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Application of Hypoxic Exposure Combined with Osteogenic Induction for the Enhancement of Multiple Osteoinductive Capabilities in Rat Mesenchymal Cells

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DOI: 10.4236/ojst.2018.82005    303 Downloads   551 Views  

ABSTRACT

Objective: The enhancement of multiple functions, including osteogenesis, angiogenesis, and cell recruitment, is required for efficient bone regeneration therapy. Recently, special attention has been focused on the microenvironment of stem cells to facilitate bone regeneration. Herein, we examined the effects of various combinations of hypoxic conditions and osteogenic induction on rat mesenchymal cells, to develop a specific protocol for enhancing the multiple cellular functions beneficial to bone regeneration. Methods: Rat mesenchymal cells, isolated from bone marrow, adipose tissue, and periodontal ligament, were examined. The cells were cultured under varied conditions of O2 tension (hypoxia) and duration and timing of hypoxic exposure, with or without osteogenic induction. Consequently, four different protocols were examined by measuring the gene expression levels of Runx2, Vegfa, and Cxcl12, indicating a capability for osteogenesis, angiogenesis, and cell recruitment, respectively. Finally, the mineralization ability of the rat mesenchymal cells was assessed by quantitating their calcified nodule formation. Results: The simultaneous application of hypoxic exposure and osteogenic induction promoted Vegfa expression in all types of cells, but suppressed Runx2. In contrast, hypoxic preconditioning, followed by osteogenic induction, did not increase the expression of these genes; in fact, Vegfa expression decreased significantly. Among the various protocols, 0.5% O2 exposure for 12 h after osteogenic induction exhibited the largest fold changes of gene expression level, especially of Vegfa. Hypoxic post-conditioning enhanced the formation of calcified nodules in periodontal ligament-derived cells. Conclusion: Short-term hypoxic exposure after osteogenic induction could be used to improve the efficiency of mesenchymal cells for bone regeneration.

1. Introduction

Mastication, speech, and facial aesthetics are often severely compromised by jaw bone defects caused by trauma, inflammatory disease, and benign or malignant tumors in the oral and maxillofacial region. Therefore, recovery of the structural and functional features of the jaw is an extremely important task of maxillofacial surgeons [1] [2] . Currently, although autogenous bone grafting is a standard treatment for jaw bone reconstruction, it may cause donor site morbidity, post-operative complications, healing failure, and insufficient bone volume [2] [3] [4] . For overcoming these problems, tissue engineering technology has a lot of potential, providing an alternative treatment option for autogenous bone grafting in jaw bone reconstruction and bone regeneration therapy [5] [6] [7] .

The original principle of bone regeneration therapy was that the transplanted cells could facilitate osteogenesis in host tissues by themselves [8] . However, it has been reconsidered that manipulation of the host tissue environment by a multifaceted approach, such as induction of osteogenic cells, promotion of angiogenesis, and supplementation of growth factors, is also important to promote the survival of transplanted cells and reduce the period of new-bone formation [9] . As a strategy to provide those functions to mesenchymal stem cells (MSCs), stem cell preconditioning in vitro prior to cell transplantation has been studied [10] [11] . For example, heat-shock preconditioning increases the cell survival rate, and tumor necrosis factor-alpha preconditioning enhances the osteogenic differentiation ability of adipose-derived stem cells [12] [13] . Furthermore, hypoxic preconditioning of bone marrow-derived MSCs promotes angiogenesis or neurogenesis in damaged heart and brain tissues [14] [15] . Although hypoxic preconditioning is considered to be beneficial to MSCs to enhance their angiogenic activity and cell induction ability, it is still controversial for bone regeneration therapy because some reports have demonstrated that osteogenic differentiation was accelerated under hypoxia, whereas many others stated that the process was suppressed [16] - [22] .

As a MSC source, the osteogenic potential is considered to be the most dominant in bone marrow-derived cells (BMDCs) [23] [24] . In comparison, adipose tissue-derived cells (ATDCs) are known to possess weak osteogenic ability, but their advantage is that a relatively large amount of tissue can be harvested with minimal invasiveness [25] . On the other hand, periodontal ligament-derived cells (PDLDCs) have an ability to form new bone comparable to that of BMDCs [26] . In the craniofacial and maxillofacial regions, there are many tissue sources of MSCs other than bone marrow [27] . Thus, there is a need to characterize cellular responses under hypoxic conditions according to the mesenchymal cells derived from different tissue sources. In this study, we examined the effects of various combinational uses of hypoxic conditions and osteogenic induction on rat mesenchymal cells in order to develop a specific protocol for enhancing the multiple cellular functions beneficial to bone regeneration.

2. Materials and Methods

2.1. Rat Bone Marrow-Derived Cells: Isolation and Primary Culture

Four-week-old male Fisher rats (Charles River Laboratories Japan, Yokohama, Japan) were sacrificed by cervical dislocation under deep anesthesia induced through the intraperitoneal administration of 4% chloral hydrate. The femur was aseptically removed and the adherent soft tissue was thoroughly debrided. After the epiphyses were removed, a 21-gauge needle attached to a 10-mL syringe was used to bore a small opening through the growth plate on the distal end of the femur. A 10-mL syringe fitted with a fresh 21-gauge needle was filled with alpha-minimal essential medium (α-MEM; Thermo Fisher Scientific, Waltham, MA, USA) supplemented with 10% fetal bovine serum (FBS; Thermo Fisher Scientific) and 1% antibiotics-antimycotics (Thermo Fisher Scientific). The needle was inserted into the previously prepared opening, and a small volume of medium was ejected to expel the bone marrow from the medullary canal. The cells were seeded into T-150 cell culture flasks (Corning Inc., Corning, NY, USA). Culture vessels were placed in a 37˚C humidified incubator under ambient oxygen with 5% CO2. The first medium exchange was conducted 24 h later, for the removal of blood cell components. Adherent cells were used as BMDCs.

2.2. Rat Adipose Tissue-Derived Cells: Isolation and Primary Culture

Subcutaneous adipose tissue was collected from the back of 4-week-old male Fisher rats and then minced with scissors and treated with 1% collagenase (Wako Pure Chemical Industries, Osaka, Japan) solution for 1 h at 37˚C. Following the incubation, the collagenase was neutralized with an equal volume of α-MEM supplemented with 10% FBS and 1% antibiotics-antimycotics. The samples were filtered through a 100-μm cell strainer (Corning) and centrifuged at 1300 rpm for 5 min. The cells were then seeded into T-75 cell culture flasks (Corning).

2.3. Rat Periodontal Ligament-Derived Cells: Isolation and Primary Culture

Upper and lower molars were extracted from 4-week-old male Fisher rats and the gum tissue was removed from each tooth under a magnifying glass. The molars were then placed on 100-mm cell culture dishes (Corning), to which 8 mL of α-MEM supplemented with 10% FBS and 1% antibiotics-antimycotics was added. Once the cell outgrowth80% confluent, the cells were subcultured in T-25 cell culture flasks.

These BMDCs, ATDCs from passages 2 to 3, and PDLDCs from passages 4 to 6, at an estimated confluency of 80%, were used in the study.

2.4. Flow Cytometry

The MSC profiles of the BMDCs, ATDCs, and PDLDCs were determined through study of their expression of specific cell-surface markers by flow cytometry. After 3.0 × 103 of cells had been rinsed with 1% bovine serum albumin in phosphate-buffered saline, they were incubated with the primary antibody at room temperature for 30 min. The following fluorescein isothiocyanate (FITC)-conjugated antibodies against rat were used: anti-mouse/rat CD29 FITC (1:100), anti-mouse/ rat CD90.1 FITC (1:100), and anti-rat CD45 FITC (1:200) (eBioscience, San Diego, CA, USA). Flow cytometry analysis was performed using a FACS Aria II (BD Bioscience, San Jose, CA, USA).

2.5. Hypoxic Exposure

The various tissue-derived cells were cultured in air-tight modular incubator chambers (Billups-Rothenberg, Del Mar, CA, USA). Humidity was supplied by placing an open tissue culture dish containing 10 mL of sterile distilled water at the bottom of each chamber. Gas mixtures, consisting of 0.5%, 2%, or 5% oxygen, were flushed into the chambers for 2 min to purge the ambient air. The chambers were then placed into an incubator at 37˚C. Cells were fed with the α-MEM (0.2 ml/cm2) every other day. Prior to feeding under hypoxic conditions, the fresh complete medium was equilibrated under three different O2 tensions for at least 48 h. For normoxic cell culture, culture vessels were placed in a 37˚C humidified incubator under ambient oxygen with 5% CO2.

2.6. Induction of Osteogenic Differentiation

For osteogenic differentiation, the cells were cultured in a standard osteogenic induction medium supplemented with 100 nM dexamethasone (Sigma-Aldrich, St. Louis, MO, USA), 10 mM beta-glycerophosphate (Wako Pure Chemical Industries), and 50 mM ascorbic acid (Sigma-Aldrich).

2.7. Protocols of Hypoxic Exposure and Osteogenic Induction

To explore and narrow down the most effective conditions for the combinational use of hypoxic exposure and osteogenic induction, we examined four protocols (detailed in Sections 2.7.1 through 2.7.4) in which different O2 tensions and duration and timing of hypoxic exposure, with or without osteogenic induction, were applied.

The four protocols were examined in order of 1 through 4 every time by analyzing the rat gene expression levels of runt-related transcription factor 2 (Runx2; an essential transcription factor for osteoblast differentiation, and an osteogenic differentiation marker), vascular endothelial growth factor A (Vegfa; an angiogenesis marker), and C-X-C motif chemokine 12 (Cxcl12; a marker of cell recruitment), using the reverse transcription real-time polymerase chain reaction (RT-qPCR).

2.7.1. Protocol 1: Effects of Simultaneous Treatment of Osteogenic Induction and 2% O2 Exposure

Cells were cultured for 96 h under normoxic (21% O2) (Figure 1(A)-a) or hypoxic (2% O2) (Figure 1(A)-b) conditions without osteogenic induction, or under hypoxia with simultaneous treatment of osteogenic induction (Figure 1(A)-c).

Figure 1. Different protocols tested in this study to optimize the combinational use of hypoxic exposure and osteogenic induction for enhancing the multiple osteoinductive capabilities of mesenchymal cells. (A) Protocol 1: Simultaneous application of hypoxic exposure and osteogenic induction; (B) Protocol 2: Hypoxic preconditioning followed by osteogenic induction; (C) Protocol 3: Short-time hypoxic exposure under different oxygen tensions; (D) Protocol 4: Hypoxic (post-) conditioning after osteogenic induction; (E) The cell culture protocol for Alizarin Red S staining.

2.7.2. Protocol 2: Effects of Hypoxic Preconditioning

For the hypoxic preconditioning tests, cells were first cultured under hypoxia (2% O2) (Figure 1(B)-c) without osteogenic induction for 72 h and then subjected to osteogenic induction under normoxia for 96 h. As a control, cells were cultured under normoxia (Figure 1(B)-b) instead of hypoxia. As a baseline control, cells were cultured under normoxia (Figure 1(B)-a) for a total of 168 h.

2.7.3. Protocol 3: Effects of Different Low O2 Tension Levels within 24 h

Cells were cultured at different low O2 tensions of 0.5% (Figure 1(C)-a-c), 2% (Figure 1(C)-d-f), or 5% (Figure 1(C)-g-i), for 6 h (Figure 1(C)-a, Figure 1(C)-d, and Figure 1(C)-g), 12 h (Figure 1(C)-b, Figure 1(C)-e, and Figure 1(C)-h), and 24 h (Figure 1(C)-c, Figure 1(C)-f, and Figure 1(C)-i).

2.7.4. Protocol 4: Effects of Hypoxic Post-Conditioning

After cells were cultured with (Figure 1(D)-b and Figure 1(D)-c) or without (Figure 1(D)-a) osteogenic induction for 7 days under 21% O2, they were subsequently cultured under either hypoxic (0.5% O2) (Figure 1(D)-c) or normoxic (21% O2) (Figure 1(D)-a and Figure 1(D)-b) conditions for 12 h.

2.8. Reverse Transcription Real-Time PCR

Total RNA was extracted from the cells using an RNeasy mini kit (Qiagen, Valencia, CA, USA), with DNase I treatment (Qiagen). RT-qPCRs were carried out using the TaqMan Fast Virus 1-Step Master Mix (Thermo Fisher Scientific) and TaqMan gene expression assays (Thermo Fisher Scientific) in the ABI PRISM 7000 sequence detection system (Thermo Fisher Scientific). The PCR cycle conditions were reverse transcription at 50˚C for 5 min, reverse transcription inactivation/initial denaturation at 95˚C for 1 min, amplification at 95˚C for 15 s, and 40 cycles of amplification at 60˚C for 1 min. In this study, expression of the following genes was measured: Runx2 (Rn01512298_m1; Thermo Fisher Scientific), Vegfa (Rn01512298_m1; Thermo Fisher Scientific), and Cxcl12 (Rn00573260_m1; Thermo Fisher Scientific). The expression level of the target gene, normalized to that of the TATA-box binding protein gene (Tbp: Rn01455648_m1; Thermo Fisher Scientific), was then calculated using the dCT method.

2.9. Alizarin Red S Staining

In order to examine the efficacy of Protocol 4 in enhancing the subsequent osteogenic potential of the mesenchymal cells, osteogenic induction was conducted for another 14 days under normoxia, and calcified nodule formation by the cells was evaluated by Alizarin Red S staining (Figure 1(E)). After being washed with phosphate-buffered saline, the cells were fixed at room temperature with 100% ethanol for 10 min, washed with distilled water, and then stained with 1% Alizarin Red S solution (Wako Pure Chemical Industries) for 2 min. After excess stain solution had been removed with distilled water, the stained area was measured using Image J software (Version 1.4.5I-j; National Institutes of Health, Bethesda, USA; http://rsb.info.nih.gov/ij/).

2.10. Statistical Analysis

Data are expressed as the mean ± standard deviation. Statistical analyses were performed using IBM SPSS Statistics 21 (IBM Japan, Tokyo, Japan). Differences among groups were assessed by one-way analysis of variance, followed by Tukey’s honest significant difference test. Statistics in the two groups were compared by applying Student’s t-test. A p-value of less than 0.05 was considered statistically significant.

3. Results

3.1. Flow Cytometric Analysis

Cells positive for CD29 and CD90, both rat MSC markers [28] , numbered 90% or greater in the BMDCs, ATDCs, and PDLDCs (Figure 2(A) and Figure 2(B)), suggesting that the cells used in the experiments had stem cell characteristics. On the other hand, cells positive for CD45, a negative hematopoietic marker, were present only at 1.5% and 0.6% in the ATDCs and PDLDCs, respectively, in contrast to 27.3% in the BMDCs, implying that blood cells had remained in the BMDC culture even after subculture (Figure 2(C)).

3.2. Expression of Runx2, Vegfa, and Cxcl12 under the Combinational Use of Hypoxic Exposure and Osteogenic Induction

We first examined the effects of simultaneous treatment with hypoxic exposure and osteogenic induction, according to Protocol 1 (Figure 3). Compared with the normoxic control, the simultaneous treatment did not show any increase in Runx2 expression in all three types of cells; in fact, the gene expression level under simultaneous treatment was significantly lower than that under hypoxic exposure alone in the ATDCs. The expression of Vegfa was significantly upregulated in the BMDCs and ATDCs under hypoxic exposure alone, but was remarkably downregulated by the simultaneous treatment. In contrast, in the PDLDCs, both treatments significantly increased Vegfa expression relative to that of the normoxic control. The Cxcl2 expression level was significantly dampened in the BMDCs and ATDCs under the hypoxic condition, but it remained unchanged in the PDLDCs. The results indicate that Protocol 1 has an inhibitory effect on bone regenerative activity in BMDCs and ATDCs.

Next, we tested how hypoxic preconditioning according to Protocol 2 affects gene expression (Figure 4). This second protocol did not produce any significant increase in the expression of Runx2 and Cxcl12 mRNAs in all three types of cells. Moreover, it significantly decreased the expression of Vegfa, indicating that hypoxic preconditioning had no effect to enhance multiple functions when subsequent normoxic culture was applied.

(a) (b) (C)

Figure 2. Flow cytometric analysis showing the immunopositive rates of CD29, CD90, and CD45 of the mesenchymal cells. Representative histograms of rat bone marrow-derived cells (BMDCs), adipose tissue-derived cells (ATDCs), and periodontal ligament-derived cells (PDLDCs).

Since the previous two protocols did not significantly enhance Runx2 expression (an osteogenic differentiation marker), we then simply assessed the effect of hypoxia by changing the O2 tension under exposures shorter than 24 h (Protocol 3). As expected, short hypoxic exposures did not decrease Runx2 expression under all O2 tension levels examined. In addition, Vegfa expression was significantly upregulated and reached a peak at under 0.5% O2 for 12 h in the BMDCs and ATDCs. However, there were only slight effects on the expression of Cxcl12 with Protocol 3 (Figure 5).

(A) (B) (C)

Figure 3. Average mRNA expression of Runx2 (A); Vegfa (B); and Cxcl12 (C) in rat bone marrow-derived cells (BMDCs), adipose tissue-derived cells (ATDCs), and periodontal ligament-derived cells (PDLDCs), under normoxia (A); hypoxia (2%) (B); and simultaneous treatment of hypoxic exposure and osteogenic induction (C) (n = 3; *p < 0.05).

(A) (B) (C)

Figure 4. Average mRNA expression of Runx2 (A); Vegfa (B); and Cxcl12 (C) in rat bone marrow-derived cells (BMDCs), adipose tissue-derived cells (ATDCs), and periodontal ligament-derived cells (PDLDCs), under normoxia (A); osteogenic induction (B); and hypoxic preconditioning followed by osteogenic induction (C) (n = 3; *p < 0.05).

Finally, we examined the effect of hypoxic conditioning (0.5% O2 for 12 h) after osteogenic induction, according to Protocol 4. Whereas the Runx2 and Cxcl12 expression levels did not show any significant changes between osteogenic induction treatments with and without hypoxic post-conditioning in the BMDCs and ATDCs, the Runx2 expression level in the PDLDCs was significantly increased (Figure 6). In contrast, the expression level of Vegfa in all three types of cells rose drastically following hypoxic post-conditioning. Protocol 4 provided the largest fold changes of gene expression, especially of Vegfa, among the four protocols examined.

3.3. Calcified Nodule Formation

Using Protocol 4, the formation of calcified nodules following osteogenic induction for 2 weeks was analyzed. In the BMDCs, regardless of hypoxic post-conditioning, the area positive for Alizarin Red was larger than 90% of a 6-well

(A)(B)(C)

Figure 5. Average mRNA expression of Runx2 (A); Vegfa (B); and Cxcl12 (C) in bone marrow-derived cells (BMDCs), adipose tissue-derived cells (ATDCs), and periodontal ligament-derived cells (PDLDCs), under different oxygen tensions for 6, 12, and 24 h (n = 3).

microplate well (Figure 7). In the ATDCs, however, the stained calcified area was less than 10%, both with and without hypoxic post-conditioning. The PDLDCs were the only cell type revealing an affect by hypoxic post-conditioning, where the area stained was seven times larger than that without the treatment.

4. Discussion

A During serial cell culture, the cell population that expresses phenotypic markers for MSCs is predisposed to decline in number, resulting in the lack of effective osteogenic differentiation [29] . The present study, showing that the majority of cells obtained from the three different rat tissues expressed CD29 and CD90, confirmed that these cell populations had maintained the phenotypes of MSCs after serial cell culture. Nonetheless, our examination also detected some cells

(A) (B) (C)

Figure 6. Average mRNA expression of Runx2 (A); Vegfa (B); and Cxcl12 (C) in bone marrow-derived cells (BMDCs), adipose tissue-derived cells (ATDCs), and periodontal ligament-derived cells (PDLDCs), under normoxia (A); osteogenic induction (B); and hypoxic (post-) conditioning after osteogenic induction (C) (n = 3; *p < 0.05).

positive for CD45 in the BMDCs only, likely due to the presence of blood cell components after a few cell passages. In the present study, unsorted cells, instead of cells sorted by specific cell-surface markers, were used for the analyses. Thus, they were not prepared of phenotypically distinctive MSC populations at the beginning, suggesting that cell sorting might not necessarily be required prior to analyses. Although flow cytometry enables sorting of multipotent MSCs from various tissues [30] [31] , it also has disadvantages in that it may cause cell damage, have a high contamination risk and cost, and reduce the number of cells retrieved [32] . Since a large number of cells can be obtained from bone marrow and adipose tissue, it is conceivable to differentiate cells without using a cell sorter in the clinical arena. Nevertheless, it is noted that contamination with cells other than MSCs may affect the efficiency of multiple osteoinductive capabilities.

In order to explore an efficient protocol for bone regeneration using a hypoxic environment, changes in cellular metabolism under hypoxia, which is a critical factor that influences responses for osteogenic differentiation, need to be considered. As an endogenous control, we used Tbp instead of glyceraldehyde 3-phosphate dehydrogenase (Gapdh), because previous reports have shown that the ribosomal protein L13A (Rpl13A), Tbp, and beta-2 microglobulin (B2m) genes, instead of the Gapdh and actin-beta (Actb) genes, need to be chosen for hypoxic cells [33] [34] . Others also showed that Tbp and Rpl13A are appropriate endogenous controls for studies on the induction of MSC differentiation, whereas ribosomal protein 18, Actb, and B2m genes are not [35] [36] . Those are consistent with our preliminary results (data not shown). Thus, the choice of inappropriate control genes that are susceptible to hypoxia might lead to discrepancies and contradictory results among studies.

This study showed that the simultaneous application of 2% O2 and osteogenic induction for 96 h did not enhance, but rather diminished, the expression levels of the three genes beneficial to rat bone regeneration, except for Vegfa expression in PDLDCs. This outcome is consistent with those of previous studies [18]

(A)(B)(C)

Figure 7. Formation of calcified nodules under Protocol 4 in bone marrow-derived cells (BMDCs) (A); adipose tissue-derived cells (ATDCs) (B); and periodontal ligament-derived cells (PDLDCs) (C); The left panels show a representative macroscopic view of the Alizarin Red S staining. The right panels show the percentage of area stained with Alizarin Red, measured using ImageJ software. Differences in the percentage of area stained were compared by applying Student’s t-test to the results for each mesenchymal stem cell type treated without (A) and with (B) hypoxic post-conditioning (n = 3; *p < 0.05).

[21] [22] . However, other investigations have demonstrated that the hypoxic condition promoted osteogenic differentiation [16] [20] . This discrepancy among the different reports is likely due to the different cell culture conditions used, such as cell origin and O2 tensions, as well as exposure time and cell density seeded, although further clarification of this is needed. In terms of the cell culture medium composition, one study in which cells were cultured in α-MEM containing 10% FBS (the same as our study) showed that hypoxia suppressed osteogenic differentiation [22] . However, other studies, in which cells were grown in Dulbecco’s modified Eagle’s medium, concluded that hypoxia promoted osteogenic differentiation [16] [20] . Thus, the type of cell culture medium may also be a factor that affects the cellular hypoxic response.

Moreover, not only did the simultaneous treatment application not significantly increase any gene expression levels, nor did the combinational use of osteogenic induction for 96 h with hypoxic preconditioning for 72 h. Contrary to Protocol 1, which showed a significant increase in Vegfa expression under the hypoxic environment alone, the expression was downregulated by hypoxic preconditioning. According to Wagner et al. [37] , 100 nM of dexamethasone inhibited the nuclear transfer of hypoxia-inducible factor, resulting in the inhibition of VEGF expression. The chemical hypoxia also suppressed VEGF expression during osteogenic induction [38] . Since dexamethasone may counteract the effect of the hypoxic preconditioning that enhances Vegfa expression, this seemed to result from the subsequent osteogenic induction under normoxia, although further study to verify this is mandated.

Rupture of the vasculature within wound beds by surgical interventions causes the O2 pressure in the wound to decrease [39] . The negative impacts of Protocols 1 and 2 on osteoinductive capability could be due to the 2% O2 tension used in those protocols, because the oxygen concentration in vivo that implies physiological “normoxia” ranges from 2% to 9% [40] [41] . As expected, the expression of Runx2 and Cxcl12 did not decrease significantly under 0.5% O2 (severe hypoxia) within 24 h. When we applied “hypoxic conditioning” after osteogenic induction under Protocol 4, the expression levels of the three different genes were restored compared with the levels under Protocol 2. In addition, the fold changes of expression level of the three genes were larger in Protocol 4 than in Protocol 1, although the expression patterns did not change significantly. Furthermore, under Protocol 4, the formation of calcified nodules was distinctly different among the three types of cells, suggesting there are differential responses to hypoxia and osteogenic induction, with varying levels, among MSCs of different tissue origins. This is consistent with a previous investigation that demonstrated the enhanced osteogenic capacity of PDLDCs by the paracrine effect of VEGF-A [42] .

This study clearly showed that hypoxic responses vary among cells that originated from different mesenchymal tissues. For instance, the intrinsic gene expression levels of Vegfa and Cxcl12 are higher in BMDCs than in ATDCs [43] [44] . Since the hypoxic responses of MSCs are likely to be tissue specific, the origin of the MSCs needs to be considered before their use as therapeutic agents.

5. Conclusion

In summary, the largest fold changes of expression level of the three genes pertaining to multiple osteoinductive capabilities were induced by Protocol 4 (0.5% O2 hypoxic post-conditioning with osteogenic induction), although the Vegfa and Cxcl12 expression levels were the most and least susceptible to this protocol, respectively. Since there were differential responses of the mineralized nodule formation among mesenchymal cells from different tissues, the optimal protocol developed should be specific to the origin of the mesenchymal cells. Although further in vivo studies on protein expression and cell behaviors are necessary, manipulating mesenchymal cells with hypoxic exposure after osteogenic induction before transplantation could have potential for improving their therapeutic efficiency in bone regeneration.

Ethical Approval

This experiment was approved by the Niigata University Animal Experimentation Ethics Committee (Approval No. 71-4), and performed according to the animal experiment rules of Niigata University.

Conflict of Interest

There is no conflict of interest.

Acknowledgements

The Authors would like to thank all the staff in the divisions of Oral Anatomy, Bio-prosthodontics, Biomimetics, and Oral Reconstructive Surgery at Niigata University Graduate School of Medical and Dental Sciences. This work was supported by a Grant-in-Aid for JSPS Fellows (15J01649).

Conflicts of Interest

The authors declare no conflicts of interest.

Cite this paper

Saito, N. , Kato, H. , Akiba, Y. , Hara, Y. , Kojima, T. , Yoshizawa, M. , Ohazama, A. , Maeda, T. , Kobayashi, T. and Izumi, K. (2018) Application of Hypoxic Exposure Combined with Osteogenic Induction for the Enhancement of Multiple Osteoinductive Capabilities in Rat Mesenchymal Cells. Open Journal of Stomatology, 8, 53-69. doi: 10.4236/ojst.2018.82005.

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