1. Identify cell-type specific protein subsets: Cells differentiate by triggering RNA transcription from specific subsets of genes. The RNA transcripts are translated into proteins, which alter the structure and function of the cells. To identify these subsets and understand how they evolved, we purified cell types from species taken from each of the 4 major groups and sequenced their RNAs. Broadly, the spores, stalk and disc cells expressed different subsets of proteins involved cell wall synthesis, while the cup cells expressed novel protein with roles in communication, motility and adhesion. (Kin BMC Genomics, 2018).
2. Evolutionary genetic change: Regulatory genes that process perceived signals into cell differentiation make up several families such as receptors to detect the signals, protein kinases and GTPases to transduce it and transcription factors that regulate gene expression. We used available genome and transcriptome data to record conservation and change in protein functional domains, cell-type specificity and developmental regulation of these genes across Dictyostelid evolution (Forbes GBE 2019; Forbes SmallGTPases 2022; Hall Open ResEur 2023; Kin CellSignal 2023). This work yielded many clues for changes that might have caused cell-type innovations.
3. A novel cell type by gene duplication: We noticed a group 4 specific gene duplication in the transcription factor cdl1. Gene knock-out of 1 copy cdl1A showed that this gene was essential for the evolution of cup cells. Cdl1 initial function was in stalk formation (Kin CurrBiol 2022).
4. Novel gene functions: Many genes, such as gskA, dgcA, stlB, acaA, acrA, acgA, atg7 that are essential for group 4 development were deleted in P. pallidum (Ppal) and P.violaceum (Pvio) which reside in group 2 and just outside to group 4, respectively. Loss of dgcA, acaA, acrA, acgA produced less severe effects in Ppal and Pvio than in group 4, loss of stlB had the opposite effect. Loss of gskA, which in group 4 promotes spore over disc differentiation has no role in Ppal spore formation, but causes cells to aggregate when starved rather than encyst individually (Kawabe EvoDevo 2018; Narita GenomeBiolEvol 2020; Kawabe EvoDevo 2022). The essential role of the autophagy gene atg7 in spore gene expression was conserved (Du OpenResEur 2022).
5. Ultimate cause: To understand if and why spores formed multicellularly are better than individually formed cysts, we recorded their long-term survival under climate mimicking conditions It appeared that spores were frost resistant while cysts were not, due to greater state of compaction and thicker more structured wall of the spores. Dictyostelia evolved from unicellular amoebas just after the neoproterozoid glaciations (snowball earth) and group 4 with the most frost resistant spores still uniquely colonizes arctic regions. Dictyostelid multicellular sporulation was therefore likely caused by a cooling climate (Lawal, SciRep 2020).
6. Autophagy of soma feeds the spores. We found early spore gene expression requires autophagy (self-digestion) and that unlike cysts, spores formed from single cells are not viable.
Because autophagy mostly occurs in stalk cells, which self-digest before dying, spores likely build up their thicker walls and food stores from nutrients produced by stalk autophagy.