UV protection of euglenoids: computation of the electromagnetic response

Euglenoids are a group of predominantly free-living unicellular microorganisms that mostly live in freshwater bodies but can also be found in marine and brackish waters. These organisms have a characteristic that distinguishes them form the other protists: they are covered by a surface pellicle formed by S-shaped overlapping bands which resemble a diffraction grating. These microorganisms have developed numerous protection mechanisms intended to avoid or reduce the damage produced by UV radiation, such as the production of pigments and the repair mechanisms in hours of darkness and during daylight. In a recent paper we have investigated the role played by the pellicle of Euglenoids in the protection of the cell against UV radiation, by means of an electromagnetic approach based on the approximation of the pellicle profile by a one-dimensional diffraction grating. This simplified model allowed us to confirm that under certain incidence conditions, the corrugation of the pellicle helps increase the UV reflection, and consequently, diminish the UV radiation that enters the cell. In order to analyze the electromagnetic response of the whole cell, we extend two different approaches to calculate the reflected response: a simulation method especially developed to deal with complex biological structures that permits the introduction of the scattering object via an electron microscopy image, and the integral method, which has been widely used to compute the electromagnetic response of finite structures. Numerical results of near and far fields are shown.

[1]  W. Steen Absorption and Scattering of Light by Small Particles , 1999 .

[2]  A. Dolinko,et al.  Enhanced method for determining the optical response of highly complex biological photonic structures. , 2013, Journal of the Optical Society of America. A, Optics, image science, and vision.

[3]  John B. Shoven,et al.  I , Edinburgh Medical and Surgical Journal.

[4]  木下 修一,et al.  Structural colors in the realm of nature , 2008 .

[5]  Marina E. Inchaussandague,et al.  Electromagnetic response of the protective pellicle of different unicellular microalgae , 2014, Smart Structures.

[6]  Mohan Srinivasarao,et al.  Nano‐Optics in the Biological World: Beetles, Butterflies, Birds, and Moths , 1999 .

[7]  N. Ekelund Interactions between photosynthesis and 'light-enhanced dark respiration' (LEDR) in the flagellate Euglena gracilis after irradiation with ultraviolet radiation. , 2000, Journal of photochemistry and photobiology. B, Biology.

[8]  D. Hanelt,et al.  Effects of ultraviolet radiation on photosynthesis and related enzyme reactions of marine macroalgae , 2000, Planta.

[9]  Dennis Saleh Zs , 2001 .

[10]  Andrew R. Parker,et al.  515 million years of structural colour , 2000 .

[11]  A. Dolinko From Newton's second law to Huygens's principle: visualizing waves in a large array of masses joined by springs , 2009 .

[12]  Jean-Pol Vigneron,et al.  Photonic crystal type structures of biological origin: Structural and spectral characterization , 2006 .

[13]  T. McMeekin,et al.  Effect of uv-b on lipid content of three antarctic marine phytoplankton , 1998 .

[14]  J. L. Pérez-Lloréns,et al.  The changing irradiance environment: consequences for marine macrophyte physiology, productivity and ecology , 1998 .

[15]  D. Karentz,et al.  Survey of mycosporine-like amino acid compounds in Antarctic marine organisms: Potential protection from ultraviolet exposure , 1991 .

[16]  P. Jokiel,et al.  Importance of ultraviolet radiation in photoinhibition of microalgal growth1 , 1984 .

[17]  L. Biró,et al.  Optical structure and function of the white filamentary hair covering the edelweiss bracts. , 2005, Physical review. E, Statistical, nonlinear, and soft matter physics.

[18]  J. Sambles,et al.  Photonic structures in biology , 2003, Nature.