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Miguel Mies is a Brazilian academic, oceanographer, and researcher.^[1]^[2]^[3] He is currently a professor at the Oceanographic Institute of the University of São Paulo (IO-USP) and leads the Coral Reefs and Climate Change Laboratory (LARC).^[4]^[5] He also serves as the research coordinator for the Coral Vivo Project and is the vice president of the Coral Vivo Institute.^[5]

Early life and education

Mies was born in Brazil. He holds a BSc and a PhD in oceanography from the Oceanographic Institute of the University of São Paulo (IO-USP).^[5] His PhD dissertation focused on the impact of climate change on the molecular relationship between marine invertebrate larvae and their symbionts.^[6] It also provided the first demonstration of coral larvae susceptibility to bleaching.^[7]

Career

Mies holds a professorship at IO-USP and leads the Coral Reefs and Climate Change Laboratory (LARC).^[5] He also serves as the Research Coordinator for the Coral Vivo Project and is the vice president of the Coral Vivo Institute.^[5] He was involved as the deputy coordinator for GT7 (Recifes) in response to the oil spill on the Brazilian coast.^[5]

During his career, Mies has served as a reviewer for more than 30 international scientific journals and was a member of the editorial board for Frontiers in Marine Science, focusing on coral reef research.^[5]

Research

Mies researches subjects such as reef ecology, molecular biology, and genetics of zooxanthellae, larval development of reef organisms, trophic ecology of corals, and the effects of climate change on coral reefs.^[5] His research, focused mostly on field and experimental assessments of coral bleaching, spans both global and regional scales.^[8] His studies have contributed to the understanding of the unique responses of Brazilian coral reefs to climate change, compared to other reef ecosystems.^[9]

Selected publications

Mies, Miguel; Francini-Filho, Ronaldo B.; Zilberberg, Carla; Garrido, Amana G.; Longo, Guilherme O.; Laurentino, Eduarda; Güth, Arthur Z.; Sumida, Paulo Y. G.; Banha, Thomás N. S. (March 12, 2020). "South Atlantic Coral Reefs Are Major Global Warming Refugia and Less Susceptible to Bleaching". Frontiers in Marine Science. 7. doi:10.3389/fmars.2020.00514.
Mies, M.; Güth, A. Z.; Tenório, A. A.; Banha, T. N. S.; Waters, L. G.; Polito, P. S.; Taniguchi, S.; Bícego, M. C.; Sumida, P. Y. G. (September 1, 2018). "In situ shifts of predominance between autotrophic and heterotrophic feeding in the reef-building coral Mussismilia hispida: an approach using fatty acid trophic markers". Coral Reefs. 37 (3): 677–689. Bibcode:2018CorRe..37..677M. doi:10.1007/s00338-018-1692-z. S2CID 253806861 – via Springer Link.
Banha, T. N. S.; Capel, K. C. C.; Kitahara, M. V.; Francini-Filho, R. B.; Francini, C. L. B.; Sumida, P. Y. G.; Mies, M. (June 1, 2020). "Low coral mortality during the most intense bleaching event ever recorded in subtropical Southwestern Atlantic reefs". Coral Reefs. 39 (3): 515–521. doi:10.1007/s00338-019-01856-y. S2CID 253811219 – via Springer Link.
Mies, M.; Dor, P.; Güth, A. Z.; Sumida, P. Y. G. (October 2, 2017). "Production in Giant Clam Aquaculture: Trends and Challenges". Reviews in Fisheries Science & Aquaculture. 25 (4): 286–296. Bibcode:2017RvFSA..25..286M. doi:10.1080/23308249.2017.1285864. S2CID 90048377 – via CrossRef.
Mies, Miguel; Sumida, Paulo Y. G.; Rädecker, Nils; Voolstra, Christian R. (March 12, 2017). "Marine Invertebrate Larvae Associated with Symbiodinium: A Mutualism from the Start?". Frontiers in Ecology and Evolution. 5. doi:10.3389/fevo.2017.00056.
Mies, M.; Voolstra, C. R.; Castro, C. B.; Pires, D. O.; Calderon, E. N.; Sumida, P. Y. G. (May 12, 2017). "Expression of a symbiosis-specific gene in Symbiodinium type A1 associated with coral, nudibranch and giant clam larvae". Royal Society Open Science. 4 (5): 170253. Bibcode:2017RSOS....470253M. doi:10.1098/rsos.170253. PMC 5451836. PMID 28573035.
Mies, Miguel; Braga, Felipe; Scozzafave, Marcello Santos; Lemos, Daniel Eduardo Lavanholi de; Sumida, Paulo Yukio Gomes (June 12, 2012). "Early development, survival and growth rates of the giant clam Tridacna crocea (Bivalvia: Tridacnidae)". Brazilian Journal of Oceanography. 60 (2): 127–133. doi:10.1590/S1679-87592012000200003 – via SciELO.
Mies, Miguel (December 1, 2019). "Evolution, diversity, distribution and the endangered future of the giant clam–Symbiodiniaceae association". Coral Reefs. 38 (6): 1067–1084. Bibcode:2019CorRe..38.1067M. doi:10.1007/s00338-019-01857-x. S2CID 203388892 – via Springer Link.
Marangoni, Laura Fernandes de Barros; Mies, Miguel; Güth, Arthur Z.; Banha, Thomás N. S.; Inague, Alex; Fonseca, Juliana da Silva; Dalmolin, Camila; Faria, Samuel Coelho; Ferrier-Pagès, Christine; Bianchini, Adalto (October 12, 2019). "Peroxynitrite Generation and Increased Heterotrophic Capacity Are Linked to the Disruption of the Coral–Dinoflagellate Symbiosis in a Scleractinian and Hydrocoral Species". Microorganisms. 7 (10): 426. doi:10.3390/microorganisms7100426. PMC 6843776. PMID 31600926.

References

^ "Especialista comenta os avanços do óleo e os impactos à biodiversidade". G1.
^ "Assistir Jornal Hoje - Eventos climáticos extremos ficaram mais frequentes no Brasil online | Globoplay" – via globoplay.globo.com.
^ Magazine, Hakai. "Giant Clams Spread Their Symbiotic Algae through Their Poop". Hakai Magazine.
^ "Miguel Mies". www.io.usp.br.
^ ^a ^b ^c ^d ^e ^f ^g ^h http://lattes.cnpq.br/2178720179557276
^ Mies, Miguel (2019). The symbiotic relationship between >i<Symbiodinium>/I< and coral reef larvae: Gene expression, fatty acid biochemistry and responses to thermal stress (Thesis). Universidade de São Paulo. doi:10.11606/T.21.2019.tde-22042019-102141.
^ Mies, M.; Güth, A. Z.; Castro, C. B.; Pires, D. O.; Calderon, E. N.; Pompeu, M.; Sumida, P. Y. G. (November 9, 2017). "Bleaching in reef invertebrate larvae associated with Symbiodinium strains within clades A–F". Marine Biology. 165 (1): 6. doi:10.1007/s00227-017-3263-1. S2CID 253776271 – via Springer Link.
^ da Silva Fonseca, Juliana; Mies, Miguel; Paranhos, Alana; Taniguchi, Satie; Güth, Arthur Z.; Bícego, Márcia C.; Marques, Joseane Aparecida; Fernandes de Barros Marangoni, Laura; Bianchini, Adalto (January 1, 2021). "Isolated and combined effects of thermal stress and copper exposure on the trophic behavior and oxidative status of the reef-building coral Mussismilia harttii". Environmental Pollution. 268 (Pt B): 115892. Bibcode:2021EPoll.26815892D. doi:10.1016/j.envpol.2020.115892. PMID 33120157. S2CID 225175282 – via ScienceDirect.
^ Mies, Miguel; Francini-Filho, Ronaldo B.; Zilberberg, Carla; Garrido, Amana G.; Longo, Guilherme O.; Laurentino, Eduarda; Güth, Arthur Z.; Sumida, Paulo Y. G.; Banha, Thomás N. S. (March 12, 2020). "South Atlantic Coral Reefs Are Major Global Warming Refugia and Less Susceptible to Bleaching". Frontiers in Marine Science. 7. doi:10.3389/fmars.2020.00514.

[1] "Especialista comenta os avanços do óleo e os impactos à biodiversidade". G1.

[2] "Assistir Jornal Hoje - Eventos climáticos extremos ficaram mais frequentes no Brasil online | Globoplay" – via globoplay.globo.com.

[3] Magazine, Hakai. "Giant Clams Spread Their Symbiotic Algae through Their Poop". Hakai Magazine.

[4] "Miguel Mies". www.io.usp.br.

[auto-5] ^ ^a ^b ^c ^d ^e ^f ^g ^h http://lattes.cnpq.br/2178720179557276

[6] Mies, Miguel (2019). The symbiotic relationship between >i<Symbiodinium>/I< and coral reef larvae: Gene expression, fatty acid biochemistry and responses to thermal stress (Thesis). Universidade de São Paulo. doi:10.11606/T.21.2019.tde-22042019-102141.

[7] Mies, M.; Güth, A. Z.; Castro, C. B.; Pires, D. O.; Calderon, E. N.; Pompeu, M.; Sumida, P. Y. G. (November 9, 2017). "Bleaching in reef invertebrate larvae associated with Symbiodinium strains within clades A–F". Marine Biology. 165 (1): 6. doi:10.1007/s00227-017-3263-1. S2CID 253776271 – via Springer Link.

[8] Silva Fonseca, Juliana; Mies, Miguel; Paranhos, Alana; Taniguchi, Satie; Güth, Arthur Z.; Bícego, Márcia C.; Marques, Joseane Aparecida; Fernandes de Barros Marangoni, Laura; Bianchini, Adalto (January 1, 2021). "Isolated and combined effects of thermal stress and copper exposure on the trophic behavior and oxidative status of the reef-building coral Mussismilia harttii". Environmental Pollution. 268 (Pt B): 115892. Bibcode:2021EPoll.26815892D. doi:10.1016/j.envpol.2020.115892. PMID 33120157. S2CID 225175282 – via ScienceDirect.

[9] Mies, Miguel; Francini-Filho, Ronaldo B.; Zilberberg, Carla; Garrido, Amana G.; Longo, Guilherme O.; Laurentino, Eduarda; Güth, Arthur Z.; Sumida, Paulo Y. G.; Banha, Thomás N. S. (March 12, 2020). "South Atlantic Coral Reefs Are Major Global Warming Refugia and Less Susceptible to Bleaching". Frontiers in Marine Science. 7. doi:10.3389/fmars.2020.00514.

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@@ Line 2: / Line 2: @@
 ==Early life and education==
-Mies was born in Brazil. He holds a [[BSc]] and a [[PhD]] in [[oceanography]] from the Oceanographic Institute of the [[University of São Paulo]] (IO-USP).<ref name="auto"/> His PhD dissertation focused on the impact of [[climate change]] on the molecular relationship between marine invertebrate larvae and their symbionts.<ref>https://www.teses.usp.br/teses/disponiveis/21/21134/tde-22042019-102141/pt-br.php</ref> It also provided the first demonstration of coral larvae susceptibility to bleaching.<ref>{{Cite journal|url=https://doi.org/10.1007/s00227-017-3263-1|title=Bleaching in reef invertebrate larvae associated with Symbiodinium strains within clades A–F|first1=M.|last1=Mies|first2=A. Z.|last2=Güth|first3=C. B.|last3=Castro|first4=D. O.|last4=Pires|first5=E. N.|last5=Calderon|first6=M.|last6=Pompeu|first7=P. Y. G.|last7=Sumida|date=November 9, 2017|journal=Marine Biology|volume=165|issue=1|pages=6|via=Springer Link|doi=10.1007/s00227-017-3263-1}}</ref>
+Mies was born in Brazil. He holds a [[BSc]] and a [[PhD]] in [[oceanography]] from the Oceanographic Institute of the [[University of São Paulo]] (IO-USP).<ref name="auto"/> His PhD dissertation focused on the impact of [[climate change]] on the molecular relationship between marine invertebrate larvae and their symbionts.<ref>{{cite thesis | url=https://www.teses.usp.br/teses/disponiveis/21/21134/tde-22042019-102141/pt-br.php | doi=10.11606/T.21.2019.tde-22042019-102141 | title=The symbiotic relationship between >i<Symbiodinium>/I< and coral reef larvae: Gene expression, fatty acid biochemistry and responses to thermal stress | date=2019 | last1=Mies | first1=Miguel | publisher=Universidade de São Paulo }}</ref> It also provided the first demonstration of coral larvae susceptibility to bleaching.<ref>{{Cite journal|url=https://doi.org/10.1007/s00227-017-3263-1|title=Bleaching in reef invertebrate larvae associated with Symbiodinium strains within clades A–F|first1=M.|last1=Mies|first2=A. Z.|last2=Güth|first3=C. B.|last3=Castro|first4=D. O.|last4=Pires|first5=E. N.|last5=Calderon|first6=M.|last6=Pompeu|first7=P. Y. G.|last7=Sumida|date=November 9, 2017|journal=Marine Biology|volume=165|issue=1|pages=6|via=Springer Link|doi=10.1007/s00227-017-3263-1|s2cid=253776271 }}</ref>
 ==Career==
@@ Line 10: / Line 10: @@
 ==Research==
-Mies researches subjects such as reef ecology, [[molecular biology]], and [[genetics]] of [[zooxanthellae]], larval development of reef organisms, trophic ecology of corals, and the effects of climate change on [[coral reef]]s.<ref name="auto"/> His research, focused mostly on field and experimental assessments of coral bleaching, spans both global and regional scales.<ref>{{Cite journal|url=https://www.sciencedirect.com/science/article/pii/S0269749120365817|title=Isolated and combined effects of thermal stress and copper exposure on the trophic behavior and oxidative status of the reef-building coral Mussismilia harttii|first1=Juliana|last1=da Silva Fonseca|first2=Miguel|last2=Mies|first3=Alana|last3=Paranhos|first4=Satie|last4=Taniguchi|first5=Arthur Z.|last5=Güth|first6=Márcia C.|last6=Bícego|first7=Joseane Aparecida|last7=Marques|first8=Laura|last8=Fernandes de Barros Marangoni|first9=Adalto|last9=Bianchini|date=January 1, 2021|journal=Environmental Pollution|volume=268|pages=115892|via=ScienceDirect|doi=10.1016/j.envpol.2020.115892}}</ref> His studies have contributed to the understanding of the unique responses of Brazilian coral reefs to climate change, compared to other reef ecosystems.<ref>{{Cite journal|url=https://www.frontiersin.org/articles/10.3389/fmars.2020.00514|title=South Atlantic Coral Reefs Are Major Global Warming Refugia and Less Susceptible to Bleaching|first1=Miguel|last1=Mies|first2=Ronaldo B.|last2=Francini-Filho|first3=Carla|last3=Zilberberg|first4=Amana G.|last4=Garrido|first5=Guilherme O.|last5=Longo|first6=Eduarda|last6=Laurentino|first7=Arthur Z.|last7=Güth|first8=Paulo Y. G.|last8=Sumida|first9=Thomás N. S.|last9=Banha|date=March 12, 2020|journal=Frontiers in Marine Science|volume=7|via=Frontiers|doi=10.3389/fmars.2020.00514}}</ref>
+Mies researches subjects such as reef ecology, [[molecular biology]], and [[genetics]] of [[zooxanthellae]], larval development of reef organisms, trophic ecology of corals, and the effects of climate change on [[coral reef]]s.<ref name="auto"/> His research, focused mostly on field and experimental assessments of coral bleaching, spans both global and regional scales.<ref>{{Cite journal|url=https://www.sciencedirect.com/science/article/pii/S0269749120365817|title=Isolated and combined effects of thermal stress and copper exposure on the trophic behavior and oxidative status of the reef-building coral Mussismilia harttii|first1=Juliana|last1=da Silva Fonseca|first2=Miguel|last2=Mies|first3=Alana|last3=Paranhos|first4=Satie|last4=Taniguchi|first5=Arthur Z.|last5=Güth|first6=Márcia C.|last6=Bícego|first7=Joseane Aparecida|last7=Marques|first8=Laura|last8=Fernandes de Barros Marangoni|first9=Adalto|last9=Bianchini|date=January 1, 2021|journal=Environmental Pollution|volume=268|issue=Pt B |pages=115892|via=ScienceDirect|doi=10.1016/j.envpol.2020.115892|pmid=33120157 |bibcode=2021EPoll.26815892D |s2cid=225175282 }}</ref> His studies have contributed to the understanding of the unique responses of Brazilian coral reefs to climate change, compared to other reef ecosystems.<ref>{{Cite journal|title=South Atlantic Coral Reefs Are Major Global Warming Refugia and Less Susceptible to Bleaching|first1=Miguel|last1=Mies|first2=Ronaldo B.|last2=Francini-Filho|first3=Carla|last3=Zilberberg|first4=Amana G.|last4=Garrido|first5=Guilherme O.|last5=Longo|first6=Eduarda|last6=Laurentino|first7=Arthur Z.|last7=Güth|first8=Paulo Y. G.|last8=Sumida|first9=Thomás N. S.|last9=Banha|date=March 12, 2020|journal=Frontiers in Marine Science|volume=7|doi=10.3389/fmars.2020.00514|doi-access=free }}</ref>
 ==Selected publications==
-* {{Cite journal|url=https://www.frontiersin.org/articles/10.3389/fmars.2020.00514|title=South Atlantic Coral Reefs Are Major Global Warming Refugia and Less Susceptible to Bleaching|first1=Miguel|last1=Mies|first2=Ronaldo B.|last2=Francini-Filho|first3=Carla|last3=Zilberberg|first4=Amana G.|last4=Garrido|first5=Guilherme O.|last5=Longo|first6=Eduarda|last6=Laurentino|first7=Arthur Z.|last7=Güth|first8=Paulo Y. G.|last8=Sumida|first9=Thomás N. S.|last9=Banha|date=March 12, 2020|journal=Frontiers in Marine Science|volume=7|via=Frontiers|doi=10.3389/fmars.2020.00514/full}}
+* {{Cite journal|title=South Atlantic Coral Reefs Are Major Global Warming Refugia and Less Susceptible to Bleaching|first1=Miguel|last1=Mies|first2=Ronaldo B.|last2=Francini-Filho|first3=Carla|last3=Zilberberg|first4=Amana G.|last4=Garrido|first5=Guilherme O.|last5=Longo|first6=Eduarda|last6=Laurentino|first7=Arthur Z.|last7=Güth|first8=Paulo Y. G.|last8=Sumida|first9=Thomás N. S.|last9=Banha|date=March 12, 2020|journal=Frontiers in Marine Science|volume=7|doi=10.3389/fmars.2020.00514|doi-access=free }}
-* {{Cite journal|url=https://doi.org/10.1007/s00338-018-1692-z|title=In situ shifts of predominance between autotrophic and heterotrophic feeding in the reef-building coral Mussismilia hispida: an approach using fatty acid trophic markers|first1=M.|last1=Mies|first2=A. Z.|last2=Güth|first3=A. A.|last3=Tenório|first4=T. N. S.|last4=Banha|first5=L. G.|last5=Waters|first6=P. S.|last6=Polito|first7=S.|last7=Taniguchi|first8=M. C.|last8=Bícego|first9=P. Y. G.|last9=Sumida|date=September 1, 2018|journal=Coral Reefs|volume=37|issue=3|pages=677–689|via=Springer Link|doi=10.1007/s00338-018-1692-z}}
+* {{Cite journal|url=https://doi.org/10.1007/s00338-018-1692-z|title=In situ shifts of predominance between autotrophic and heterotrophic feeding in the reef-building coral Mussismilia hispida: an approach using fatty acid trophic markers|first1=M.|last1=Mies|first2=A. Z.|last2=Güth|first3=A. A.|last3=Tenório|first4=T. N. S.|last4=Banha|first5=L. G.|last5=Waters|first6=P. S.|last6=Polito|first7=S.|last7=Taniguchi|first8=M. C.|last8=Bícego|first9=P. Y. G.|last9=Sumida|date=September 1, 2018|journal=Coral Reefs|volume=37|issue=3|pages=677–689|via=Springer Link|doi=10.1007/s00338-018-1692-z|bibcode=2018CorRe..37..677M |s2cid=253806861 }}
-* {{Cite journal|url=https://doi.org/10.1007/s00338-019-01856-y|title=Low coral mortality during the most intense bleaching event ever recorded in subtropical Southwestern Atlantic reefs|first1=T. N. S.|last1=Banha|first2=K. C. C.|last2=Capel|first3=M. V.|last3=Kitahara|first4=R. B.|last4=Francini-Filho|first5=C. L. B.|last5=Francini|first6=P. Y. G.|last6=Sumida|first7=M.|last7=Mies|date=June 1, 2020|journal=Coral Reefs|volume=39|issue=3|pages=515–521|via=Springer Link|doi=10.1007/s00338-019-01856-y}}
+* {{Cite journal|url=https://doi.org/10.1007/s00338-019-01856-y|title=Low coral mortality during the most intense bleaching event ever recorded in subtropical Southwestern Atlantic reefs|first1=T. N. S.|last1=Banha|first2=K. C. C.|last2=Capel|first3=M. V.|last3=Kitahara|first4=R. B.|last4=Francini-Filho|first5=C. L. B.|last5=Francini|first6=P. Y. G.|last6=Sumida|first7=M.|last7=Mies|date=June 1, 2020|journal=Coral Reefs|volume=39|issue=3|pages=515–521|via=Springer Link|doi=10.1007/s00338-019-01856-y|s2cid=253811219 }}
-* {{Cite journal|url=https://www.tandfonline.com/doi/full/10.1080/23308249.2017.1285864|title=Production in Giant Clam Aquaculture: Trends and Challenges|first1=M.|last1=Mies|first2=P.|last2=Dor|first3=A. Z.|last3=Güth|first4=P. Y. G.|last4=Sumida|date=October 2, 2017|journal=Reviews in Fisheries Science & Aquaculture|volume=25|issue=4|pages=286–296|via=CrossRef|doi=10.1080/23308249.2017.1285864}}
+* {{Cite journal|url=https://www.tandfonline.com/doi/full/10.1080/23308249.2017.1285864|title=Production in Giant Clam Aquaculture: Trends and Challenges|first1=M.|last1=Mies|first2=P.|last2=Dor|first3=A. Z.|last3=Güth|first4=P. Y. G.|last4=Sumida|date=October 2, 2017|journal=Reviews in Fisheries Science & Aquaculture|volume=25|issue=4|pages=286–296|via=CrossRef|doi=10.1080/23308249.2017.1285864|bibcode=2017RvFSA..25..286M |s2cid=90048377 }}
-* {{Cite journal|url=https://www.frontiersin.org/articles/10.3389/fevo.2017.00056|title=Marine Invertebrate Larvae Associated with Symbiodinium: A Mutualism from the Start?|first1=Miguel|last1=Mies|first2=Paulo Y. G.|last2=Sumida|first3=Nils|last3=Rädecker|first4=Christian R.|last4=Voolstra|date=March 12, 2017|journal=Frontiers in Ecology and Evolution|volume=5|via=Frontiers|doi=10.3389/fevo.2017.00056/full}}
+* {{Cite journal|title=Marine Invertebrate Larvae Associated with Symbiodinium: A Mutualism from the Start?|first1=Miguel|last1=Mies|first2=Paulo Y. G.|last2=Sumida|first3=Nils|last3=Rädecker|first4=Christian R.|last4=Voolstra|date=March 12, 2017|journal=Frontiers in Ecology and Evolution|volume=5|doi=10.3389/fevo.2017.00056|doi-access=free }}
-* {{Cite journal|url=https://royalsocietypublishing.org/doi/10.1098/rsos.170253|title=Expression of a symbiosis-specific gene in Symbiodinium type A1 associated with coral, nudibranch and giant clam larvae|first1=M.|last1=Mies|first2=C. R.|last2=Voolstra|first3=C. B.|last3=Castro|first4=D. O.|last4=Pires|first5=E. N.|last5=Calderon|first6=P. Y. G.|last6=Sumida|date=May 12, 2017|journal=Royal Society Open Science|volume=4|issue=5|pages=170253|via=CrossRef|doi=10.1098/rsos.170253|pmid=28573035|pmc=PMC5451836}}
+* {{Cite journal|title=Expression of a symbiosis-specific gene in Symbiodinium type A1 associated with coral, nudibranch and giant clam larvae|first1=M.|last1=Mies|first2=C. R.|last2=Voolstra|first3=C. B.|last3=Castro|first4=D. O.|last4=Pires|first5=E. N.|last5=Calderon|first6=P. Y. G.|last6=Sumida|date=May 12, 2017|journal=Royal Society Open Science|volume=4|issue=5|pages=170253|doi=10.1098/rsos.170253|pmid=28573035|pmc=5451836|bibcode=2017RSOS....470253M }}
-* {{Cite journal|url=https://www.scielo.br/j/bjoce/a/6Jzmg8bnTLnCwk9Wmt3fzsQ/?lang=en|title=Early development, survival and growth rates of the giant clam Tridacna crocea (Bivalvia: Tridacnidae)|first1=Miguel|last1=Mies|first2=Felipe|last2=Braga|first3=Marcello Santos|last3=Scozzafave|first4=Daniel Eduardo Lavanholi de|last4=Lemos|first5=Paulo Yukio Gomes|last5=Sumida|date=June 12, 2012|journal=Brazilian Journal of Oceanography|volume=60|pages=127–133|via=SciELO}}
+* {{Cite journal|url=https://www.scielo.br/j/bjoce/a/6Jzmg8bnTLnCwk9Wmt3fzsQ/?lang=en|title=Early development, survival and growth rates of the giant clam Tridacna crocea (Bivalvia: Tridacnidae)|first1=Miguel|last1=Mies|first2=Felipe|last2=Braga|first3=Marcello Santos|last3=Scozzafave|first4=Daniel Eduardo Lavanholi de|last4=Lemos|first5=Paulo Yukio Gomes|last5=Sumida|date=June 12, 2012|journal=Brazilian Journal of Oceanography|volume=60|issue=2 |pages=127–133|doi=10.1590/S1679-87592012000200003 |via=SciELO}}
-* {{Cite journal|url=https://doi.org/10.1007/s00338-019-01857-x|title=Evolution, diversity, distribution and the endangered future of the giant clam–Symbiodiniaceae association|first=Miguel|last=Mies|date=December 1, 2019|journal=Coral Reefs|volume=38|issue=6|pages=1067–1084|via=Springer Link|doi=10.1007/s00338-019-01857-x}}
+* {{Cite journal|url=https://doi.org/10.1007/s00338-019-01857-x|title=Evolution, diversity, distribution and the endangered future of the giant clam–Symbiodiniaceae association|first=Miguel|last=Mies|date=December 1, 2019|journal=Coral Reefs|volume=38|issue=6|pages=1067–1084|via=Springer Link|doi=10.1007/s00338-019-01857-x|bibcode=2019CorRe..38.1067M |s2cid=203388892 }}
-* {{Cite journal|url=https://www.mdpi.com/2076-2607/7/10/426|title=Peroxynitrite Generation and Increased Heterotrophic Capacity Are Linked to the Disruption of the Coral–Dinoflagellate Symbiosis in a Scleractinian and Hydrocoral Species|first1=Laura Fernandes de Barros|last1=Marangoni|first2=Miguel|last2=Mies|first3=Arthur Z.|last3=Güth|first4=Thomás N. S.|last4=Banha|first5=Alex|last5=Inague|first6=Juliana da Silva|last6=Fonseca|first7=Camila|last7=Dalmolin|first8=Samuel Coelho|last8=Faria|first9=Christine|last9=Ferrier-Pagès|first10=Adalto|last10=Bianchini|date=October 12, 2019|journal=Microorganisms|volume=7|issue=10|pages=426|via=www.mdpi.com|doi=10.3390/microorganisms7100426}}
+* {{Cite journal|title=Peroxynitrite Generation and Increased Heterotrophic Capacity Are Linked to the Disruption of the Coral–Dinoflagellate Symbiosis in a Scleractinian and Hydrocoral Species|first1=Laura Fernandes de Barros|last1=Marangoni|first2=Miguel|last2=Mies|first3=Arthur Z.|last3=Güth|first4=Thomás N. S.|last4=Banha|first5=Alex|last5=Inague|first6=Juliana da Silva|last6=Fonseca|first7=Camila|last7=Dalmolin|first8=Samuel Coelho|last8=Faria|first9=Christine|last9=Ferrier-Pagès|first10=Adalto|last10=Bianchini|date=October 12, 2019|journal=Microorganisms|volume=7|issue=10|pages=426|doi=10.3390/microorganisms7100426|doi-access=free |pmid=31600926 |pmc=6843776 }}
 ==References==