The Spectrochemical Characterization of Novel Vis-NIR Fluorescence Dyes and Developing a Laser Induced Fluorescence Capillary Zone Electrophoresis (LIF-CZE) Technique to Study Alkanesulfonate Monooxygenase

Beckford, Garfield

12 August 2014

A new Laser Induced Fluorescence Capillary Zone Electrophoresis (LIF-CZE) bioassay to detect and study the catalytic activity of the sulfur assimilating enzyme commonly found in E. coli species; alkanesulfonate monooxygenase (EC 1.14.14.5) is described for the first time. This technique enables the possibility for direct injection onto a capillary for detection without the need for pre-concentration of sample and with minimal sample preparative steps prior to analysis. In this bioassay, a group of Fischer based cyanine dyes and two Oxazine (Nile red) derivatives were designed for further optimization as key Vis-NIR fluorescent substrate. In developing this technique, the test dyes were first assessed for their photophysical properties, based on four criteria; (1) photostable (2) solvatochromism (3) binding affinity towards both the monooxygenase active site and serum albumin and (4) chemical stability in strong electric field strength. Applying key dye characterization procedures including; molar absorptivity determination, quantum yield determination, photostability, solvatochromism and protein interaction studies it was determined that the Fischer indolium cyanine dyes were most suitable for the method development. The data revealed that under the test conditions, reduced flavin, the oxidative monooxygenase catalytically specifically converts the alkylsulfonate substituted cyanine dyes to the corresponding aldehyde. This new bioassay has proven to be quick, portable, sensitive, reliable and the exhibit the possibility of ‘on-the-spot’ detection; advantages not readily realized with other commonly applied techniques such as PCR, SPR, ELISA and GC used to study bacterial sulfur assimilation processes. In addition, recent literature results proposed by other research groups developing similar techniques showed strong reliance on GC analyses. Those assays involve the use of low molecular weight straight chain non-emissive alkanesulfonate substrates. Once enzyme catalysis occurs the aldehyde is formed becomes rather volatile and requires complex and tedious headspace sampling for GC analyses. This feature limits the in vitro applicability and eliminated the possibility in vivo development. Our goal is to further develop, optimize and present this CZE based bioassay as a suitable alternative to the current trends in the field while creating a more robust and sensitive in vitro monooxygenase detection method with the possibilities of in vivo application.

Human Serum Albumin (HSA)

Steric specificity

Solvatochromism

Riboflavin mononucleotide

Alkanesulfonate monooxygenase.

Quantum Chemical Studies of Protein-Bound Chromophores, UV-Light Induced DNA Damages, and Lignin Formation

Durbeej, Bo

January 2004

<p>Quantum chemical methods have been used to provide a better understanding of the photochemistry of astaxanthin and phytochromobilin; the photoenzymic repair of UV-light induced DNA damages; and the formation of lignin. </p><p>The carotenoid astaxanthin (AXT) is responsible for the colouration of lobster shell. In solution, the electronic absorption spectra of AXT peak in the 470-490 nm region, corresponding to an orange-red colouration. Upon binding to the lobster-shell protein-complex α-crustacyanin, the absorption maximum is shifted to 632 nm, yielding a slate-blue colouration. Herein, the structural origin of this bathochromic shift is investigated on the basis of recent experimental work.</p><p>The tetrapyrrole phytochromobilin (PΦB) underlies the photoactivation of the plant photoreceptor phytochrome. Upon absorption of 660-nm light, PΦB isomerizes from a C15-<i>Z,syn</i> configuration (in the inactive form of the protein) to C15-<i>E,anti</i> (in the active form). In this work, a reaction mechanism for this isomerization is proposed. </p><p>DNA photolyases are enzymes that repair DNA damages resulting from far-UV-light induced [2+2] cycloaddition reactions involving pyrimidine nucleobases. The catalytic activity of these enzymes is initiated by near-UV and visible light, and is governed by electron transfer processes between a catalytic cofactor of the enzyme and the DNA lesions. Herein, an explanation for the experimental observation that the repair of cyclobutane pyrimidine dimers (CPD) – the major type of lesion – proceeds by electron transfer from the enzyme to the dimer is presented. Furthermore, the formation of CPD is studied.</p><p>Lignin is formed by dehydrogenative polymerization of hydroxycinnamyl alcohols. A detailed understanding of the polymerization mechanism and the factors controlling the outcome of the polymerization is, however, largely missing. Quantum chemical calculations on the initial dimerization step have been performed in order to gain some insight into these issues.</p>

Quantum chemistry

quantum chemistry

calculations

density functional theory

excited states

photochemistry

chromophores

absorption spectra

bathochromic shift

isomerization

UV radiation

DNA damages

cycloaddition reactions

photoenzymic repair

electron transfer

lignin

polymerization

phenoxy radicals

dilignols

Kvantkemi

Quantum chemistry

Kvantkemi

Quantum Chemical Studies of Protein-Bound Chromophores, UV-Light Induced DNA Damages, and Lignin Formation

Durbeej, Bo

January 2004

Quantum chemical methods have been used to provide a better understanding of the photochemistry of astaxanthin and phytochromobilin; the photoenzymic repair of UV-light induced DNA damages; and the formation of lignin. The carotenoid astaxanthin (AXT) is responsible for the colouration of lobster shell. In solution, the electronic absorption spectra of AXT peak in the 470-490 nm region, corresponding to an orange-red colouration. Upon binding to the lobster-shell protein-complex α-crustacyanin, the absorption maximum is shifted to 632 nm, yielding a slate-blue colouration. Herein, the structural origin of this bathochromic shift is investigated on the basis of recent experimental work. The tetrapyrrole phytochromobilin (PΦB) underlies the photoactivation of the plant photoreceptor phytochrome. Upon absorption of 660-nm light, PΦB isomerizes from a C15-Z,syn configuration (in the inactive form of the protein) to C15-E,anti (in the active form). In this work, a reaction mechanism for this isomerization is proposed. DNA photolyases are enzymes that repair DNA damages resulting from far-UV-light induced [2+2] cycloaddition reactions involving pyrimidine nucleobases. The catalytic activity of these enzymes is initiated by near-UV and visible light, and is governed by electron transfer processes between a catalytic cofactor of the enzyme and the DNA lesions. Herein, an explanation for the experimental observation that the repair of cyclobutane pyrimidine dimers (CPD) – the major type of lesion – proceeds by electron transfer from the enzyme to the dimer is presented. Furthermore, the formation of CPD is studied. Lignin is formed by dehydrogenative polymerization of hydroxycinnamyl alcohols. A detailed understanding of the polymerization mechanism and the factors controlling the outcome of the polymerization is, however, largely missing. Quantum chemical calculations on the initial dimerization step have been performed in order to gain some insight into these issues.

Quantum chemistry

quantum chemistry

calculations

density functional theory

excited states

photochemistry

chromophores

absorption spectra

bathochromic shift

isomerization

UV radiation

DNA damages

cycloaddition reactions

photoenzymic repair

electron transfer

lignin

polymerization

phenoxy radicals

dilignols

Kvantkemi

Quantum chemistry

Kvantkemi