Ankle2 deficiency-associated microcephaly and spermatogenesis defects in zebrafish are alleviated by heterozygous deletion of vrk1.

Autosomal recessive primary microcephaly (MCPH) is a rare congenital disorder characterized by a below average brain volume at birth and is associated with neurodevelopmental disorders such as growth retardation and intellectual disability. Mutations in ANKLE2 have been identified as one of the causes of MCPH (MCPH16). ANKLE2 is a target molecule of the Zika virus NS4a protein that interferes with ANKLE2 function, resulting in severe microcephaly. ANKLE2 is essential for organizing the nuclear envelope and chromatin structures during the mitotic-end process via barrier to autointegration factor (BAF) dephosphorylation. However, the precise mechanism by which the loss of ANKLE2 function causes the pathogenesis of microcephaly remains unclear. In this study, we generated Ankle2-deficient zebrafish (ankle2-/-) with a significant reduction in brain size compared with that of their control siblings. The ankle2-/- brain showed a significant decrease in the number of radial glial progenitor cells, suggesting that Ankle2 deficiency in zebrafish causes neurogenesis defects. Furthermore, ankle2-/- male zebrafish showed infertility owing to defects in spermatogenesis. Notably, microcephaly was overcome by vrk1 morpholino knockdown or vrk1 heterozygous deletion. In addition, spermatogenesis in ankle2-/- zebrafish males was partially restored by the vrk1 heterozygous deletion, although infertility was not resolved. These results indicate that ANKLE2 and VRK1 coordinate with each other for BAF phosphorylation to maintain normal mitosis during neurogenesis and spermatogenesis.

Modeling a human CLP1 mutation in mouse identifies an accumulation of tyrosine pre-tRNA fragments causing pontocerebellar hypoplasia type 10.

Cleavage factor polyribonucleotide kinase subunit 1 (CLP1), an RNA kinase, plays essential roles in protein complexes involved in the 3'-end formation and polyadenylation of mRNA and the tRNA splicing endonuclease complex, which is involved in precursor tRNA splicing. The mutation R140H in human CLP1 causes pontocerebellar hypoplasia type 10 (PCH10), which is characterized by microcephaly and axonal peripheral neuropathy. Previously, we reported that RNA fragments derived from isoleucine pre-tRNA introns (Ile-introns) accumulate in fibroblasts of patients with PCH10. Therefore, it has been suggested that this intronic RNA fragment accumulation may trigger PCH10 onset. However, the molecular mechanism underlying PCH10 pathogenesis remains elusive. Thus, we generated knock-in mutant mice that harbored a CLP1 mutation consistent with R140H. As expected, these mice showed progressive loss of the upper motor neurons, resulting in impaired locomotor activity, although the phenotype was milder than that of the human variant. Mechanistically, we found that the R140H mutation causes intracellular accumulation of Ile-introns derived from isoleucine pre-tRNAs and 5' tRNA fragments derived from tyrosine pre-tRNAs, suggesting that these two types of RNA fragments were cooperatively or independently involved in the onset and progression of the disease. Taken together, the CLP1-R140H mouse model provided new insights into the pathogenesis of neurodegenerative diseases, such as PCH10, caused by genetic mutations in tRNA metabolism-related molecules.

Exosc2 deficiency leads to developmental disorders by causing a nucleotide pool imbalance in zebrafish.

Exosc2 is one of the components of the exosome complex involved in RNA 3' end processing and degradation of various RNAs. Recently, EXOSC2 mutation has been reported in German families presenting short stature, hearing loss, retinitis pigmentosa, and premature aging. However, the in vivo function of EXOSC2 has been elusive. Herein, we generated Exosc2 knockout (exosc2-/-) zebrafish that showed larval lethality 13 days post fertilization, with microcephaly, loss of spinal motor neurons, myelin deficiency, and retinitis pigmentosa. Mechanistically, Exosc2 deficiency caused impaired mRNA turnover, resulting in a nucleotide pool imbalance. Rapamycin, which modulated mRNA turnover by inhibiting the mTOR pathway, improved nucleotide pool imbalance in exosc2-/- zebrafish, resulting in prolonged survival and partial rescue of neuronal defects. Taken together, our findings offer new insights into the disease pathogenesis caused by Exosc2 deficiency, and might help explain fundamental molecular mechanisms in neuronal diseases, such as Alzheimer's disease, amyotrophic lateral sclerosis, and spinal muscular atrophy.

Tyrosine pre-transfer RNA fragments are linked to p53-dependent neuronal cell death via PKM2.

Fragments of transfer RNA (tRNA), derived either from pre-tRNA or mature tRNA, have been discovered to play an essential role in the pathogenesis of various disorders such as neurodegenerative disease. CLP1 is an RNA kinase involved in tRNA biogenesis, and mutations in its encoding gene are responsible for pontocerebellar hypoplasia type-10. Mutation of the CLP1 gene results in the accumulation of tRNA fragments of several different kinds. These tRNA fragments are expected to be associated with the disease pathogenesis. However, it is still unclear which of the tRNA fragments arising from the CLP1 gene mutation has the greatest impact on the onset of neuronal disease. We found that 5' tRNA fragments derived from tyrosine pre-tRNA (5' Tyr-tRF) caused p53-dependent neuronal cell death predominantly more than other types of tRNA fragment. We also showed that 5' Tyr-tRF bound directly to pyruvate kinase M2 (PKM2). Injection of zebrafish embryos with PKM2 mRNA ameliorated the neuronal defects induced in zebrafish embryos by 5' Tyr-tRF. Our findings partially uncovered a mechanistic link between 5' Tyr-tRF and neuronal cell death that is regulated by PKM2.

CLP1 acts as the main RNA kinase in mice.

CLP1 plays an essential role in the protein complex involved in mRNA 3'-end formation and polyadenylation as well as in the tRNA splicing endonuclease (TSEN) complex involved in the splicing of precursor tRNAs. NOL9 localizes in the nucleolus of cells and plays an essential role in ribosomal RNA maturation. Both CLP1 and NOL9 are RNA kinases that phosphorylate the 5' end of RNAs. From the evidence that phosphorylation of the 5' end of a siRNA is essential for its efficient RNA cleavage, it was expected that CLP1 and NOL9 would be corresponding molecules. However, there had been no direct evidence that this is the case. In this study, murine NOL9 showed no apparent RNA kinase activity in cells or even in an RNA kinase assay using recombinant murine NOL9 protein. Although siRNA efficiency was decreased in CLP1 kinase-dead (Clp1K/K) cells, it was not influenced by NOL9 overexpression. These findings indicate that in mouse cells it is CLP1 that mainly acts to phosphorylate the 5' end of RNAs in the siRNA pathway, with no apparent involvement of NOL9.