Review Article
Biology of Bone Tissue: Structure, Function,
and Factors That Influence Bone Cells

Rinaldo Florencio-Silva,1 Gisela Rodrigues da Silva Sasso,1 Estela Sasso-Cerri,2

Manuel Jesus Simões,1 and Paulo Sérgio Cerri2

1Department of Morphology and Genetics, Laboratory of Histology and Structural Biology, Federal University of São Paulo,
04023-900 São Paulo, SP, Brazil
2Department of Morphology, Laboratory of Histology and Embryology, Dental School, Universidade Estadual Paulista (UNESP),
14801-903 Araraquara, SP, Brazil

Correspondence should be addressed to Paulo Sérgio Cerri; pcerri@foar.unesp.br

Received 3 December 2014; Revised 30 April 2015; Accepted 4 May 2015

Academic Editor: Wanda Lattanzi

Copyright © 2015 Rinaldo Florencio-Silva 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.

Bone tissue is continuously remodeled through the concerted actions of bone cells, which include bone resorption by osteoclasts
and bone formation by osteoblasts, whereas osteocytes act as mechanosensors and orchestrators of the bone remodeling process.
This process is under the control of local (e.g., growth factors and cytokines) and systemic (e.g., calcitonin and estrogens) factors
that all together contribute for bone homeostasis. An imbalance between bone resorption and formation can result in bone diseases
including osteoporosis. Recently, it has been recognized that, during bone remodeling, there are an intricate communication among
bone cells. For instance, the coupling from bone resorption to bone formation is achieved by interaction between osteoclasts and
osteoblasts. Moreover, osteocytes produce factors that influence osteoblast and osteoclast activities, whereas osteocyte apoptosis is
followed by osteoclastic bone resorption. The increasing knowledge about the structure and functions of bone cells contributed to
a better understanding of bone biology. It has been suggested that there is a complex communication between bone cells and other
organs, indicating the dynamic nature of bone tissue. In this review, we discuss the current data about the structure and functions
of bone cells and the factors that influence bone remodeling.

1. Introduction

Bone is a mineralized connective tissue that exhibits four
types of cells: osteoblasts, bone lining cells, osteocytes, and
osteoclasts [1, 2]. Bone exerts important functions in the
body, such as locomotion, support and protection of soft
tissues, calcium and phosphate storage, and harboring of
bone marrow [3, 4]. Despite its inert appearance, bone is a
highly dynamic organ that is continuously resorbed by osteo-
clasts and neoformed by osteoblasts. There is evidence that
osteocytes act as mechanosensors and orchestrators of this
bone remodeling process [5–8]. The function of bone lining
cells is not well clear, but these cells seem to play an important
role in coupling bone resorption to bone formation [9].

Bone remodeling is a highly complex process by which
old bone is replaced by new bone, in a cycle comprised of

three phases: (1) initiation of bone resorption by osteoclasts,
(2) the transition (or reversal period) from resorption to new
bone formation, and (3) the bone formation by osteoblasts
[10, 11]. This process occurs due to coordinated actions
of osteoclasts, osteoblasts, osteocytes, and bone lining cells
which together form the temporary anatomical structure
called basic multicellular unit (BMU) [12–14].

Normal bone remodeling is necessary for fracture healing
and skeleton adaptation to mechanical use, as well as for
calcium homeostasis [15]. On the other hand, an imbalance
of bone resorption and formation results in several bone
diseases. For example, excessive resorption by osteoclasts
without the corresponding amount of nerformed bone by
osteoblasts contributes to bone loss and osteoporosis [16],
whereas the contrary may result in osteopetrosis [17]. Thus,
the equilibrium between bone formation and resorption is

Hindawi Publishing Corporation
BioMed Research International
Volume 2015, Article ID 421746, 17 pages
http://dx.doi.org/10.1155/2015/421746

http://dx.doi.org/10.1155/2015/421746


2 BioMed Research International

Oc

Ot

Ob

Ob

B

B

(a)

BV

BV

B

B

(b)

B

B

B
Ob

Ob

(c)

B
B

B

(d)

Figure 1: (a)–(d) Light micrographs of portions of alveolar bone of rats. (a) HE-stained section showing a portion of a bony trabecula (B).
Polarized osteoblasts (Ob) and giant multinucleated osteoclasts (Oc) are observed in the bone surface; osteocyte (Ot) surrounding bone
matrix is also observed. (b) Section subjected to immunohistochemistry for osteocalcin detection and counterstained with hematoxylin.
Note osteocalcin-positive osteoblasts (arrows) on the surface of a bony trabecula (B). BV: blood vessel. (c) Undecalcified section subjected to
the Gomori method for the detection of alkaline phosphatase, evidencing a portion of bone matrix (B) positive to the alkaline phosphatase
(in brown/black). Ob: osteoblasts. (d) Undecalcified section subjected to the von Kossa method for calcium detection (brown/dark color).
von Kossa-positive bone matrix (B) is observed; some positive granules (arrow) can also be observed on the surface of the bone trabeculae.
Scale bar: 15𝜇m.

necessary and depends on the action of several local and
systemic factors including hormones, cytokines, chemokines,
and biomechanical stimulation [18–20].

Recent studies have shown that bone influences the
activity of other organs and the bone is also influenced by
other organs and systems of the body [21], providing new
insights and evidencing the complexity and dynamic nature
of bone tissue.

In this review we will address the current data about bone
cells biology, bone matrix, and the factors that influence the
bone remodeling process. Moreover, we will briefly discuss
the role of estrogen on bone tissue under physiological and
pathological conditions.

2. Bone Cells

2.1. Osteoblasts. Osteoblasts are cuboidal cells that are located
along the bone surface comprising 4–6% of the total resident
bone cells and are largely known for their bone forming
function [22].These cells showmorphological characteristics
of protein synthesizing cells, including abundant rough endo-
plasmic reticulum and prominent Golgi apparatus, as well

as various secretory vesicles [22, 23]. As polarized cells, the
osteoblasts secrete the osteoid toward the bone matrix [24]
(Figures 1(a), 1(b), and 2(a)).

Osteoblasts are derived from mesenchymal stem cells
(MSC). The commitment of MSC towards the osteopro-
genitor lineage requires the expression of specific genes,
following timely programmed steps, including the synthesis
of bone morphogenetic proteins (BMPs) and members of
the Wingless (Wnt) pathways [25]. The expressions of Runt-
related transcription factors 2,Distal-less homeobox 5 (Dlx5),
and osterix (Osx) are crucial for osteoblast differentiation
[22, 26]. Additionally, Runx2 is a master gene of osteoblast
differentiation, as demonstrated by the fact that Runx2-null
mice are devoid of osteoblasts [26, 27]. Runx2 has demon-
strated to upregulate osteoblast-related genes such as ColIA1,
ALP, BSP, BGLAP, and OCN [28].

Once a pool of osteoblast progenitors expressing Runx2
and ColIA1 has been established during osteoblast differenti-
ation, there is a proliferation phase. In this phase, osteoblast
progenitors show alkaline phosphatase (ALP) activity, and
are considered preosteoblasts [22]. The transition of pre-
osteoblasts to mature osteoblasts is characterized by an



BioMed Research International 3

B
Ob

Otd

Otd

B

ObOb

B

(a)

B

N

N

BLC

Otd
Otd

(b)

Figure 2: Electron micrographs of portions of alveolar bone of rats.
(a) Oteoblasts exhibiting abundant rough endoplasmic reticulum
are observed adjacent to the bone (B) surface. A layer of bundles
of collagen fibrils situated between osteoblasts (Ob) and calcified
bone surface (B) constitutes the osteoid (Otd). Scale bar: 2.7 𝜇m. (b)
Bone lining cells (BLC) exhibiting scarce cytoplasm are situated on
the osteoid surface (Otd). Bone lining cells (BLC) extend some thin
cytoplasmic projections (arrows) towards the osteoid (Otd). Scale
bar: 2 𝜇m. N: nucleus.

increase in the expression of Osx and in the secretion of bone
matrix proteins such as osteocalcin (OCN), bone sialopro-
tein (BSP) I/II, and collagen type I. Moreover, the osteoblasts
undergo morphological changes, becoming large and cu-
boidal cells [26, 29–31].

There is evidence that other factors such as fibroblast
growth factor (FGF), microRNAs, and connexin 43 play
important roles in the osteoblast differentiation [32–35].
FGF-2 knockoutmice showed a decreased bonemass coupled
to increase of adipocytes in the bone marrow, indicating
the participation of FGFs in the osteoblast differentiation
[34]. It has also been demonstrated that FGF-18 upregulates
osteoblast differentiation in an autocrine mechanism [36].
MicroRNAs are involved in the regulation of gene expression
in many cell types, including osteoblasts, in which somemic-
roRNAs stimulate and others inhibit osteoblast differentia-
tion [37, 38]. Connexin 43 is known to be the main con-
nexin in bone [35]. The mutation in the gene encoding con-
nexin 43 impairs osteoblast differentiation and causes skeletal
malformation in mouse [39].

The synthesis of bone matrix by osteoblasts occurs in
two main steps: deposition of organic matrix and its subse-
quent mineralization (Figures 1(b)–1(d)). In the first step, the
osteoblasts secrete collagen proteins, mainly type I collagen,
noncollagen proteins (OCN, osteonectin, BSP II, and osteo-
pontin), and proteoglycan including decorin and biglycan,
which form the organic matrix. Thereafter, mineralization
of bone matrix takes place into two phases: the vesicular

and the fibrillar phases [40, 41]. The vesicular phase occurs
when portions with a variable diameter ranging from 30 to
200 nm, called matrix vesicles, are released from the apical
membrane domain of the osteoblasts into the newly formed
bone matrix in which they bind to proteoglycans and other
organic components. Because of its negative charge, the
sulphated proteoglycans immobilize calcium ions that are
stored within the matrix vesicles [41, 42]. When osteoblasts
secrete enzymes that degrade the proteoglycans, the calcium
ions are released from the proteoglycans and cross the
calcium channels presented in thematrix vesicles membrane.
These channels are formed by proteins called annexins [40].

On the other hand, phosphate-containing compounds are
degraded by the ALP secreted by osteoblasts, releasing phos-
phate ions inside the matrix vesicles. Then, the phosphate
and calcium ions inside the vesicles nucleate, forming the
hydroxyapatite crystals [43]. The fibrillar phase occurs when
the supersaturation of calcium and phosphate ions inside the
matrix vesicles leads to the rupture of these structures and
the hydroxyapatite crystals spread to the surrounding matrix
[44, 45].

Mature osteoblasts appear as a single layer of cuboidal
cells containing abundant rough endoplasmic reticulum and
large Golgi complex (Figures 2(a) and 3(a)). Some of these
osteoblasts show cytoplasmic processes towards the bone
matrix and reach the osteocyte processes [46]. At this stage,
the mature osteoblasts can undergo apoptosis or become
osteocytes or bone lining cells [47, 48]. Interestingly, round/
ovoid structures containing dense bodies and TUNEL-pos-
itive structures have been observed inside osteoblast vac-
uoles.These findings suggest that besides professional phago-
cytes, osteoblasts are also able to engulf anddegrade apoptotic
bodies during alveolar bone formation [49].

2.2. Bone Lining Cells. Bone lining cells are quiescent flat-
shaped osteoblasts that cover the bone surfaces, where neither
bone resorption nor bone formation occurs [50]. These
cells exhibit a thin and flat nuclear profile; its cytoplasm
extends along the bone surface and displays few cytoplasmic
organelles such as profiles of rough endoplasmic reticulum
and Golgi apparatus [50] (Figure 2(b)). Some of these cells
show processes extending into canaliculi, and gap junctions
are also observed between adjacent bone lining cells and
between these cells and osteocytes [50, 51].

The secretory activity of bone lining cells depends on the
bone physiological status, whereby these cells can reacquire
their secretory activity, enhancing their size and adopting
a cuboidal appearance [52]. Bone lining cells functions are
not completely understood, but it has been shown that
these cells prevent the direct interaction between osteoclasts
and bone matrix, when bone resorption should not occur,
and also participate in osteoclast differentiation, producing
osteoprotegerin (OPG) and the receptor activator of nuclear
factor kappa-B ligand (RANKL) [14, 53]. Moreover, the bone
lining cells, together with other bone cells, are an important
component of the BMU, an anatomical structure that is
present during the bone remodeling cycle [9].



4 BioMed Research International

Ot

Ot

BV

BLC

Ob

BLC

B

BV
Ob

B

(a)

*

*

Ot

Ot

(b)

Ot

Ot

B

(c)

Ot N

La

Ca

B

(d)

Figure 3: Light (a and b) and electron micrographs of portions of alveolar bone rats. (a) a semithin section stained with toluidine blue
showing a portion of a bony trabecula (B). Osteoblasts (Ob) and bone lining cells (BLC) are present on bone surface while osteocytes (Ot)
are observed entrapped in the bone matrix. BV: blood vessels. Scale bar: 15𝜇m. (b) Section subjected to the silver impregnation method.
Note the cytoplasmic processes (arrows) of the osteocytes (Ot) connecting them with each other. Scale bar: 15𝜇m. (c) Scanning electron
micrograph showing two osteocytes (Ot) surrounded by bonematrix (B). Note that the cytoplasmic processes (arrows) are observed between
the osteocytes (Ot) forming an interconnected network. Scale bar: 2𝜇m. (d) Transmission electron micrograph showing a typical osteocyte
(Ot) inside a lacuna (La) in the bonematrix (B), with its cytoplasmic processes (arrows) inside the canaliculi (Ca). Scale bar: 2 𝜇m.N: nucleus.

2.3. Osteocytes. Osteocytes, which comprise 90–95% of the
total bone cells, are the most abundant and long-lived cells,
with a lifespan of up to 25 years [54]. Different from oste-
oblasts and osteoclasts, which have been defined by their
respective functions during bone formation and bone resorp-
tion, osteocytes were earlier defined by their morphology
and location. For decades, due to difficulties in isolating
osteocytes from bone matrix led to the erroneous notion that
these cells would be passive cells, and their functions were
misinterpreted [55]. The development of new technologies
such as the identification of osteocyte-specific markers, new
animal models, development of techniques for bone cell
isolation and culture, and the establishment of phenotypically
stable cell lines led to the improvement of the understanding
of osteocyte biology. In fact, it has been recognized that these
cells play numerous important functions in bone [8].

The osteocytes are located within lacunae surrounded
by mineralized bone matrix, wherein they show a dendritic
morphology [15, 55, 56] (Figures 3(a)–3(d)).Themorphology
of embedded osteocytes differs depending on the bone type.
For instance, osteocytes from trabecular bone are more

rounded than osteocytes from cortical bone, which display
an elongated morphology [57].

Osteocytes are derived from MSCs lineage through oste-
oblast differentiation. In this process, four recognizable stages
have been proposed: osteoid-osteocyte, preosteocyte, young
osteocyte, and mature osteocyte [54]. At the end of a
bone formation cycle, a subpopulation of osteoblasts becomes
osteocytes incorporated into the bone matrix. This process is
accompanied by conspicuous morphological and ultrastruc-
tural changes, including the reduction of the round osteoblast
size. The number of organelles such as rough endoplasmic
reticulum andGolgi apparatus decreases, and the nucleus-to-
cytoplasm ratio increases, which correspond to a decrease in
the protein synthesis and secretion [58].

During osteoblast/osteocyte transition, cytoplasmic pro-
cess starts to emerge before the osteocytes have been encased
into the bone matrix [22]. The mechanisms involved in
the development of osteocyte cytoplasmic processes are not
well understood. However, the protein E11/gp38, also called
podoplanin may have an important role. E11/gp38 is highly
expressed in embedding or recently embedded osteocytes,



BioMed Research International 5

similarly to other cell types with dendritic morphology such
as podocytes, type II lung alveolar cells, and cells of the
choroid plexus [59]. It has been suggested that E11/gp38 uses
energy from GTPase activity to interact with cytoskeletal
components andmolecules involved in cell motility, whereby
regulate actin cytoskeleton dynamics [60, 61]. Accordingly,
inhibition of E11/gp38 expression in osteocyte-like MLO-Y4
cells has been shown to block dendrite elongation, suggesting
that E11/gp38 is implicated in dendrite formation in osteo-
cytes [59].

Once the stage of mature osteocyte totally entrapped
within mineralized bone matrix is accomplished, several of
the previously expressed osteoblast markers such as OCN,
BSPII, collagen type I, and ALP are downregulated. On the
other hand, osteocyte markers including dentine matrix pro-
tein 1 (DMP1) and sclerostin are highly expressed [8, 62–64].

Whereas the osteocyte cell body is located inside the
lacuna, its cytoplasmic processes (up to 50 per each cell)
cross tiny tunnels that originate from the lacuna space called
canaliculi, forming the osteocyte lacunocanalicular system
[65] (Figures 3(b)–3(d)). These cytoplasmic processes are
connected to other neighboring osteocytes processes by gap
junctions, as well as to cytoplasmic processes of osteoblasts
and bone lining cells on the bone surface, facilitating the
intercellular transport of small signaling molecules such
as prostaglandins and nitric oxide among these cells [66].
In addition, the osteocyte lacunocanalicular system is in
close proximity to the vascular supply, whereby oxygen and
nutrients achieve osteocytes [15].

It has been estimated that osteocyte surface is 400-fold
larger than that of the all Haversian and Volkmann systems
and more than 100-fold larger than the trabecular bone
surface [67, 68].The cell-cell communication is also achieved
by interstitial fluid that flows between the osteocytes pro-
cesses and canaliculi [68]. By the lacunocanalicular system
(Figure 3(b)), the osteocytes act as mechanosensors as their
interconnected network has the capacity to detectmechanical
pressures and loads, thereby helping the adaptation of bone
to daily mechanical forces [55]. By this way, the osteocytes
seem to act as orchestrators of bone remodeling, through
regulation of osteoblast and osteoclast activities [15, 69].
Moreover, osteocyte apoptosis has been recognized as a
chemotactic signal to osteoclastic bone resorption [70–73].
In agreement, it has been shown that during bone resorption,
apoptotic osteocytes are engulfed by osteoclasts [74–76].

The mechanosensitive function of osteocytes is accom-
plished due to the strategic location of these cells within
bone matrix. Thus, the shape and spatial arrangement of the
osteocytes are in agreement with their sensing and signal
transport functions, promoting the translation of mechanical
stimuli into biochemical signals, a phenomenon that is called
piezoelectric effect [77].Themechanisms and components by
which osteocytes convert mechanical stimuli to biochemical
signals are not well known. However, two mechanisms have
been proposed. One of them is that there is a protein complex
formed by a cilium and its associated proteins PolyCystins 1
and 2, which has been suggested to be crucial for osteocyte
mechanosensing and for osteoblast/osteocyte-mediated bone
formation [78]. The second mechanism involves osteocyte

cytoskeleton components, including focal adhesion protein
complex and its multiple actin-associated proteins such as
paxillin, vinculin, talin, and zyxin [79]. Upon mechanical
stimulation, osteocytes produce several secondary messen-
gers, for example, ATP, nitric oxide (NO), Ca2+, and pros-
taglandins (PGE

2
and PGI

2
,) which influence bone physiol-

ogy [8, 80]. Independently of the mechanism involved, it is
important to mention that the mechanosensitive function of
osteocytes is possible due to the intricate canalicular network,
which allows the communication among bone cells.

2.4. Osteoclasts. Osteoclasts are terminally differentiated
multinucleated cells (Figures 4(a)–4(d)), which originate
from mononuclear cells of the hematopoietic stem cell
lineage, under the influence of several factors. Among these
factors the macrophage colony-stimulating factor (M-CSF),
secreted by osteoprogenitor mesenchymal cells and oste-
oblasts [81], and RANK ligand, secreted by osteoblasts,
osteocytes, and stromal cells, are included [20]. Together,
these factors promote the activation of transcription factors
[81, 82] and gene expression in osteoclasts [83, 84].

M-CSF binds to its receptor (cFMS) present in osteo-
clast precursors, which stimulates their proliferation and
inhibits their apoptosis [82, 85]. RANKL is a crucial fac-
tor for osteoclastogenesis and is expressed by osteoblasts,
osteocytes, and stromal cells. When it binds to its recep-
tor RANK in osteoclast precursors, osteoclast formation is
induced [86]. On the other hand, another factor called oste-
oprotegerin (OPG), which is produced by a wide range
of cells including osteoblasts, stromal cells, and gingival
and periodontal fibroblasts [87–89], binds to RANKL, pre-
venting the RANK/RANKL interaction and, consequently,
inhibiting the osteoclastogenesis [87] (Figure 5). Thus, the
RANKL/RANK/OPG system is a key mediator of osteoclas-
togenesis [19, 86, 89].

The RANKL/RANK interaction also promotes the
expression of other osteoclastogenic factors such as NFATc1
and DC-STAMP. By interacting with the transcription
factors PU.1, cFos, and MITF, NFATc1 regulates osteoclast-
specific genes including TRAP and cathepsin K, which are
crucial for osteoclast activity [90]. Under the influence of
the RANKL/RANK interaction, NFATc1 also induces the
expression of DC-STAMP, which is crucial for the fusion of
osteoclast precursors [91, 92].

Despite these osteoclastogenic factors having been well
defined, it has recently been demonstrated that the osteo-
clastogenic potential may differ depending on the bone site
considered. It has been reported that osteoclasts from long
bone marrow are formed faster than in the jaw.This different
dynamic of osteoclastogenesis possibly could be, due to the
cellular composition of the bone-site specific marrow [93].

During bone remodeling osteoclasts polarize; then, four
types of osteoclast membrane domains can be observed: the
sealing zone and ruffled border that are in contact with the
bonematrix (Figures 4(b) and 4(d)), as well as the basolateral
and functional secretory domains, which are not in contact
with the bone matrix [94, 95]. Polarization of osteoclasts
during bone resorption involves rearrangement of the actin



6 BioMed Research International

Oc

OtBV B

Oc

(a)

B

N
N

Oc

V
V

RB
RB

V

(b)

B

Ot

Oc

Ap

Oc1

(c)

Oc
N

N

B

V

Ap

CZCZ
RB

(d)

Figure 4: Light (a and c) and electron micrographs (b and d) of portions of alveolar bone of rats. In (a) tartrate-resistant acid phosphatase
(TRAP) activity (in red color) is observed in the cytoplasm of osteoclasts (OC) adjacent to the alveolar bone (B) surface. Note that in the
opposite side of the bony trabecula B is covered by large and polarized osteoblasts (Ob). Ot, osteocytes (Ot); BV: blood vessel. Bar: 40 𝜇m. (b)
Multinucleated osteoclast (OC) shows evident ruffled border (RB) adjacent to the excavated bone surface (arrows). Several vacuoles (V) are
observed in the cytoplasm adjacent to ruffled border (RB). N: nucleus. Bar: 4𝜇m. (c) Portions of TRAP-positive osteoclasts (Oc and Oc

1
) are

observed in a resorbing bone lacuna. A round cell (Ap) with condensed irregular blocks of chromatin, typical apoptotic cell, is observed inside
a large vacuole of the Oc

1
. B: bone matrix; Ot: osteocyte. Bar: 15𝜇m. (d) An osteoclast (Oc) showing ruffled border (RB) and clear zone (CZ)

is in close juxtaposition to the excavation of the bone surface (arrows), that is, Howship lacuna. Vacuoles (V) with varied size are present next
to the ruffled border (RB); one of them contains a round cell with masses of condensed chromatin (Ap), typical of cell undergoing apoptosis.
B: bone matrix; N: nucleus. Bar: 3 𝜇m.

cytoskeleton, in which an F-actin ring that comprises a dense
continuous zone of highly dynamic podosome is formed and
consequently an area of membrane that develop into the
ruffled border is isolated. It is important tomention that these
domains are only formed when osteoclasts are in contact
with extracellular mineralized matrix, in a process which
𝛼v𝛽3-integrin, as well as the CD44, mediates the attachment
of the osteoclast podosomes to the bone surface [96–99].
Ultrastructurally, the ruffled border is a membrane domain
formed by microvilli, which is isolated from the surrounded
tissue by the clear zone, also known as sealing zone. The
clear zone is an area devoid of organelles located in the
periphery of the osteoclast adjacent to the bone matrix [98].
This sealing zone is formed by an actin ring and several other
proteins, including actin, talin, vinculin, paxillin, tensin,
and actin-associated proteins such as 𝛼-actinin, fimbrin,
gelsolin, and dynamin [95]. The 𝛼v𝛽3-integrin binds to non-
collagenous bone matrix containing-RGD sequence such as
bone sialoprotein, osteopontin, and vitronectin, establishing
a peripheric sealing that delimits the central region, where the
ruffled border is located [98] (Figures 4(b)–4(d)).

The maintenance of the ruffled border is also essen-
tial for osteoclast activity; this structure is formed due to
intense trafficking of lysosomal and endosomal components.
In the ruffled border, there is a vacuolar-type H+-ATPase
(V-ATPase), which helps to acidify the resorption lacuna
and hence to enable dissolution of hydroxyapatite crystals
[20, 100, 101]. In this region, protons and enzymes, such
as tartrate-resistant acid phosphatase (TRAP), cathepsin K,
and matrix metalloproteinase-9 (MMP-9) are transported
into a compartment called Howship lacuna leading to bone
degradation [94, 101–104] (Figure 5). The products of this
degradation are then endocytosed across the ruffled border
and transcytosed to the functional secretory domain at the
plasma membrane [7, 95].

Abnormal increase in osteoclast formation and activity
leads to some bone diseases such as osteoporosis, where
resorption exceeds formation causing decreased bone density
and increased bone fractures [105]. In some pathologic condi-
tions including bone metastases and inflammatory arthritis,
abnormal osteoclast activation results in periarticular ero-
sions and painful osteolytic lesions, respectively [83, 105, 106].



BioMed Research International 7

CZ CZ

RB

Cp

TRAP

CAII

RANKL RANK

OPG
Sclerostin, DKK-1

PGE2, NO, IGF-1

RANK RANKL

OPG

Sema4D
Sema3A

Eph2 Eph4

Cx3

Oc

N

N

Ob

Ot

Col1
OCN
OSN
OSP
BSP
BMP

BLC

Cx3

HL

Cx3

Ot

B

B

5

HCO3
−

Cl−

Cl−

Cl−

CO2 + H2O

H+ H+

H+MMP-9

HCO3 + H

Figure 5: Schematic summary of bone tissue showing bone cells and the relationships among them and with bone matrix (B). Osteoclast
(Oc) activation occurs after binding of RANKL to its receptor RANK, present in the membrane of osteoclast precursors. Then, osteoclast
becomes polarized through its cytoskeleton reorganization; the ruffled border (RB) and clear zone (CZ) are membrane specializations
observed in the portion of the osteoclast juxtaposed to the bone resorption surface, Howship lacuna (HL). Dissolution of hydroxyapatite
occurs in the bone surface adjacent to the ruffled border (RF) upon its acidification due to pumping of hydrogen ions (H+) to the HL. H+
and ions bicarbonate (HCO3

−) originate from the cleavage of carbonic acid (H
2
CO
3
) under the action of carbonic anhydrase II (CAII).

After dissolution of mineral phase, osteoclast (Oc) releases cathepsin (Cp), matrix metalloproteinase-9 (MMP-9), and tartrate-resistant
acid phosphatase (TRAP) that degrade the organic matrix. EphrinB2 (Eph2) present in osteoclast membrane binds to ephrinB4 (Eph4)
in osteoblast (Ob) membrane, promoting its differentiation, whereas the reverse signaling (ephrinB4/ephrinB2) inhibits osteoclastogenesis.
Sema4Dproduced by osteoclasts inhibits osteoblasts, while Sema3A secreted by osteoblasts inhibits osteoclasts. Osteoblasts (Ob) also produce
receptor activator of nuclear factor KB (RANKL) and osteoprotegerin (OPG), which increase and decrease osteoclastogenesis, respectively.
Osteoblasts (Ob) secrete collagenous (Col1) and noncollagenous proteins such as osteocalcin (OCN), osteopontin (OSP), osteonectin (OSN),
bone sialoprotein (BSP), and bone morphogenetic proteins (BMP). Osteocytes (Ot) are located within lacunae surrounded by mineralized
bone matrix (B). Its cytoplasmic processes cross canaliculi to make connection with other neighboring osteocytes processes by gap junctions,
mainly composed by connexin 43 (Cx3), as well as to cytoplasmic processes of osteoblasts (Ob) and bone lining cells (BLC) on bone surface.
RANKL secreted by osteocytes stimulates osteoclastogenesis, while prostaglandin E

2
(PGE2), nitric oxide (NO), and insulin-like growth

factor (IGF) stimulate osteoblast activity. Conversely, osteocytes produce OPG that inhibits osteoclastogenesis; moreover, osteocytes produce
sclerostin and dickkopf WNT signaling pathway inhibitor (DKK-1) that decrease osteoblast activity.

In periodontitis, a disease of the periodontium caused by bac-
terial proliferation [107, 108] induces themigration of inflam-
matory cells. These cells produce chemical mediators such
as IL-6 and RANKL that stimulate the migration of osteo-
clasts [89, 109, 110]. As a result, an abnormal increased bone
resorption occurs in the alveolar bone, contributing to the
loss of the insertions of the teeth and to the progression of
periodontitis [89, 111].

On the other hand, in osteopetrosis, which is a rare bone
disease, genetic mutations that affect formation and resorp-
tion functions in osteoclasts lead to decreased bone resorp-
tion, resulting in a disproportionate accumulation of bone

mass [17]. These diseases demonstrate the importance of the
normal bone remodeling process for themaintenance of bone
homeostasis.

Furthermore, there is evidence that osteoclasts display
several other functions. For example, it has been shown that
osteoclasts produce factors called clastokines that control
osteoblast during the bone remodeling cycle, which will be
discussed below.Other recent evidence is that osteoclastsmay
also directly regulate the hematopoietic stem cell niche [112].
These findings indicate that osteoclasts are not only bone
resorbing cells, but also a source of cytokines that influence
the activity of other cells.



8 BioMed Research International

2.5. Extracellular Bone Matrix. Bone is composed by inor-
ganic salts and organic matrix [113]. The organic matrix con-
tains collagenous proteins (90%), predominantly type I colla-
gen, andnoncollagenous proteins including osteocalcin, oste-
onectin, osteopontin, fibronectin and bone sialoprotein II,
bone morphogenetic proteins (BMPs), and growth factors
[114]. There are also small leucine-rich proteoglycans includ-
ing decorin, biglycan, lumican, osteoaderin, and seric pro-
teins [114–116].

The inorganic material of bone consists predominantly
of phosphate and calcium ions; however, significant amounts
of bicarbonate, sodium, potassium, citrate, magnesium, car-
bonate, fluorite, zinc, barium, and strontium are also present
[1, 2]. Calcium and phosphate ions nucleate to form the
hydroxyapatite crystals, which are represented by the chem-
ical formula Ca

10
(PO
4
)
6
(OH)
2
. Together with collagen, the

noncollagenous matrix proteins form a scaffold for hydrox-
yapatite deposition and such association is responsible for the
typical stiffness and resistance of bone tissue [4].

Bone matrix constitutes a complex and organized frame-
work that provides mechanical support and exerts essential
role in the bone homeostasis. The bone matrix can release
several molecules that interfere in the bone cells activity
and, consequently, has a participation in the bone remod-
eling [117]. Once loss of bone mass alone is insufficient to
cause bone fractures [118], it is suggested that other factors,
including changes in the bone matrix proteins and their
modifications, are of crucial importance to the understanding
and prediction of bone fractures [119]. In fact, it is known that
collagen plays a critical role in the structure and function of
bone tissue [120].

Accordingly, it has been demonstrated that there is a
variation in the concentration of bone matrix proteins with
age, nutrition, disease, and antiosteoporotic treatments [119,
121, 122] which may contribute to postyield deformation and
fracture of bone [119]. For instance, in vivo and in vitro
studies have reported that the increase in hyaluronic acid
synthesis after parathyroid hormone (PTH) treatment was
related to a subsequent bone resorption [123–127] suggesting
a possible relationship between hyaluronic acid synthesis and
the increase in osteoclast activity.

2.6. Interactions between Bone Cells and Bone Matrix. As
previously discussed, bone matrix does not only provides
support for bone cells, but also has a key role in regu-
lating the activity of bone cells through several adhesion
molecules [117, 128]. Integrins are themost common adhesion
molecules involved in the interaction between bone cells and
bone matrix [129]. Osteoblasts make interactions with bone
matrix by integrins, which recognize and bind to RGD and
other sequences present in bone matrix proteins including
osteopontin, fibronectin, collagen, osteopontin, and bone
sialoprotein [130, 131]. The most common integrins present
in osteoblasts are 𝛼1𝛽1, 𝛼2𝛽1, and 𝛼5𝛽1 [132]. These proteins
also play an important role in osteoblast organization on the
bone surface during osteoid synthesis [129].

On the other hand, the interaction between osteoclasts
and bone matrix is essential for osteoclast function, since
as previously mentioned, bone resorption occurs only when

osteoclasts bind to mineralized bone surface [97]. Thus,
during bone resorption osteoclasts express 𝛼v𝛽3 and 𝛼2𝛽1
integrins to interact with the extracellular matrix, in which
the former bind to bone-enriched RGD-containing proteins,
such as bone sialoprotein and osteopontin, whereas 𝛽1 inte-
grins bind to collagenfibrils [133, 134].Despite these bindings,
osteoclasts are highly motile even active resorption and, as
migrating cells, osteoclasts do not express cadherins. How-
ever, it has been demonstrated that cadherins provide inti-
mate contact between osteoclast precursors and stromal cells,
which express crucial growth factors for osteoclast differenti-
ation [135].

Integrins play a mediating role in osteocyte-bone matrix
interactions. These interactions are essential for the mechan-
osensitive function of these cells, whereby signals induced
by tissue deformation are generated and amplified [136]. It
is still not clear which integrins are involved, but it has been
suggested that 𝛽3 and 𝛽1 integrins are involved in osteocyte-
bone matrix interaction [137, 138]. These interactions occur
between osteocyte body and the bone matrix of the lacuna
wall as well as between canalicular wall with the osteocyte
processes [137].

Only a narrow pericellular space filled by a fluid separates
the osteocyte cell body and processes from a mineralized
bone matrix [58]. The space between osteocyte cell body and
the lacunar wall is approximately 0.5–1.0𝜇m wide, whereas
the distance between the membranes of osteocyte processes
and the canalicular wall varies from 50 to 100 nm [139].
The chemical composition of the pericellular fluid has not
been precisely defined. However, a diverse array of macro-
molecules produced by osteocytes such as osteopontin, osteo-
calcin, dentin matrix protein, proteoglycans, and hyaluronic
acid is present [136, 140, 141].

The osteocyte and their processes are surrounded by a
nonorganized pericellular matrix; delicate fibrous connec-
tions were observed within the canalicular network, termed
“tethers” [139]. It has been suggested that perlecan is a
possible compound of these tethers [141]. Osteocyte proc-
esses can also attach directly by the “hillocks,” which are
protruding structures originating from the canalicular walls.
These structures form close contacts, possibly by means
of 𝛽
3
-integrins, with the membrane of osteocyte processes

[137, 142]. Thus, these structures seem to play a key role
in the mechanosensitive function of osteocytes, by sensing
the fluid flux movements along with the pericellular space,
provoked by mechanical load forces [143]. In addition, the
fluid flux movement is also essential for the bidirectional
solute transport in the pericellular space, which influences
osteocyte signaling pathways and communication among
bone cells [144, 145].

2.7. Local and Systemic Factor That Regulate Bone Home-
ostasis. Bone remodeling is a highly complex cycle that is
achieved by the concerted actions of osteoblasts, osteo-
cytes, osteoclasts, and bone lining cells [3]. The formation,
proliferation, differentiation, and activity of these cells are
controlled by local and systemic factors [18, 19]. The local
factors include autocrine and paracrine molecules such as
growth factors, cytokines, and prostaglandins produced by



BioMed Research International 9

the bone cells besides factors of the bone matrix that are
released during bone resorption [46, 146]. The systemic
factors which are important to the maintenance of bone
homeostasis include parathyroid hormone (PTH), calci-
tonin, 1,25-dihydroxyvitaminD

3
(calcitriol), glucocorticoids,

androgens, and estrogens [16, 147–150]. Similar to PTH, PTH
related protein (PTHrP), which also binds to PTH receptor,
has also been reported to influence bone remodeling [147].

Estrogen plays crucial roles for bone tissue homeostasis;
the decrease in estrogen level at menopause is the main
cause of bone loss and osteoporosis [16]. The mechanisms
by which estrogen act on bone tissue are not completely
understood. Nevertheless, several studies have shown that
estrogenmaintains bone homeostasis by inhibiting osteoblast
and osteocyte apoptosis [151–153] and preventing excessive
bone resorption. The estrogen suppresses the osteoclast
formation and activity as well as induces osteoclast apop-
tosis [16, 76, 104, 154]. It has been suggested that estrogen
decreases osteoclast formation by inhibiting the synthesis
of the osteoclastogenic cytokine RANKL by osteoblasts and
osteocytes. Moreover, estrogen stimulates these bone cells to
produce osteoprotegerin (OPG), a decoy receptor of RANK
in osteoclast, thus inhibiting osteoclastogenesis [19, 155–
159]. In addition, estrogen inhibits osteoclast formation by
reducing the levels of other osteoclastogenic cytokines such
as IL-1, IL-6, IL-11, TNF-𝛼, TNF-𝛽, and M-CSF [160, 161].

Estrogen acts directly on bone cells by its estrogen
receptors 𝛼 and 𝛽 present on these cells [162]. Moreover, it
has been shown that osteoclast is a direct target for estro-
gen [163, 164]. Accordingly, immunoexpression of estrogen
receptor 𝛽 has been demonstrated in alveolar bone cells
of estradiol-treated female rats. Moreover, the enhanced
immunoexpression observed in TUNEL-positive osteoclasts
indicates that estrogen participates in the control of osteoclast
life span directly by estrogen receptors [163]. These findings
demonstrate the importance of estrogen for the maintenance
of bone homeostasis.

2.8. Bone Remodeling Process. The bone remodeling cycle
takes place within bone cavities that need to be remodeled
[165]. In these cavities, there is the formation of tempo-
rary anatomical structures called basic multicellular units
(BMUs), which are comprised of a group of osteoclasts ahead
forming the cutting cone and a group of osteoblasts behind
forming the closing cone, associated with blood vessels and
the peripheral innervation [11, 166]. It has been suggested that
BMU is covered by a canopy of cells (possibly bone lining
cells) that form the bone remodeling compartment (BRC)
[13]. The BRC seems to be connected to bone lining cells
on bone surface, which in turn are in communication with
osteocytes enclosed within the bone matrix [13, 14].

The bone remodeling cycle begins with an initiation
phase, which consists of bone resorption by osteoclasts,
followed by a phase of bone formation by osteoblasts but
between these two phases, there is a transition (or reversal)
phase. The cycle is completed by coordinated actions of
osteocytes and bone lining cells [10, 11]. In the initiation
phase, under the action of osteoclastogenic factors including
RANKL and M-CSF, hematopoietic stem cells are recruited

to specific bone surface areas and differentiate into mature
osteoclasts that initiate bone resorption [167, 168].

It is known that during bone remodeling cycle, there are
direct and indirect communications among bone cells in a
process called coupling mechanism, which include soluble
coupling factors stored in bonematrix that would be released
after osteoclast bone resorption [169]. For instance, factors
such as insulin-like growth factors (IGFs), transforming
growth factor 𝛽 (TGF-𝛽), BMPs, FGF, and platelet-derived
growth factor (PDGF) seem to act as coupling factors, since
they are stored in bone matrix and released during bone
resorption [170]. This idea is supported by genetic studies
in humans and mice as well as by pharmacological studies
[105, 171].

Recently, it has been suggested that another category of
molecules called semaphorins is involved in the bone cell
communication during bone remodeling [146]. During the
initial phase, osteoblast differentiation and activity must be
inhibited, in order to completely remove the damaged or aged
bone. The osteoclasts express a factor called semaphorin4D
(Sema4D) that inhibits bone formation during bone resorp-
tion [172]. Semaphorins comprise a large family of glycopro-
teins which are not only membrane-bound but also exist as
soluble forms that are found in a wide range of tissues and
shown to be involved in diverse biological processes such
as immune response, organogenesis, cardiovascular devel-
opment, and tumor progression [172, 173]. In bone, it has
been suggested that semaphorins are also involved in cell-cell
communication between osteoclasts and osteoblasts during
the bone remodeling cycle [174–176].

Sema4D expressed in osteoclasts binds to its receptor
(Plexin-B1) present in osteoblasts and inhibits IGF-1 pathway,
essential for osteoblast differentiation [172], suggesting that
osteoclasts suppress bone formation by expressing Sema4D.
Conversely, anothermember of semaphorin family (Sema3A)
has been found in osteoblasts and is considered an inhibitor
of osteoclastogenesis [177]. Thus, during the bone remod-
eling cycle, osteoclasts inhibit bone formation by express-
ing Sema4D, in order to initiate bone resorption, whereas
osteoblasts express Sema3A that suppresses bone resorption,
prior to bone formation [146] (Figure 5).

Recent studies also suggest the existence of other factors
involved in the coupling mechanism during the bone remod-
eling cycle. One of these factors is ephrinB2, a membrane-
bound molecule expressed in mature osteoclasts, which bind
to ephrinB4, found in the plasma membrane of osteoblasts.
The ephrinB2/ephrinB4 binding transduces bidirectional
signals, which promote osteoblast differentiation, whereas
the reverse signaling (ephrinB4/ephrinB2) inhibits osteoclas-
togenesis [178] (Figure 5). These findings suggest that
ephrinB2/ephrinB4 pathway may be involved in the ending
of bone resorption and induces osteoblast differentiation in
the transition phase [178].

In addition, it has been shown that ephrinB2 is also
expressed in osteoblasts [179]. Furthermore, mature osteo-
clasts secrete a number of factors that stimulate osteoblast
differentiation such as the secreted signaling molecules
Wnt10b, BMP6, and the signaling sphingolipid, sphingosine-
1-phosphate [180]. These findings suggest a highly complex



10 BioMed Research International

mechanism of ephrins and the involvement of other factors
in osteoclast/osteoblast communication during the bone
remodeling cycle. On the other hand, despite the stud-
ies reporting the involvement of semaphorins and ephrins
on osteoclast/osteoblast communication, the direct contact
between mature osteoblasts and osteoclasts has not been
demonstrated in vivo and it is still controversial.

Besides osteoclasts and osteoblasts, it has been demon-
strated that osteocytes play key roles during the bone remod-
eling cycle [8]. In fact, under the influence of several factors,
the osteocytes act as orchestrators of the bone remodeling
process, producing factors that influence osteoblast and
osteoclast activities [55] (Figure 5). For example, mechanical
loading stimulates osteocyte to produce factors that exert
anabolic action on bone such as PGE

2
, prostacyclin (PGI

2
),

NO, and IGF-1 [181–184]. On the other hand, mechanical
unloading downregulates anabolic factors and stimulates
osteocytes to produce sclerostin and DKK-1, which are
inhibitors of osteoblast activity [185–188], as well as specific
factors that stimulate local osteoclastogenesis [189]. Scle-
rostin is a product of the SOST gene and is known to be
a negative regulator of bone formation, by antagonizing in
osteoblasts the actions of Lrp5, a key receptor of the Wnt/𝛽-
catenin signaling pathway [63].

Osteocyte apoptosis has been shown to act as a chemo-
tactic signal for local osteoclast recruitment [70, 150, 152, 190,
191]. Accordingly, it has been reported that osteoclasts engulf
apoptotic osteocytes [74, 75, 192], suggesting that osteoclasts
are able to remove dying osteocytes and/or osteoblasts from
a remodeling site (Figures 4(c) and 4(d)). Moreover, it is
reported that the osteoclastogenic factors is also produced by
viable osteocytes nearby the dying osteocytes [193]. There is
evidence that osteocytes act as the main source of RANKL
to promote osteoclastogenesis [167, 168], although this factor
has also been demonstrated to be produced by other cell
types such as stromal cells [194], osteoblasts, and fibroblasts
[88, 89].

Thus, there are still uncertainties about the precise
osteoclastogenesis-stimulating factors produced by osteo-
cytes. Recent reviews have focused on some molecules that
may be candidates for signaling between osteocyte apoptosis
and osteoclastogenesis [72, 73]. For instance, in bones sub-
jected to fatigue loading, viable osteocytes near the apoptotic
ones express, besides high RANKL/OPG ratio, increased
levels of vascular endothelial growth factor (VEGF) and
monocyte chemoattractant protein-1 (CCL2) promoting an
increase in local osteoclastogenesis [194, 195]. It has been
suggested that osteocytes act as the main source of RANKL
to promote osteoclastogenesis [166, 167]. In addition, an
increase in RANKL/OPG ratio expressed by osteocytes was
also observed in connexin43-deficient rats, suggesting that a
disruption in cell-to-cell communication between osteocytes
may induce the release of local proosteoclastogenic cytokines
[33, 196, 197]. High mobility group box protein 1 (HMGB1)
[198–200] and M-CSF [201] have also been suggested to be
produced by osteocytes that stimulate osteoclast recruitment
during bone remodeling [72, 73]. Thus, future studies are
required to address this issue.

2.9. Endocrine Functions of Bone Tissue. The classical func-
tions of bone tissue, besides locomotion, include support and
protection of soft tissues, calcium, and phosphate storage and
harboring of bone marrow. Additionally, recent studies have
focused on the bone endocrine functions which are able to
affect other organs [202]. For instance, osteocalcin produced
by osteoblasts has been shown to act in other organs [203].
Osteocalcin can be found in twodifferent forms: carboxylated
and undercarboxylated. The carboxylated form has high
affinity to the hydroxyapatite crystals, remaining into bone
matrix during its mineralization. The undercarboxylated
form shows lower affinity to minerals, due to acidification of
bone matrix during osteoclast bone resorption, and then it is
ferried by the bloodstream, reaching other organs [204, 205].
It has been shown that the undercarboxylated osteocalcin
has some effects in pancreas, adipose tissue, testis, and the
nervous system. In the pancreas, osteocalcin acts as a positive
regulator of pancreatic insulin secretion and sensitivity as
well as for the proliferation of pancreatic 𝛽-cells [110]. In
the adipose tissue, osteocalcin stimulates adiponectin gene
expression that in turn enhances insulin sensitivity [204]. In
the testis, osteocalcin can bind to a specific receptor in Leydig
cells and enhances testosterone synthesis and, consequently,
increases fertility [206]. Osteocalcin also stimulates the syn-
thesis of monoamine neurotransmitters in the hippocampus
and inhibits gamma-aminobutyric acid (GABA) synthesis,
improving learning and memory skills [207].

Another endocrine function of bone tissue is promoted
by osteocytes. These cells are able to regulate phosphate
metabolism by the production of FGF23, which acts on other
organs including parathyroid gland and kidneys to reduce the
circulating levels of phosphates [208, 209]. Osteocytes also
act on the immune system by modifying the microenviron-
ment in primary lymphoid organs and thereby influencing
lymphopoiesis [210]. Not only osteocyte but also osteoblast
and osteoclast activities are known to influence the immune
system,mainly upon bone inflammatory destruction. Indeed,
the discovery of communication interplay between skeletal
and immune systems led to a new field of study called
osteoimmunology [211].

3. Conclusions

The knowledge of the structural, molecular, and functional
biology of bone is essential for the better comprehension of
this tissue as a multicellular unit and a dynamic structure
that can also act as an endocrine tissue, a function still poorly
understood. In vitro and in vivo studies have demonstrated
that bone cells respond to different factors and molecules,
contributing to the better understanding of bone cells plastic-
ity. Additionally, bone matrix integrins-dependent bone cells
interactions are essential for bone formation and resorption.
Studies have addressed the importance of the lacunocanalic-
ular system and the pericellular fluid, by which osteocytes act
as mechanosensors, for the adaptation of bone to mechanical
forces. Hormones, cytokines, and factors that regulate bone
cells activity, such as sclerostin, ephrinB2, and semaphoring,
have played a significant role in the bone histophysiology
under normal and pathological conditions.Thus, such deeper



BioMed Research International 11

understanding of the dynamic nature of bone tissue will
certainly help tomanage new therapeutic approaches to bone
diseases.

Conflict of Interests

The authors declare that there is no conflict of interests
regarding the publication of this paper.

Acknowledgments

This research was supported by Fundação de Amparo à
Pesquisa do Estado de São Paulo (FAPESP-2010/10391-9;
2012/19428-8, and 2012/22666-8), Conselho Nacional de
Desenvolvimento Cient́ıfico e Tecnológico (CNPq), and
Coordenação de Aperfeiçoamento de Pessoal de Nı́vel Supe-
rior (CAPES), Brazil.

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