Investigation of LIN-28 Function in Somatic Gonadal Development and Fertility, and Characterization of the LIN-28 Isoforms in C. elegans Hermaphrodites

Choi, Sungwook

29 August 2018

lin-28 was first characterized as a developmental timing regulator in Caenorhabditis elegans. Loss of lin-28 function (lin-28(lf)) mutants skip the hypodermal cell fates specific to the 2nd larval stage. Here, we studied two aspects of lin-28 which had not yet been investigated. First, we show that lin-28(lf) mutants exhibit reduced fertility associated with abnormal somatic gonadal morphology. In particular, the abnormal spermatheca-uterine valve morphology of lin-28(lf) hermaphrodites traps embryos in the spermatheca, which disrupts ovulation and causes embryonic lethality. The same genes downstream of lin-28 in the regulation of hypodermal developmental timing also act downstream of lin-28 in somatic gonadal morphogenesis and fertility. Importantly, we find that hypodermal expression, but not somatic gonadal expression, of lin-28 is sufficient for restoring normal somatic gonadal morphology in lin-28(lf) mutants. We propose that the abnormal somatic gonadal morphogenesis of lin-28(lf) hermaphrodites results from temporal discoordination between the accelerated hypodermal development and normally timed somatic gonadal development. Thus, our findings exemplify how a cell-intrinsic developmental timing program can also control proper development of other interacting tissues, cell non-autonomously. We also investigated the expression patterns and functions of two lin-28 isoforms in C. elegans. Our analysis of spatial expression patterns suggests that lin-28a and lin-28b are co-expressed in diverse tissues. Consistently, neither of isoform specific knock-out mutant, lin-28a(lf) or lin-28b(lf), exhibits defects in hypodermal development, somatic gonad, or fertility, indicating functional redundancy of two isoforms. Our study will contribute to further investigation of lin-28 isoforms by providing the mutants of each isoform as well as the primary analysis of their phenotypes.

LIN-28

C. elegans

somatic gonad

reproductive system

Developmental Biology

Robustness Mechanisms of Temporal Cell-Fate Progression in C. Elegans

Ilbay, Orkan

16 December 2019

Robustness is a ubiquitous property of biological systems, however, underlying mechanisms that help reinforce the optimal phenotypes despite environmental or physiological perturbations are poorly understood. C. elegans development consists of four larval stages (L1-L4) and well-characterized invariant cell lineages, within which the heterochronic pathway controls the order and timing of cell-fates. Environmental or physiological stress signals can slow or temporarily halt larval stage progression; remarkably, however, temporal cell-fate progression remains unaffected. We show that two widely conserved signaling pathways, insulin and TGF- β, that regulate C. elegans larval stage progression in response to starvation and crowding, respectively, also regulate a rewiring of the heterochronic pathway so that cell-fates remain temporally anchored to appropriate larval stages. This rewiring is mediated by the nuclear hormone receptor DAF-12, and it involves a shift from the reliance on let-7-family microRNAs to the reliance on LIN-46 for proper downregulation of the transcription factor, Hunchback-like-1 (HBL-1), which promotes L2 cell-fates and opposes L3 cell-fates. LIN-46 (which is a homolog of bacterial molybdopterin molybdenum transferase (moeA) and human gephyrin) post-translationally inhibits HBL-1 activity. LIN-46 expression is repressed by the RNA-binding protein LIN-28 at the early stages to permit HBL-1 activity and hence the proper execution of L2 cell-fates. Our results indicate that robustness mechanisms of temporal cell-fate progression in C. elegans involves 1) coordinated regulation of temporal cell-fates and larval stage progression and 2) collaboration between translational regulation exerted by microRNAs and post-translational regulation exerted by LIN-46 to coordinate HBL-1 downregulation with stage progression.

Developmental robustness

heterochronic pathway

developmental timing

microRNAs

let-7

LIN-28

pluripotency

reprogramming.

Cell and Developmental Biology

Developmental Biology

Life Sciences