It is known that membrane proteins are important in various secretory pathways, with
a possible role of their transmembrane domains (TMDs) as sorting determinant
factors. One key aspect of TMDs associated with various
“checkposts” (i.e. organelles) of intracellular trafficking
is their length. To explore possible linkages in organisms with varying
“complexity” and differences in TMD lengths of membrane
proteins associated with different organelles (such as Endoplasmic Reticulum, Golgi,
Endosomes, Nucleus, Plasma Membrane), we analyzed ~70000 membrane
protein sequences in over 300 genomes of fungi, plants, non-mammalian vertebrates
and mammals. We report that as we move from simpler to complex organisms, variation
in organellar TMD lengths decreases, especially compared to their respective plasma
membranes, with increasing organismal complexity. This suggests an evolutionary
pressure in modulating length of TMDs of membrane proteins with increasing
complexity of communication between sub-cellular compartments. We also report
functional applications of our findings by discovering remarkable distinctions in
TMD lengths of membrane proteins associated with different intracellular transport
pathways. Finally, we show that TMD lengths extracted from viral proteins can serve
as somewhat weak indicators of viral replication sites in plant cells but very
strong indicators of different entry pathways employed by animal viruses.
Natural products have long served as a rich resource for drug discovery in the treatment of illnesses and chronic diseases. Among many families exhibiting fascinating structural complexity and impressive bioactivity,...
The eradication of malaria remains
challenging due to the complex
life cycle of Plasmodium and the rapid emergence
of drug-resistant forms of Plasmodium falciparum and Plasmodium vivax. New, effective, and inexpensive antimalarials
against multiple life stages of the parasite are urgently needed to
combat the spread of malaria. Here, we synthesized a set of novel
hydroxyethylamines and investigated their activities in vitro and
in vivo. All of the compounds tested had an inhibitory effect on the
blood stage of P. falciparum at submicromolar concentrations,
with the best showing 50% inhibitory concentrations (IC50) of around 500 nM against drug-resistant P. falciparum parasites. These compounds showed inhibitory actions against plasmepsins,
a family of malarial aspartyl proteases, and exhibited a marked killing
effect on blood stage Plasmodium. In chloroquine-resistant Plasmodium berghei and P. berghei ANKA
infected mouse models, treating mice with both compounds led to a
significant decrease in blood parasite load. Importantly, two of the
compounds displayed an inhibitory effect on the gametocyte stages
(III–V) of P. falciparum in culture and the
liver-stage infection of P. berghei both in in vitro
and in vivo. Altogether, our findings suggest that fast-acting hydroxyethylamine-phthalimide
analogs targeting multiple life stages of the parasite could be a
valuable chemical lead for the development of novel antimalarial drugs.
Osmotic behavior of erythrocytes is not only important clinically, but is also significant in understanding of material transport across biological membranes. It is most commonly studied through fragiligrams – plots of the degree of hemolysis as a function of extracellular osmolarity. A fundamental assumption in experimental and theoretical studies on osmolarity driven transport of water across the plasma membranes of all cells is the sigmoidal nature of their osmotic behavior. Sigmoidal data is mathematically monotonic showing either a decreasing only or an increasing only trend, but not both, within certain thresholds; beyond these thresholds the data is asymptotic or flat. Fragiligrams of erythrocytes are usually sigmoidal, with maximal hemolysis in plain solute-free water and often up to a certain extracellular hypotonic environment. In this work, we report a new discovery of non-monotonic osmotic behavior of avian erythrocytes. In contrast to the expected monotonic fragiligrams obtained for mammalian erythrocytes, fragiligrams of avian erythrocytes show non-monotonic curves. Maximal hemolysis of avian erythrocytes was not observed at the most hypotonic conditions – instead, maximal hemolysis was observed at mild hypotonic conditions. Hemolysis of avian erythrocytes first increases then decreases with increasing extracellular osmolarity. We also report that the non-monotonic fragiligrams of chicken erythrocytes are converted to the expected monotonic sigmoids subsequent to controlled extracellular trypsinization. While possibly having profound evolutionary implications for vertebrates, the findings reported in this work have a direct impact on understanding of avian physiology. Our results also compel revisiting of experimental and theoretical models for understanding material transport across biological membranes under different osmotic conditions.
Over time, several exciting advances have been made in the treatment and prevention of malaria; however, this devastating disease continues to be a major global health problem and affects millions of people every year. Notably, the paucity of new efficient drug molecules and the inevitable drug resistance of the malaria parasite, Plasmodium falciparum, against frontline therapeutics are the foremost struggles facing malaria eradication initiatives. According to the malaria eradication agenda, the discovery of new chemical entities that can destroy the parasite at the liver stage, the asexual blood stage, the gametocyte stage, and the insect ookinete stage of the parasite life cycle (i.e., compounds exhibiting multistage activity) are in high demand, preferably with novel and multiple modes of action. Phenotypic screening of chemical libraries against the malaria parasite is certainly a crucial step toward overcoming these crises. In the last few years, various research groups, including industrial research laboratories, have performed large-scale phenotypic screenings that have identified a wealth of chemical entities active against multiple life stages of the malaria parasite. Vital scientific and technological developments have led to the discovery of multistage inhibitors of the malaria parasite; these compounds, considered highly valuable starting points for subsequent drug discovery and eradication of malaria, are reviewed.
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