Genomic and biological panoramas of non-muscle actinopathies

  1. Nataliya Di Donato
  2. NMA Consortium
  3. Andrew Thom
  4. Andreas Rump
  5. Johannes N. Greve
  6. Marcus Kropp
  7. Juan Cadiñanos
  8. Salvatore Calabro
  9. Sara Cathey
  10. Brian Chung
  11. Heidi Cope
  12. Maria Costales
  13. Sara Cuvertino
  14. Philine Dinkel
  15. Kalliopi Erripi
  16. Andrew E. Fry
  17. Livia Garavelli
  18. Kaomei Guan
  19. Sabine Hoffjan
  20. Wibke G. Janzarik
  21. Matti Koenig
  22. Insa Kreimer
  23. Karolina Kuenzel
  24. Grazia Mancini
  25. Purificacion Marin-Reina
  26. Andrea Meinhardt
  27. Indra Niehaus
  28. Daniela Pilz
  29. Ivana Ricca
  30. Fernando Santos Simarro
  31. Evelin Schrock
  32. Anja Marquardt
  33. Manuel H. Taft
  34. Kamer Tezcan
  35. Sofia Thunström
  36. Judith Verhagen
  37. Alain Verloes
  38. Bernd Wollnik
  39. Peter Krawitz
  40. Tzung-Chien Hsieh
  41. Leo Zeef
  42. Michael Seifert
  43. Michael Heide
  44. Catherine B. Lawrence
  45. Neil Roberts
  46. Dietmar Manstein
  47. Adrian S. Woolf
  48. Siddharth Banka
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Abstract

Background

Cytoskeletal non-muscle actin isoforms are the most abundant intracellular proteins and extensively interact with other molecules. Biological consequences and genotype-phenotype correlations of the variants in genes encoding these isoforms, ACTB and ACTG1, are not delineated.

Methods

Clinical data analysis from 290 individuals with pathogenic ACTB/ACTG1 variants; characterization of patient cells, mutant proteins, patient-derived iPSC-based models and mutant mice.

Results

We show that ACTB and ACTG1 variants have distinct clinical profiles. ACTB nonsense, frameshift and missense variants that lead to rapid protein degradation result in milder phenotypes. Heterozygous Actb knockout causes altered neuronal cell morphology and abnormal expression of actin-related genes in newborn mouse brains. Truncating ACTG1 variants are likely to be non-pathogenic, but chromosomal deletions encompassing ACTG1 and flanking genes may result in susceptibility to neurodevelopmental phenotypes. Subsets of disease-causing ACTB missense variants (MVs) result in more severe Type 1 Baraitser-Winter Cerebrofrontofacial (BWCFF1) or Deafness Dystonia syndromes. Pathogenic ACTG1 MVs cause BWCFF2 or isolated hearing loss. These amino acid substitutions are associated with dramatically dysregulated actin polymerization and depolymerization dynamics and, in induced pluripotent stem cells (iPSC) derived models, lead to neuronal migration defects. A significant subset of MVs result in disorders that cannot yet be classified into recognizable groups.

Conclusions

ACTB or ACTG1 variants and result in minimum eight mechanistically diverse non-muscle actinopathies. These results will improve their diagnosis and management, and pave the way for new treatment strategies. This study reflects the scale of collaborative clinical studies and multi-modal mechanistic studies required to dissect rare allelic disorders.

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  1. Version published to 10.1101/2024.08.21.24310320v1 on medRxiv