We are interested in uncovering cellular and molecular regulators of proneural gene expression in the context of left-right asymmetric neurogenesis. To achieve this, we focus on the C lineage. Asymmetric expression of the proneural bHLH transcription factor
hlh-14/Ascl1 on the left of the lineage is required to produce two glutamatergic tail neurons, DVC and PVR, on the left only. Taking advantage of the invariant cell lineage and single-cell resolution of C. elegans we are performing a 4D-lineage based screen of a collection of over 2000 temperature sensitive embryonic lethal mutants from our collaborator Ralf Schnabel. In wildtype, the cell cycle of the DVC neuroblast(Caapa) is twice the duration of those of its hypoblast cousins. In
hlh-14 mutants, neurogenesis is lost with the transformed DVC neuroblast dividing precociously in line with with the hypoblasts, its daughters adopting a hypodermal fate. Through preliminary screening for this precocious division in 150 4D-recordings, comprising 75 mutant strains and secondary screening of our own we have identified three strains of interest. These are
and-7(
t3224),
and-8(
t3294) and,
and-4(
t3200); which has been mapped and cloned and is an allele of
let-19, a Mediator complex component.
and-4 also displays a symmetrisation of an asymmetric division in the C lineage correlating with loss of neurogenesis (see poster by Terry Felton). Closer study of
and-7(
t3224) reveals additional ectopic DVC neurons rather than loss. 4D-lineage characterization assessing number and timing of divisions has shown the strain displays highly variable lineage transformations, with the P4 blastomere displaying the greatest and most obvious aberrations. Whole genome sequencing has identified two promising candidates: an endosomal budding gene,
pad-1/Dop1p and zinc finger TF
sma-9/Schnurri. Loss of
pad-1 in embryos is lethal and causes misplacement of cells by an unknown mechanism. This could be due to aberrant lineal origins. In the postembryonic M lineage
sma-9 has been shown to antagonize anterior-posterior lineage identity though modulation of TGF beta signaling, yet to our knowledge, a role for TGF beta in the embryo has not been described. Combining modern and classical methods the screen is proving successful in uncovering mutants of the class it was designed for in addition to others. Furthermore, through the identification of
let-19 the screen has uncovered another avenue of inquiry in asymmetric control of daughter size in the lineage, a potential cellular regulator of asymmetric neurogenesis in the lineage.