Identification and characterization lncRNAs and lineage specific coding genes in Andropogoneae: common patterns of evolution of emerging genes

Recently, comparative genomics studies, aiming to better elucidate the null hypothesis of models of evolution, i. e. the neutral evolution, originate a new theory that elects the population size as the main factor acting in evolution. Small populations are subject to stronger influence of genetic drift, which raises genomic entropy. Genomic complexity, which means the information content in genome, such as genes, is a byproduct of the high entropy levels and selection would then display a secondary role, mainly as a modulator of the evolutionary process. Assuming this model, the emergence and degeneration of lineage-specific transcripts are primarily subject to neutral evolution. The pervasive transcription, especially in germinal cell lines, is the causal agent of birth of genes and their fixation, in face to the reduced population size of multicellular eukaryotes, as Saccarum officinarum and Sorghum bicolor plant species, is ruled by genetic drift. The integration of new genes, initially neutral or weakly deleterious, in functional networks is still poorly understood. The integration becomes more robust with the individual historical evolutionary path of these loci. In this context, this study aimed identify protein coding and noncoding genes of recent emergence in in sugarcane and sorghum to elucidate the hypothesis that the gene architecture and integration in biological networks display common patterns of evolution. We then identified sugarcane lncRNAs from public cDNA databases that allowed us to characterize the expression of these transcripts in six different contrasting varieties of sugarcane. As sorghum bicolor genome is available, the identification of lineage-specific coding and noncoding could be done to a higher resolution. We could then determine a correlation between gene architecture and network integration with its relative age. Despite the correlation observed, a stronger effect seen in noncoding transcripts reveals other factors that may be influencing their evolution. We propose the hypothesis that the translation event may increase negative selection efficiency over the emerging transcript, what would result in the stronger turnover of lincRNAs and higher conservation levels of coding lineage-specific genes (AU)