In 2016, colorectal cancer was the second most common cancer type and the third most common cause of cancer-associated mortality worldwide (1). In Japan, due to changes in lifestyles, the incidence and mortality rates of colorectal cancer are increasing annually. In 2010, the incidence rate of colorectal cancer was second to gastric cancer, and in 2013, its mortality rate was second to lung cancer, in Japan (2). Despite advances in diagnostic techniques and the increasing prevalence of screening programs, surgical resection with lymph node dissection remains the most common curative therapy for colorectal cancer (3). The types of radiotherapy (RT) used for colorectal cancer are adjuvant and palliative RT (3). Adjuvant RT is used to prevent postoperative recurrence following surgery and reduce the tumor volume to enable preservation of the anal sphincter prior to surgery in locally advanced rectal cancer (4,5). Palliative RT is used to relieve the symptoms and prolong the lives of patients with unresectable or recurrent colorectal cancer, who have symptomatic lesions (6,7). However, curative RT has not yet been established, and it is controversial whether RT for colorectal cancer improves the survival rate (8–13). One reason for this may be the low radiosensitivity of colorectal cancer (14). RT has certain adverse effects in patients with colorectal cancer, including skin (pain, erythema, epilation, desquamation, edema, ulceration, hemorrhage and necrosis), gastrointestinal (nausea, diarrhea, abdominal or rectal discomfort, abdominal or rectal pain, mucous or blood discharge, ileus, obstruction, fistula and perforation), genitourinary (frequent urination, nocturia, dysuria, bladder spasm, hematuria and bladder obstruction), neurological (pain and a feeling of discomfort in the legs or gluteal region) and other adverse effects (15,16). In particular, late adverse effects, including anal dysfunction, bowel dysfunction and sexual dysfunction, depend on the radiation dose fraction size (8). The majority of adverse effects should lessen over time; however, certain adverse effects may continue after completing treatments, which often makes the continuation of treatments after radiotherapy difficult (5,8,11,17,18). The present study considers that a new RT for colorectal cancer is necessary, which has equivalent effectiveness to conventional RT but involves lower doses of radiation. In addition, enhancing the radiosensitivity of colorectal cancer may improve survival rates and lessen adverse effects. 5-aminolevulinic acid (5-ALA) is a natural amino acid that is biosynthesized in the mitochondria of animals. 5-ALA is an important precursor of heme and is synthesized from glycine and succinyl CoA by mitochondrial aminolevulinic acid synthase in animal cells (19). In tumor cells, exogenous administration of 5-ALA induces high accumulation of protoporphyrin IX (PpIX) resulting from high expression of peptide transporter 1 and low expression of ATP-binding cassette sub-family G member 2 (20,21). PpIX is used as a photosensitizer in photodynamic diagnosis (PDD) and photodynamic therapy (PDT) for various types of cancer (19,20,22–24). Hematoporphyrin derivatives (HpD) and photofrin are used in PDT, and their effectiveness has been demonstrated in several cancer types (25–27). Previous studies have reported that HpD and photofrin also act as significant radiosensitizers (28,29). Although the radiosensitizing effect of 5-ALA is controversial, it has been demonstrated in glioma and melanoma by numerous studies (30–33). The mechanisms remain unclear; however, a previous study has reported that the initial reactive oxygen species (ROS) generated from water radiolysis and delayed production of ROS in mitochondria following ionizing irradiation enhance radiosensitivity (33). The present study assessed the radiosensitizing effects of 5-ALA in colorectal cancer in vitro and in vivo using the human colorectal cell line HT29.

Current RT for colorectal cancer can reduce the tumor size (4); however, there are certain adverse effects specific to the disease. These adverse effects often lower patient quality of life and make the continuation of treatment prior to RT difficult (5,8,11,17,18). A new RT approach for colorectal cancer is desirable, involving more effective tumor suppression with lower doses of radiation. PDT and PDD are based on excitation of a photosensitizer administered systemically or topically by light of a specific wavelength corresponding to the absorption peak of the photosensitizer (19,20). PDT and PDD are widely used for treatment of various cancer types (e.g., malignant glioma, bladder cancer, lung cancer, skin cancer, esophageal cancer and cholangiocarcinoma) due to their high selectivity for targeted tumors and non-invasiveness (19,20,22–27). Previous studies have demonstrated that HpD, photofrin, and 5-ALA are suitable photosensitizers for PDT and PDD of several types of cancer (e.g., malignant glioma, bladder cancer, lung cancer, skin cancer, esophageal cancer and cholangiocarcinoma) (19,20,22–27). However, there are certain side effects associated with these modalities. The main side effect is phototoxicity. The administration of a photosensitizer results in increased sensitivity of the skin and eyes of the patients to sunlight and bright indoor light for several weeks. Thus, the patient has to avoid exposure to bright light for a long period until the photosensitizer is metabolized in their body (34–36). HpD and photofrin require ~6 weeks of photosensitivity precautions (34–36). By contrast, PpIX synthesized from 5-ALA is cleared from the body within 24–48 h after systemic ALA administration (20). This is one of the main advantages of 5-ALA. HpD and photofrin have been demonstrated to act as radiosensitizers in previous studies (28,29). Photofrin has been reported to enhance radiosensitivity in human bladder cancer and human glioblastoma cell lines, but not in a colorectal cancer cell line (14). In general, ionizing radiation damages living cells via two mechanisms, namely by direct and indirect reactions. In the direct reaction, radiation is absorbed into the cells and affects DNA directly. In the indirect reaction, radiation induces water radiolysis and generates ROS, including superoxide, hydroxyl radicals and hydrogen peroxide, which damage DNA and cell organelles (37,38). Previous studies have reported that 5-ALA-induced PpIX serves an important role in the production of ROS (31,33). The radiosensitivity induced by HpD and photofrin is caused by higher intracellular concentrations of porphyrin compounds relative to 5-ALA-induced PpIX (39). Another study demonstrated that ionizing irradiation dose not decrease the quantity of 5-ALA-induced PpIX. Therefore, ionizing radiation does not influence the synthesis of 5-ALA-induced PpIX (33). Previous studies have demonstrated the radiosensitizing effects of 5-ALA in glioma and melanoma (30–33). Certain studies have reported that delayed production of ROS in mitochondria following ionizing irradiation, in addition to the initial ROS generated by water radiolysis, enhances radiosensitivity (33,40,41). The present study assessed the effects of 5-ALA in colorectal cancer using the human HT29 colorectal cancer cell line. To the best of our knowledge, this is the first study to demonstrate the possibility of the radiosensitivity of colorectal cancer as a result of 5-ALA both in vitro and in vivo. It was identified that 5-ALA radiosensitized HT29 cells following multi-dose irradiation but not single-dose irradiation. This result is similar to that reported in previous studies involving glioma cell lines (30,32,33). Pretreatment with 5-ALA prior to ionizing irradiation increased the delayed ROS production in the cytoplasm of glioma cells. Consequently, 5-ALA may act as a radiosensitizer (33). The current results suggest that radiotherapy with 5-ALA may enhance the therapeutic effect in colon cancer and the possibility of reducing the dose of radiation.

The present study had several limitations. First, the molecular mechanism underlying the radiosensitizing effect of 5-ALA was not investigated and the presence of increased intracellular ROS was not confirmed. In common with a previous study involving glioma, increased intracellular ROS may have led to the result that 5-ALA had a radiosensitizing effect in the HT29 cell line (33). However, other uncertain mechanisms may have contributed to the results. It has been reported that ROS generation is significantly higher in ALA-PDT-treated cells compared with control cells of the MKN-45 human gastric cancer cell line (42). In future studies the molecular mechanism underlying the radiosensitizing effect of 5-ALA should be investigated. Second, the RT alone group exhibited no radiosensitizing effect in the single-dose irradiation experiment in vivo. However, since single-dose irradiation has been performed clinically for certain types of neoplasm (e.g., breast cancer and metastatic brain tumor) (43,44). It is uncertain whether single-dose irradiation is not curative in colorectal cancer or whether 5-ALA exhibits no effect under the conditions used in the present study. Fractionated irradiation is widely applied to many cancer types based on the difference in the reactions of tumor and normal tissues (45,46) and fractionated irradiation is generally used for radiotherapy of colorectal cancer in Japan (3). Clinically, colorectal cancer demonstrates radiation resistance. A previous study has reported that human HT29 colorectal cancer cells have lower radiosensitivity compared with other cell lines (14). The result of the single dose irradiation experiment is possible in clinical practice. In the present study, the dose in the single dose irradiation experiment may be too low for tumor shrinkage. However, in the multi-dose irradiation experiment, the result was improved. Further experiments should be performed to verify this point. Third, images of the tumors were not obtained and were not presented in the current study. Photographs of the tumors should be presented to demonstrate the extent that the tumor sizes were altered. Fourth, although a significant difference was identified in the tumor size ratios of the control and the RT+5-ALA groups in the multi-dose irradiation experiment, no significant difference in tumor weight was revealed between the RT group and the RT+5-ALA group. A previous study has reported that a long interval between preoperative irradiation and surgery increases tumor downstaging. A long interval (6–8 weeks) between preoperative radiotherapy and surgery is associated with a significantly improved clinical tumor response and pathological downstaging (5). If observations were extended over a longer period, a significant difference may be identified between the two groups regarding tumor weight.