Похождения видов. Вампироноги, паукохвосты и другие переходные формы в эволюции животных - Андрей Юрьевич Журавлёв
Шрифт:
Интервал:
Закладка:
Botting J. P., Zhang Y., Muir L. A. (2017) Discovery of missing link between demosponges and hexactinellids confirms palaeontological model of sponge evolution. Scientific Reports, 7, 5286. DOI: 10.1038/s41598-017-05604-6.
Boyajian G. E., Labarbera M. (1987) Biomechanical analysis of passive flow of stromatoporoids – Morphologic, paleoecologic, and systematic implications. Lethaia, 20, 223–9.
Carrera M. G., Maletz J. (2014) Ordovician sponge spicules from the Spitsbergen, Nevada and Newfoundland: new evidence for hexactinellid and demosponge early diversification. Journal of Systematic Palaeontology, 12, 961–81.
Chen J. et al. (2004) Sponge fossil assemblage from the Early Cambrian Hetang Formation in southern Anhui. Chinese Science Bulletin, 49, 1625–8.
Conway K., Barrie J., Krautter M. (2005) Geomorphology of unique reefs on the western Canadian shelf: sponge reefs mapped by multibeam bathymetry. Geo-Marine Letters, 25, 205–13.
Debrenne F. et al. (2015) Treatise on Invertebrate Paleontology, Part E (Revised), Porifera, Vol. 4–5: Hypercalcified Porifera. – Lawrence, Kansas: University Kansas Paleontological Institute.
Ehrlich H. et al. (2010) Mineralization of the metre-long biosilica structures of glass sponges is templated on hydroxylated collagen. Nature Chemistry, 2, 1084–8.
Ehrlich H. et al. (2013) Discovery of 505-million-year old chitin in the basal demosponge Vauxia gracilenta. Scientific Reports, 3, 03497. DOI: 10.1038/srep03497.
Ereskovsky A. V. et al. (2009) The homoscleromorph sponge Oscarella lobularis, a promising sponge model in evolutionary and developmental biology. BioEssays, 31, 89–97.
Fairclough S. R., Dayel M. J., King N. (2010) Multicellular development in a choanoflagellate. Current Biology, 20, R875–6.
Fairclough S. R. et al. (2013) Premetazoan genome evolution and the regulation of cell differentiation in the choanoflagellate Salpingoeca rosetta. Genome Biology, 14, R15. DOI: 10.1186//gb-2013-14-2-r15.
Fernandes M. C. et al. (2021) Mechanically robust lattices inspired by deep-sea glass sponges. Nature Materials, 20, 237–41.
Finks R. M., Reid R. E. H., Rigby J. K. (2004) Treatise on Invertebrate Paleontology, Part E (Revised), Porifera, Vol. 3: Porifera (Demospongea, Hexactinellida, Heteractinida, Calcarea). – Boulder, Colorado: Geological Society of America; Lawrence, Kansas: University Kansas Paleontological Institute.
Gautret P., Reitner J., Marin F. (1996). Mineralization events during growth of the coralline sponges Acanthochaetetes and Vaceletia. Bulletin de l’Institut océanographique de Monaco, no. special 14, 325–334.
Gazave E. et al. (2012) No longer Demospongiae: Homoscleromorpha formal nomination as a fourth class of Porifera. Hydrobiologia, 687, 3–10.
Harvey T. H. P. (2010) Carbonaceous preservation of Cambrian hexactinellid sponge spicules. Biological Letters, 6, 834–7.
Kirkpatrick R. (1908) On two new genera of Recent pharetronid sponges. Annals and Magazine of Natural History; Zoology, Botany, and Geology, Series 8, 2, 503–514.
Kirkpatrick R. (1913) The Nummulosphere. An Account of the Organic Origin of So-Called Igneous Rocks and of Abyssal Red Clays. – L.: Lamley & Co.
Kozur H. W., Mostler H., Repetski J. E. (2008) A new heteractinellid sponge from the lowermost Ordovician of Nevada and a discussion of the suborder Heteractinellidae. Geo.Alp, 5, 53–67.
Kruse P. D., Zhuravlev A. Yu. (2008) Middle-Late Cambrian Rankenella-Girvanella reefs of the Mila Formation, northern Iran. Canadian Journal of Earth Sciences, 45, 619–39.
Lavrov A. I., Kosevich I. A. (2018) Stolonial movement: A new type of whole-organism behavior in Porifera. The Biological Bulletin, 234 (1), 58–67.
Lee W. L. et al. (2012) An extraordinary new carnivorous sponge, Chondrocladia lyra, in the new subgenus Symmetrocladia (Demospongiae, Cladorhizidae), from off of northern California, USA. Invertebrate Biology, 131, 259–84.
Leys S. P. (2003) The significance of syncytial tissues for the position of the Hexactinellida in the Metazoa. Integrative and Comparative Biology, 43, 19–27.
Leys S. P. (2015) Elements of a ‘nervous system’ in sponges. The Journal of Experimental Biology, 218, 581–91.
Luo C., Zhao F., Zeng H. (2020) The first report of a vauxiid sponge from the Cambrian Chengjiang Biota. Journal of Paleontology, 94, 28–33.
Luo C., Yang A., Zhuravlev A. Y., Reitner J. (2021) Vauxiids as descendants of archaeocyaths: a hypothesis. Lethaia. DOI: 10.1111/let.12433.
Maldonado M. (2004) Choanoflagellates, choanocytes, and animal multicellularity. Invertebrate Biology, 123, 1–22.
Mehl D. (1996) Phylogenie und Evolutionsökologie der Hexactinellida (Porifera) im Paläozoikum. Geologische Paläontologische Mitteilungen der Universität Innsbruck, Sonderband, 4, 1–55.
Mills D. B. et al. (2018) The last common ancestor of animals lacked the HIF pathway and respired in low-oxygen environments. eLife, 7, e31176. DOI: 10.7554/eLife.31176.
Mostler H. (1990) Mikroskleren von Demospongien (Porifera) aus dem basalen Jura der nördlichen Kalkalpen. Geologische Paläontologische Mitteilungen der Universität Innsbruck, 17, 119–42.
Mostler H. (1996) Polyactinellid Schwämme, eine auf das Paläozoikum beschränkte Calcispongien-Gruppe. Geologische Paläontologische Mitteilungen der Universität Innsbruck, 21, 223–43.
Nitecki M. H. (1972) North American Silurian receptaculitid algae. Fieldiana (Geology), 28, 1–108.
Peña J. F. et al. (2016) Conserved expression of vertebrate microvillar gene homologs in choanocytes of freshwater sponges. EvoDevo, 7, 13. DOI: 10.1186/s13227-016-0050-x.
Pronzato R., Manconi R. (2008) Mediterranean commercial sponges: over 5000 years of natural history and cultural heritage. Marine Ecology, 29, 146–66.
Pronzato R., Pisera A., Manconi R. (2017) Fossil freshwater sponges: Taxonomy, geographic distribution, and critical review. Acta Palaeontologica Polonica, 62, 467–95.
Rhebergen F., Botting J. P. (2014) A new Silurian (Llandovery, Telychian) sponge assemblage from Gotland, Sweden. Fossil and Strata, 60, 1–87.
Rigby J. K. (1986) Sponges of the Burgess Shale (Middle Cambrian), British Columbia. Palaeontographica Canadiana, 2, 1–105.
Rigby J. K., Collins D. (2004) Sponges of the Middle Cambrian Burgess Shale and Stephen Formation, British Columbia. Royal Ontario Museum Contributions in Science, 1, 1–164.
Rigby J. K., Johnston P. A. (2004) An unusually large Aulocopella winnipegensis and associated demosponges from the Upper Ordovician Beaverfoot Formation, southeastern British Columbia. Canadian Journal of Earth Sciences, 41, 939–47.
Schuster A. et al. (2015) Deceptive desmas: Molecular phylogenetics suggests a new classification and uncovers convergent evolution of lithistid sponges. PLoS ONE, 10, e116038. DOI: 10.1371/journal.pone.0116038.
Sethmann I., Wörheide G. (2007) Structure and composition of calcareous sponge spicules: A review and comparison to structurally related biominerals. Micron, 39, 209–28.
Soest R. W. M. van. (1984) Deficient Merlia normani Kirkpatrick, 1908, from the Curacao reefs, with a discussion on the phylogenetic interpretation of sclerosponges. Bijdragen tot de Dierkunde, 54, 211–9.
