The genome of the reef-building glass sponge Aphrocallistes vastus provides insights into silica biomineralization.
Warren R FrancisMichael EitelSergio VargasCatalina A Garcia-EscuderoNicola ConciFabian DeisterJasmine L MahNadège GuiglielmoniStefan KrebsHelmut BlumSally P LeysGert WörheidePublished in: Royal Society open science (2023)
Well-annotated and contiguous genomes are an indispensable resource for understanding the evolution, development, and metabolic capacities of organisms. Sponges, an ecologically important non-bilaterian group of primarily filter-feeding sessile aquatic organisms, are underrepresented with respect to available genomic resources. Here we provide a high-quality and well-annotated genome of Aphrocallistes vastus , a glass sponge (Porifera: Hexactinellida) that forms large reef structures off the coast of British Columbia (Canada). We show that its genome is approximately 80 Mb, small compared to most other metazoans, and contains nearly 2500 nested genes, more than other genomes. Hexactinellida is characterized by a unique skeletal architecture made of amorphous silicon dioxide (SiO 2 ), and we identified 419 differentially expressed genes between the osculum, i.e. the vertical growth zone of the sponge, and the main body. Among the upregulated ones, mineralization-related genes such as glassin, as well as collagens and actins, dominate the expression profile during growth. Silicateins, suggested being involved in silica mineralization, especially in demosponges, were not found at all in the A. vastus genome and suggests that the underlying mechanisms of SiO 2 deposition in the Silicea sensu stricto (Hexactinellida + Demospongiae) may not be homologous.