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Main Authors: Marulanda-Gomez, Angela M, Mueller, Benjamin, Bayer, Kristina, Abukhalaf, Mohammad, Cassidy, Liam, Tholey, Andreas, Fraune, Sebastian, Pita, Lucia, Hentschel, Ute
Format: Artículo científico
Language:en
Published: mBio 2025
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Online Access:https://pubmed.ncbi.nlm.nih.gov/40576359/
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author Marulanda-Gomez, Angela M
Mueller, Benjamin
Bayer, Kristina
Abukhalaf, Mohammad
Cassidy, Liam
Tholey, Andreas
Fraune, Sebastian
Pita, Lucia
Hentschel, Ute
author_facet Marulanda-Gomez, Angela M
Mueller, Benjamin
Bayer, Kristina
Abukhalaf, Mohammad
Cassidy, Liam
Tholey, Andreas
Fraune, Sebastian
Pita, Lucia
Hentschel, Ute
Marulanda-Gomez, Angela M
Mueller, Benjamin
Bayer, Kristina
Abukhalaf, Mohammad
Cassidy, Liam
Tholey, Andreas
Fraune, Sebastian
Pita, Lucia
Hentschel, Ute
collection PubMed - marine biology
contents Combined cellular and proteomics approach suggests differential processing of a native and a foreign vibrio in the sponge . Marulanda-Gomez, Angela M Mueller, Benjamin Bayer, Kristina Abukhalaf, Mohammad Cassidy, Liam Tholey, Andreas Fraune, Sebastian Pita, Lucia Hentschel, Ute Animals Vibrio Proteomics Phagocytosis Porifera Proteome Phagocytosis is a conserved cellular mechanism for food uptake, defense, and animal-microbe interactions in metazoans. How the discrimination and subsequent processing of different microbes in marine invertebrates is facilitated remains largely unknown. Thereto, we combined a recently developed phagocytic assay with proteomics analysis to compare the phagocytic activity of the sponge upon encounter with the native Hal 281 (i.e., isolate) and the foreign NJ 1 (i.e., isolate) . The sponge cell fraction was recovered after exposure of 30 and 60 min and used for cellular (fluorescence-activated cell sorting and microscopy) and proteomics analyses. While the number of phagocytically active cells was similar between the isolates ( = 0.19), the distribution of vibrios over cell types differed ( = 0.02) over time, with the tendency for accumulation of NJ 1 in choanocyte-like cells compared to a shift of Hal 281 being incorporated from choanocyte-like to archaeocyte-like cells. Initially, both vibrios elicited a proteomic response related to bacterial infection and immunity (e.g., ADAM10, RAPTOR), followed by an increase of lysosomal and endocytic proteins (e.g., NPC2) after 60 min. The attenuation of the immune response and concomitant increase of vesicular trafficking in Hal 281 after 60 min corroborates cellular observations suggesting the fast transfer of Hal 281 from choanocyte-like cells to archaeocyte-like cells, compared to an accumulation of NJ 1 in the former. Subtle but distinct differences suggest strain-specific discrimination between the two tested vibrios and may indicate a degree of immune specificity in sponges. Metazoans recognize and discriminate between different microbes. In marine invertebrates, the underlying mechanisms of microbial discrimination and immune specificity are, however, not well understood. Phagocytosis is a conserved cellular process from amoeba to humans that facilitates the ingestion and digestion of microbial cells and likely plays a role in this discrimination. To elucidate the molecular and cellular basis of this microbial discrimination, we examined the differential phagocytic processing of a native (i.e., sponge-isolated) and foreign (i.e., sea anemone-isolate) in a marine sponge. Our findings revealed that both vibrios provoke an initial bacterial infection- and immune-related, followed by a lysosomal- and endocytic-related proteomic response. Nuanced differences in the cellular and molecular processing suggest a strain-specific discrimination between the two vibrios. This study investigates a mechanism for microbial discrimination in an early-divergent metazoan and may provide a valuable model for studying the evolution of immunity and its role in animal-microbe interactions.
format Artículo científico
id pubmed_40576359
institution PubMed
language en
publishDate 2025
publisher mBio
record_format pubmed
spellingShingle Combined cellular and proteomics approach suggests differential processing of a native and a foreign vibrio in the sponge .
Marulanda-Gomez, Angela M
Mueller, Benjamin
Bayer, Kristina
Abukhalaf, Mohammad
Cassidy, Liam
Tholey, Andreas
Fraune, Sebastian
Pita, Lucia
Hentschel, Ute
Animals
Vibrio
Proteomics
Phagocytosis
Porifera
Proteome
Combined cellular and proteomics approach suggests differential processing of a native and a foreign vibrio in the sponge . Marulanda-Gomez, Angela M Mueller, Benjamin Bayer, Kristina Abukhalaf, Mohammad Cassidy, Liam Tholey, Andreas Fraune, Sebastian Pita, Lucia Hentschel, Ute Animals Vibrio Proteomics Phagocytosis Porifera Proteome Phagocytosis is a conserved cellular mechanism for food uptake, defense, and animal-microbe interactions in metazoans. How the discrimination and subsequent processing of different microbes in marine invertebrates is facilitated remains largely unknown. Thereto, we combined a recently developed phagocytic assay with proteomics analysis to compare the phagocytic activity of the sponge upon encounter with the native Hal 281 (i.e., isolate) and the foreign NJ 1 (i.e., isolate) . The sponge cell fraction was recovered after exposure of 30 and 60 min and used for cellular (fluorescence-activated cell sorting and microscopy) and proteomics analyses. While the number of phagocytically active cells was similar between the isolates ( = 0.19), the distribution of vibrios over cell types differed ( = 0.02) over time, with the tendency for accumulation of NJ 1 in choanocyte-like cells compared to a shift of Hal 281 being incorporated from choanocyte-like to archaeocyte-like cells. Initially, both vibrios elicited a proteomic response related to bacterial infection and immunity (e.g., ADAM10, RAPTOR), followed by an increase of lysosomal and endocytic proteins (e.g., NPC2) after 60 min. The attenuation of the immune response and concomitant increase of vesicular trafficking in Hal 281 after 60 min corroborates cellular observations suggesting the fast transfer of Hal 281 from choanocyte-like cells to archaeocyte-like cells, compared to an accumulation of NJ 1 in the former. Subtle but distinct differences suggest strain-specific discrimination between the two tested vibrios and may indicate a degree of immune specificity in sponges. Metazoans recognize and discriminate between different microbes. In marine invertebrates, the underlying mechanisms of microbial discrimination and immune specificity are, however, not well understood. Phagocytosis is a conserved cellular process from amoeba to humans that facilitates the ingestion and digestion of microbial cells and likely plays a role in this discrimination. To elucidate the molecular and cellular basis of this microbial discrimination, we examined the differential phagocytic processing of a native (i.e., sponge-isolated) and foreign (i.e., sea anemone-isolate) in a marine sponge. Our findings revealed that both vibrios provoke an initial bacterial infection- and immune-related, followed by a lysosomal- and endocytic-related proteomic response. Nuanced differences in the cellular and molecular processing suggest a strain-specific discrimination between the two vibrios. This study investigates a mechanism for microbial discrimination in an early-divergent metazoan and may provide a valuable model for studying the evolution of immunity and its role in animal-microbe interactions.
title Combined cellular and proteomics approach suggests differential processing of a native and a foreign vibrio in the sponge .
topic Animals
Vibrio
Proteomics
Phagocytosis
Porifera
Proteome
url https://pubmed.ncbi.nlm.nih.gov/40576359/