Disentangling specific and unspecific components of innate immune memory in a copepod–tapeworm system

Ng TH; Harrison MC; Scharsack JP; Kurtz J

Forschungsartikel (Zeitschrift) | Peer reviewed

Zusammenfassung

Evidence that the innate immune system can respond with forms of memory upon reinfection has been accumulating over the past few years. These phenomena of “immune priming” in invertebrates, and “trained immunity” in vertebrates, are contrary to previous belief that immune memory and specificity are restricted to the adaptive immune system. However, while trained immunity is usually a response with rather low specificity, immune priming has shown highly specific responses in certain species. To date, it is largely unknown how specificity in innate immune memory can be achieved in response to different parasite types. Here, we revisited a system where an exceptionally high degree of innate immune specificity had been demonstrated for the first time, consisting of the copepod Macrocyclops albidus and its natural parasite, the tapeworm Schistocephalus solidus. Using homologous (same family) vs. heterologous (different family) priming-challenge experiments, we first confirm that copepods exposed to the same parasite family benefit from reduced secondary infections. We further focused on exposed-but-not-infected copepods in primary exposure to employ a transcriptomic approach, distinguishing between immunity that was either specific or unspecific regarding the discrimination between tapeworm types. A weighted gene co−expression network (WGCN) revealed differences between specific and unspecific immunity; while both involved histone modification regulation, specific immunity involved gene-splicing factors, whereas unspecific immunity was primarily involved in metabolic shift. We found a functional enrichment in spliceosome in specific immunity, whereas oxidative phosphorylation and carbon metabolism were enriched in unspecific immunity. Our findings allow discrimination of specific and unspecific components of an innate immune memory, based on gene expression networks, and deepen our understanding of basic aspects of immune systems. Copyright © 2024 Ng, Harrison, Scharsack and Kurtz.

Details zur Publikation

FachzeitschriftFrontiers in immunology (Front Immunol)
Jahrgang / Bandnr. / Volume15
StatusVeröffentlicht
Veröffentlichungsjahr2024
Sprache, in der die Publikation verfasst istEnglisch
DOI: 10.3389/fimmu.2024.1307477
Link zum Volltexthttps://www.scopus.com/inward/record.uri?eid=2-s2.0-85184683980&doi=10.3389%2ffimmu.2024.1307477&partnerID=40&md5=1ddf18ddb68e1fd558c53fb6562d3672
StichwörterAnimals; Cestoda; Cestode Infections; Copepoda; Host-Parasite Interactions; Immunologic Memory; Parasites; Trained Immunity; heat shock protein; heterochromatin protein 1; histone acetyltransferase; histone deacetylase; RNA polymerase II; adult; Article; controlled study; copepod; differential expression analysis; fluorescence analysis; gene ontology; histone modification; immunological memory; innate immunity; macrocyclops albidus; male; nonhuman; oxidative phosphorylation; parasite; protein protein interaction; quality control; reinfection; risk assessment; RNA sequencing; schistocephalus solidus; transcriptomics; upregulation; weighted gene co expression network analysis; animal; cestode; cestodiasis; genetics; host parasite interaction; immunological memory; parasite; parasitology; trained immunity

Autor*innen der Universität Münster

Kurtz, Joachim
Arbeitsgruppe Evolutionsökologie der Tiere (Prof. Kurtz)