Chan J , Wang L , Li L , Mu K , Bushek D , Xu Y , Guo X , Zhang G , Zhang L .

	FIGURE 1. Schematic diagram of experimental design. FSW, filtered seawater.
	FIGURE 2. Transcriptional changes induced by P. marinus in C. virginica. (A), Volcano plots of transcriptional change under short-term and long-term P. marinus challenge. Blue points represent downregulated genes, red points represent upregulated genes, and black points represent non-differentially expressed genes. (B), Functional annotation of differentially expressed genes under P. marinus challenge. (C), Immune-related genes significantly up-regulated after dermo challenge.
	FIGURE 3. Comparative transcriptome analysis between C. gigas and C. virginica under P. marinus challenge. (A), Number of immune-related genes identified (Left) and number of immune-related genes differentially expressed (Right) in C. gigas (Cg) and C. virginica (Cv). (B), Venn diagrams of differentially expressed immune genes under P. marinus challenge between the two oyster species. (C), Unique and differentially expressed immune genes induced by P. marinus in two oyster species. (D), Transcriptional change of differentially expressed immune genes shared by two oyster species, including pattern recognition receptors (e.g., TLRs) and immune effectors (e.g., TRAFs).
	FIGURE 4. GO enrichment analysis of the differentially expressed genes after Dermo challenge between C. virginica (A) and C. gigas (B). Red and blue columns represent functional enrichments of up-regulated and down-regulated genes, respectively.
	FIGURE 5. Expansion of TLRs and divergent expression patterns under P. marinus challenge between C. gigas and C. virginica. (A), Phylogenetic tree constructed with the maximum likelihood method showing lineage-specific expansion of TLRs in C. gigas (red font) and C. virginica (blue font). Red and blue asterisks represent the differentially expressed TLRs in C. gigas and C. virginica, respectively. (B), Comparison of TLRs with different domain architectures in: human (Homo sapiens-Hs), sea urchin (Strongylocentrotus purpuratus-SP), fruit fly (Drosophila melanogaster-Dm), Pacific oyster (Crassostrea gigas-Cg), Eastern oyster (Crassostrea virginica-Cv), and staghorn coral (Acropora digitifera-Ad). LRRCT in red, LRRNT in blue and LRR in yellow. Toll/interleukin-1 receptor (TIR) domains are shown as gold triangles. (C), Diverse expression pattern of the differentially expressed TLRs, marked with asterisks in (A), during P. marinus challenge in C. gigas (Top) and C. virginica (Bottom).
	FIGURE 6. Tandem duplication and positive selection of TLRs in C. virginica. (A), Tandem repeats as the major source of TLRs duplication in C. virginica. (B), The largest tandem repeat cluster (Top) and divergent expression patterns (Bottom) of tandemly linked TLRs in NC_035786.1 under P. marinus challenge. The wide arrows represent TLR genes, and genes with red background are differentially expressed under P. marinus challenge. A pseudogene LOC111105057 was detected in this repeat cluster. (C), Evolutionary relationships of duplicated TLRs. The calculated dN/dS (ω) values (gold) and bootstrap values are shown for each branch. The branches with ω values >1.0 are marked with red rectangle. The differential genes under P. marinus challenge that are positively selected are boxed with red dash lines. (D), Structural modeling of TLR depicting sites (blue) under positive selection. Positive selection sites (Asp27, Glu62, Asn199) are represented by black arrows.
	FIGURE 7. Expansion of C1qDCs and divergent expression patterns under P. marinus challenge between C. virginica and C. gigas. (A), Phylogenetic tree constructed with the maximum likelihood method showing lineage-specific expansion of C1qDCs in C. virginica (red font) and C. gigas (gray font). Different color backgrounds represent different types of C1qDC domain composition, and the red and gray asterisks represent differentially expressed C1qDCs under P. marinus challenge in C. virginica and C. gigas, respectively. (B), Domain composition of the “galactose-binding lectin” containing C1qDC gene. (C), A C1qDC gene (LOC111120224) with “galactose-binding lectin” domain was significantly upregulated in C. virginica after P. marinus challenge.
	FIGURE 8. Expansion and phylogeny of FBGDC gene family in C. virginica (red font) and C. gigas (gray font). The phylogenetic tree is constructed with the maximum likelihood method showing lineage-specific expansion of FBGDC in C. virginica (red font) and C. gigas (gray font). Different color backgrounds represent different domain composition types, and the red and gray asterisks represent differentially expressed FBGDCs under P. marinus challenge in C. virginica and C. gigas, respectively.

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