ER-associated degradation
Correctly folding proteins is a severely complicated process. Within eukaryotes an optimal environment for protein folding is provided by the endoplasmic reticulum (ER). In addition, proper folding requires the activity of numerous molecular chaperones and folding enzymes. Despite the controlled environment and numerous molecular helpers, misfolded proteins do sometimes occur. ER-associated degradation (ERAD) is a normal cell function that detects and deals with these occurrences. Through the ERAD process, misfolded proteins are recognized, retrotranslocated to the cytosol, ubiquinated, and then degraded by the proteosome.
Aging
Aging in C. elegans involves measurable declines in morphology, reproduction, and behavior. Understanding the cellular and molecular processes leading to senescence in this nematode began in the early 1980s with the targeted identification of mutants with extended life spans (an AGE phenotype). These studies identified at least two key regulators of life span, DAF-2, an insulin/IGF receptor ortholog, and DAF-16, a Forkhead-related transcription factor. Since then many more genes and pathways involved in senescence have been identified. Almost all of these genes play important roles in cellular and organismal-level processes other than aging, such as dauer formation, stress response, feeding, and chemosensation. A common marker for aging in C. elegans is the accumulation of lysosomal deposits of lipofuscin, resulting in an increase in intestinal autofluorescence over time.
Wnt signaling pathway
Wnt glycoproteins are signaling molecules that control a wide range of developmental processes and is a conserved feature of metazoan development. In C. elegans Wnt signaling has been shown to play a role in cell fate specification and determination of cell polarity, cell migration, and axis determination during axon outgrowth. A 'canonical' Wnt signaling pathway has been elucidated in vertebrate and invertebrate model systems where Wnt binding leads to the stabilization of the transcription factor beta-catenin, which then enters the nucleus to regulate Wnt pathway target genes. Like other species, the C. elegans genome encodes multiple genes for Wnt ligands, EGL-20, LIN-44, MOM-2, CWN-1, CWN-2) and Wnt receptors (LIN-17, MOM-5, MIG-1, CFZ-2, LIN-18). Canonical Wnt signaling in C. elegans, utilizes the beta-catenin BAR-1 to convert POP-1 into an activator and controls the expression of several homeobox genes. However, unlike vertebrates or Drosophila, the C. elegans genome encodes multiple beta-catenin genes (HMP-2, BAR-1, SYS-1, WRM-1), which give rise to noncanonical Wnt signalling pathways: for example, the endoderm induction pathway requires the beta-catenin WRM-1 and parallel input from a mitogen-activated kinase (MAPK) pathway to downregulate POP-1.