Plasmodium falciparum Cyclic GMP-Dependent Protein Kinase Interacts with a Subunit of the Parasite Proteasome.

Malaria is caused by the protozoan parasite Plasmodium, which undergoes a complex life cycle in a human host and a mosquito vector. The parasite's cyclic GMP (cGMP)-dependent protein kinase (PKG) is essential at multiple steps of the life cycle. Phosphoproteomic studies in Plasmodium falciparum erythrocytic stages and Plasmodium berghei ookinetes have identified proteolysis as a major biological pathway dependent on PKG activity. To further understand PKG's mechanism of action, we screened a yeast two-hybrid library for P. falciparum proteins that interact with P. falciparum PKG (PfPKG) and tested peptide libraries to identify its phosphorylation site preferences. Our data suggest that PfPKG has a distinct phosphorylation site and that PfPKG directly phosphorylates parasite RPT1, one of six AAA+ ATPases present in the 19S regulatory particle of the proteasome. PfPKG and RPT1 interact in vitro, and the interacting fragment of RPT1 carries a PfPKG consensus phosphorylation site; a peptide carrying this consensus site competes with the RPT1 fragment for binding to PfPKG and is efficiently phosphorylated by PfPKG. These data suggest that PfPKG's phosphorylation of RPT1 could contribute to its regulation of parasite proteolysis. We demonstrate that proteolysis plays an important role in a biological process known to require Plasmodium PKG: invasion by sporozoites of hepatocytes. A small-molecule inhibitor of proteasomal activity blocks sporozoite invasion in an additive manner when combined with a Plasmodium PKG-specific inhibitor. Mining the previously described parasite PKG-dependent phosphoproteomes using the consensus phosphorylation motif identified additional proteins that are likely to be direct substrates of the enzyme.

Probing intracellular dynamics in living cells with near-field optics.

Near-field optics (NFO) overcomes the diffraction limit of light microscopes and permits visualization of single molecules. However, despite numerous applications of NFO in the physical sciences, there is still a paucity of applications in the neurosciences. In this work, the authors have developed NFO probes to image intracellular dynamic processes in living cells. This is the first time a NFO probe has been inserted inside a living cell to deliver light to a spatially controlled region for optical measurements and to record cellular responses to external stimuli. Two different optical detection systems (CCD camera and avalanche photon detection) were developed to monitor cellular responses to drug administration in two different cell types. NG108-15 neuroblastoma cells and vascular smooth muscle cells (VSMC) were penetrated with NFO probes. Intracellular Ca2+ increases post drug stimulation were detected by NFO probes. The cells were loaded with either fura-2/AM or fluo-3/AM calcium dyes. VSMC were stimulated with angiotensin II, resulting in a precise area of intracellular Ca2+ increase. Different response profiles of Ca2+ increases were observed after ionomycin and bradykinin administration in NG108-15 cells. Responsive heterogeneities due to ionomycin among different cells of the same type were recorded. The results show that NFO probes make possible real-time visualization of intracellular events. With refinement, intracellular NFO probes offer the potential of probing cell function with fast temporal and excellent spatial resolutions.