These tools will no longer be maintained as of December 31, 2024. Archived website can be found here. PubMed4Hh GitHub repository can be found here. Contact NLM Customer Service if you have questions.
227 related articles for article (PubMed ID: 33481002)
21. Molecular evolution and depth-related adaptations of rhodopsin in the adaptive radiation of cichlid fishes in Lake Tanganyika. Ricci V; Ronco F; Musilova Z; Salzburger W Mol Ecol; 2022 May; 31(10):2882-2897. PubMed ID: 35302684 [TBL] [Abstract][Full Text] [Related]
23. Vertebrate rhodopsin adaptation to dim light via rapid meta-II intermediate formation. Sugawara T; Imai H; Nikaido M; Imamoto Y; Okada N Mol Biol Evol; 2010 Mar; 27(3):506-19. PubMed ID: 19858068 [TBL] [Abstract][Full Text] [Related]
24. Spectral-tuning mechanisms of marine mammal rhodopsins and correlations with foraging depth. Fasick JI; Robinson PR Vis Neurosci; 2000; 17(5):781-8. PubMed ID: 11153657 [TBL] [Abstract][Full Text] [Related]
25. Functional characterization of the rod visual pigment of the echidna (Tachyglossus aculeatus), a basal mammal. Bickelmann C; Morrow JM; Müller J; Chang BS Vis Neurosci; 2012 Sep; 29(4-5):211-7. PubMed ID: 22874131 [TBL] [Abstract][Full Text] [Related]
26. Convergent selection pressures drive the evolution of rhodopsin kinetics at high altitudes via nonparallel mechanisms. Castiglione GM; Schott RK; Hauser FE; Chang BSW Evolution; 2018 Jan; 72(1):170-186. PubMed ID: 29143302 [TBL] [Abstract][Full Text] [Related]
27. High molecular diversity in the rhodopsin gene in closely related goby fishes: A role for visual pigments in adaptive speciation? Larmuseau MH; Huyse T; Vancampenhout K; Van Houdt JK; Volckaert FA Mol Phylogenet Evol; 2010 May; 55(2):689-98. PubMed ID: 19822217 [TBL] [Abstract][Full Text] [Related]
28. Evolution of nonspectral rhodopsin function at high altitudes. Castiglione GM; Hauser FE; Liao BS; Lujan NK; Van Nynatten A; Morrow JM; Schott RK; Bhattacharyya N; Dungan SZ; Chang BSW Proc Natl Acad Sci U S A; 2017 Jul; 114(28):7385-7390. PubMed ID: 28642345 [TBL] [Abstract][Full Text] [Related]
29. The complex evolutionary history of seeing red: molecular phylogeny and the evolution of an adaptive visual system in deep-sea dragonfishes (Stomiiformes: Stomiidae). Kenaley CP; Devaney SC; Fjeran TT Evolution; 2014 Apr; 68(4):996-1013. PubMed ID: 24274363 [TBL] [Abstract][Full Text] [Related]
30. Scotopic rod vision in tetrapods arose from multiple early adaptive shifts in the rate of retinal release. Liu Y; Cui Y; Chi H; Xia Y; Liu H; Rossiter SJ; Zhang S Proc Natl Acad Sci U S A; 2019 Jun; 116(26):12627-12628. PubMed ID: 31182589 [TBL] [Abstract][Full Text] [Related]
31. Do freshwater fishes diversify faster than marine fishes? A test using state-dependent diversification analyses and molecular phylogenetics of new world silversides (atherinopsidae). Bloom DD; Weir JT; Piller KR; Lovejoy NR Evolution; 2013 Jul; 67(7):2040-57. PubMed ID: 23815658 [TBL] [Abstract][Full Text] [Related]
32. Accelerated evolution and positive selection of rhodopsin in Tibetan loaches living in high altitude. Lv W; Lei Y; Deng Y; Sun N; Liu X; Yang L; He S Int J Biol Macromol; 2020 Dec; 165(Pt B):2598-2606. PubMed ID: 33470199 [TBL] [Abstract][Full Text] [Related]
33. Presence of rhodopsin and porphyropsin in the eyes of 164 fishes, representing marine, diadromous, coastal and freshwater species--a qualitative and comparative study. Toyama M; Hironaka M; Yamahama Y; Horiguchi H; Tsukada O; Uto N; Ueno Y; Tokunaga F; Seno K; Hariyama T Photochem Photobiol; 2008; 84(4):996-1002. PubMed ID: 18422881 [TBL] [Abstract][Full Text] [Related]
34. Comparative analysis of Japanese three-spined stickleback clades reveals the Pacific Ocean lineage has adapted to freshwater environments while the Japan Sea has not. Ravinet M; Takeuchi N; Kume M; Mori S; Kitano J PLoS One; 2014; 9(12):e112404. PubMed ID: 25460163 [TBL] [Abstract][Full Text] [Related]
35. Diversified Mammalian Visuasl Adaptations to Bright- or Dim-Light Environments. Gai Y; Tian R; Liu F; Mu Y; Shan L; Irwin DM; Liu Y; Xu S; Yang G Mol Biol Evol; 2023 Apr; 40(4):. PubMed ID: 36929909 [TBL] [Abstract][Full Text] [Related]
36. Cone-like rhodopsin expressed in the all-cone retina of the colubrid pine snake as a potential adaptation to diurnality. Bhattacharyya N; Darren B; Schott RK; Tropepe V; Chang BSW J Exp Biol; 2017 Jul; 220(Pt 13):2418-2425. PubMed ID: 28468872 [TBL] [Abstract][Full Text] [Related]
37. Visual adaptation of opsin genes to the aquatic environment in sea snakes. Seiko T; Kishida T; Toyama M; Hariyama T; Okitsu T; Wada A; Toda M; Satta Y; Terai Y BMC Evol Biol; 2020 Nov; 20(1):158. PubMed ID: 33243140 [TBL] [Abstract][Full Text] [Related]
39. Contrasting modes of evolution of the visual pigments in Heliconius butterflies. Yuan F; Bernard GD; Le J; Briscoe AD Mol Biol Evol; 2010 Oct; 27(10):2392-405. PubMed ID: 20478921 [TBL] [Abstract][Full Text] [Related]
40. Ecological and Lineage-Specific Factors Drive the Molecular Evolution of Rhodopsin in Cichlid Fishes. Torres-Dowdall J; Henning F; Elmer KR; Meyer A Mol Biol Evol; 2015 Nov; 32(11):2876-82. PubMed ID: 26187436 [TBL] [Abstract][Full Text] [Related] [Previous] [Next] [New Search]