Introduction
Wounds are generated by injuries such as mechanical trauma, burn, surgical procedures, etc. In general, wounds can be restored to a normal structure and function through the wound healing process, the normal physiological response to injury [3]. This process involves a series of cellular and biochemical events, and is divided into inflammation, proliferation and remodeling phases [8, 22]. These stages are accomplished by complicated and overlapping actions of numerous cells, growth factors and cytokines, which accelerate the wound healing process [9, 23]. However, additional treatments (e.g., wound dressing and medicines) are necessary to facilitate regeneration and prevent inflammation in the presence of severe or extensive wounds. Thus development of materials that facilitate wound healing by stimulating those cells and factors is important.
Plants have long been used for wound healing [17, 28, 30], and active components have been identified by in vitro and in vivo studies. Medicinal plants also exert effects on inflammation, collagenation, epithelialization and antioxidant activity. In addition, they influence production of extracellular matrix (ECM), cell proliferation, antioxidant activity and production of wound healingrelated factors [1]. As a representative plant-based commercialized medicine, Madecassol®, which contains extract of Centella asiatica, has been widely used for promoting wound repair [32]. It has significant wound healing activity by promoting fibroblast proliferation and collagen synthesis [21]. It also inhibits proliferative activity related to formation of keloid and hypertrophic scars, which are abnormal healing responses to cutaneous injuries caused by hyper-proliferation of dense fibrous tissue, excessive fibrosis, and decomposition of extracellular matrix [11, 29, 35]. Research into plant substances for wound healing is ongoing.
Rice is a cereal grain that provides the daily calories consumed by more than half of the world’s population. It contains substantial bioactive compounds such as sterols, waxes, and organic acids including fatty acids, amino acids, etc. [34]. These compounds have been reported to reduce the risk of several chronic diseases, such as cancer, cardiovascular disease, diabetes, and obesity [27]. In particular, phenolic compounds in rice have marked antioxidant activities. Moreover, rice reduces the risk of oxidative damage, which facilitates wound healing [10]. An ongoing inflammatory cascade results in increased tissue destruction and necrosis rather than healing, so compounds with antioxidant properties will be useful not only against oxidative damage but also contribute to wound healing [2]. Thus, rice may have potential as a wound-healing agent. In addition, the main advantage of this is that a large amount of rice callus can be produced from a few seeds within a short time starting from callus induction [7, 16]. Discovery and commercialization of drugs from natural compounds has been limited by building up and maintaining a high-quality product but seasonal or environmental variations in production such as production area, source, and limited harvest time cause problems [18].
No study of rice treatment for wound healing is extant. The present study, therefore, aimed to evaluate the wound-healing properties of hot water and ethanolic extraction of rice callus cells (Oryza sativa L.) using an in vitro assay. We carried out cytotoxicity and cell migration assays to evaluate the wound healing potential of RCEs using two human skin cell types (dermal fibroblasts and keratinocytes). In addition, the effects of RCEs on collagen type I mRNA and protein levels in human dermal fibroblasts were investigated.
Materials and Methods
Rice cell culture
Oryza sativa L. was provided by the Rural Development Administration (Korea) and used for generation of callus. The rice callus was suspended in N6 medium comprising 2 mg/l of 2,4-dichlorophenoxyacetic acid, 30 g/l of sucrose, 0.02 mg/l of kinetin, 300 mg/l of casamino acids, 500 mg/l of proline, 500 mg/l of glutamine, 500 mg/l of 2-(N-morpholino) ethanesulfonic acid and 10 mg/l of myo-inositol. Medium pH was adjusted to 5.8 and autoclaved prior to use. The suspension cells were cultured at 120 rpm and 28℃ in a shaking incubator and the culture medium was replaced with fresh medium every 10 days. Rice cells were harvested using Whatman No. 1 filter paper. The filtered cells were washed three times with phosphate-buffered saline (PBS; pH 7.4) and then stored in a deep freezer at -80℃ until used for extraction.
Preparation of rice cell extracts
For pressurized hot water extraction of rice cells (PHWE-RC), 100 g of freeze-dried rice cells were added to a 1 L Pyrex glass bottle containing 0.3 L of distilled water. The bottle was tightly closed with a stopper and heated in an autoclave at 125℃ and 1.5 bar for 30 min. Then, the extracted mixture was filtered through Whatman No.1 filter paper and the filtrate was freeze-dried and stored at -20℃ until use. For ethanolic extraction of rice cells (E-RC), freeze-dried calli were added to a 0.25 L glass bottle containing 0.15 L of ethanol (99%) and incubated in a water bath at 60℃ for 4 h. The extracted mixture was separated by filtration and the filtrate was evaporated at 45℃ in a rotatory evaporator (N-1001SW, Rikakikai Co., Ltd., Japan) (Fig. 1).
Fig. 1.The procedure for extraction from rice cells.
Determination of total phenolic and flavonoid contents
Total phenolic contents of two rice extracts were analyzed using the Folin-Ciocalteu method [23]. Briefly, each extract sample (100 μg) was resolved in 1 ml distilled water. Then, 0.2 ml of the sample solution was mixed with 5.6 ml of distilled water and 0.2 ml of 50% Folin-Ciocalteu reagent and reacted for 3 min at room temperature. Then, after 4 ml of 2% Na2CO3 was added in the solution, it was incubated for 1 h at 37℃. Absorbance of the sample was determined at 725 nm using a microplate reader (BioTek Inc., USA). Gallic was used as a standard.
The total flavonoid contents of two rice extracts were determined according to the previous report [31]. Briefly, after 200 μl of 10-fold diluted extracts, 200 μl of 1 N NaOH, and 2 ml of diethyl glycol were mixed each other, the solution was incubated for 1 h at 37℃. Absorbance of the sample was determined at 510 nm. Quercetin was chosen as a standard.
Human dermal fibroblast and keratinocyte cultures
Human primary dermal fibroblasts (PCS-201-012, American Type Culture Collection, USA) and the spontaneously immortalized Human adult low Calcium high Temperature (HaCaT) cells, established by Professor N.E. Fusenig (German Cancer Research Center, Germany) [4], were used for in vitro studies. Dermal fibroblasts and HaCaT cells were cultured in high-glucose Dulbecco’s Modified Eagle’s Medium (DMEM; Invitrogen, USA) supplemented with a fibroblast growth kit (PCS-201-041, ATCC) and 1% penicillin-streptomycin (P/S; Hyclone, USA) and in high-glucose DMEM supplemented with a keratinocyte growth kit (PCS-200-040, ATCC) and 1% P/S at 37℃ in a 5% CO2 incubator, respectively. The cell lines were seeded at 5 × 105 and 1 × 106 cells in a T-175 flask (SPL Life Sciences, Korea), respectively, and then grown to 80−90% confluence. Dermal fibroblasts at passages 6−7 and HaCaT cells at passages 4−5 were used in the experiments.
Cytotoxicity test of rice cell extract
The effect of 25−100 μg/ml RCE on dermal fibroblast and HaCaT cell viability was evaluated by WST-1 assay. Fibroblasts and HaCaT cells were seeded at 3 × 103 and 1 × 104 /well in 96-well plates, respectively. Both cell lines were maintained in DMEM (Hyclone) supplemented with 10% fetal bovine serum (FBS; Hyclone) at 37℃ in a 5% CO2 incubator for 24 h. The cells were then treated with 10% v/v WST-1 reagent (LPS Solution, Korea) and incubated at 37℃ in a 5% CO2 incubator for 2 h. The absorbance at 450 nm of the samples was determined using a microplate reader (BioTek Inc.).
Scratch migration assay
Dermal fibroblasts and HaCaT cells were seeded at 2 × 104 and 4 × 104 per well in six-well plates, respectively. The cells were allowed to form a confluent monolayer at 37℃ in a 5% CO2 incubator. Cells were then changed to serum-free medium for 24 h. Subsequently, vertical wounds were created using a sterile pipette tip. The cells were extensively rinsed with PBS to remove cellular debris prior to treatment with E-RC and PHWE-RC at 25−100 μg/ml. As positive and negative controls, 10% FBS (Hyclone) and non-treated cells were used, respectively. After 24 and 48 h, images of migrated cells were obtained using a digital camera (TCC-5.01CE, Tucsen Imaging Technology, China) connected to an inverted microscope (Eclipse E600, Nikon Corp., Japan) to observe wound closure.
Quantification of collagen type I mRNA by RT-PCR
Dermal fibroblasts were seeded at 2 × 104 cells per well in six-well plates. The cells were changed to serum-free medium for 24 h. The culture medium was replaced with fresh serum-free medium containing PHWE-RC or E-RC at 25−100 μg/ml, and then incubated at 37℃ in a 5% CO2 incubator for 24 h. Cells were harvested and the total RNA was extracted using the Easy-spinTM [DNA free] Total RNA Extraction Kit (iNtRON Biotechnology, Korea) according to the manufacturer’s protocols. Extracted RNAs were diluted in 20 μl of elution buffer. The quantity and purity of RNAs were determined using an ND-1000 spectrophotometer (NanoDrop Technologies, USA). cDNA synthesis was performed from 1 μg of pure total RNA using Reverse Transcription Master Premix (iNtRON Biotechnology). Amplification was performed under the following conditions: pre-denaturation at 94℃ for 5 min; 25 cycles of denaturation at 94℃ for 30 s, annealing at 60℃ for 30 s, extension at 72℃ for 30 s, and a final extension at 72℃ for 10 min. PCR products were visualized by electrophoresis in a 1.5% (w/v) agarose gel. Primer sequences were as follows: COL1A2 (forward: 5'-ACC TGG TCA AAC TGG TCC TG-3', reverse: 5'-CGT CCT CTC TCA CCA GGA AG-3' and GAPDH (forward: 5'-TGA AGG TCG GTG TGA ACG-3', anti-sense: 5'-TGA TGG CAA CAA TGT CCA C-3'). The amounts of PCR products were normalized to that of the housekeeping gene, GAPDH, to determine the relative expression ratios of each mRNA in relation to the control. Media without RCEs and containing 500 μM vitamin C were used as negative and positive controls, respectively. mRNA was quantified in triplicate independently.
Measurement of collagen type I in human dermal fibroblasts by ELISA
Collagen type I protein was quantified using an enzyme-linked immunosorbent assay (ELISA) kit (Human Pro-collagen I a1 DY6220-05, R&D Systems, USA) according to the manufacturer’s instructions. Briefly, human dermal fibroblasts (5 × 103 /well) were grown to confluence in 24-well tissue culture plates. Cells were switched to serum-free medium for 24 h. The serum-free medium was then replaced with that containing 25–100 μg/ml of PHWE-RC or E-RC. Media without RCEs and containing 500 μM vitamin C were used as negative and positive controls, respectively. After 24 h of treatment, culture supernatant was collected and stored at -80℃ until use. The assay was performed in three independent experiments.
Statistical analysis
The Student’s t-test or one-way ANOVA followed by Dunnett’s test was used for comparison of multiple means with the SigmaPlot 12.0 software (Systat Software, USA). A p-value of 0.05 represents a significant difference between groups.
Results and Discussion
In this study, rice cells were extracted by pressurized hot water and ethanolic extraction methods. Several methods can be available for extraction of natural compounds. Among them, we used the above methods because they are able to extract roughly active constituents by polarity [12]. In addition, these tests are suitable for studies of human wound healing. Although other solvents such as acetone, methanol, and chloroform can also be used, residues may affect the results [20].
Total polyphenol and flavonoid contents of rice cell extracts were evaluated. As shown in Table 1, total polyphenol contents of PHWE-RC and E-RC were 50.8 mg/g and 132.3 mg/g, respectively. Total flavonoid contents of E-RC (65.9 mg/g) were also higher than that of PHWE-RC (37.9 mg/g). Ethanolic extraction was more effective method due to polarity of the compounds and the result was corresponded to previous report [31]. The result indicated rice cell extracts contained comparable level of those compounds to other plant extracts [25]. It has been well studied that phenolic compounds showed immune and inflammatory cell function as well as antioxidant activity [24]. Thus, we expect that existence of the compounds in rice extracts could contribute to promoting wound healing by treatment of rice extracts.
Table 1.Total polyphenol and flavonoid content of two rice extracts.
As a preliminary experiment, we evaluated the cytotoxicity of 25−100 μg/ml of both RCEs against dermal fibroblasts and HaCaT cells by WST-1 assay. As shown in Fig. 2A and B, treatment of both RCEs did not result in significant cytotoxicity compared with the non-treated control. Furthermore, both RCEs promoted growth of both cell lines in a dose-dependent manner. Treatment with 100 μg/ml RCEs increased the proliferation of both cell types by 25% compared with the control.
Fig. 2.Cytotoxic effects of RCE on the viability of human dermal fibroblasts (A) and HaCaT cells (B). The cells were treated in DMEM serum-free medium with 25, 50, 75 and 100 μg/ml RCE for 24 h. Results are expressed as percentage viability compared to non-treated controls.
We quantified fibroblast and HaCaT cell migration using an in vitro scratch wound assay at 24 and 48 h post-wounding. Both RCEs at 25−100 μg/ml were applied to wounded monolayer cultures of both cell types. As shown in Fig. 3B, significant migration of dermal fibroblast cells into the scratch wound area was observed in the presence of both RCEs. The cell migration was proportional to the RCE concentration. In particular, E-RC treatment resulted in 130−350% greater cell migration compared with the control (p < 0.001). Notably, the effect of 25 μg/ml E-RC was comparable to that of 100 μg/ml PHWE-RC. Similar results were obtained using HaCaT cells (Fig. 3C). Treatment with E-RC prompted significant migration of HaCaT cells in a dosedependent manner (p < 0.001). Superior migratory abilities of HaCaT cell migration was accelerated 70−250% by E-RC compared with PHWE-RC. Healing involves complex processes, but re-epithelialization by proliferation and migration of these cells is essential [5, 19], because those cells migrate into wound area to cover damaged tissue surface as well as to promote secretion of various factors involved in wound healing such as growth factors, cytokines, and extracellular matrix [33]. Therefore, cell-to-cell signaling by growth factors and cytokines occurs in the wound area. Thus, these results indicate that E-RC actively recruited cells adjacent to the wound and accelerated cell proliferation.
Fig. 3.Effect of the RCEs on scratch wound closure in fibroblast and HaCaT cell layers. Phase contrast micrographs of dermal fibroblasts and HaCaT cells taken at 0, 24 and 48 h after treatment with various concentration and type of RCEs. Scale bar 200 μm, ×40 (A). For quantifications, the area covered by dermal fibroblasts (B) and HaCaT cells (C) after incubation for 24 and 48 h was measured using ImageJ and normalized to control cells. The effect of REC was statistically significant in comparison to the control sample, as evaluated by the Student's t-test; *p < 0.05, **p < 0.01, **p < 0.001. The error bars indicate S.D. (n= 3).
The effects of the RCEs on collagen type I in dermal fibroblasts were examined compared with that of 500 μM vitamin C, which induces collagen production, as a positive control [26]. Indeed, wound dressings containing vitamin C enhance release of growth factors involved in wound healing. Collagens play a critical role in wound healing by activating integrins, which initiate signaling cascades that produce matrix metalloproteinases (MMPs) [6, 14, 15]. The enzymes degrade the collagen matrix and facilitate keratinocyte migration to the wound area. This results in rapid re-epithelialization and accelerated wound healing. As shown in Fig. 4(A), treatment with >50 μg/ml PHWE-RCs significantly increased collagen type I mRNA levels (p <0.05); however, this increase was less than that induced by vitamin C. In contrast to PHWE-RC, E-RC treatment enhanced mRNA levels in a dose-dependent manner. In addition treatment with >75 μg/ml E-RC had an effect comparable to that of 500 μM vitamin C.
Fig. 4.Effect of the RCEs on collagen type I mRNA (A) and protein (B) levels in human dermal fibroblasts. (A) mRNA levels were determined by RT-PCR at 24 h after treatment with various concentrations of RCEs. Upper panel, representative RT-PCR analysis. Lower panel, quantification of collagen type I mRNA expression. (B) Production of collagen type I was evaluated by ELISA of fibroblast culture supernatant at treatment after 24 h (*p < 0.05, **p < 0.01 vs. the non-treated group). Each value and error bar represent the mean of triplicate samples and its S.D.
We also quantified collagen type 1 protein levels following treatment with 25−100 μg/ml RCEs. Dermal fibroblast cultures were collected at 24 h after the treatments. As shown in Fig. 4(B), both RCEs significantly promoted collagen production in a dose-dependent manner. PHWE-RC enhanced production of collagen type I by up to 47% compared with the non-treated control, but the magnitude of the increase was less than that of vitamin C, even at 100 mg/ml (p < 0.05). In contrast, E-RC at 25 μg/ml stimulated production of collagen type I by 1.8-fold compared to the non-treated control (p < 0.01), comparable to the effect of vitamin C. E-RC at 100 μg/ml resulted in a 2.2-fold increase in collagen production. Therefore, both RCEs promoted collagen type 1 synthesis in human dermal fibroblasts. The effect of E-RC on collagen production was greater than that of PHWE-RC. As mentioned above, collagen type I gives not only ECM for cell migration and adhesion but also strength of tissues. This stimulation by RCEs might contribute to wound healing.
This study is first report on the wound healing property of RCEs in vitro. PHWE-RC and E-RC exhibited no cytotoxicity to human dermal cells. In addition, both RCEs promoted the proliferation of human fibroblasts and keratinocytes. They increased collagen type I mRNA and protein levels, and thus may play a critical role in the wound healing process. However, further studies such as identification and separation of effective materials in RCEs should be performed. In addition, efficacy should be evaluated in an animal study. These preliminary data suggest RCEs to be potential wound healing materials.
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