Imaging Arm Regeneration: Label-Free Multiphoton Microscopy to Dissect the Process in Octopus vulgaris

Cephalopod mollusks are endowed with an impressive range of features that have captured the attention of scientists from different fields, the imaginations of artists, and the interests of the public. The ability to spontaneously regrow lost or damaged structures quickly and functionally is among on...

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Published in	Frontiers in cell and developmental biology Vol. 10; p. 814746
Main Authors	Imperadore, Pamela, Galli, Roberta, Winterhalder, Martin J., Zumbusch, Andreas, Uckermann, Ortrud
Format	Journal Article
Language	English
Published	Switzerland Frontiers Media S.A 04.02.2022
Subjects	Cell and Developmental Biology cephalopod mollusks chromatophores hemocytes label-free imaging spontaneous functional regeneration vibrational spectroscopy label-free imaging vibrational spectroscopy chromatophores spontaneous functional regeneration cephalopod mollusks hemocytes
Online Access	Get full text
ISSN	2296-634X 2296-634X
DOI	10.3389/fcell.2022.814746

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Abstract	Cephalopod mollusks are endowed with an impressive range of features that have captured the attention of scientists from different fields, the imaginations of artists, and the interests of the public. The ability to spontaneously regrow lost or damaged structures quickly and functionally is among one of the most notable peculiarities that cephalopods possess. Microscopical imaging techniques represent useful tools for investigating the regenerative processes in several species, from invertebrates to mammals. However, these techniques have had limited use in cephalopods mainly due to the paucity of specific and commercially available markers. In addition, the commonly used immunohistochemical staining methods provide data that are specific to the antigens studied. New microscopical methods were recently applied to vertebrates to investigate regenerative events. Among them, multiphoton microscopy appears promising. For instance, it does not depend on species-related epitopes, taking advantage of the specific characteristics of tissues and allowing for its use in a species-independent way. Here, we illustrate the results obtained by applying this label-free imaging technique to the injured arm of Octopus vulgaris , a complex structure often subject to injury in the wild. This approach allowed for the characterization of the entire tissue arm architecture (muscular layers, nerve component, connective tissues, etc.) and elements usually hardly detectable (such as vessels, hemocytes, and chromatophores). More importantly, it also provided morpho-chemical information which helped decipher the regenerative phases after damage, from healing to complete arm regrowth, thereby appearing promising for regenerative studies in cephalopods and other non-model species.
AbstractList	Cephalopod mollusks are endowed with an impressive range of features that have captured the attention of scientists from different fields, the imaginations of artists, and the interests of the public. The ability to spontaneously regrow lost or damaged structures quickly and functionally is among one of the most notable peculiarities that cephalopods possess. Microscopical imaging techniques represent useful tools for investigating the regenerative processes in several species, from invertebrates to mammals. However, these techniques have had limited use in cephalopods mainly due to the paucity of specific and commercially available markers. In addition, the commonly used immunohistochemical staining methods provide data that are specific to the antigens studied. New microscopical methods were recently applied to vertebrates to investigate regenerative events. Among them, multiphoton microscopy appears promising. For instance, it does not depend on species-related epitopes, taking advantage of the specific characteristics of tissues and allowing for its use in a species-independent way. Here, we illustrate the results obtained by applying this label-free imaging technique to the injured arm of Octopus vulgaris , a complex structure often subject to injury in the wild. This approach allowed for the characterization of the entire tissue arm architecture (muscular layers, nerve component, connective tissues, etc.) and elements usually hardly detectable (such as vessels, hemocytes, and chromatophores). More importantly, it also provided morpho-chemical information which helped decipher the regenerative phases after damage, from healing to complete arm regrowth, thereby appearing promising for regenerative studies in cephalopods and other non-model species. Cephalopod mollusks are endowed with an impressive range of features that have captured the attention of scientists from different fields, the imaginations of artists, and the interests of the public. The ability to spontaneously regrow lost or damaged structures quickly and functionally is among one of the most notable peculiarities that cephalopods possess. Microscopical imaging techniques represent useful tools for investigating the regenerative processes in several species, from invertebrates to mammals. However, these techniques have had limited use in cephalopods mainly due to the paucity of specific and commercially available markers. In addition, the commonly used immunohistochemical staining methods provide data that are specific to the antigens studied. New microscopical methods were recently applied to vertebrates to investigate regenerative events. Among them, multiphoton microscopy appears promising. For instance, it does not depend on species-related epitopes, taking advantage of the specific characteristics of tissues and allowing for its use in a species-independent way. Here, we illustrate the results obtained by applying this label-free imaging technique to the injured arm of , a complex structure often subject to injury in the wild. This approach allowed for the characterization of the entire tissue arm architecture (muscular layers, nerve component, connective tissues, etc.) and elements usually hardly detectable (such as vessels, hemocytes, and chromatophores). More importantly, it also provided morpho-chemical information which helped decipher the regenerative phases after damage, from healing to complete arm regrowth, thereby appearing promising for regenerative studies in cephalopods and other non-model species. Cephalopod mollusks are endowed with an impressive range of features that have captured the attention of scientists from different fields, the imaginations of artists, and the interests of the public. The ability to spontaneously regrow lost or damaged structures quickly and functionally is among one of the most notable peculiarities that cephalopods possess. Microscopical imaging techniques represent useful tools for investigating the regenerative processes in several species, from invertebrates to mammals. However, these techniques have had limited use in cephalopods mainly due to the paucity of specific and commercially available markers. In addition, the commonly used immunohistochemical staining methods provide data that are specific to the antigens studied. New microscopical methods were recently applied to vertebrates to investigate regenerative events. Among them, multiphoton microscopy appears promising. For instance, it does not depend on species-related epitopes, taking advantage of the specific characteristics of tissues and allowing for its use in a species-independent way. Here, we illustrate the results obtained by applying this label-free imaging technique to the injured arm of Octopus vulgaris, a complex structure often subject to injury in the wild. This approach allowed for the characterization of the entire tissue arm architecture (muscular layers, nerve component, connective tissues, etc.) and elements usually hardly detectable (such as vessels, hemocytes, and chromatophores). More importantly, it also provided morpho-chemical information which helped decipher the regenerative phases after damage, from healing to complete arm regrowth, thereby appearing promising for regenerative studies in cephalopods and other non-model species.Cephalopod mollusks are endowed with an impressive range of features that have captured the attention of scientists from different fields, the imaginations of artists, and the interests of the public. The ability to spontaneously regrow lost or damaged structures quickly and functionally is among one of the most notable peculiarities that cephalopods possess. Microscopical imaging techniques represent useful tools for investigating the regenerative processes in several species, from invertebrates to mammals. However, these techniques have had limited use in cephalopods mainly due to the paucity of specific and commercially available markers. In addition, the commonly used immunohistochemical staining methods provide data that are specific to the antigens studied. New microscopical methods were recently applied to vertebrates to investigate regenerative events. Among them, multiphoton microscopy appears promising. For instance, it does not depend on species-related epitopes, taking advantage of the specific characteristics of tissues and allowing for its use in a species-independent way. Here, we illustrate the results obtained by applying this label-free imaging technique to the injured arm of Octopus vulgaris, a complex structure often subject to injury in the wild. This approach allowed for the characterization of the entire tissue arm architecture (muscular layers, nerve component, connective tissues, etc.) and elements usually hardly detectable (such as vessels, hemocytes, and chromatophores). More importantly, it also provided morpho-chemical information which helped decipher the regenerative phases after damage, from healing to complete arm regrowth, thereby appearing promising for regenerative studies in cephalopods and other non-model species. Cephalopod mollusks are endowed with an impressive range of features that have captured the attention of scientists from different fields, the imaginations of artists, and the interests of the public. The ability to spontaneously regrow lost or damaged structures quickly and functionally is among one of the most notable peculiarities that cephalopods possess. Microscopical imaging techniques represent useful tools for investigating the regenerative processes in several species, from invertebrates to mammals. However, these techniques have had limited use in cephalopods mainly due to the paucity of specific and commercially available markers. In addition, the commonly used immunohistochemical staining methods provide data that are specific to the antigens studied. New microscopical methods were recently applied to vertebrates to investigate regenerative events. Among them, multiphoton microscopy appears promising. For instance, it does not depend on species-related epitopes, taking advantage of the specific characteristics of tissues and allowing for its use in a species-independent way. Here, we illustrate the results obtained by applying this label-free imaging technique to the injured arm of Octopus vulgaris, a complex structure often subject to injury in the wild. This approach allowed for the characterization of the entire tissue arm architecture (muscular layers, nerve component, connective tissues, etc.) and elements usually hardly detectable (such as vessels, hemocytes, and chromatophores). More importantly, it also provided morpho-chemical information which helped decipher the regenerative phases after damage, from healing to complete arm regrowth, thereby appearing promising for regenerative studies in cephalopods and other non-model species.
Author	Zumbusch, Andreas Winterhalder, Martin J. Imperadore, Pamela Uckermann, Ortrud Galli, Roberta
AuthorAffiliation	2 Association for Cephalopod Research—CephRes , Napoli , Italy 4 Medical Physics and Biomedical Engineering , Faculty of Medicine Carl Gustav Carus, TU Dresden , Dresden , Germany 7 Division of Medical Biology , Department of Psychiatry and Psychotherapy , University Hospital Carl Gustav Carus and Faculty of Medicine, TU Dresden , Dresden , Germany 5 Department of Chemistry , University of Konstanz , Konstanz , Germany 6 Department of Neurosurgery , University Hospital Carl Gustav Carus and Faculty of Medicine, TU Dresden , Dresden , Germany 1 Department of Biology and Evolution of Marine Organisms , Napoli , Italy 3 Clinical Sensoring and Monitoring , Anesthesiology and Intensive Care Medicine, TU Dresden , Dresden , Germany
AuthorAffiliation_xml	– name: 4 Medical Physics and Biomedical Engineering , Faculty of Medicine Carl Gustav Carus, TU Dresden , Dresden , Germany – name: 5 Department of Chemistry , University of Konstanz , Konstanz , Germany – name: 1 Department of Biology and Evolution of Marine Organisms , Napoli , Italy – name: 2 Association for Cephalopod Research—CephRes , Napoli , Italy – name: 3 Clinical Sensoring and Monitoring , Anesthesiology and Intensive Care Medicine, TU Dresden , Dresden , Germany – name: 7 Division of Medical Biology , Department of Psychiatry and Psychotherapy , University Hospital Carl Gustav Carus and Faculty of Medicine, TU Dresden , Dresden , Germany – name: 6 Department of Neurosurgery , University Hospital Carl Gustav Carus and Faculty of Medicine, TU Dresden , Dresden , Germany
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Cites_doi	10.3389/fphys.2017.00598 10.1177/0023677215580006 10.3389/fphys.2018.00593 10.3390/cells9091925 10.1017/s1464793101005772 10.1016/j.zool.2021.125940 10.1117/1.jbo.18.11.116011 10.1111/j.1469-7998.1992.tb04606.x 10.1016/j.stem.2014.06.009 10.1016/j.jembe.2013.02.015 10.1111/j.1469-7998.1963.tb01862.x 10.1098/rsif.2017.0889 10.1016/j.jneumeth.2009.01.021 10.1038/nbt899 10.1007/s12035-014-8842-2 10.3389/fcell.2017.00053 10.1111/j.1365-2818.2007.01729.x 10.1038/s41598-020-69222-5 10.1007/978-3-030-42618-7_25 10.3389/fphys.2017.00393 10.1016/j.msec.2010.12.004 10.1038/srep46564 10.1016/B978-0-12-751411-6.50010-2 10.36253/88-8453-376-7 10.1089/soro.2014.0001 10.1088/1748-3190/10/4/046012 10.1002/jez.1400310102 10.1007/s10158-013-0165-x 10.1016/j.optcom.2007.07.067 10.1002/dvdy.178 10.1016/B978-0-12-751411-6.50016-3 10.1073/pnas.0508282102 10.1038/s41598-019-49067-3
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Copyright	Copyright © 2022 Imperadore, Galli, Winterhalder, Zumbusch and Uckermann. Copyright © 2022 Imperadore, Galli, Winterhalder, Zumbusch and Uckermann. 2022 Imperadore, Galli, Winterhalder, Zumbusch and Uckermann
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Keywords	label-free imaging vibrational spectroscopy chromatophores spontaneous functional regeneration cephalopod mollusks hemocytes
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SubjectTerms	Cell and Developmental Biology cephalopod mollusks chromatophores hemocytes label-free imaging spontaneous functional regeneration vibrational spectroscopy
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Title	Imaging Arm Regeneration: Label-Free Multiphoton Microscopy to Dissect the Process in Octopus vulgaris
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