possible effects
of diabetes over host response throughout immunohisto-
chemical evaluations. Interestingly, we observed an increase
in the number of immunostained cells to RAGE after 6,
9, and 12 months of diabetes induction, confirming the
involvement of these receptors. In agreement, it has been
found an increase in RAGE expression in the gingival tissues
of diabetic patients compared to nondiabetic patients with
periodontal disease [30, 31]. Likewise, diabetic mice showed
an increased AGEs deposition and RAGE expression in
the gingival tissues [32]. In addition, blockade of AGE-
RAGE interaction with soluble RAGE receptor in diabetic
mice decreased alveolar bone resorption and expression of
cytokines and metalloproteinases [13, 18]. Likewise, RAGE
was demonstrated to mediate osteoclasts formation and
activation with consequent bone resorption and decrease of
bone density, and to upregulate the expression of proinflam-
matory cytokines [33].

Accordingly, we observed an increased number of TNF-
alpha, IL-1beta, and IL-6-positive cells in diabetic groups.
Regarding to TNF-alpha, we found an increase in the
number of TNF-alpha-positive cells after 6 and 12 months
of diabetes induction. In accordance with our data, higher
serum levels of this cytokine have been detected in patients
with poorly controlled diabetes when compared to healthy
patients [34, 35]. Also, increased expression of TNF-alpha
was also observed in diabetic mice after oral inoculation of
Porphyromonas gingivalis [23]. In fact, macrophages from
diabetic patients had greater ability to produce TNF-alpha
when compared to macrophages from nondiabetic patients
[19]. It also has been demonstrated that LPS stimulation
resulted in a trend of increase in TNF-alpha, IL-1beta, and
IL-6 expression in vitro [36].

Regarding IL-1beta, we observed an increased number of
immunostaining cells after 12 months of diabetes induction.
Other studies also reported increased expression of IL-
1beta in diabetic patients with periodontal disease [19, 37].
Conversely, it has been described that diabetic patients with
periodontal disease presented decreased levels of IL-1 when
compared to non-diabetic patients [28], while other authors
did not found differences regarding to cytokines expression
in diabetic and non-diabetic patients with periodontitis [38].
It is possible that increased TNF-alpha and IL-1beta levels
affect the expression of IL-6, considering that we detected an
increase in the number of immunostained cells to IL-6 after
9 and 12 months of diabetes induction. Considering that an
augment was observed in IL-6 expression in cultures of gin-
gival fibroblasts stimulated with TNF-alpha and IL-1beta, it
has been suggested that exacerbated expression of TNF-alpha
and IL-1beta regulate IL-6 expression [39]. According to
our results, increased expression of IL-6 has been described
in diabetic patients with periodontitis [35]. Similarly, other
authors demonstrated a trend to increased IL-6 levels in
diabetic subjects with periodontal disease [37, 38].



6 Experimental Diabetes Research

∗

∗

TNF-α

1 3 6 9 12
0

20

40

60

80

Diabetic
Control

Time (months)

N
u

m
be

r 
of

 im
m

u
n

or
ea

ct
iv

e 
ce

lls
/m

m
2

(a)

1 3 6 9 12
0

20

40

60

80

100

Time (months)

Diabetic
Control

IL-1β

∗

N
u

m
be

r 
of

 im
m

u
n

or
ea

ct
iv

e 
ce

lls
/m

m
2

(b)

1 3 6 9 12
0

50

100

150

200

250

Diabetic
Control

Time (months)

IL-6

∗ ∗

N
u

m
be

r 
of

 im
m

u
n

or
ea

ct
iv

e 
ce

lls
/m

m
2

(c)

RANKL

1 3 6 9 12
0

25

50

75

100

125

Diabetic
Control

Time (months)

∗

N
u

m
be

r 
of

 im
m

u
n

or
ea

ct
iv

e 
ce

lls
/m

m
2

(d)

Figure 3: Increased number of immunoreactive cells for TNF-alpha, IL-1beta, IL-6, and RANKL in diabetic groups. After 1, 3, 6, 9, and 12
months of diabetes induction, histological sections of periodontal tissues were submitted to immunohistochemical analyses for TNF-alpha,
IL-1beta, IL-6, and RANKL. The results are presented as mean± SD of immunoreactive cells per mm2 in 3 semiserial section of each animal,
∗P < 0.05, one-way analysis of variance (ANOVA) followed by Tukey’s test.

It is well established that the proinflammatory cytokines
above discussed present a great influence in osteoclastoge-
nesis and characteristically affect RANKL expression [39].
Indeed, our data showed increased number of RANKL-
positive cells after 9 months of diabetes induction. Although
contradictory results have been demonstrated that diabetes
did not affect RANKL expression [38], other authors showed
that diabetic mice presented decreased bone density accom-
panied by higher levels of RANKL, IL-1, and IL-6 [40].
Then, it has been described that increased expression of
RANKL axis suggesting that RANK/RANKL/OPG is involved
in the molecular basis of the association between diabetes
and periodontal disease [41].

In addition, other authors have evaluated the influence
of diabetes in MMPs expression, demonstrating higher levels
of MMP-8 and MMP-9 in periodontal tissue of diabetic
patients with periodontitis [42]. However, other authors did
not found differences in MMP-1 and MMP-8 expression in
periodontal tissue and gingival crevicular fluid of diabetic
and nondiabetic patients, both with periodontal disease [37].
Although our data did not show significant differences in
MMP-2 and MMP-9 immunoreactivities, we detected a trend
of increase in the number of MMP-9-positive cells in rats
after 9 and 12 months of diabetes induction. Accordingly,
differences in MMP-2 levels in diabetic rats with ligature-
induced periodontal disease was not observed; however,



Experimental Diabetes Research 7

1 3 6 9 12
0

25

50

75

100

125

150

Diabetic
Control

Time (months)

MMP-2
N

u
m

be
r 

of
 im

m
u

n
or

ea
ct

iv
e 

ce
lls

/m
m

2

(a)

1 3 6 9 12
0

100

200

300

400

Diabetic
Control

Time (months)

MMP-9

N
u

m
be

r 
of

 im
m

u
n

or
ea

ct
iv

e 
ce

lls
/m

m
2

(b)

Figure 4: Absence of differences in the number of MMP-2 and MMP-9-positive cells between control and diabetic groups. After 1, 3, 6,
9, and 12 months of diabetes induction, histological sections of periodontal tissues were submitted to immunohistochemical analyses for
MMP-2 (a) and MMP-9 (b). The results are presented as mean± SD of immunoreactive cells per mm2 in 3 semiserial section of each animal,
∗P < 0.05, one-way analysis of variance (ANOVA) followed by Tukey’s test.

1 3 6 9 12
4

6

8

10

16S

16
S 

ba
ct

er
ia

l D
N

A

Diabetic
Control

Time (months)

Figure 5: Variations in the number of immunoreactive cells is not
associated with bacterial load. Bacterial load (16S) in periodontal
tissues was quantified by Real-TimePCR, using SyberGreen system
and normalized by tissue weight. One-way analysis of variance
(ANOVA) followed by Tukey’s test.

higher levels of MMP-9 were detected [22]. Other authors
demonstrated that, even in the absence of periodontal
disease, MMP-8 and MMP-9 expression was increased in
periodontal tissue of diabetic rats, while no differences
were observed regarding to MMP-2 and MMP-3 between
control and diabetic groups [43]. In addition, it has been
demonstrated that the amount of glucose affects the MMP-1
expression in vitro [44].

Based on these data, it is possible to suggest that
diabetes affect expression of mediators related to establish-
ment and progression of periodontal disease. Although the
mechanisms remain poorly understood, the coinduction of
periodontitis by diabetes is supposed to be the result of the
RAGE/AGEs interaction, which results in the generation of a
proinflammatory environment [12, 13, 18, 31]. Accordingly,
the upregulation of RAGE immunoreactive cells number
precedes the increase of proinflammatory cytokines and
RANKL expression. Interestingly, these changes seem to
not be accompanied by a marked change in the overall
bacterial load in oral cavity. While this data do not support
the statement that the coinduction is independent of the
microbial stimuli, the pattern of immunostaining for all the
factors investigated demonstrate that the expression of RAGE
and cytokines is not limited to the gingival area, where the
periodontal biofilm-stimulated responses characteristically
are localized. Therefore, it is possible to suggest that factors
other than the oral microflora could act as triggers, or the
“second hit”, in distinct areas of the periodontal tissues.

In this context, it is interesting to consider that RAGE
signalling results in an upregulation of TLR2 and TLR4
receptors, resulting in an MyD88-dependent signaling and
subsequent activation of NF-kappaB, increasing the expres-
sion of inflammatory cytokines such as IL-6, IL-1, and TNF-
alpha [45]. Classically, the pathogen-associated molecular
patterns (PAMPs) of commensal subgingival flora are rec-
ognized as the typical ligands of TLRs in oral environment
[46]. However, the presence of high concentration of AGEs,
as a consequence of chronic hyperglycemia, may act as
an endogenous danger signal, related to damage-associated
molecular pattern (DAMPs), which can also trigger the
TLR/MyD88/NF-kappaB pathway. The identification of this



8 Experimental Diabetes Research

“danger signal” by atypical pattern-recognition receptors
such as RAGE seems to stimulate and exacerbate the
conventional response.

In this way, the initial inflammatory and immune
response could be sustained throughout the interaction
between the high concentrations of AGEs and atypical
pattern-recognition receptors such as RAGE. In this way,
DAMPs could not only activate the response but could also
influence the pattern of immune and inflammatory response,
exacerbating these responses even in the absence of classic
PAMPs in areas of periodontal tissue distant from the gin-
gival biofilm. The absence of differences could be explained
based on RAGE expression, which seems to be upregulated
in presence of chronic hyperglycemic environment.

Considering that higher levels of glycemia affect all
periodontal regions, not only the regions in contact with
periodontopathogens, the absence of differences in the
distribution of immunoreactive cells could be explained
based on the central role of AGE-RAGE interaction, whose
could be detected in all regions of periodontal tissues. In
fact, this mechanism seems to be associated with arthritis
development, a chronic systemic disease related to altered
patterns of bone resorption, as observed in periodontitis
[47–49].

Taken together, diabetes seems to be associated with
host response dysfunction, which exacerbates the expres-
sion and/or activation of intracellular signaling molecules,
resulting in upregulation of inflammatory mediators. Our
results demonstrated that diabetes may trigger periodon-
tal disease induction throughout the dysregulation of
immune and inflammatory response against commensal
periodopathogenic microbiota. In fact, these biological
events may partially explain the increased severity of peri-
odontal disease and decreased ability to repair tissue in
presence of diabetes. However, further studies must be
carried out to improve knowledge on the interaction between
diabetes and periodontal diseases, which may serve as a basis
for the development of more effective strategies for preven-
tion and treatment of periodontitis in diabetic patients.

Acknowledgment

This paper was supported by Grants from Fundação
de Amparo à Pesquisa do Estado de São Paulo-FAPESP
(2007/07681-2).

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