Belinda S. W. Chang scite author profile

Significance The molecular basis of morphological and physiological adaptations in snakes is largely unknown. Here, we study these phenotypes using the genome of the Burmese python ( Python molurus bivittatus ), a model for extreme phenotypic plasticity and metabolic adaptation. We discovered massive rapid changes in gene expression that coordinate major changes in organ size and function after feeding. Many significantly responsive genes are associated with metabolism, development, and mammalian diseases. A striking number of genes experienced positive selection in ancestral snakes. Such genes were related to metabolism, development, lungs, eyes, heart, kidney, and skeletal structure—all highly modified features in snakes. Snake phenotypic novelty seems to be driven by the system-wide coordination of protein adaptation, gene expression, and changes in genome structure.

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Retinal counterion switch in the photoactivation of the G protein-coupled receptor rhodopsin

Yan

Kazmi²,

Ganim³

et al. 2003

Proc. Natl. Acad. Sci. U.S.A.

206

279

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The biological function of Glu-181 in the photoactivation process of rhodopsin is explored through spectroscopic studies of site-specific mutants. Preresonance Raman vibrational spectra of the unphotolyzed E181Q mutant are nearly identical to spectra of the native pigment, supporting the view that Glu-181 is uncharged (protonated) in the dark state. The pH dependence of the absorption of the metarhodopsin I (Meta I)-like photoproduct of E181Q is investigated, revealing a dramatic shift of its Schiff base pKa compared with the native pigment. This result is most consistent with the assignment of Glu-181 as the primary counterion of the retinylidene protonated Schiff base in the Meta I state, implying that there is a counterion switch from Glu-113 in the dark state to Glu-181 in Meta I. We propose a model where the counterion switch occurs by transferring a proton from Glu-181 to Glu-113 through an H-bond network formed primarily with residues on extracellular loop II (EII). The resulting reorganization of EII is then coupled to movements of helix III through a conserved disulfide bond (Cys110 -Cys187); this process may be a general element of G proteincoupled receptor activation.

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Function of Extracellular Loop 2 in Rhodopsin: Glutamic Acid 181 Modulates Stability and Absorption Wavelength of Metarhodopsin II

et al. 2002

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The second extracellular loop of rhodopsin folds back into the membrane-embedded domain of the receptor to form part of the binding pocket for the 11-cis-retinylidene chromophore. A carboxylic acid side chain from this loop, Glu181, points toward the center of the retinal polyene chain. We studied the role of Glu181 in bovine rhodopsin by characterizing a set of site-directed mutants. Sixteen of the 19 single-site mutants expressed and bound 11-cis-retinal to form pigments. The lambda(max) value of mutant pigment E181Q showed a significant spectral red shift to 508 nm only in the absence of NaCl. Other substitutions did not significantly affect the spectral features of the mutant pigments in the dark. Thus, Glu181 does not contribute significantly to spectral tuning of the ground state of rhodopsin. The most likely interpretation of these data is that Glu181 is protonated and uncharged in the dark state of rhodopsin. The Glu181 mutants displayed significantly increased reactivity toward hydroxylamine in the dark. The mutants formed metarhodopsin II-like photoproducts upon illumination but many of the photoproducts displayed shifted lambda(max) values. In addition, the metarhodopsin II-like photoproducts of the mutant pigments had significant alterations in their decay rates. The increased reactivity of the mutants to hydroxylamine supports the notion that the second extracellular loop prevents solvent access to the chromophore-binding pocket. In addition, Glu181 strongly affects the environment of the retinylidene Schiff base in the active metarhodopsin II photoproduct.

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Belinda S. W. Chang

The Burmese python genome reveals the molecular basis for extreme adaptation in snakes

Retinal counterion switch in the photoactivation of the G protein-coupled receptor rhodopsin

Function of Extracellular Loop 2 in Rhodopsin: Glutamic Acid 181 Modulates Stability and Absorption Wavelength of Metarhodopsin II

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