Detailed Information on Publication Record

PETRLOVÁ, Jitka, Richard PRŮŠA, Bernd SURES, Vojtěch ADAM, Ladislav ZEMAN, Libuše TRNKOVÁ and René KIZEK. Study of nucleic acids interactions with platinum based cytostatics using biosensor. In 11th International conference on electroanalysis. první. Bordeaux: European Society for ElectroAnalytical Chemistry, 2006, p. 7-7.

Other formats: BibTeX LaTeX RIS

TY  - JOUR
ID  - 637916
AU  - Petrlová, Jitka - Průša, Richard - Sures, Bernd - Adam, Vojtěch - Zeman, Ladislav - Trnková, Libuše - Kizek, René
PY  - 2006
TI  - Study of nucleic acids interactions with platinum based cytostatics using biosensor
PB  - European Society for ElectroAnalytical Chemistry
CY  - Bordeaux
KW  - Platinum based cytostatic drugs
KW  - nucleic acids
KW  - biosensor
KW  - electrochemistry
KW  - interaction DNA;
N2  - Introduction. Although platinum based cytostatic drugs have been successfully used in the chemotherapy of cancer for more than 30 years, its biochemical mechanism of action is still unclear. The current accepted opinion about cisplatin mechanism of action is that the drug induces its cytotoxic properties through binding to the nuclear DNA and subsequent interference with normal transcription, and/or DNA replication mechanisms. Objective. The aim of this paper was to study of binding of platinum cytostatic to DNA structure using of platinum biosensor. Materials and methods. Preparation of DNA adduct with cisplatin. dsDNA was modified in the presence NaClO4 by cisplatin for in the dark of a thermostatic box. Purification of DNA adduct. The obtained DNA adduct was purified by ultrafiltration. Preparation of biosensor. Metallothionein modified surface of hanging mercury drop electrode was used as a platinum biosensor. The platinum and Pt-DNA adduct were detected by adsorptive transfer stripping (AdTS) differential pulse voltammetry (DPV). AdTS DPV parameters: time of accumulation 240 s, time of interaction 400 s. Results. Here we studied a binding of different platinum based cytostatics (cisplatin, carboplatin and oxaliplatin) to genome DNA. The influence of concentration of DNA, temperature and ionic strength on yield of adducts has been described. Consequently, we used the suggested heavy metal biosensor to detection of platinum modified DNA. We found out that the highest yield of Pt-DNA adducts has been obtained, if we used 100 mg/ml DNA at temperature 37 C for 24 h, because the yield of the modification was very low up to 10 h. In addition, increasing ionic strength negatively influenced yield of the modification. We were able to analyse tens of nanograms of Pt-DNA adduct per millilitre using the biosensor. Conclusions. The suggested approach shows the possible way for simple, sensitive, and rapid detection and determination of cisplatin and Pt-DNA adducts. In addition, the biosensor could be applied to study of binding of platinum to DNA structure.
ER  -

Basic information
Original name	Study of nucleic acids interactions with platinum based cytostatics using biosensor
Name in Czech	Studium interakcí nukleových kyselin a platinových cytostatik s použitím biosenzoru
Authors	PETRLOVÁ, Jitka (203 Czech Republic), Richard PRŮŠA (203 Czech Republic), Bernd SURES (276 Germany), Vojtěch ADAM (203 Czech Republic), Ladislav ZEMAN (203 Czech Republic), Libuše TRNKOVÁ (203 Czech Republic, guarantor) and René KIZEK (203 Czech Republic).
Edition	první. Bordeaux, 11th International conference on electroanalysis, p. 7-7, 1 pp. 2006.
Publisher	European Society for ElectroAnalytical Chemistry

Other information
Original language	English
Type of outcome	Proceedings paper
Field of Study	10405 Electrochemistry
Country of publisher	France
Confidentiality degree	is not subject to a state or trade secret
RIV identification code	RIV/00216224:14310/06:00020012
Organization unit	Faculty of Science
Keywords in English	Platinum based cytostatic drugs; nucleic acids; biosensor; electrochemistry; interaction DNA;
Tags	biosensor, electrochemistry, interaction DNA, nucleic acids, Platinum based cytostatic drugs
Changed by	Changed by: prof. RNDr. Libuše Trnková, CSc., učo 1027. Changed: 20/6/2008 12:47.

Abstract
Introduction. Although platinum based cytostatic drugs have been successfully used in the chemotherapy of cancer for more than 30 years, its biochemical mechanism of action is still unclear. The current accepted opinion about cisplatin mechanism of action is that the drug induces its cytotoxic properties through binding to the nuclear DNA and subsequent interference with normal transcription, and/or DNA replication mechanisms. Objective. The aim of this paper was to study of binding of platinum cytostatic to DNA structure using of platinum biosensor. Materials and methods. Preparation of DNA adduct with cisplatin. dsDNA was modified in the presence NaClO4 by cisplatin for in the dark of a thermostatic box. Purification of DNA adduct. The obtained DNA adduct was purified by ultrafiltration. Preparation of biosensor. Metallothionein modified surface of hanging mercury drop electrode was used as a platinum biosensor. The platinum and Pt-DNA adduct were detected by adsorptive transfer stripping (AdTS) differential pulse voltammetry (DPV). AdTS DPV parameters: time of accumulation 240 s, time of interaction 400 s. Results. Here we studied a binding of different platinum based cytostatics (cisplatin, carboplatin and oxaliplatin) to genome DNA. The influence of concentration of DNA, temperature and ionic strength on yield of adducts has been described. Consequently, we used the suggested heavy metal biosensor to detection of platinum modified DNA. We found out that the highest yield of Pt-DNA adducts has been obtained, if we used 100 mg/ml DNA at temperature 37 C for 24 h, because the yield of the modification was very low up to 10 h. In addition, increasing ionic strength negatively influenced yield of the modification. We were able to analyse tens of nanograms of Pt-DNA adduct per millilitre using the biosensor. Conclusions. The suggested approach shows the possible way for simple, sensitive, and rapid detection and determination of cisplatin and Pt-DNA adducts. In addition, the biosensor could be applied to study of binding of platinum to DNA structure.

Abstract

Introduction. Although platinum based cytostatic drugs have been successfully used in the chemotherapy of cancer for more than 30 years, its biochemical mechanism of action is still unclear. The current accepted opinion about cisplatin mechanism of action is that the drug induces its cytotoxic properties through binding to the nuclear DNA and subsequent interference with normal transcription, and/or DNA replication mechanisms. Objective. The aim of this paper was to study of binding of platinum cytostatic to DNA structure using of platinum biosensor. Materials and methods. Preparation of DNA adduct with cisplatin. dsDNA was modified in the presence NaClO4 by cisplatin for in the dark of a thermostatic box. Purification of DNA adduct. The obtained DNA adduct was purified by ultrafiltration. Preparation of biosensor. Metallothionein modified surface of hanging mercury drop electrode was used as a platinum biosensor. The platinum and Pt-DNA adduct were detected by adsorptive transfer stripping (AdTS) differential pulse voltammetry (DPV). AdTS DPV parameters: time of accumulation 240 s, time of interaction 400 s. Results. Here we studied a binding of different platinum based cytostatics (cisplatin, carboplatin and oxaliplatin) to genome DNA. The influence of concentration of DNA, temperature and ionic strength on yield of adducts has been described. Consequently, we used the suggested heavy metal biosensor to detection of platinum modified DNA. We found out that the highest yield of Pt-DNA adducts has been obtained, if we used 100 mg/ml DNA at temperature 37 C for 24 h, because the yield of the modification was very low up to 10 h. In addition, increasing ionic strength negatively influenced yield of the modification. We were able to analyse tens of nanograms of Pt-DNA adduct per millilitre using the biosensor. Conclusions. The suggested approach shows the possible way for simple, sensitive, and rapid detection and determination of cisplatin and Pt-DNA adducts. In addition, the biosensor could be applied to study of binding of platinum to DNA structure.

Abstract (in Czech)
Studium interakcí nukleových kyselin a platinových cytostatik s použitím biosenzoru

Links
GP525/04/P132, research and development project	Name: Studium obranných mechanismů rostlin při stresu způsobeném těžkými kovy
MSM0021622412, plan (intention)	Name: Interakce mezi chemickými látkami, prostředím a biologickými systémy a jejich důsledky na globální, regionální a lokální úrovni (INCHEMBIOL) (Acronym: INCHEMBIOL)
MSM0021622412, plan (intention)	Investor: Ministry of Education, Youth and Sports of the CR, Interactions among the chemicals, environment and biological systems and their consequences on the global, regional and local scales (INCHEMBIOL)