{"id":490,"date":"2024-06-04T13:51:44","date_gmt":"2024-06-04T13:51:44","guid":{"rendered":"https:\/\/openpress.wheatoncollege.edu\/molecularecologyv1\/?post_type=back-matter&p=490"},"modified":"2024-06-04T14:51:53","modified_gmt":"2024-06-04T14:51:53","slug":"references","status":"publish","type":"back-matter","link":"https:\/\/openpress.wheatoncollege.edu\/molecularecologyv1\/back-matter\/references\/","title":{"raw":"Bibliography","rendered":"Bibliography"},"content":{"raw":"Ellegren, H., & Galtier, N. (2016). Determinants of genetic diversity. Nature Reviews Genetics<\/i>, 17<\/i>(7), 422-433.\r\n\r\nRowe, G., Sweet, M., & Beebee, T. J. C. (2017). An introduction to molecular ecology<\/i>. Oxford University Press.\r\n\r\nHadrys, H., Balick, M., & Schierwater, B. (1992). Applications of random amplified polymorphic DNA (RAPD) in molecular ecology. Molecular ecology<\/i>, 1<\/i>(1), 55-63.\r\n\r\nVieira, M. L. C., Santini, L., Diniz, A. L., & Munhoz, C. D. F. (2016). Microsatellite markers: what they mean and why they are so useful. Genetics and molecular biology<\/i>, 39<\/i>, 312-328.\r\n\r\nKarl, S. A., Toonen, R. J., Grant, W. S., & Bowen, B. W. (2012). Common misconceptions in molecular ecology: echoes of the modern synthesis. Molecular Ecology<\/i>, 21<\/i>(17), 4171-4189.\r\n\r\nEkblom, R., & Galindo, J. (2011). Applications of next generation sequencing in molecular ecology of non-model organisms. Heredity<\/i>, 107<\/i>(1), 1-15.\r\n\r\nRoss, K. G. (2001). Molecular ecology of social behaviour: analyses of breeding systems and genetic structure. Molecular ecology<\/i>, 10<\/i>(2), 265-284.\r\n\r\nKirk, H., & Freeland, J. R. (2011). Applications and implications of neutral versus non-neutral markers in molecular ecology. International journal of molecular sciences<\/i>, 12<\/i>(6), 3966-3988.\r\n\r\nMcKinney, G. J., Larson, W. A., Seeb, L. W., & Seeb, J. E. (2017). RAD seq provides unprecedented insights into molecular ecology and evolutionary genetics: comment on Breaking RAD by Lowry et al.(2016). Molecular ecology resources<\/i>, 17<\/i>(3), 356-361.\r\n\r\nAndrew, R. L., Bernatchez, L., Bonin, A., Buerkle, C. A., Carstens, B. C., Emerson, B. C., ... & Rieseberg, L. H. (2013). A road map for molecular ecology. Molecular ecology<\/i>, 22<\/i>(10), 2605-2626.\r\n\r\nFord, M. J. (2002). Applications of selective neutrality tests to molecular ecology. Molecular Ecology<\/i>, 11<\/i>(8), 1245-1262.\r\n\r\nBensch, S., & \u00c5kesson, M. (2005). Ten years of AFLP in ecology and evolution: why so few animals?. Molecular ecology<\/i>, 14<\/i>(10), 2899-2914.\r\n\r\nJohnson, J. B., Peat, S. M., & Adams, B. J. (2009). Where's the ecology in molecular ecology?. Oikos<\/i>, 118<\/i>(11), 1601-1609.\r\n\r\nMoritz, C. (1994). Applications of mitochondrial DNA analysis in conservation: a critical review. Molecular ecology<\/i>, 3<\/i>(4), 401-411.\r\n\r\nDeSalle, R., & Goldstein, P. (2019). Review and interpretation of trends in DNA barcoding. Frontiers in Ecology and Evolution<\/i>, 7<\/i>, 302.\r\n\r\nValentini, A., Pompanon, F., & Taberlet, P. (2009). DNA barcoding for ecologists. Trends in ecology & evolution<\/i>, 24<\/i>(2), 110-117.\r\n\r\nHebert, P. D., & Gregory, T. R. (2005). The promise of DNA barcoding for taxonomy. Systematic biology<\/i>, 54<\/i>(5), 852-859.\r\n\r\nPires, A. C., & Marinoni, L. (2010). DNA barcoding and traditional taxonomy unified through Integrative Taxonomy: a view that challenges the debate questioning both methodologies. Biota Neotropica<\/i>, 10<\/i>, 339-346.\r\n\r\nHey, J. (2006). On the failure of modern species concepts. Trends in ecology & evolution<\/i>, 21<\/i>(8), 447-450.\r\n\r\nDe Queiroz, K. (2007). Species concepts and species delimitation. Systematic biology<\/i>, 56<\/i>(6), 879-886.\r\n\r\nMayr, E. (2000). The biological species concept. Species concepts and phylogenetic theory: a debate. Columbia University Press, New York<\/i>, 17-29.\r\n\r\nMoritz, C. (1994). Defining \u2018evolutionarily significant units\u2019 for conservation. Trends in ecology & evolution<\/i>, 9<\/i>(10), 373-375.\r\n\r\nCasacci, L. P., Barbero, F., & Balletto, E. (2014). The \u201cEvolutionarily Significant Unit\u201d concept and its applicability in biological conservation. Italian Journal of Zoology<\/i>, 81<\/i>(2), 182-193.\r\n\r\nBarton, N. H. (2001). The role of hybridization in evolution. Molecular ecology<\/i>, 10<\/i>(3), 551-568.\r\n\r\nAbbott, R., Albach, D., Ansell, S., Arntzen, J. W., Baird, S. J., Bierne, N.,\u00a0et al.\u00a0<\/em> (2013). Hybridization and speciation. Journal of evolutionary biology<\/i>, 26<\/i>(2), 229-246.\r\n\r\nChan, W. Y., Hoffmann, A. A., & van Oppen, M. J. (2019). Hybridization as a conservation management tool. Conservation Letters<\/i>, 12<\/i>(5), e12652.\r\n\r\nAllendorf, F. W., Leary, R. F., Spruell, P., & Wenburg, J. K. (2001). The problems with hybrids: setting conservation guidelines. Trends in ecology & evolution<\/i>, 16<\/i>(11), 613-622\r\n\r\nBohling, J. H. (2016). Strategies to address the conservation threats posed by hybridization and genetic introgression. Biological Conservation<\/i>, 203<\/i>, 321-327\r\n\r\nBuggs, R. J. A. (2007). Empirical study of hybrid zone movement. Heredity<\/i>, 99<\/i>(3), 301-312.\r\n\r\nBock, D. G., Caseys, C., Cousens, R. D., Hahn, M. A., Heredia, S. M., H\u00fcbner, S., et al<\/em>. (2016). What we still don't know about invasion genetics. Invasion genetics: The baker and stebbins legacy<\/i>, 346-370\r\n\r\nFicetola, G. F., Bonin, A., & Miaud, C. (2008). Population genetics reveals origin and number of founders in a biological invasion. Molecular Ecology<\/i>, 17<\/i>(3), 773-782\r\n\r\nLynch, M., Ackerman, M. S., Gout, J. F., Long, H., Sung, W., Thomas, W. K., & Foster, P. L. (2016). Genetic drift, selection and the evolution of the mutation rate. Nature Reviews Genetics<\/i>, 17<\/i>(11), 704-714.\r\n\r\nPetrie, M., Doums, C., & M\u00f8ller, A. P. (1998). The degree of extra-pair paternity increases with genetic variability. Proceedings of the National Academy of Sciences<\/i>, 95<\/i>(16), 9390-9395\r\n\r\nBrouwer, L., & Griffith, S. C. (2019). Extra\u2010pair paternity in birds. Molecular ecology<\/i>, 28<\/i>(22), 4864-4882.\r\n\r\nHeckel, G., & Von Helversen, O. (2003). Genetic mating system and the significance of harem associations in the bat Saccopteryx bilineata. Molecular Ecology<\/i>, 12<\/i>(1), 219-227.\r\n\r\nNunney, L. (1993). The influence of mating system and overlapping generations on effective population size. Evolution<\/i>, 47<\/i>(5), 1329-1341.\r\n\r\nCharpentier, M., Hossaert-McKey, M., Wickings, E. J., & Peignot, P. (2005). Consequences of a one-male harem reproductive system and inbreeding in a captive group of Cercopithecus solatus. International Journal of Primatology<\/i>, 26<\/i>, 697-710.\r\n\r\nAvise, J. C. (2009). Phylogeography: retrospect and prospect. Journal of biogeography<\/i>, 36<\/i>(1), 3-15.\r\n\r\nKnowles, L. L. (2009). Statistical phylogeography. Annual Review of Ecology, Evolution, and Systematics<\/i>, 40<\/i>, 593-612.\r\n\r\nBeheregaray, L. B. (2008). Twenty years of phylogeography: the state of the field and the challenges for the Southern Hemisphere. Molecular ecology<\/i>, 17<\/i>(17), 3754-3774\r\n\r\nArbogast, B. S., & Kenagy, G. J. (2001). Comparative phylogeography as an integrative approach to historical biogeography. Journal of Biogeography<\/i>, 28<\/i>(7), 819-825\r\n\r\nDeSalle, R., & Amato, G. (2009). The expansion of conservation genetics. Conservation genetics in the age of genomics<\/i>, 1-24\r\n\r\nFrankham, R., Briscoe, D. A., & Ballou, J. D. (2002). Introduction to conservation genetics<\/i>. Cambridge university press.\r\n\r\nOuborg, N. J., Pertoldi, C., Loeschcke, V., Bijlsma, R. K., & Hedrick, P. W. (2010). Conservation genetics in transition to conservation genomics. Trends in genetics<\/i>, 26<\/i>(4), 177-187.\r\n\r\nHohenlohe, P. A., Funk, W. C., & Rajora, O. P. (2021). Population genomics for wildlife conservation and management. Molecular Ecology<\/i>, 30<\/i>(1), 62-82.\r\n\r\nAndrews, K. R., Good, J. M., Miller, M. R., Luikart, G., & Hohenlohe, P. A. (2016). Harnessing the power of RADseq for ecological and evolutionary genomics. Nature Reviews Genetics<\/i>, 17<\/i>(2), 81-92.\r\n\r\nShapiro, B. (2017). Pathways to de\u2010extinction: how close can we get to resurrection of an extinct species?. Functional Ecology<\/i>, 31<\/i>(5), 996-1002.\r\n\r\nBeaumont, M. A. (2005). Adaptation and speciation: what can Fst tell us?. Trends in ecology & evolution<\/i>, 20<\/i>(8), 435-440\r\n\r\nWilliams, S. E., & Hoffman, E. A. (2009). Minimizing genetic adaptation in captive breeding programs: a review. Biological conservation<\/i>, 142<\/i>(11), 2388-2400.\r\n\r\nAttard, C. R. M., M\u00f6ller, L. M., Sasaki, M., Hammer, M. P., Bice, C. M., Brauer, C. J., ... & Beheregaray, L. B. (2016). A novel holistic framework for genetic\u2010based captive\u2010breeding and reintroduction programs. Conservation Biology<\/i>, 30<\/i>(5), 1060-1069.\r\n\r\nBowen, B. W., Gaither, M. R., DiBattista, J. D., Iacchei, M., Andrews, K. R., Grant, W. S.,\u00a0et al.\u00a0<\/em> (2016). Comparative phylogeography of the ocean planet. Proceedings of the National Academy of Sciences<\/i>, 113<\/i>(29), 7962-7969.\r\n\r\nBlomqvist, D., Pauliny, A., Larsson, M., & Flodin, L. \u00c5. (2010). Trapped in the extinction vortex? Strong genetic effects in a declining vertebrate population. BMC Evolutionary Biology<\/i>, 10<\/i>, 1-9.","rendered":"

Ellegren, H., & Galtier, N. (2016). Determinants of genetic diversity. Nature Reviews Genetics<\/i>, 17<\/i>(7), 422-433.<\/p>\n

Rowe, G., Sweet, M., & Beebee, T. J. C. (2017). An introduction to molecular ecology<\/i>. Oxford University Press.<\/p>\n

Hadrys, H., Balick, M., & Schierwater, B. (1992). Applications of random amplified polymorphic DNA (RAPD) in molecular ecology. Molecular ecology<\/i>, 1<\/i>(1), 55-63.<\/p>\n

Vieira, M. L. C., Santini, L., Diniz, A. L., & Munhoz, C. D. F. (2016). Microsatellite markers: what they mean and why they are so useful. Genetics and molecular biology<\/i>, 39<\/i>, 312-328.<\/p>\n

Karl, S. A., Toonen, R. J., Grant, W. S., & Bowen, B. W. (2012). Common misconceptions in molecular ecology: echoes of the modern synthesis. Molecular Ecology<\/i>, 21<\/i>(17), 4171-4189.<\/p>\n

Ekblom, R., & Galindo, J. (2011). Applications of next generation sequencing in molecular ecology of non-model organisms. Heredity<\/i>, 107<\/i>(1), 1-15.<\/p>\n

Ross, K. G. (2001). Molecular ecology of social behaviour: analyses of breeding systems and genetic structure. Molecular ecology<\/i>, 10<\/i>(2), 265-284.<\/p>\n

Kirk, H., & Freeland, J. R. (2011). Applications and implications of neutral versus non-neutral markers in molecular ecology. International journal of molecular sciences<\/i>, 12<\/i>(6), 3966-3988.<\/p>\n

McKinney, G. J., Larson, W. A., Seeb, L. W., & Seeb, J. E. (2017). RAD seq provides unprecedented insights into molecular ecology and evolutionary genetics: comment on Breaking RAD by Lowry et al.(2016). Molecular ecology resources<\/i>, 17<\/i>(3), 356-361.<\/p>\n

Andrew, R. L., Bernatchez, L., Bonin, A., Buerkle, C. A., Carstens, B. C., Emerson, B. C., … & Rieseberg, L. H. (2013). A road map for molecular ecology. Molecular ecology<\/i>, 22<\/i>(10), 2605-2626.<\/p>\n

Ford, M. J. (2002). Applications of selective neutrality tests to molecular ecology. Molecular Ecology<\/i>, 11<\/i>(8), 1245-1262.<\/p>\n

Bensch, S., & \u00c5kesson, M. (2005). Ten years of AFLP in ecology and evolution: why so few animals?. Molecular ecology<\/i>, 14<\/i>(10), 2899-2914.<\/p>\n

Johnson, J. B., Peat, S. M., & Adams, B. J. (2009). Where’s the ecology in molecular ecology?. Oikos<\/i>, 118<\/i>(11), 1601-1609.<\/p>\n

Moritz, C. (1994). Applications of mitochondrial DNA analysis in conservation: a critical review. Molecular ecology<\/i>, 3<\/i>(4), 401-411.<\/p>\n

DeSalle, R., & Goldstein, P. (2019). Review and interpretation of trends in DNA barcoding. Frontiers in Ecology and Evolution<\/i>, 7<\/i>, 302.<\/p>\n

Valentini, A., Pompanon, F., & Taberlet, P. (2009). DNA barcoding for ecologists. Trends in ecology & evolution<\/i>, 24<\/i>(2), 110-117.<\/p>\n

Hebert, P. D., & Gregory, T. R. (2005). The promise of DNA barcoding for taxonomy. Systematic biology<\/i>, 54<\/i>(5), 852-859.<\/p>\n

Pires, A. C., & Marinoni, L. (2010). DNA barcoding and traditional taxonomy unified through Integrative Taxonomy: a view that challenges the debate questioning both methodologies. Biota Neotropica<\/i>, 10<\/i>, 339-346.<\/p>\n

Hey, J. (2006). On the failure of modern species concepts. Trends in ecology & evolution<\/i>, 21<\/i>(8), 447-450.<\/p>\n

De Queiroz, K. (2007). Species concepts and species delimitation. Systematic biology<\/i>, 56<\/i>(6), 879-886.<\/p>\n

Mayr, E. (2000). The biological species concept. Species concepts and phylogenetic theory: a debate. Columbia University Press, New York<\/i>, 17-29.<\/p>\n

Moritz, C. (1994). Defining \u2018evolutionarily significant units\u2019 for conservation. Trends in ecology & evolution<\/i>, 9<\/i>(10), 373-375.<\/p>\n

Casacci, L. P., Barbero, F., & Balletto, E. (2014). The \u201cEvolutionarily Significant Unit\u201d concept and its applicability in biological conservation. Italian Journal of Zoology<\/i>, 81<\/i>(2), 182-193.<\/p>\n

Barton, N. H. (2001). The role of hybridization in evolution. Molecular ecology<\/i>, 10<\/i>(3), 551-568.<\/p>\n

Abbott, R., Albach, D., Ansell, S., Arntzen, J. W., Baird, S. J., Bierne, N.,\u00a0et al.\u00a0<\/em> (2013). Hybridization and speciation. Journal of evolutionary biology<\/i>, 26<\/i>(2), 229-246.<\/p>\n

Chan, W. Y., Hoffmann, A. A., & van Oppen, M. J. (2019). Hybridization as a conservation management tool. Conservation Letters<\/i>, 12<\/i>(5), e12652.<\/p>\n

Allendorf, F. W., Leary, R. F., Spruell, P., & Wenburg, J. K. (2001). The problems with hybrids: setting conservation guidelines. Trends in ecology & evolution<\/i>, 16<\/i>(11), 613-622<\/p>\n

Bohling, J. H. (2016). Strategies to address the conservation threats posed by hybridization and genetic introgression. Biological Conservation<\/i>, 203<\/i>, 321-327<\/p>\n

Buggs, R. J. A. (2007). Empirical study of hybrid zone movement. Heredity<\/i>, 99<\/i>(3), 301-312.<\/p>\n

Bock, D. G., Caseys, C., Cousens, R. D., Hahn, M. A., Heredia, S. M., H\u00fcbner, S., et al<\/em>. (2016). What we still don’t know about invasion genetics. Invasion genetics: The baker and stebbins legacy<\/i>, 346-370<\/p>\n

Ficetola, G. F., Bonin, A., & Miaud, C. (2008). Population genetics reveals origin and number of founders in a biological invasion. Molecular Ecology<\/i>, 17<\/i>(3), 773-782<\/p>\n

Lynch, M., Ackerman, M. S., Gout, J. F., Long, H., Sung, W., Thomas, W. K., & Foster, P. L. (2016). Genetic drift, selection and the evolution of the mutation rate. Nature Reviews Genetics<\/i>, 17<\/i>(11), 704-714.<\/p>\n

Petrie, M., Doums, C., & M\u00f8ller, A. P. (1998). The degree of extra-pair paternity increases with genetic variability. Proceedings of the National Academy of Sciences<\/i>, 95<\/i>(16), 9390-9395<\/p>\n

Brouwer, L., & Griffith, S. C. (2019). Extra\u2010pair paternity in birds. Molecular ecology<\/i>, 28<\/i>(22), 4864-4882.<\/p>\n

Heckel, G., & Von Helversen, O. (2003). Genetic mating system and the significance of harem associations in the bat Saccopteryx bilineata. Molecular Ecology<\/i>, 12<\/i>(1), 219-227.<\/p>\n

Nunney, L. (1993). The influence of mating system and overlapping generations on effective population size. Evolution<\/i>, 47<\/i>(5), 1329-1341.<\/p>\n

Charpentier, M., Hossaert-McKey, M., Wickings, E. J., & Peignot, P. (2005). Consequences of a one-male harem reproductive system and inbreeding in a captive group of Cercopithecus solatus. International Journal of Primatology<\/i>, 26<\/i>, 697-710.<\/p>\n

Avise, J. C. (2009). Phylogeography: retrospect and prospect. Journal of biogeography<\/i>, 36<\/i>(1), 3-15.<\/p>\n

Knowles, L. L. (2009). Statistical phylogeography. Annual Review of Ecology, Evolution, and Systematics<\/i>, 40<\/i>, 593-612.<\/p>\n

Beheregaray, L. B. (2008). Twenty years of phylogeography: the state of the field and the challenges for the Southern Hemisphere. Molecular ecology<\/i>, 17<\/i>(17), 3754-3774<\/p>\n

Arbogast, B. S., & Kenagy, G. J. (2001). Comparative phylogeography as an integrative approach to historical biogeography. Journal of Biogeography<\/i>, 28<\/i>(7), 819-825<\/p>\n

DeSalle, R., & Amato, G. (2009). The expansion of conservation genetics. Conservation genetics in the age of genomics<\/i>, 1-24<\/p>\n

Frankham, R., Briscoe, D. A., & Ballou, J. D. (2002). Introduction to conservation genetics<\/i>. Cambridge university press.<\/p>\n

Ouborg, N. J., Pertoldi, C., Loeschcke, V., Bijlsma, R. K., & Hedrick, P. W. (2010). Conservation genetics in transition to conservation genomics. Trends in genetics<\/i>, 26<\/i>(4), 177-187.<\/p>\n

Hohenlohe, P. A., Funk, W. C., & Rajora, O. P. (2021). Population genomics for wildlife conservation and management. Molecular Ecology<\/i>, 30<\/i>(1), 62-82.<\/p>\n

Andrews, K. R., Good, J. M., Miller, M. R., Luikart, G., & Hohenlohe, P. A. (2016). Harnessing the power of RADseq for ecological and evolutionary genomics. Nature Reviews Genetics<\/i>, 17<\/i>(2), 81-92.<\/p>\n

Shapiro, B. (2017). Pathways to de\u2010extinction: how close can we get to resurrection of an extinct species?. Functional Ecology<\/i>, 31<\/i>(5), 996-1002.<\/p>\n

Beaumont, M. A. (2005). Adaptation and speciation: what can Fst tell us?. Trends in ecology & evolution<\/i>, 20<\/i>(8), 435-440<\/p>\n

Williams, S. E., & Hoffman, E. A. (2009). Minimizing genetic adaptation in captive breeding programs: a review. Biological conservation<\/i>, 142<\/i>(11), 2388-2400.<\/p>\n

Attard, C. R. M., M\u00f6ller, L. M., Sasaki, M., Hammer, M. P., Bice, C. M., Brauer, C. J., … & Beheregaray, L. B. (2016). A novel holistic framework for genetic\u2010based captive\u2010breeding and reintroduction programs. Conservation Biology<\/i>, 30<\/i>(5), 1060-1069.<\/p>\n

Bowen, B. W., Gaither, M. R., DiBattista, J. D., Iacchei, M., Andrews, K. R., Grant, W. S.,\u00a0et al.\u00a0<\/em> (2016). Comparative phylogeography of the ocean planet. Proceedings of the National Academy of Sciences<\/i>, 113<\/i>(29), 7962-7969.<\/p>\n

Blomqvist, D., Pauliny, A., Larsson, M., & Flodin, L. \u00c5. (2010). Trapped in the extinction vortex? Strong genetic effects in a declining vertebrate population. BMC Evolutionary Biology<\/i>, 10<\/i>, 1-9.<\/p>\n","protected":false},"author":13,"menu_order":1,"template":"","meta":{"pb_show_title":"on","pb_short_title":"","pb_subtitle":"","pb_authors":[],"pb_section_license":""},"back-matter-type":[],"contributor":[],"license":[],"class_list":["post-490","back-matter","type-back-matter","status-publish","hentry"],"_links":{"self":[{"href":"https:\/\/openpress.wheatoncollege.edu\/molecularecologyv1\/wp-json\/pressbooks\/v2\/back-matter\/490"}],"collection":[{"href":"https:\/\/openpress.wheatoncollege.edu\/molecularecologyv1\/wp-json\/pressbooks\/v2\/back-matter"}],"about":[{"href":"https:\/\/openpress.wheatoncollege.edu\/molecularecologyv1\/wp-json\/wp\/v2\/types\/back-matter"}],"author":[{"embeddable":true,"href":"https:\/\/openpress.wheatoncollege.edu\/molecularecologyv1\/wp-json\/wp\/v2\/users\/13"}],"version-history":[{"count":7,"href":"https:\/\/openpress.wheatoncollege.edu\/molecularecologyv1\/wp-json\/pressbooks\/v2\/back-matter\/490\/revisions"}],"predecessor-version":[{"id":499,"href":"https:\/\/openpress.wheatoncollege.edu\/molecularecologyv1\/wp-json\/pressbooks\/v2\/back-matter\/490\/revisions\/499"}],"metadata":[{"href":"https:\/\/openpress.wheatoncollege.edu\/molecularecologyv1\/wp-json\/pressbooks\/v2\/back-matter\/490\/metadata\/"}],"wp:attachment":[{"href":"https:\/\/openpress.wheatoncollege.edu\/molecularecologyv1\/wp-json\/wp\/v2\/media?parent=490"}],"wp:term":[{"taxonomy":"back-matter-type","embeddable":true,"href":"https:\/\/openpress.wheatoncollege.edu\/molecularecologyv1\/wp-json\/pressbooks\/v2\/back-matter-type?post=490"},{"taxonomy":"contributor","embeddable":true,"href":"https:\/\/openpress.wheatoncollege.edu\/molecularecologyv1\/wp-json\/wp\/v2\/contributor?post=490"},{"taxonomy":"license","embeddable":true,"href":"https:\/\/openpress.wheatoncollege.edu\/molecularecologyv1\/wp-json\/wp\/v2\/license?post=490"}],"curies":[{"name":"wp","href":"https:\/\/api.w.org\/{rel}","templated":true}]}}