Last Updated: 06/11/2023
Functional characterization of Plasmodium falciparum TATA-box binding-like Protein (PfTLP)
Objectives
This study investigates two Plasmodium-specific features of TATA box-binding-like protein (PfTLP).
Plasmodium falciparum, the deadliest strain of human malaria, affected 200 million people and resulted in several hundred thousand deaths in 2017 (World Health Organization, 2018). A better understanding of the mechanisms of P. falciparum gene regulation can open novel avenues for the development of much needed new drugs. A key step in eukaryotic gene regulation is the process of transcription, which is largely uncharacterized in Plasmodium. Bioinformatic analysis identified putatuve P. falciparum orthologues of RNA polymerase II general transcription factors (Bing, 2014; Milton, 2017), including a TATA box-binding-like protein, PfTLP. Bioinformatic analysis suggested that PfTLP is a TRF2-type TBP-like protein. However, PfTLP differs in several aspects from previously characterized TRF2-type proteins. These differences are thought to be Plasmodium specific adaptations to the parasite’s intricate life cycle and AT-rich genome. Firstly, DNA binding by eukaryotic TATA-box binding protein (TBP) is mediated by four evolutionary conserved phenylalanine residues, two of which intercalate into the DNA. These residues are absent in previously characterized TRF2-type TLPs, and consistent with this, these proteins lack detectable DNA binding activity (Duttke et al., 2014). In contrast, PfTLP, a TRF2-type TLP, has DNA binding activity, and all four of the DNA binding phenylalanine residues are conserved (Bing, 2014; Milton, 2017). The importance of evolutionary conserved intercalating phenylalanine residues F60 and F283 was investigated by generating mutant PfTLP proteins, carrying alanine substitutions, and analysing their DNA-binding properties. The results suggest that while both phenylalanine residues are important for PfTLP DNA-binding, only F60 is critical for stabilization of PfTLP/DNA complexes. Secondly, PfTLP possesses two low-complexity or intrinsically disordered regions (LCR1 and 2), which are absent in TLPs from model eukaryotes. These regions are located at the same positions within the two quasi-symmetrical repeats of the TLP core structure and show a non-random compositional bias towards a limited set of amino acids. A growing body of evidence supports the idea that low complexity or intrinsically disordered proteins mediate liquid-liquid phase separation (LLPS) (Alberti et al., 2019; Brangwynne et al., 2009; Elbaum-Garfinkle et al., 2015; Nott et al., 2015). Bioinformatic analysis revealed that PfTLP LCRs are enriched in asparagine and lysine, and that these regions are well conserved throughout Plasmodium TLPs. PfTLP LCRs were fused to fluorescent proteins and the fusion proteins were functionally characterized in liquid-liquid phase separating assays. The results demonstrate that PfTLP LCR1 is capable of mediating LLPS, at least under certain conditions in vitro.
Feb 2020