For example, one approach consisted of a DNA
motif discovery framework based on the detection of dependencies between microarray-based transcriptomic data and the presence of DNA motifs within the 5′ untranslated regions of genes (50). This approach identified in silico 21 potential motifs found in approximately 2700 genes expressed in P. falciparum. The method, however, may not perform very well on highly degenerated or atypical motifs. Another approach consists of identifying quantitative trait loci that are involved in gene expression variations (eQTLs) in various clones of P. falciparum (51). Using tiling arrays, Gonzales et al. identified hot spots of sequence polymorphisms spread throughout the entire genome that control Temozolomide concentration the expression of nearly 18% of the genes from a distance.
More recently, potential regulatory sequences found at nucleosome-free regions of DNA have been identified using formaldehyde-assisted isolation of regulatory elements (FAIRE) coupled with NGS at high resolution and large scale (13). In addition, ChIP-on-chip experiments using histone H4-specific antibodies were used to discover nucleosome-bound sequences and also suggest the potential presence of nucleosome-free regulatory elements (52). These kinds of studies Erlotinib have provided a considerable amount of data in just a few years. The mechanisms that P. falciparum uses to regulate gene expression remain nonetheless elusive. Indeed, the remarkable changes in steady-state mRNA levels, with a tightly coordinated cascade of transcripts throughout the parasite life cycle, remain challenging to comprehend. The core transcriptional machinery that drives RNA polymerase II-dependent transcription (53) and 27 Apicomplexan AP2 (ApiAP2) plant-related transcription factors (54,55) have been identified
as major regulators of parasite gene expression. All together, the proteins involved in the transcriptional machinery (including general transcription factors), along with ApiAP2-specific transcription factors, represent <2% of the total genome. Considering the P. falciparum’s genome Chorioepithelioma size, twice this amount is required for a classical ‘transcription factor-mediated’ model of gene regulation (53,56,57). Thus, either more atypical and elusive regulators remain to be discovered, or gene regulation in Plasmodium is not so classically based on the coordinated action of specific positive/negative regulators only. The initial characterization of the ApiAP2 transcription factor family was a major step forward understanding key regulators in Plasmodium (58). However, their exact role in the parasite’s biology remains to be determined. Furthermore, recent studies have started to underline that the malaria parasite may have adapted and optimized its mechanisms of transcriptional regulation for its lifestyle.