α-OXIDASE ACTIVITY IN PLANTS AS PROMOTOR OF ELECTRONIC ENERGY

Abstract The a-oxidase activity of higher plants acting on long chain fatty acids generates the lower aldehyde in the ground state; however if chlorophyll or chioroplasts are present the chlorophylls are excited most likely by a chemically initiated electron exchange (CIEEL) luminescence process with the putative a-peroxylactone intermediate. When the aldehyde is substituted for the acid, the lower aldehyde appears in the triplet state. The chiral discrimination observed in the quenching by D- and L-tryptophan of the chlorophyll sensitized emission indicates that the triplet aldehyde is generated within the enzymatic preparation and transfers energy while still bound to the enzyme.
Chlorophylls in chioroplasts are excited by addition of a long chain fatty acid or aldehyde. The mechanism, however, is unknown.     

EXCITATION OF MESOPHYLL AND BUNDLE SHEATH CHLOROPLASTS OF Atriplex repanda IN THE ABSENCE OF LIGHT

Abstract— Mesophyll and bundle sheath chloroplasts isolated from Atriplex repanda cells promote oxygen consumption by isobutyraldehyde or phenylacetaldehyde. In all cases, a red emission and reduction of tetrazolium blue was observed. Addition of horseradish peroxidase greatly increases the reduction of the dye. In the presence of 3-(3, 4-dichlorophenyl)-1, 1-dimethylurea, the reduction of the Hill acceptor was fully suppressed. This suppression was abolished when 2, 6-dichlorophenolindophenol and ascorbate were added to the systems. These results indicate that, in mesophyll and bundle sheath chloroplasts, chlorophylls can be efficiently excited in the absence of light and an electron flow through the photosystems can be promoted.     

CHEMIEXCITATION IN THE ARACHIDONIC ACID CASCADE

As investigated in neutrophils, the very weak luminescence accompanying the arachidonic acid cascade is associated with the lipoxygenase pathway. The emission is dramatically enhanced by energy transfer to chlorophyll a. The number of chlorophyll molecules excited to the fluorescent state per oxygen consumed, (the S1/O2 ratio), equal to the product of the quantum yields of chemiexcitation and of energy transfer, is 5.4 x 10(-6). The quantum yield of chemiexcitation is inferred to be higher than 1 x 10(-3). The two most likely chemiexcitation routes point to triplet conjugated carbonyls as the most likely candidates for the excited species that transfer to chlorophyll. As such the emission intensity may reflect the level of hydroperoxyeicosatetraenoic acid. This is the first case where addition of a biotic substrate to a cellular system results in substantial generation of electronic excited states without any drastic loss of cell viability. Whether the formation of excited states in the arachidonic acid cascade in neutrophils is accidental or has a biological role is an open question.     

机械泵驱动两相回路的实时动态模型分析

在航空航天领域,为了加速系统设计及测试进度,通常需要进行半实物实时仿真,即控制器用实物,受控对象采用数学模型。本文开发出了基于Matlab/Simulink的两相传热模块,并用其搭建了某机械泵驱动两相回路的实时动态模型。通过与实验的对比,验证了模型的可靠性,表明该模型满足实时要求,可以在下一步用于半实物仿真。     

HEAVY ATOM PERTURBATION IN MOLECULES RELATED TO THYROXINE

En conección con la perturbación producida en las hormonas tiroideas y moléculas asociadas, por el átomo pesado iodo; se ha investigado el espectro de absorción singulete-triplete de la p—benzoquinona (max = 539 nm) cuando se la sustituye en la posicién 2–6 con el dihalógeno. En oposición a los resultados reportados por Kuboyama, no se observaun cambio en la intensidad cuando se sustituyen dos átomos de cloro. La ausencia de acomplamiento spin-órbita se ve confirmada por la pequen?a intensificación de la absorción cuando los átomos sustituidos son bromo o iodo, y probablemente está conectada con el caracter n→π* de la transición. Algo sorpresivamente. la sustitución de dos átomos de iodo produce un marcado efecto batocromico cerca de donde esta localizada la transición singulete- triplete, aproximadamente encima de los 600 nm.     

EXCITATION OF CHLOROPLASTS IN Euglena gracilis IN THE ABSENCE OF LIGHT

Abstract— Challenging Euglena gracilis —a unicellular microorganism that contains chloroplasts—with phenylacetaldehyde induces malondialdehyde formation, sustained red emission and Hill activity. In chloroplasts, phenylacetaldehyde appears to undergo peroxidase catalyzed oxidation to formic acid and triplet benzaldehyde; the latter or, less likely, a precursor thereof promotes lipid peroxidation. Triplet benzaldehyde and/or the excited species formed in lipid peroxidation transfer energy to the chlorophylls. This explanation also applies to spinach chloroplasts preparations, thus accounting for the previous unexplained observation that phenylacetaldehyde induced sustained red emission and Hill activity. A homogeneous picture is now available regarding the intracellular generation of excited states and concomitant excitation of built-in structures.