Acetilación N-terminal, acetiltransferasas y mutaciones en subunidad auxiliar NAA15 de N-terminal acetiltransferasa A, asociadas a discapacidad intelectual y trastorno del espectro autista: una revisión bibliográfica / N-terminal acetylation, acetyltransferases and variants in NAA15 auxiliary subunit of the N-terminal acetyltransferase A associated with intellectual disability and autism spectrum disorder: a literature review

Las N-terminal acetiltransferasas (NaT) son fundamentales en el desarrollo, funcionamiento y vida media celular, acetilando gran parte del proteoma humano. Entre las ocho NaT identificadas, N-terminal acetiltransferasa A (NaTA) acetila a un mayor número de sustratos, teniendo además un rol fundamental en el neurodesarrollo. Previamente, estudios han demostrado que mutaciones en la subunidad catalítica de NaTA, NAA10, se asocian con trastornos del neurodesarrollo. Sin embargo, nuevas líneas investigativas sugieren que mutaciones de la subunidad auxiliar, NAA15, también tendrían un rol importante en el desarrollo de estos trastornos. Esta revisión se realiza con el objetivo de recopilar evidencia sobre variantes de NAA15 relacionadas con Discapacidad Intelectual (DI) y Trastorno de Espectro Autista (TEA). Se consultaron fuentes actualizadas sobre acetilación N-terminal, NaT, DI y TEA y mutaciones reportadas de NAA15 y sus expresiones fenotípicas, publicadas entre 2011 y 2022. Se concluye que, aun cuando existe relación entre mutaciones de NAA15, DI y TEA, todavía es necesario esclarecer los mecanismos fisiopatológicos de estos trastornos, el rol de NaTA y el impacto de variantes de sus subunidades en las vías moleculares y el fenotipo, lo que se dificulta por razones que van desde la complejidad de estas vías hasta el elevado costo de análisis genéticos. Se sugiere continuar la investigación en esta área, para comprender las bases moleculares subyacentes a estos trastornos y el rol de las mutaciones en subunidades de NaTA, con el fin último de estudiar potenciales tratamientos que mejoren la calidad de vida de las personas con estos trastornos y sus familias.

Nt-acetyltransferases (NaT) are essential in cell development, function and half-life, catalyzing most of the human proteome. Among the eight NaTs identified, N-terminal acetyltransferase A (NaTA) acetylates a greater number of substrates, also having a fundamental role in neurodevelopment. Previously, studies have shown that mutations in the catalytic subunit of NaTA, NAA10, are associated with neurodevelopmental disorders. However, new research lines suggest that mutations of the NAA15 helper subunit also plays an important role in the development of these disorders. This review is carried out with the objective of gathering evidence on NAA15 variants related to Intellectual Disability (ID) and Autism Spectrum Disorder (ASD). Updated sources on N-terminal acetylation, N-acetyltransferases, DI and TEA and reported mutations of NAA15 and their phenotypic expressions, published between 2011 and 2022 were consulted. It is concluded that even though there is a relationship between mutations of NAA15, ID and ASD exists, it is still necessary to clarify the pathophysiological mechanisms of these disorders, the role of NaTA and the impact of variants of its subunits in the molecular pathways and in the phenotype, for reasons ranging from the complexity of these pathways to the high cost of genetic testing. It is suggested to continue research in this area, to understand the molecular bases underlying these disorders and the role of mutations in NatA subunits, with the ultimate aim of studying potential treatments that improve the quality of life of people with these disorders and their families.

The N-terminal acetyltransferase Naa10 is essential for zebrafish development.

N-terminal acetylation, catalysed by N-terminal acetyltransferases (NATs), is among the most common protein modifications in eukaryotes and involves the transfer of an acetyl group from acetyl-CoA to the α-amino group of the first amino acid. Functions of N-terminal acetylation include protein degradation and sub-cellular targeting. Recent findings in humans indicate that a dysfunctional Nα-acetyltransferase (Naa) 10, the catalytic subunit of NatA, the major NAT, is associated with lethality during infancy. In the present study, we identified the Danio rerio orthologue zebrafish Naa 10 (zNaa10). In vitro N-terminal acetylation assays revealed that zNaa10 has NAT activity with substrate specificity highly similar to that of human Naa10. Spatiotemporal expression pattern was determined by in situ hybridization, showing ubiquitous expression with especially strong staining in brain and eye. By morpholino-mediated knockdown, we demonstrated that naa10 morphants displayed increased lethality, growth retardation and developmental abnormalities like bent axis, abnormal eyes and bent tails. In conclusion, we identified the zebrafish Naa10 orthologue and revealed that it is essential for normal development and viability of zebrafish.