Combination of tert-butyl hydroperoxide with vorinostat induces cell death of Acanthamoeba through cell cycle arrest

Journal Pre-proof Combination of tert-butyl hydroperoxide with vorinostat induces cell death of Acanthamoeba through cell cycle arrest Hae-Ahm Lee, Eun-Kyung Moon, Fu-Shi Quan PII:

S0014-4894(19)30282-6

DOI:

https://doi.org/10.1016/j.exppara.2020.107833

Reference:

YEXPR 107833

To appear in:

Experimental Parasitology

Received Date: 24 June 2019 Revised Date:

6 December 2019

Accepted Date: 10 January 2020

Please cite this article as: Lee, H.-A., Moon, E.-K., Quan, F.-S., Combination of tert-butyl hydroperoxide with vorinostat induces cell death of Acanthamoeba through cell cycle arrest, Experimental Parasitology (2020), doi: https://doi.org/10.1016/j.exppara.2020.107833. This is a PDF file of an article that has undergone enhancements after acceptance, such as the addition of a cover page and metadata, and formatting for readability, but it is not yet the definitive version of record. This version will undergo additional copyediting, typesetting and review before it is published in its final form, but we are providing this version to give early visibility of the article. Please note that, during the production process, errors may be discovered which could affect the content, and all legal disclaimers that apply to the journal pertain. © 2020 Published by Elsevier Inc.

Author statement

Hae-Ahm Lee: Methodology, Formal analysis, Investigation Eun-Kyung Moon: Conceptualization, Validation, Writing – Original draft preparation Fu-Shi Quan: Writing – Reviewing and Editing

1 2

Title: Combination of tert-butyl hydroperoxide with vorinostat induces cell death of Acanthamoeba through cell cycle arrest

3 4 5 6

RT: Combination of tBHP with vorinostat

7 8 9

Authors: Hae-Ahm Lee1, Eun-Kyung Moon2, and Fu-Shi Quan1, 2, *

10 11

Address: 1Medical Research Center for Bioreaction to Reactive Oxygen Species and

12

Biomedical Science Institute, School of Medicine, Graduate school, Kyung

13

Hee University, Seoul, Republic of Korea, 2 Department of Medical Zoology,

14

Kyung Hee University School of Medicine, Seoul, Republic of Korea

15 16

17

* Corresponding author

18

Fu-Shi Quan: Department of Medical Zoology, Kyung Hee University School of

19

Medicine, Seoul, Republic of Korea

20 21

Tel: +82-2-961-2302

22

Fax: +82-2-961-0278

23

E-mail: [email protected]

24

１

25

ABSTRACT

26

Safety precautions prior to contact lens usage is essential for preventing

27

Acanthamoeba keratitis. Contact lens disinfecting solutions containing 3% hydrogen

28

peroxide (H2O2) are known to exert amoebicidal effect against Acanthamoeba. Yet,

29

these solutions need to be neutralized to prevent ocular irritation, which consequently

30

may result in incomplete disinfection. In this study, amoebicidal effect of tert-butyl

31

hydroperoxide (tBHP) was investigated and its efficacy was compared to those of

32

hydrogen peroxide (H2O2). H2O2 and tBHP showed dose dependent amoebicidal effect,

33

however high concentration of these compounds demonstrated cytotoxicity in human

34

corneal epithelial (HCE) cells. To reduce their cytotoxicity, the concentrations of both

35

compounds were diluted to 50 µM and subsequently combined with 10 µM vorinostat to

36

enhance amoebicidal effect. Addition of vorinostat induced high amoebicidal effect

37

against Acanthamoeba trophozoites, even at low concentrations of H2O2 or tBHP.

38

Cellular damage induced by combined treatment of H2O2 or tBHP with vorinostat in

39

Acanthamoeba were determined by assessing cell cycle arrest and apoptosis via FACS

40

analysis. While 50 µM H2O2 combined with 10 µM vorinostat showed 36.26%

41

cytotoxicity on HCE cells during 24 h exposure, 50 µM tBHP with 10 µM vorinostat did

42

not show cytotoxicity on HCE cells. These findings suggest that the application of tBHP

43

and vorinostat for Acanthamoeba keratitis treatment and contact lens disinfection

44

system is highly plausible.

45 46 47

Key Words: Acanthamoeba, tBHP, vorinostat

48

２

49

INTRODUCTION

50

Acanthamoeba keratitis (AK) caused by the pathogenic Acanthamoeba is a rare

51

disease, but its incidence is increasing (Auran et al., 1987). The risk factor of AK

52

infection is associated with contact lens usage and poor lens hygiene (Jasim et al., 2012;

53

Maycock and Jayaswal, 2016). Diagnosis of AK is difficult and often delayed. Limited

54

effective treatment options, as well as difficulties arising from highly drug-resistant cyst

55

stage of Acanthamoeba also remains a challenge that needs to be addressed. Most of the

56

currently used agents for AK treatment are biguanides (0.02% polyhexamethylene

57

biguanide or 0.02% chlorhexidine) and diamidine (0.1% propamidine or 0.1%

58

hexamidine) (Lorenzo-Morales et al., 2015; Carrijo-Carvalho et al., 2017), whose potent

59

side effects are the results of drug toxicity and sensitive reaction of the corneal cell.

60

Approximately 90% of AK infections occur in contact lens wearers (Jasim et

61

al., 2012; Maycock and Jayaswal, 2016). Therefore, correct contact lens use and

62

disinfection can reduce AK incidence. Current trend in contact lens care system is the

63

use of multi-purpose solution (MPS) for cleansing and disinfection (Stevenson and Seal,

64

1998). Most of the MPSs contain polyhexamethylene biguanide, and they are effective

65

against microorganisms. However, they showed cytotoxicity in human corneal epithelial

66

(HCE) cells and its efficacy was insufficient to thwart Acanthamoeba infections,

67

particularly those arising from cysts (Beattie et al., 2003; Moon et al., 2016). Hydrogen

68

peroxide (H2O2) is known to be an effective antimicrobial agent, and 3% H2O2 solution

69

is used widely for contact lens disinfection (Gasset et al., 1975; Nichols et al., 2019).

70

H2O2-derived free radicals can serve as either essential components of cells or

71

detriments, which can destroy integral cell components (Lowe and Brennan, 1987).

72

Because HCE cells are also susceptible to the oxidative effects of H2O2, lens care

３

73

solution containing H2O2 require complete neutralization (Nichols et al., 2019). Varying

74

consequences may arise depending on the neutralization process, as extremely rapid

75

H2O2 neutralization reaction can result in inadequate disinfection, whereas ocular

76

irritation may occur from incomplete neutralization (Kilvington and Winterton, 2017).

77

For successful contact lens care, an investigation researching simple yet effective lens

78

disinfection system would be necessary.

79

Oxidative stress caused by reactive oxygen species (ROS) induce cellular

80

damages to DNA, proteins, and lipids (Kehrer, 1993). Tert-butyl hydroperoxide (tBHP)

81

is a representative oxidant that induces mitochondrial dysfunction and cell death

82

(Prakash and Kumar, 2014). Two stressors, H2O2 and tBHP enhanced cell damage and

83

ROS generation. Previous studies have documented apoptosis and necroptosis induction

84

by tBHP in endothelial cells (Zhao et al., 2017). The combination of tBHP plus

85

cetyltrimethyl ammonium bromide and a tetra-amido macrocyclic ligand is effective in

86

killing Bacillus subtilis spores (Paul et al., 2007). While the research of amoebicdal

87

effects of H2O2 against Acanthamoeba is progressing well, the effect of tBHP in

88

Acanthamoeba remains unknown.

89

Histone deacetylase (HDAC) inhibitors are chemical compounds that inhibit

90

histone deacetylases, and they have shown to induce cell cycle arrest, differentiation, or

91

apoptosis in tumor cells (Dokmanovic and Marks, 2005; Mei et al., 2004). Vorinostat is

92

a one of the numerous types of HDAC inhibitor and their effects on cell growth,

93

differentiation, and apoptosis have been reported (Bubna, 2015). Its application as a

94

monotherapeutic agent or in combination with other drugs have been documented.

95

In this study, we demonstrated the amoebicidal effect and its mechanism in

96

tBHP compared to that of H2O2. Furthermore, we investigated the effect of tBHP

４

97

combined with vorinostat to Acanthamoeba trophozoites and HCE cells.

98

５

99 100

MATERIALS AND METHODS Cell cultures

101

Acanthamoeba castellanii Castellani was obtained from the American Type

102

Culture Collection (ATCC 30868). Acanthamoeba trophozoites were cultured axenically

103

in PYG medium (20 g proteose peptone, 1 g yeast extract, 0.1M glucose, 4 mM MgSO4,

104

0.4 mM CaCl2, 3.4 mM sodium citrate, 0.05 mM Fe(NH4)2(SO4)2, 2.5 mM Na2HPO4,

105

and 2.5 mM K2HPO4 in 1 liter of distilled water with the final pH adjusted to 6.5) at

106

25°C incubator. Human corneal epithelial (HCE) cells (ATCC PCS-700-010) were

107

cultured in endothelial cell growth medium kits (KGM BulletKit; Lonza, Portsmouth,

108

NH, USA) in a humidified incubator containing 5% CO2 at 37°C.

109

110

Amoebicidal effects on Acanthamoeba

111

Acanthamoeba trophozoites were seeded into 96-well culture plates at a density

112

of 1 × 104 cells/well. To determine the effect of H2O2 (12.5, 25, 50, 100, and 200 µM)

113

tBHP (12.5, 25, 50, 100, and 200 µM), vosinostat (0.5, 1, and 10 µM), combination of

114

H2O2 and 10 µM vorinostat, and combination of tBHP and 10 µM vorinostat,

115

monolayers of amoebae were incubated with aforementioned reagents for 24 h at 25°C.

116

After incubation, 10 µl of cell counting kit-8 (CCK-8) was added to each well and the

117

plate was incubated for 6 h at 25°C. The sample absorbance was measured at the 450

118

nm wavelength against blank which contained medium only. The cell viability was

119

calculated according to the following formula: (%) = (OD of sample - OD of

120

blank)/(OD of control - OD of blank) × 100%. All assays were performed in triplicate.

６

121

122

Cytopathic effects (CPE) on human corneal cells

123

HCE cells were seeded into 96-well culture plates at a density of 1 × 104

124

cells/well. The next day, HCE cell monolayers were incubated with H2O2 (50 and 500

125

µM), tBHP (50 and 500 µM), vorinostat (10 µM), combination of 50 µM H2O2 and 10

126

µM vorinostat, or combination of 50 µM tBHP and 10 µM vorinostat at 37°C in 5%

127

CO2 for 24 h. After incubation, CPE on HCE cells were assessed using the

128

aforementioned CCK-8. All assays were performed in triplicate.

129

130

Detection of apoptosis and cell cycle arrest

131

Apoptotic cell death was detected using FITC Annexin V Apoptosis Detection

132

Kit (BD Bioscience, San Jose, California, United States). All experiments were

133

conducted following the manufacturer's protocol. Briefly, A. castellanii trophozoites

134

were seeded into 6-well culture plates at a density of 5×105 cells per well. After

135

overnight culture, monolayers of amoebae were incubated with 0.0002% PHMB, 50 µM

136

H2O2, combination of 50 µM H2O2 and 10 µM vorinostat, 50 µM tBHP, or combination

137

of 50 µM tBHP and 10 µM vorinostat for 24 h at 25°C. Amoebae were washed with

138

PBS to remove excess drug, and re-suspended in 1x binding buffer at a concentration of

139

1×106 cells/ml. Amoebae (1×105 cells/100 µl) were transferred to a new tube and

140

incubated with 5 µl of FITC annexin V and 5 µl of propidium iodide (PI) for 15 min at

141

RT in the dark. Finally, 400 µl of 1x binding buffer was added, and cells were analyzed

142

by a fluorescent microscope (Leica DMi8, Wetzlar, Germany) and flow cytometry using

143

BD Accuri C6. To investigate the cell cycle arrest, amoebae were treated as above for

７

144

apoptosis assessment. Samples were fixed with 70% ethanol for 30 min, and washed

145

twice with PBS. Afterwards, cells were treated with ribonuclease (final conc. 10 µg/ml)

146

for 10 min at 37°C, and stained with PI for 30 min at RT in the dark. Stained cells were

147

analyzed by flow cytometry using BD Accuri C6.

148 149

Statistical analysis

150

Data are presented as mean ± SD from three independent experiments.

151

Statistical analysis was performed using Student's t-test. A p value of < 0.05 was

152

considered statistically significant.

153

８

154

RESULTS

155

H2O2 and tBHP showed amoebicidal effect on Acanthamoeba trophozoites

156

Cell viability assay using CCK-8 showed that H2O2 decreased Acanthamoeba

157

viability in a dose dependent manner (Fig. 1A). However, 50 µM of H2O2 that showed

158

amoebicidal effect also demonstrated 34.98% of cytotoxicity against HCE cells (Fig.

159

1B). Amoebicidal effects of tBHP were noticeable at 50, 100, and 200 µM (Fig 1C).

160

Although miniscule levels of amoebicidal effect were induced by 50 µM tBHP, its

161

cytotoxicity to HCE cells were significantly low (Fig 1D). Neither Acanthamoeba nor

162

HCE cell viabilities were affected by vorinostat concentrations of 0.1 ~ 10 µM (Fig. 1E

163

and F).

164

165

Vorinostat increased the amoebicidal effects of H2O2 and tBHP

166

To increase the amoebidical effects of H2O2 and tBHP, 10 µM vorinostat was

167

combined with them. Upon addition of vorinostat, morphological changes were

168

observed in Acanthamoeba treated with 50 ~ 200 µM H2O2 or tBHP (Fig. 2B and D).

169

Cell viability assay confirmed increased amoebicidal effects at low concentrations of

170

H2O2 and tBHP when vorinostat was combined (Fig. 2E and F). Cyst formation was not

171

observed from these samples. Compared to single treatment of H2O2 and tBHP, the

172

combination of 50 µM H2O2 with 10 µM vorinostat showed increased amoebicidal

173

effect from 25.12% to 34.89%, and the combination of 50 µM tBHP with 10 µM

174

vorinostat showed drastically increased amoebicidal effects from 2.63% to 34.58% (Fig.

175

2G and H). These results suggest that vorinostat enhanced the amoebicidal effects of

９

176

low concentration of H2O2 and tBHP.

177 178

H2O2 induced apoptosis in Acanthamoeba

179

To investigate the effects of two combinations on Acanthamoeba, apoptosis

180

analysis was performed (Fig. 3). Acanthamoeba treated with 50 µM H2O2 induced

181

20.7% apoptosis (Fig. 3B), and the combination of 50 µM H2O2 with 10 µM vorinostat

182

induced 18.3% apoptosis (Fig. 3C), while untreated control cells showed 13.2%

183

apoptosis (Fig. 3A). The 50 µM tBHP showed 8.1% apoptotic cell death, and the

184

combination of 50 µM tBHP with 10 µM vorinostat showed 9.0% apoptosis in

185

Acanthamoeba (Fig. 3D and E). The addition of vorinostat did not affect apoptosis by

186

H2O2 and tBHP. These results suggest that 50 µM H2O2 induced apoptosis in

187

Acanthamoeba, whereas 50 µM tBHP did not induce apoptotic cell death in

188

Acanthamoeba.

189 190

tBHP combined with vorinostat arrested the cell cycle of Acanthamoeba

191

To determine whether these combinations arrest the cell cycle of

192

Acanthamoeba, flow cytometry was performed (Fig. 4). We divided the DNA

193

replication cycle of Acanthamoeba into three segments: M1, M2, and M3 (Fig. 4).

194

Because Acanthamoeba trophozoites in this study were examined in asynchronous

195

culture, majority of the amoebae were in a single phase of the cycle. We supposed that

196

M2 segment corresponded to G2 phase, which were set to be approximately 90%.

197

Population changes and cell distribution among the three segments were investigated

198

after treatment with the four aforementioned combinations. Acanthamoeba exposed to

１０

199

50 µM H2O2 showed reduced M2, and increased M1 and M3 population compared to

200

control (Fig. 4B). The addition of 10 µM vorinostat to H2O2 increased M3 population

201

(Fig. 4C). Acanthamoeba treated with 50 µM tBHP alone revealed reduced M2 and M3,

202

but increased M1 populations compared to control cells (Fig. 4D). Combining 50 µM

203

tBHP with 10 µM vorinostat significantly increased M1 population, whereas M3

204

population was reduced (Fig. 4E). These findings suggested that H2O2 combined with

205

vorinostat induced cell cycle arrest at G2/M phase (Fig. 4C, M3 segment), and tBHP

206

combined with vorinostat induced cell cycle arrest at G1 phase (Fig. 4E, M1 segment).

207 208

Combining tBHP with vorinostat did not show cytotoxicity to HCE cells

209

To determine the cytotoxicity of two combinations in HCE cells, HCE cells

210

were treated with 50 µM H2O2, 50 µM H2O2 combined with 10 µM vorinostat, 50 µM

211

tBHP, and 50 µM tBHP combined with 10 µM vorinostat (Fig. 5). The combination of

212

50 µM H2O2 and 10 µM vorinostat showed 36.26% cytotoxicity to HCE cells, which

213

was similar level to that of 50 µM H2O2 (Fig. 5A). The combination of 50 µM tBHP and

214

10 µM vorinostat showed slight cytotoxicity (6.98%) to HCE cells (Fig. 5B). The

215

addition of 10 µM vorinostat did not increase the cytotoxicity by 50 µM tBHP, and this

216

combination was considered to be non-toxic to HCE cells.

217

１１

218

DISCUSSION

219

In this study, we report that oxidant tBHP has amoebicidal effect on

220

Acanthamoeba trophozoite. The combination of low concentration of tBHP (50 µM) and

221

vorinostat (10 µM) showed high amoebicidal effect on Acanthamoeba, and low

222

cytotoxicity on HCE cells (Fig. 2 and 5).

223

Although

vorinostat

alone have

not

shown

amoebicidal

effect

on

224

Acanthamoeba, it showed strong amoebicidal effect when combined with tBHP or H2O2.

225

However, there were no significant differences among different concentrations of H2O2

226

or tBHP (Fig. 2E and F). A 3% H2O2 solution can effectively disinfect soft contact

227

lenses (Gasset et al., 1975), but H2O2 is widely regarded as a cytotoxic agent whose

228

levels must be minimized (Halliwell et al., 2000). In this study, to reduce the

229

cytotoxicity of H2O2, the concentration was diluted to 50 µM. One mole solution of

230

H2O2 is equivalent to 3.4% H2O2. By addition of 10 µM of vorinostat to 50 µM H2O2,

231

the amoebicidal effect was increased (Fig. 2).

232

The actual mechanism of action for the combined treatments remains unclear.

233

H2O2 induced apoptosis in Acanthamoeba, while tBHP did not induce apoptotic cell

234

death (Fig. 3). We speculate that the concentration of tBHP (50 µM) was too low to

235

induce apoptosis of Acanthamoeba (Fig. 1C and 3D). Spector et al. found that H2O2-

236

induced cell death was related to the extensive DNA damage caused by peroxide, and

237

tBHP under similar conditions caused little DNA damage (Spector et al., 2002). In line

238

with this notion, results acquired from the present study also showed a pattern similar to

239

this. The addition of vorinostat did not affect induction of apoptosis.

240

The DNA replication cycle of Acanthamoeba has been examined. In synchrony

１２

241

cultured Acanthamoeba, trophozoites appeared to consist of 37-47% G1 (presynthetic

242

gap), 13% S (synthesis), and 40-50% G2 (postsynthetic gap) plus M (mitosis) (Byers et

243

al., 1991). In asynchronous cultures of Acanthamoeba, the cycle appeared to consist of

244

at least 90% G2, essentially no G1, and 8-10% M plus S (Byers et al., 1991).

245

Acanthamoeba treated with 50 µM H2O2 showed increased G1/S and M (Fig. 4B -

246

segments M1 and M3) compared to untreated control cells. After addition of 10 µM

247

vorinostat, M was increased (Fig. 4C - segment M3). Acanthamoeba treated with 50 µM

248

tBHP showed increased G1/S (Fig. 4D - segment M1). After addition of 10 µM

249

vorinostat, G1/S was increased further and M was decreased (Fig. 4E - segments M1

250

and M3). Vorinostat induces cell-cycle arrest at the G1 or the G2/M boundary in a cell-

251

type dependent and/or dose-related fashion (Richon et al., 2009). In Acanthamoeba,

252

vorinostat with H2O2 induced cell cycle arrest at the G2M boundary, and vorinostat with

253

tBHP induced cell cycle arrest at the G1 phase. These results suggest that vorinostat

254

combined with H2O2 or tBHP increased amoebicidal effect on Acanthamoeba by cell

255

cycle arrest. Prospective studies investigating the effects of these combinations on

256

Acanthamoeba cyst and various clinical strains would be of great value.

257

The low concentration of tBHP (50 µM) combined with 10 µM vorinostat did

258

not show cytotoxicity, while 50 µM H2O2 combined with 10 µM vorinostat showed

259

cytotoxicity to HCE cells (Fig. 5). Although organic peroxides are widely used in

260

various oxidation processes, tBHP has been documented to be a better alternative for

261

H2O2 and has been frequently utilized in oxidative stress studies (15). The effect of

262

tBHP combined with vorinostat on Acanthamoeba will provide important information to

263

develop safe and optimized contact lens care system and treatment for Acanthamoeba

１３

264

keratitis.

265

１４

266

267 268

ACKNOWLEDGEMENT This work was supported by grants from the National Research Foundation of Korea (NRF) (2016R1D1A1B03933863, and 2018R1A6A1A03025124).

269

１５

270

REFERENCES

271

Auran JD, Starr MB, Jakobiec FA. 1987. Acanthamoeba keratitis. A review of the

272

literature. Cornea 6:2-26.

273

Beattie TK, Seal DV, Tomlinson A, McFadyen AK, Grimason AM. 2003.

274

Determination of amoebicidal activities of multipurpose contact lens solutions by

275

using a most probable number enumeration technique. J Clin Microbiol 41:2992-

276

3000.

277

Bubna AK. 2015. Vorinostat-An Overview. Indian J Dermatol 60:419.

278

Byers TJ, Kim BG, King LE, Hugo ER. 1991. Molecular aspects of the cell cycle and

279

encystment of Acanthamoeba. Rev Infect Dis Suppl 5:S373-384.

280

Carrijo-Carvalho LC, Sant'ana VP, Foronda AS, de Freitas D, de Souza Carvalho FR.

281

2017. Therapeutic agents and biocides for ocular infections by free-living amoebae

282

of Acanthamoeba genus. Surv Ophthalmol 62:203-218.

283 284 285 286 287 288

Dokmanovic M, Marks PA. 2005. Prospects: histone deacetylase inhibitors. J Cell Biochem 96:293-304. Gasset AR, Ramer RM, Katzin D. 1975. Hydrogen peroxide sterilization of hydrophilic contact lenses. Arch Ophthalmol 93:412-415. Halliwell B, Clement MV, Long LH. 2000. Hydrogen peroxide in the human body. FEBS Lett 486:10-13.

289

Jasim H, Knox-Cartwright N, Cook S, Tole D. 2012. Increase in Acanthamoeba

290

keratitis may be associated with use of multipurpose contact lens solution. BMJ

291

344:e1246.

１６

292 293 294 295 296 297 298 299 300 301 302 303

Kehrer JP. 1993. Free radicals as mediators of tissue injury and disease. Crit Rev Toxicol 23:21-48. Kilvington S, Winterton L. 2017. Fibrous Catalyst-Enhanced Acanthamoeba Disinfection by Hydrogen Peroxide. Optom Vis Sci 94:1022-1028. Lorenzo-Morales J, Khan NA, Walochnik J. 2015. An update on Acanthamoeba keratitis: diagnosis, pathogenesis and treatment. Parasite 22:10. Lowe R, Brennan NA. 1987. Hydrogen peroxide disinfection of hydrogel contact lenses: An overview. Clin Exp Optom 70:190-197. Maycock NJ, Jayaswal R. 2016. Update on Acanthamoeba Keratitis: Diagnosis, Treatment, and Outcomes. Cornea 35:713-720. Mei S, Ho AD, Mahlknecht U. 2004. Role of histone deacetylase inhibitors in the treatment of cancer. Int J Oncol 25:1509-1519.

304

Moon EK, Park HR, Quan FS, Kong HH. 2016. Efficacy of Korean Multipurpose

305

Contact Lens Disinfecting Solutions against Acanthamoeba castellanii. Korean J

306

Parasitol 54:697-702.

307

Nichols JJ, Chalmers RL, Dumbleton K, Jones L, Lievens CW, Merchea MM,

308

Szczotka-Flynn L. 2019. The Case for Using Hydrogen Peroxide Contact Lens

309

Care Solutions: A Review. Eye Contact Lens 45:69-82.

310 311

Paul M, Setlow B, Setlow P. 2007. Killing of spores of Bacillus subtilis by tert-butyl hydroperoxide plus a TAML activator. J Appl Microbiol 102:954-962.

312

Prakash A, Kumar A. 2014. Implicating the role of lycopene in restoration of

313

mitochondrial enzymes and BDNF levels in β-amyloid induced Alzheimer‫׳‬s disease.

314

Eur J Pharmacol 741:104-111.

１７

315 316

Richon VM, Garcia-Vargas J, Hardwick JS. 2009. Development of vorinostat: current applications and future perspectives for cancer therapy. Cancer Lett 280:201-210.

317

Spector A, Ma W, Sun F, Li D, Kleiman NJ. 2002. The effect of H2O2 and tertiary butyl

318

hydroperoxide upon a murine immortal lens epithelial cell line, alphaTN4-1. Exp

319

Eye Res 75:573-582.

320

Stevenson RW, Seal DV. 1998. Has the introduction of multi-purpose solutions

321

contributed to a reduced incidence of Acanthamoeba keratitis in contact lens

322

wearers? A review. Cont Lens Anterior Eye 21:89-92.

323

Zhao W, Feng H, Sun W, Liu K, Lu JJ, Chen X. 2017. Tert-butyl hydroperoxide (t-

324

BHP) induced apoptosis and necroptosis in endothelial cells: Roles of NOX4 and

325

mitochondrion. Redox Biol 11:524-534.

326

１８

327

FIGURE LEGENDS

328 329

Figure 1. Amoebicidal effect and cytotoxicity of H2O2, tBHP and vorinostat. To

330

investigate the amoebicidal effect of H2O2, tBHP and vorinostat on Acanthamoeba,

331

Acanthamoeba trophozoites were treated with 12.5 ~ 200 µM H2O2 (A), 12.5 ~ 200 µM

332

tBHP (C) or 0.1 ~ 10 µM vorinostat (E) for 24 h. To determine the cytotoxicity of H2O2,

333

tBHP and vorinostat to HCE cells, HCE cells were treated with 50 and 500 µM H2O2

334

(B), 50 and 500 µM tBHP (D) or 10 µM vorinostat (F) for 24 h. *, **: Asterisks denote

335

statistically significant differences (*P<0.05 and **P<0.01) between untreated cells

336

(control) and each agent-treated cells

337 338

Figure 2. Amoebicidal effects of H2O2 and tBHP combined with vorinostat. To enhance

339

the amoebicidal effect of H2O2 and tBHP, 10 µM vorinostat was combined with them.

340

Acanthamoeba were treated with 50 ~ 200 µM H2O2 (A), 50 ~ 200 µM H2O2 with 10

341

µM vorinostat (B), 50 ~ 200 µM tBHP (C), or 50~200 µM tBHP with 10 µM vorinostat

342

(D) for 24 h. After incubation, morphological changes were observed under the

343

microscope (400x) (A ~ D). Panels (E) and (F) summarizes the amoebicidal effects

344

observed in (B) and (D). The amoebicidal effects of the combinations (H2O2 with

345

vorinostat, and tBHP with vorinostat) were compared to H2O2 or tBHP treatment alone

346

(G and H). **: Asterisks denote statistically significant differences (**P<0.01) between

347

control and cells treated with the three combinations.

348

１９

349

Figure 3. Detection of apoptosis. To measure apoptotic cell death of Acanthamoeba,

350

Acanthamoeba trophozoites were treated with 50 µM H2O2 (B), 50 µM H2O2 with 10

351

µM vorinostat (C), 50 µM tBHP (D), or 50 µM tBHP with 10 µM vorinostat (E) for 24

352

h. Untreated cells were used as normal control (A). Cells were subsequently stained

353

with annexin V and propidium iodide (PI), and these cells were assessed using flow

354

cytometry. The upper right quadrant (Q2-UR) in each flow cytometry plot indicates

355

apoptosis.

356 357

Figure 4. DNA and cell cycle analysis. To analyze the cell cycle of Acanthamoeba,

358

asynchronous cultured Acanthamoeba was stained with PI, and were subjected to flow

359

cytometry (A). DNA replication cycle of Acanthamoeba was divided into three

360

segments: M1, M2, and M3. After treatment of 50 µM H2O2 (B), 50 µM H2O2 with 10

361

µM vorinostat (C), 50 µM tBHP (D), or 50 µM tBHP with 10 µM vorinostat (E) for 24

362

h, the percentage of cells with fractional DNA content was estimated.

363 364

Figure 5. Cytotoxicity of the two combinations to HCE cells. To evaluate the

365

cytotoxicity of two combinations to HCE cells, HCE cells were treated with 50 µM

366

H2O2, 50 µM H2O2 with 10 µM vorinostat, 50 µM tBHP, and 50 µM tBHP with 10 µM

367

vorinostat for 24 h (A and B). The cytotoxicity of the combinations were compared to

368

those of control (untreated) and cells receiving single treatment. *, **: Asterisks denote

369

statistically significant differences (*P<0.05 and **P<0.01) between control and each

370

treated cells.

２０

▪ The combination of 50 µM tBHP and 10 µM vorinostat showed high amoebicidal

effect on Acanthamoeba, and low cytotoxicity on HCE cells. ▪ Vorinostat combined with H2O2 or tBHP increased amoebicidal effect on Acanthamoeba by cell cycle arrest. ▪ The effect of tBHP combined with vorinostat on Acanthamoeba will provide important information to develop safe and optimized contact lens care system and treatment for Acanthamoeba keratitis.