M.Tech. / Low level laser therapy, commonly known as LLLT or biomodulation, is a form of phototherapy which involves the application of low power monochromatic and coherent light to injuries and lesions to stimulate healing. In the medical field, lasers are classified as high power or surgical lasers and low level lasers which are used to stimulate cellular responses. Phototherapy has been successfully used for pain attenuation and induction of wound healing in non healing defects. Even though phototherapy has been found to be beneficial in a wide variety of therapeutic applications, it has been shown that phototherapy can induce DNA damage; however this damage appears to be repairable (Houreld and Abrahamse, 2008). DNA repair is vital to cells to avoid mutation. Literature reports show that red light or phototherapy up or down regulates genes involved in DNA repair (Zhang et al., 2003). N-methylpurine DNA glycosylase (MPG) is involved in DNA repair by catalysing the excision of a variety of modified bases. The exact mechanism by which phototherapy works is still poorly understood. Several authors have demonstrated that phototherapy enhances cell proliferation and migration. However, these cellular responses seem to confuse scientists as to whether wound healing is due to cell proliferation or migration or both. To determine the effect of phototherapy on cell proliferation or migration, a mini project was conducted (Zungu et al., 2008). Thus, cell proliferation was arrested using 5 mM hydroxyurea (HU) which is an antiproliferative drug. Wounded (W) human skin fibroblast cells (WS1, ATCC iii CRL 1502) were irradiated with 5 J/cm2 using a Helium-Neon (He-Ne) laser with a wavelength (λ) of 632.8 nm on day 1 and 4. Cell morphology, viability and proliferation were measured 24 h post irradiation. Reports indicate that several cell culture studies have used HU to control proliferation (Cai et al., 2000; Hamuro et al., 2002). Thereafter, the main study which was aimed at determining the effects of phototherapy on DNA damage and gene activation related to repair using 5 or 16 J/cm2 on W human skin fibroblast (WS1) cells was performed. Both studies involved growing WS1 cells aseptically in complete minimum essential medium (MEM) with Earle’s balanced salt solution and incubated at 37 °C in 5% CO2 and 85% humidity. Normal (N) and W cell cultures were irradiated with 5 or 16 J/cm2 30 min and 72 h (day 1 and 4) post wounding. Non irradiated cells (0 J/cm2) served as controls, while irradiated cells were the experimental groups. A wound was simulated by creating a central scratch across a monolayer of cells using a sterile 1 ml pipette. A 3 mW/cm2 He-Ne laser, λ 632.8 nm, was used to irradiate cells. After a repair time of 1 or 24 h on day 4, cell morphology (microscopy), cell viability (Trypan blue exclusion test and ATP luminescent assay), proliferation (XTT assay) and DNA integrity (alkaline comet assay with and without Formamidopyrimidine glycosylase [Fpg]) were assessed. The up or down regulation of the DNA repair gene, MPG, and regulation of three reference genes namely; beta Actin (ACTB), Glyceraldehyde 3 phosphate dehydrogenase (GPDH) and Ubiquitin c (UBC) were assessed by real time reverse transcriptase polymerase chain reaction (real time RT-PCR). iv Non irradiated HU treated cells had a reduced number of cells in the central scratch compared to non irradiated non treated cells, suggesting that HU inhibited cellular proliferation. Irradiated HU treated cells showed an increased number of cells in the central scratch compared to non irradiated treated cells. This observation proved that this increase was due to the stimulatory effect of irradiation with 5 J/cm2. The addition of HU had no significant effect on cell viability. The Trypan blue exclusion test showed no significant difference in percent viability between treated and non treated cells. Irradiated non treated cells showed a significant increase in the formazan dye, which is as a result of cleavage of XTT by the mitochondrial succinate dehydrogenase in actively proliferating cells, compared to non irradiated non treated cells (P=0.01). W cells, which were not irradiated, showed incomplete wound closure at both 1 and 24 h, while W cells irradiated with 5 J/cm2 showed complete wound closure. Similarly, W cells irradiated with 16 J/cm2 showed incomplete wound closure at 1 and 24 h. Cell viability, proliferation and DNA integrity assays showed that irradiated and non irradiated N cells were not significantly affected at both 1 and 24 h post irradiation. W cells (1 h) irradiated with 5 J/cm2 showed a significant increase in percentage cell viability and ATP compared to non irradiated W cells (1 h), (P=0.05 and P=0.04 respectively), while irradiation with 16 J/cm2 showed a significant decrease (P=0.014 and P=0.02 respectively). W cells (24 h) irradiated with 5 J/cm2 also showed a significant increase in percentage cell viability and ATP when compared to non irradiated W cells (24 h), (P=0.006 and P=0.04 respectively). Contrary, irradiation with 16 J/cm2 showed a significant decrease (P<0.001 and P=0.003 respectively). v Cell proliferation results showed that irradiation with 5 J/cm2 was stimulatory while 16 J/cm2 was inhibitory. The comet assay demonstrated that N cells irradiated with 5 or 16 J/cm2 exhibited an insignificant change in DNA damage at both 1 and 24 h when compared to their respective controls. This finding is in agreement with Karu et al., (2003) who observed that phototherapy does not alter the biological activity of cells which at the time of irradiation are functioning normally. W cells (1 and 24 h) irradiated with 16 J/cm2 showed a significant increase in DNA damage compared to their respective controls. However, there was a significant decrease in damage at 24 h compared to 1 h incubation due to the activation of DNA repair mechanisms. Though not significant, comet assay with Fpg (modified comet assay) showed more DNA damage compared to comet assay without the enzyme (conventional comet assay). It can be explained that the modified comet assay detected and cleaved oxidised bases in addition to single strand breaks, which the conventional comet assay detected, suggesting that the modified comet assay is more sensitive than the conventional comet assay. After validation of the three reference genes, ACTB was chosen to be the gene with which to normalise MPG expression in WS1 cells. It was found to be the least variable; its expression was consistent in W cells as well as cells exposed to a He-Ne laser at a fluence of 5 or 16 J/cm2. It produced an acceptable correlation coefficient (R2 >0.999) and PCR efficiency (94%). Conversely, other primers like GAPDH produced a low PCR efficiency (82%), while UBC produced a low R2 (0.898). Wang et al., (2006) recommends the value of R2 to be more than 0.995 and a PCR efficiency of between 90 and 100% for PCR results to be reliable. Other researchers have not supported the use of ACTB as a reference gene, stating that it is highly regulated (Wang et al., 2006), however this study showed that ACTB was not regulated by laser irradiation (632.8 nm at 5 or 16 J/cm2). The cell culture conditions and vi laser irradiation in this study did not induce MPG expression; perhaps an alternative repair pathway might have been induced, and hence repaired the DNA damage. In conclusion, the mini project demonstrated that HU is able to inhibit cell proliferation through its cytostatic effect without affecting the viability of W WS1 cells. This study also showed that irradiation of W cells with 5 J/cm2 using the correct parameters enhances cell migration and proliferation as evidenced by the presence of more cells in the central scratch in HU treated cells, and a significant increase in cell proliferation as shown by the XTT assay in non treated cells respectively. Thus, migration and proliferation are the direct result of phototherapy as both are involved in wound closure. This study further confirmed that irradiation of W cells with 5 J/cm2 stimulated ATP production, and hence cellular viability, as well as cell proliferation and migration. Irradiation of cells with higher fluences such as 16 J/cm2 is damaging to DNA and inhibitory to cell proliferation, migration and possibly to MPG expression. The study further showed that N cells are not stimulated by phototherapy, supporting the notion that lasers stimulate compromised cells. Thus, if they are growing normally there is nothing to stimulate. This understanding helps to clarify why N cells irradiated with 5 or 16 J/cm2 had insignificant responses. Cell culture conditions, fluence and duration of exposures are important parameters that can affect gene expression, and hence documentation of all experimental conditions needs to be emphasised and published if reproducibility is to be achieved.
| Identifer | oai:union.ndltd.org:netd.ac.za/oai:union.ndltd.org:uj/uj:6615 |
| Date | 16 November 2009 |
| Creators | Mbene, Alwin Bilney |
| Source Sets | South African National ETD Portal |
| Detected Language | English |
| Type | Thesis |
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