Journal of the Society of Cosmetic Scientists of Korea (대한화장품학회지)

Society of Cosmetic Scientists of Korea (대한화장품학회)
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3D-QSAR Analyses on the Inhibition Activity of 4-Hydroxybenzyl alcohol Analogues Against Tyrosinase

4-Hydroxybenzyl alcohol 유도체들의 Tyrosinase 활성 저해에 대한 3D-QSAR 분석

  • Kim, Sang Jin (Department of Cosmetic Science, Daejeon Health Science College, Chemolee Lab) ;
  • Sung, Nack Do (Department of Scientific Criminal Investigation, Chungnam National University)
  • 김상진 (대전보건대학교 화장품과학과, 케모리랩) ;
  • 성낙도 (충남대학교 평화안보대학원 과학수사학과)
  • Received : 2013.07.15
  • Accepted : 2013.08.30
  • Published : 2013.12.31
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Abstract

Three-dimensional quantitative structure-activity relationships (3D-QSARs) models between the substituents with changing groups ($R_1$ & $R_2$) of 4-hydroxybenzyl alcohol (4-HBA) derivatives as substrate molecule and their inhibitory activities against tyrosinase were derived and discussed quantitatively. The optimized CoMSIA FF model showed the best predictability and fitness ($r^2$ = 0.858 & $q^2$ = 0.951). The contour maps of the optimized CoMSIA FF model showed that, the inhibitory activities of the analogues against tyrosinase were expected to increase when hydrophobic (Hy) favor, negative charge (E) favor, steric (S) disfavor and hydrogen bond donor (HD) disfavor groups were substituted at the $R_2$ position. When the hydrogen bond donor (HD) favor groups were substituted at the $R_1$ position, it is predicted that the substituents will be able to increase the inhibitory activity.

본 연구에서는 기질 화합물로써 일련의 4-hydroxybenzyl alchol (4-HBA) 유도체들의 치환기($R_1$$R_2$) 변화에 따른 tyrosinase 활성저해에 관한 3차원적인 구조-활성 상관관계(3D-QSARs) 모델을 유도하고 정량적으로 검토하였다. 그 결과, 입체장(S), 정전기장(E), 소수성장(Hy), 수소결합 받게장(HA) 및 수소결합 주게장(HD)의 조합조건에서 통계적으로 양호한 CoMSIA FF 모델(상관성; $r^2$ = 0.858 및 예측성; $q^2$ = 0.951)을 유도하였다. 등고도 분석결과에 의하면 기질분자의 $R_2$-치환기는 입체적으로 작고 음전하를 띄며, 소수성이면서 수소결합 주게장을 선호하지 않는 치환기가 올수록 tyrosinase 활성저해 작용이 용이하다. 그리고 $R_1$-치환기는 수소결합 주게장을 선호하는 치환기 이어서 $R_1$-치환체가 용이하게 탈 양성자화가 일어나야 tyrosinase 활성저해 작용을 용이하게 할 것이라고 예상되며, 이를 위해서는 $R_1$-치환기가 비 치환체(H)이어야 될 것으로 예상되었다.

Keywords

References

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