AI Article Synopsis
- Haploid larvae in non-mammalian vertebrates exhibit lethal growth issues known as 'haploid syndrome,' contrasting with mammals where imprinting misregulation leads to haploid intolerance.
- In an investigation of gynogenetic haploid zebrafish, researchers found that haploid larvae showed premature cell death and mitotic defects due to increased p53 levels, resulting in halted cell division during critical growth stages.
- The study suggests that these cellular issues are critical factors limiting larval growth in haploid conditions, indicating an evolutionary restriction on ploidy levels in vertebrates.
Article Abstract
Haploid larvae in non-mammalian vertebrates are lethal, with characteristic organ growth retardation collectively called 'haploid syndrome'. In contrast to mammals, whose haploid intolerance is attributed to imprinting misregulation, the cellular principle of haploidy-linked defects in non-mammalian vertebrates remains unknown. Here, we investigated cellular defects that disrupt the ontogeny of gynogenetic haploid zebrafish larvae. Unlike diploid control larvae, haploid larvae manifested unscheduled cell death at the organogenesis stage, attributed to haploidy-linked p53 upregulation. Moreover, we found that haploid larvae specifically suffered the gradual aggravation of mitotic spindle monopolarization during 1-3 days post-fertilization, causing spindle assembly checkpoint-mediated mitotic arrest throughout the entire body. High-resolution imaging revealed that this mitotic defect accompanied the haploidy-linked centrosome loss occurring concomitantly with the gradual decrease in larval cell size. Either resolution of mitotic arrest or depletion of p53 partially improved organ growth in haploid larvae. Based on these results, we propose that haploidy-linked mitotic defects and cell death are parts of critical cellular causes shared among vertebrates that limit the larval growth in the haploid state, contributing to an evolutionary constraint on allowable ploidy status in the vertebrate life cycle.
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| http://www.ncbi.nlm.nih.gov/pmc/articles/PMC11461072 | PMC |
| http://dx.doi.org/10.1098/rsob.240126 | DOI Listing |
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Article Synopsis
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