Ultrafast Spectroscopic Studies on the Interaction of a Potential Food Carcinogen with Biologically Relevant Macromolecules

Soma Banerjee, Siddhi Chaudhuri, S. Pal
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Abstract

Benzo[a]pyrene (BP), a potential carcinogen in a class of pyrene derivatives shows interesting photophysics including very sharp vibronic structures in the emission spectrum. A detail spectroscopic study on the close interaction of the carcinogenic molecule with other biologically relevant macromolecules through ultrafast energy/charge transfer reactions is the motive of the present review. Firstly, we present our picosecond resolved studies on the Forster resonance energy transfer (FRET) from various vibronic bands in BP, showing strong dependency on the spectral overlap of an energy acceptor in a confined environment. Our study on the dipolar interactions between BP and different acceptors ethidium (Et), acridine orange (AO) and crystal violet (CV) at the surface of a model anionic micelle reveals the Forster distance (R0) and the rate of energy transfer to be dependent on the individual spectral overlap of the vibronic bands of BP with the absorption spectra of different energy acceptors. The differential behaviour of the vibronic bands is compared with that of different dyes (quantum dots; QDs) in a ‘dye-blend’ (mixture) under FRET to an energy acceptor. Such comparison of the FRET of QDs with that of BP, not only confirms independent nature of dipolar interaction of the vibronic bands with other organic molecules, the use of deconvolution technique in the interpretation of the donor-acceptor (D-A) distance has also been justified. We have also shown that consideration of differential FRET from vibronic bands of BP and from the QDs in the ‘dye-blend’ is equally acceptable in the theoretical frameworks including ‘Infelta-Tachiya’ model and D-A distribution analysis in the nano-environments. While such energy transfer reactions act as “spectroscopic ruler” to measure the distance between two sites on a macromolecule, reactions involving electron transfer (ET)/charge transfer (CT) and reactive oxygen species (ROS) play a pivotal role in carcinogenesis and cancer biochemistry. The review further emphasizes our studies on UVA radiation induced ET reaction as one of the key aspects of BP in the presence of a wide variety of molecules covering organic para-benzoquinone (BQ), biological macromolecules like calf-thymus DNA (CT-DNA), human serum albumin (HSA) protein and inorganic zinc oxide (ZnO) nanorods (NRs). Steady-state and picosecond-resolved fluorescence spectroscopy have been used to monitor such ET reactions. Physical consequences of BP association with CT-DNA have been investigated through temperature-dependent circular dichroism (CD) spectroscopy. The temperature-dependent steady-state, picosecond-resolved fluorescence lifetime and anisotropy studies reveal the effect of temperature on the perturbation of such ET reactions from BP to biological macromolecules, highlighting their temperature-dependent association. Furthermore, the electron donating property of BP has been corroborated by measuring wavelength-dependent photocurrent in a BP-anchored ZnO NR-based photodevice, offering new physical insights for the carcinogenic study of BP
一种潜在食品致癌物与生物相关大分子相互作用的超快光谱研究
苯并[a]芘(BP)是一类芘衍生物中的潜在致癌物,在发射光谱中表现出有趣的光物理现象,包括非常尖锐的振动结构。对致癌分子与其他生物相关大分子通过超快能量/电荷转移反应密切相互作用的详细光谱研究是本综述的动机。首先,我们对BP中不同振动带的福斯特共振能量转移(FRET)进行了皮秒分辨率的研究,显示出在受限环境中能量受体的光谱重叠有很强的依赖性。我们研究了BP与不同受体乙啶(Et)、吖啶橙(AO)和结晶紫(CV)在模型阴离子胶束表面的偶极相互作用,揭示了BP与不同能量受体的吸收光谱的共振带重叠程度决定了BP的福斯特距离(R0)和能量转移速率。比较了不同染料(量子点;在FRET下的“染料混合”(混合物)中的量子点到能量受体。这种量子点的FRET与BP的比较,不仅证实了振动带与其他有机分子的偶极相互作用的独立性,而且在解释供体-受体(D-A)距离时使用反褶积技术也是合理的。我们还表明,在包括“Infelta-Tachiya”模型和纳米环境中的D-A分布分析在内的理论框架中,考虑BP的振动带和“染料-共混物”中的量子点的微分FRET是同样可以接受的。虽然这种能量转移反应是测量大分子上两个位点之间距离的“光谱标尺”,但涉及电子转移(ET)/电荷转移(CT)和活性氧(ROS)的反应在致癌和癌症生物化学中起着关键作用。本文进一步强调了在有机对苯醌(BQ)、小牛胸腺DNA (CT-DNA)、人血清白蛋白(HSA)蛋白和无机氧化锌(ZnO)纳米棒(NRs)等生物大分子存在的情况下,UVA辐射诱导的ET反应是BP的关键方面之一。稳态和皮秒分辨荧光光谱已被用于监测这种ET反应。通过温度依赖性圆二色(CD)光谱研究了BP与CT-DNA关联的物理后果。温度依赖的稳态、皮秒分辨率荧光寿命和各向异性研究揭示了温度对从BP到生物大分子的ET反应的扰动的影响,突出了它们的温度依赖关系。此外,通过测量BP锚定ZnO nr基光器件的波长依赖性光电流,证实了BP的给电子特性,为BP的致癌研究提供了新的物理见解
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