Scientific Reports (Apr 2024)

Possible involvement of zinc transporter ZIP13 in myogenic differentiation

  • Masaki Shoji,
  • Takuto Ohashi,
  • Saki Nagase,
  • Haato Yuri,
  • Kenta Ichihashi,
  • Teruhisa Takagishi,
  • Yuji Nagata,
  • Yuki Nomura,
  • Ayako Fukunaka,
  • Sae Kenjou,
  • Hatsuna Miyake,
  • Takafumi Hara,
  • Emi Yoshigai,
  • Yoshio Fujitani,
  • Hidetoshi Sakurai,
  • Heloísa G. dos Santos,
  • Toshiyuki Fukada,
  • Takashi Kuzuhara

DOI
https://doi.org/10.1038/s41598-024-56912-7
Journal volume & issue
Vol. 14, no. 1
pp. 1 – 15

Abstract

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Abstract Ehlers–Danlos syndrome spondylodysplastic type 3 (EDSSPD3, OMIM 612350) is an inherited recessive connective tissue disorder that is caused by loss of function of SLC39A13/ZIP13, a zinc transporter belonging to the Slc39a/ZIP family. We previously reported that patients with EDSSPD3 harboring a homozygous loss of function mutation (c.221G > A, p.G64D) in ZIP13 exon 2 (ZIP13 G64D ) suffer from impaired development of bone and connective tissues, and muscular hypotonia. However, whether ZIP13 participates in the early differentiation of these cell types remains unclear. In the present study, we investigated the role of ZIP13 in myogenic differentiation using a murine myoblast cell line (C2C12) as well as patient-derived induced pluripotent stem cells (iPSCs). We found that ZIP13 gene expression was upregulated by myogenic stimulation in C2C12 cells, and its knockdown disrupted myotubular differentiation. Myocytes differentiated from iPSCs derived from patients with EDSSPD3 (EDSSPD3-iPSCs) also exhibited incomplete myogenic differentiation. Such phenotypic abnormalities of EDSSPD3-iPSC-derived myocytes were corrected by genomic editing of the pathogenic ZIP13 G64D mutation. Collectively, our findings suggest the possible involvement of ZIP13 in myogenic differentiation, and that EDSSPD3-iPSCs established herein may be a promising tool to study the molecular basis underlying the clinical features caused by loss of ZIP13 function.