[
MicroPubl Biol,
2021]
Saul-Wilson Syndrome (SWS) is an ultra-rare, autosomal dominant skeletal dysplasia syndrome discovered in 1990; only 16 patients have been identified to date (Saul and Wilson 1990; Ferreira et al. 2018, OMIM#: 618150). The disease is characterized by short stature, various craniofacial abnormalities, shortened fingers and toes, and speech and physical developmental delay (Ferreira 2020). SWS is caused by a missense mutation in the COG4 gene, resulting in a G516R residue change. Other pathogenic mutations have been observed in this gene and all are clustered at the C-terminal end of the protein (R724W, R729W, R729A, E764A). These are associated with Congenital Disorder of Glycosylation type 2j (CDGIIj). This is a recessive disease characterized by mild psychomotor delay, mild dysmorphic features, epilepsy, and defective sialylation (Reynders et al. 2009). Besides the mild developmental delay, this disease seems to share virtually no phenotypic similarity with SWS.
[
Cell Calcium,
2006]
Periodic behavioral motor patterns are normally controlled by neural circuits, such as central pattern generators. We here report a novel mechanism of motor pattern generation by non-neural cells. The defecation motor program in Caenorhabditis elegans consists of three stereotyped motor steps with precise timing and this behavior has been studied as a model system of a ultradian biological clock [J.H. Thomas, Genetic analysis of defecation in C. elegans, Genetics 124 (1990) 855-872; D.W. Liu, J.H. Thomas, Regulation of a periodic motor program in C. elegans, J. Neurosci. 14 (1994) 1953-1962; K. Iwasaki, D.W. Liu, J.H. Thomas, Genes that control a temperature-compensated ultradian clock in Caenorhabditis elegans, Proc. Natl. Acad. Sci. USA 92 (1995), 10317-10321]. It was previously implied that the inositol-1,4,5-trisphosphate (IP3) receptor in the intestine was necessary for this periodic behavior [P. Dal Santo, M.A. Logan, A.D. Chisholm, E.M. Jorgensen, The inositol trisphosphate receptor regulates a 50s behavioral rhythm in C. elegans, Cell 98 (1999) 757-767]. Therefore, we developed a new assay system to study a relationship between this behavioral timing and intestinal Ca(2+) dynamics. Using this assay system, we found that the timing between the first and second motor steps is coordinated by intercellular Ca(2+)-wave propagation in the intestine. Lack of the Ca(2+)-wave propagation correlated with no coordination of the motor steps in the CaMKII mutant. Also, when the Ca(2+)-wave propagation was blocked by the IP3 receptor inhibitor heparin at the mid-intestine in wild type, the second/third motor steps were eliminated, which phenocopied ablation of the motor neurons AVL and DVB. These observations suggest that an intestinal Ca(2+)-wave propagation governs the timing of neural activities that controls specific behavioral patterns in C. elegans.