001; Additional file 6a). Second, PF-04929113 constantly expressed genes, particularly HEG and MEG with lower Ka, were most often located within the core genome (Additional file 6c). Third, lowly expressed genes were more likely slowly degraded (Additional file 7a), and four of seven exceptions described above (Figure 7a) retained in this light–dark conditions (Additional file 7a). The comparisons
of gene expression subclasses further indicated constantly and highly expressed transcripts tend to be quickly degraded (Additional file 7b). Interestingly, there was no significant MK-4827 in vivo difference between HEG and MEG (P > 0.1, Additional file 7b), and the same trait was also observed in the correlation between gene expression levels and half-lives when expression level increased to a certain degree the decay rate no longer declined (Figure 7a and Additional file 7a). These observations might be partially caused by specific growth conditions, or Selleckchem MK 1775 alternatively, by the genes’
position in operon because those genes located at 3’-end of operons are less expressed but slower degraded than 5’-end genes [29]. Therefore, half-lives of the high-operon-rate genes, such as HEG and MEG (Figure 6b), are more likely dependent upon their positions in operons. Despite opronic genes’ position, degradation distinction still can be observed in those genes with great difference in expression levels (like HEG versus LEG). However, it is not simplistic to figure out what extent the gene position can influence half-life to, and this also deviates from our topic in this study. Although all experimental conditions tested in this study are considered physiologically normal, we also wonder whether environmental stress, such as iron that
was studied by Thompson and coworkers [53], may affect the correlation between gene expression levels and molecular evolution. First, similar results were observed that highly and constantly expressed genes had lower Ka (Additional file 8a and b), and they were enriched more within the core genome (Additional file 8c). Second, those genes with constantly high expression level (HEG and MEG) had short half-lives (Additional file 9). Nonetheless, all of our observations are in accordance with previous conclusions drawn from Bacterial neuraminidase normal growth conditions under constant illumination, and this may indicate that gene expression levels have relatively self-contained influence on genome evolution in Prochlorococcus MED4. But note that the conditions we have tested are actually in the laboratory, the similar study conducted using the cultures in situ will facilitate to further elucidate the core genome stabilization of Prochlorococcus. Genes within the flexible genome are subject to relaxed constraints, and these genes can undergo frequent gain and loss in Prochlorococcus, leading to isolates differentiation.