Alternative role of noncoding RNAs: coding and noncoding properties / 浙江大学学报（英文版）（B辑：生物医学和生物技术）

Noncoding RNAs (ncRNAs) have played a critical role in cellular biological functions. Recently, some peptides or proteins originating from annotated ncRNAs were identified in organism development and various diseases. Here, we briefly review several novel peptides translated by annotated ncRNAs and related key functions. In addition, we summarize the potential mechanism of bifunctional ncRNAs and propose a specific "switch" triggering the transformation from the noncoding to the coding state under certain stimuli or cellular stress. The coding properties of ncRNAs and their peptide products may provide a novel horizon in proteomic research and can be regarded as a potential therapeutic target for the treatment of various diseases.

The central role of RNA in the genetic programming of complex organisms

Notwithstanding lineage-specific variations, the number and type of protein-coding genes remain relatively static across the animal kingdom. By contrast there has been a massive expansion in the extent of genomic non-proteincoding sequences with increasing developmental complexity. These non-coding sequences are, in fact, transcribed in a regulated manner to produce large numbers of large and small non-protein-coding RNAs that control gene expression at many levels including chromatin architecture, post-transcriptional processing and translation. Moreover, many RNAs are edited, especially in the nervous system, which may be the basis of epigenome-environment interactions and the function of the brain.

Apesar das variações linhagem-específicas, o número e tipo de genes codificadores de proteínas permanecem relativamente estáticos no reino animal. Em contraste, houve uma expansão maciça da quantidade de sequências genômicas não-codificadoras de proteínas com o aumento da complexidade do desenvolvimento. Essas sequências não codificadoras são, de fato, transcritas de maneira regulada para produzirem numerosos RNAs grandes e pequenos não-codificadores de proteínas que controlam a expressão de genes em vários níveis, incluindo a arquitetura da cromatina, o processamento pós-transcricional e a tradução. Além disso, muitos RNAs são editados, especialmente no sistema nervoso, o que pode ser a base de interações epigenoma-ambiente e a função do cérebro.