Transformation and the History of Philosophy

From ancient conceptions of becoming a philosopher to modern discussions of psychedelic drugs, the concept of transformation plays a fascinating part in the history of philosophy. However, until now there has been no sustained exploration of the full extent of its role. Transformation and the History of Philosophy is an outstanding survey of the history, nature, and development of the idea of transformation, from the ancient period to the twentieth century. Comprising twenty-two specially commissioned chapters by an international team of contributors, the volume is divided into four clear parts: - Philosophy as Transformative: Ancient China, Greece, India, and Rome - Transformation Between the Human and the Divine: Medieval and Early Modern Philosophy - Transformation After the Copernican Revolution: Post-Kantian Philosophy - Treatises, Pregnancies, Psychedelics, and Epiphanies: Twentieth-Century Philosophy. Each of these sections begins with an introduction by the editors. Transformation and the History of Philosophy is essential reading for students and researchers in the history of western and non-western philosophy, ethics, metaphysics, and aesthetics. It will also be extremely useful for those in related disciplines such as religion, sociology, and the history of ideas

Understanding the retinal basis of vision across species

The vertebrate retina first evolved some 500 million years ago in ancestral marine chordates. Since then, the eyes of different species have been tuned to best support their unique visuoecological lifestyles. Visual specializations in eye designs, large-scale inhomogeneities across the retinal surface and local circuit motifs mean that all species' retinas are unique. Computational theories, such as the efficient coding hypothesis, have come a long way towards an explanation of the basic features of retinal organization and function; however, they cannot explain the full extent of retinal diversity within and across species. To build a truly general understanding of vertebrate vision and the retina's computational purpose, it is therefore important to more quantitatively relate different species' retinal functions to their specific natural environments and behavioural requirements. Ultimately, the goal of such efforts should be to build up to a more general theory of vision

Impact of heme to protein linkages in peroxidases on redox chemistry and catalysis

The mammalian peroxidases participate in host defence against infection, hormone synthesis and pathogenesis. The most striking feature of these heme enzymes is the existence of two covalent ester bonds between the prosthetic group and the protein in the functional, mature proteins. Myeloperoxidase is unique in having an additional vinyl-sulfonium bond. The impact of heme distortion and asymmetry on the spectral and enzymatic properties is discussed as is the role of the MPO-typical electron withdrawing sulfonium ion linkage in raising the reduction potential of its redox intermediatesand maintaining a rigid solvent network at the distal heme cavity

Redox thermodynamics of lactoperoxidase and eosinophil peroxidase

Eosinophil peroxidase (EPO) and lactoperoxidase (LPO) are important constituents of the innate immunesystem of mammals. These heme enzymes belong to the peroxidase-cyclooxygenase superfamily and catalyzethe oxidation of thiocyanate, bromide and nitrite to hypothiocyanate, hypobromous acid and nitrogendioxide that are toxic for invading pathogens. In order to gain a better understanding of the observeddifferences in substrate specificity and oxidation capacity in relation to heme and protein structure, acomprehensive spectro-electrochemical investigation was performed. The reduction potential (E0) ofthe Fe(III)/Fe(II) couple of EPO and LPO was determined to be 126 mV and 176 mV, respectively(25 C, pH 7.0). Variable temperature experiments show that EPO and LPO feature different reductionthermodynamics. In particular, reduction of ferric EPO is enthalpically and entropically disfavored,whereas in LPO the entropic term, which selectively stabilizes the oxidized form, prevails on the enthalpicterm that favors reduction of Fe(III). The data are discussed with respect to the architecture of theheme cavity and the substrate channel. Comparison with published data for myeloperoxidase demonstratesthe effect of heme to protein linkages and heme distortion on the redox chemistry of mammalianperoxidases and in consequence on the enzymatic properties of these physiologically importantoxidoreductases

Intracellular catalase/peroxidase from the phytopathogenic rice blast fungus Magnaporthe grisea: expression analysis and biochemical characterization of the recombinant protein

Phytopathogenic fungi such as the rice blast fungus Magnaporthegrisea are unique in having two catalase/peroxidase (KatG)paralogues located either intracellularly (KatG1) or extracellularly(KatG2). The coding genes have recently been shownto derive from a lateral gene transfer from a (proteo)bacterialgenome followed by gene duplication and diversification. Here wedemonstrate thatKatG1 is expressed constitutively in M. grisea. Itis the first eukaryotic catalase/peroxidase to be expressed heterologouslyin Escherichia coli in high amounts, with high purity andwith almost 100% haem occupancy. Recombinant MagKatG1is an acidic, mainly homodimeric, oxidoreductase with a predominantfive-co-ordinated high-spin haem b. At 25◦C andpH 7.0, the E0 (standard reduction potential) of the Fe(III)/Fe(II)couple was found to be −186+−10 mV. It bound cyanidemonophasically with an apparent bimolecular rate constant of(9.0+−0.4)×105 M−1 · s−1 at pH 7.0 and at 25◦C and with aKd value of 1.5 μM. Its predominantly catalase activity wascharacterized by a pH optimum at 6.0 and kcat and Km valuesof 7010 s−1 and 4.8 mM respectively. In addition, it acts as aversatile peroxidase with a pH optimum in the range 5.0–5.5using both one-electron [2,2-azinobis-(3-ethylbenzothiazoline-6-sulfonic acid) o-dianisidine, pyrogallol or guaiacol] andtwo-electron (Br−, I− or ethanol) donors. Structure–functionrelationships are discussed with respect to data reported forprokaryotic KatGs, as is the physiological role of MagKatG1.Phylogenetic analysis suggests that (intracellular) MagKatG1 canbe regarded as a typical representative for catalase/peroxidase ofboth phytopathogenic and saprotrophic fungi

Redox thermodynamics of the Fe3+/Fe2+ couple in wild type and mutated heme peroxidases

The thermodynamics of the one-electron reduction of the ferricheme in wild-type and mutated heme Synechocystis catalaseperoxidase and human myeloperoxidase were determined through spectro-electrochemical experiments. The data are interpreted in terms of ligand binding features, electrostatic effects and solvation properties of the heme environment

Influence of the Covalent Heme 12Protein Bonds on the RedoxThermodynamics of Human Myeloperoxidase

Myeloperoxidase (MPO) is the most abundant neutrophil enzyme and catalyzes predominantly the twoelectron oxidation of ubiquitous chloride to generate the potent bleaching hypochlorous acid, thus contributing to pathogen killing as well as inflammatory diseases. Its catalytic properties are closely related with unique posttranslational modifications of its prosthetic group. In MPO, modified heme b is covalently bound to the protein via two ester linkages and one sulfonium ion linkage with a strong impact on its(electronic) structure and biophysical and chemical properties.Here, the thermodynamics of the one-electron reduction of the ferric heme in wild-type recombinant MPO and variants withdisrupted heme 12protein bonds (M243V, E242Q, and D94V) have been investigated by thin-layer spectroelectrochemistry. Itturns out that neither the oligomeric structure nor the N-terminal extension in recombinant MPO modifies the peculiar positivereduction potential (E\ub0\u2032 = 0.001 V at 25 \ub0C and pH 7.0) or the enthalpy or entropy of the Fe(III) to Fe(II) reduction. Bycontrast, upon disruption of the MPO 12typical sulfonium ion linkage, the reduction potential is significantly lower ( 120.182 V).The M243V mutant has an enthalpically stabilized ferric state, whereas its ferrous form is entropically favored because of the loss of rigidity of the distal H-bonding network. Exchange of an adjacent ester bond (E242Q) induced similar but less pronouncedeffects (E\ub0\u2032 = 120.094 V), whereas in the D94V variant (E\ub0\u2032 = 120.060 V), formation of the ferrous state is entropically disfavored.These findings are discussed with respect to the chlorination and bromination activity of the wild-type protein and the mutants

Visual Stimulation Switches the Polarity of Excitatory Input to Starburst Amacrine Cells

International audienceDirection-selective ganglion cells (DSGCs) are tuned to motion in one direction. Starburst amacrine cells (SACs) are thought to mediate this direction selectivity through precise anatomical wiring to DSGCs. Nevertheless, we previously found that visual adaptation can reverse DSGCs's directional tuning, overcoming the circuit anatomy. Here we explore the role of SACs in the generation and adaptation of direction selectivity. First, using pharmacogenetics and twophoton calcium imaging, we validate that SACs are necessary for direction selectivity. Next, we demonstrate that exposure to an adaptive stimulus dramatically alters SACs' synaptic inputs. Specifically, after visual adaptation, On-SACs lose their excitatory input during light onset but gain an excitatory input during light offset. Our data suggest that visual stimulation alters the interactions between rod-and cone-mediated inputs that converge on the terminals of On-cone BCs. These results demonstrate how the sensory environment can modify computations performed by anatomically defined neuronal circuits

Visual stimulation switches the polarity of excitatory input to starburst amacrine cells.

Direction-selective ganglion cells (DSGCs) are tuned to motion in one direction. Starburst amacrine cells (SACs) are thought to mediate this direction selectivity through precise anatomical wiring to DSGCs. Nevertheless, we previously found that visual adaptation can reverse DSGCs's directional tuning, overcoming the circuit anatomy. Here we explore the role of SACs in the generation and adaptation of direction selectivity. First, using pharmacogenetics and two-photon calcium imaging, we validate that SACs are necessary for direction selectivity. Next, we demonstrate that exposure to an adaptive stimulus dramatically alters SACs' synaptic inputs. Specifically, after visual adaptation, On-SACs lose their excitatory input during light onset but gain an excitatory input during light offset. Our data suggest that visual stimulation alters the interactions between rod- and cone-mediated inputs that converge on the terminals of On-cone BCs. These results demonstrate how the sensory environment can modify computations performed by anatomically defined neuronal circuits