A consensus genome sequence for the social amoeba Dictyostelium giganteum

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Abstract

ABSTRACT The life cycle of the Dictyostelid amoebae is unusual in that it alternates between a free-living solitary phase and an aggregative social phase. We used six previously collected Dictyostelium giganteum strains from distinct ecological niches in the Mudumalai Nature Reserve, India. From them, we generated short Illumina reads and assembled a consensus genome, comprising nuclear and mitochondrial genomes, representative of all six strains. The nuclear assembly has an AT content of 75.76%, accounting for 38.52 Mb, and resolves into five chromosome-scale scaffolds that are consistent with the published karyotype. Its N50 is 3.01 Mb and L50 is 5. The BUSCO analysis shows 3.9% fragmentation and 92.1% completeness. Genome assembly and completeness are also validated using ∼5,500 genes from a publicly available transcriptome dataset (PRJNA48443) derived from the post-aggregation stage. 13,251 predicted proteins are encoded by the genome, including ABC transporters, polyketide synthases, Ras/Rho GTPases, and expanded families of protein kinases. Comparative analysis demonstrates extensive conservation of syntenic blocks related to the dictyostelids D. discoideum and D. firmibasis as well as lineage-specific rearrangements. About 18% of the nuclear genome is made up of repetitive DNA, mostly in the form of simple repeats. Major transposable element classes, including piggyBac-like fragments, were found by homology searches. Long poly-asparagine/glutamine tracts are less common than in D. discoideum , but low-complexity sequences are common due to strong AT-driven codon bias. Comparative proteome-level orthology analysis across Dictyostelium species and Entamoeba identified a conserved Amoebozoan core together with a substantial Dictyostelium-specific gene repertoire. Domain-level comparisons further revealed widespread conservation of intracellular signalling and cytoskeletal modules shared with animals, whereas canonical metazoan extracellular adhesion domains were absent, highlighting the deep evolutionary roots of regulatory complexity underlying aggregative multicellularity.

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europepmc
last seen: 2026-05-20T01:45:00.602351+00:00
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last seen: 2026-05-26T02:00:01.498150+00:00
License: CC-BY-ND-4.0