A Potent Kalihinol Analogue Disrupts Apicoplast Function and Vesicular Trafficking in P. falciparum Malaria.

Here we report the discovery of MED6-189, a new analogue of the kalihinol family of isocyanoterpene (ICT) natural products. MED6-189 is effective against drug-sensitive and -resistant P. falciparum strains blocking both intraerythrocytic asexual replication and sexual differentiation. This compound was also effective against P. knowlesi and P. cynomolgi. In vivo efficacy studies using a humanized mouse model of malaria confirms strong efficacy of the compound in animals with no apparent hemolytic activity or apparent toxicity. Complementary chemical biology, molecular biology, genomics and cell biological analyses revealed that MED6-189 primarily targets the parasite apicoplast and acts by inhibiting lipid biogenesis and cellular trafficking. Genetic analyses in P. falciparum revealed that a mutation in PfSec13, which encodes a component of the parasite secretory machinery, reduced susceptibility to the drug. The high potency of MED6-189 in vitro and in vivo, its broad range of efficacy, excellent therapeutic profile, and unique mode of action make it an excellent addition to the antimalarial drug pipeline.

PfMORC protein regulates chromatin accessibility and transcriptional repression in the human malaria parasite, P. falciparum.

The environmental challenges the human malaria parasite, Plasmodium falciparum, faces during its progression into its various lifecycle stages warrant the use of effective and highly regulated access to chromatin for transcriptional regulation. Microrchidia (MORC) proteins have been implicated in DNA compaction and gene silencing across plant and animal kingdoms. Accumulating evidence has shed light into the role MORC protein plays as a transcriptional switch in apicomplexan parasites. In this study, using CRISPR/Cas9 genome editing tool along with complementary molecular and genomics approaches, we demonstrate that PfMORC not only modulates chromatin structure and heterochromatin formation throughout the parasite erythrocytic cycle, but is also essential to the parasite survival. Chromatin immunoprecipitation followed by deep sequencing (ChIP-seq) experiments suggest that PfMORC binds to not only sub-telomeric regions and genes involved in antigenic variation but is also most likely a key modulator of stage transition. Protein knockdown experiments followed by chromatin conformation capture (Hi-C) studies indicate that downregulation of PfMORC induces the collapse of the parasite heterochromatin structure leading to its death. All together these findings confirm that PfMORC plays a crucial role in chromatin structure and gene regulation, validating this factor as a strong candidate for novel antimalarial strategies.

BRK phosphorylates SMAD4 for proteasomal degradation and inhibits tumor suppressor FRK to control SNAIL, SLUG, and metastatic potential.

The tumor-suppressing function of SMAD4 is frequently subverted during mammary tumorigenesis, leading to cancer growth, invasion, and metastasis. A long-standing concept is that SMAD4 is not regulated by phosphorylation but ubiquitination. Our search for signaling pathways regulated by breast tumor kinase (BRK), a nonreceptor protein tyrosine kinase that is up-regulated in ~80% of invasive ductal breast tumors, led us to find that BRK competitively binds and phosphorylates SMAD4 and regulates transforming growth factor-ß/SMAD4 signaling pathway. A constitutively active BRK (BRK-Y447F) phosphorylates SMAD4, resulting in its recognition by the ubiquitin-proteasome system, which accelerates SMAD4 degradation. Activated BRK-mediated degradation of SMAD4 is associated with the repression of tumor suppressor gene FRK and increased expression of mesenchymal markers, SNAIL, and SLUG. Thus, our data suggest that combination therapies targeting activated BRK signaling may have synergized the benefits in the treatment of SMAD4 repressed cancers.

The Anopheles gambiae adult midgut peritrophic matrix proteome.

Malaria is a devastating disease. For transmission to occur, Plasmodium, the causative agent of malaria, must complete a complex developmental cycle in its mosquito vector. Thus, the mosquito is a potential target for disease control. Plasmodium ookinetes, which develop within the mosquito midgut, must first cross the midgut's peritrophic matrix (PM), a thick extracellular sheath that completely surrounds the blood meal. The PM poses a partial, natural barrier against parasite invasion of the midgut and it is speculated that modifications to the PM may lead to a complete barrier to infection. However, such strategies require thorough characterization of the structure of the PM. Here, we describe for the first time, the complete PM proteome of the main malaria vector, Anopheles gambiae. Altogether, 209 proteins were identified by mass spectrometry. Among them were nine new chitin-binding peritrophic matrix proteins, expanding the list from three to twelve peritrophins. Lastly, we provide a model for the putative interactions among the proteins identified in this study.

Proteomic analysis of chromatin-modifying complexes in Saccharomyces cerevisiae identifies novel subunits.

Epigenetics is the alteration of phenotype without affecting the genotype. An underlying molecular mechanism of epigenetics is the changes of chromatin structure by covalent histone modifications and nucleosome reorganization. In the yeast, Saccharomyces cerevisiae, two of the most well-studied macromolecular complexes that perform these epigenetic changes are the ATP-dependent Swi/Snf chromatin-remodelling complex and the SAGA histone acetyltransferase complex. To understand fully the mechanism by which these large protein complexes perform their functions in the cell, it is crucial that all the subunits of these complexes are identified. In an attempt to identify new subunits associated with SAGA and Swi/Snf, we used tandem affinity purification, followed by a multidimensional protein identification technology to analyse the subunit composition. Our analysis identified two novel proteins, one associated with SAGA, YPL047W (Sgf11), and another associated with Swi/Snf, Rtt102.

Fast deuterium access to the buried magnesium/manganese site in cytochrome c oxidase.

The recently determined crystal structures of bacterial and bovine cytochrome c oxidases show an area of organized water within the protein immediately above the active site where oxygen chemistry occurs. A pathway for exit of protons or water produced during turnover is suggested by possible connections of this aqueous region to the exterior surface. A non-redox-active Mg(2+) site is located in the interior of this region, and our previous studies [Florens, L., Hoganson, C., McCracken, J., Fetter, J., Mills, D., Babcock, G. T., and Ferguson-Miller, S. (1998) in Phototropic Prokaryotes (Peschek, G. A., Loeffelhard, W., and Schmetterer, G., Eds.) Kluwer Academic/Plenum, New York] have shown that the protons of water molecules that coordinate the metal can be exchanged within minutes of mixing with (2)H(2)O. Here we examine the extent and rate of deuterium exchange, using a combination of rapid freeze-quench and electron spin echo envelope modulation (ESEEM) analysis of Mn(2+)-substituted cytochrome c oxidase, which retains full activity. In the oxidized enzyme at room temperature, deuterium exchange at the Mn(2+) site occurs in less than 11 ms, which corresponds to an apparent rate constant higher than 3000 s(-1). The extent of deuterium substitution is dependent on the concentration of (2)H(2)O in the sample, indicative of rapid equilibrium, with three inner sphere (2)H(2)O exchanged per Mn(2+). This indicates that the water ligands of the Mn(2+)/Mg(2+) site, or the protons of these waters, can exchange with bulk solvent at a rate consistent with a role for this region in product release during turnover.

Where is 'outside' in cytochrome c oxidase and how and when do protons get there?

Cytochrome c oxidase moves both electrons and protons in its dual role as a terminal electron acceptor and a contributor to the proton motive force which drives the formation of ATP. Although the sequence of electron transfer events is well-defined, the correlated mechanism and routes by which protons are translocated across the membrane are not. A recent model [Michel, Proc. Natl. Acad. Sci. USA 95 (1998) 12819] offers a detailed molecular description of when and how protons are translocated through the protein to the outside, which contrasts with previous models in several respects. This article reviews the behavior of site-directed mutants of Rhodobacter sphaeroides cytochrome c oxidase in the context of these different models. Studies of the internally located lysine 362 on the K channel and aspartate 132 on the D channel, indicate that D132, but not K362, is connected to the exterior region. Analysis of the externally located arginine pair, 481 and 482, and the Mg/Mn ligands, histidine 411 and aspartate 412, which are part of the hydrogen-bonded network that includes the heme propionates, indicates that alterations in this region do not strongly compromise proton pumping, but do influence the pH dependence of overall activity and the control of activity by the pH gradient. The results are suggestive of a region of 'sequestered' protons: beyond a major energetic gate, but selectively responsive to the external environment.

Thermal stability of the polyheme cytochrome c3 superfamily.

The cytochrome c3 superfamily includes Desulfovibrio polyheme cytochromes c. We report the characteristic thermal stability parameters of the Desulfovibrio desulfuricans Norway (D.d.N.) cytochromes c3 (M(r) 13,000 and M(r) 26,000) and the Desulfovibrio vulgaris Hildenborough (D.v.H.) cytochrome c3 (M(r) 13,000) and high molecular mass cytochrome c (Hmc), as obtained with the help of electronic spectroscopy, voltammetric techniques and differential scanning calorimetry. The polyheme cytochromes are denatured over a wide range of temperatures: the D.v.H. cytochrome c3 is highly thermostable (Td = 121 degrees C) contrary to the D.d.N. protein (Td = 73 degrees C). The thermostability of the polyheme cytochromes is redox state dependent. The results are discussed in the light of the structural and functional relationships within the cytochrome c3 superfamily.

Interfacial properties of the polyheme cytochrome c3 superfamily from Desulfovibrio.

In order to compare the interfacial behavior of the polyheme cytochromes c which belong to the cytochrome c3 superfamily, the monomolecular film technique was used to determine whether and how these metalloproteins interact with (phospho)lipids). Measurements of the variations of surface pressure and surface potential versus time have shown differences in their penetration capacity into phosphatidylcholine, dicaprin, and phosphatidylglycerol films. The Desulfovibrio vulgaris Hildenborough cytochrome with 16 hemes (Hmc) and Desulfovibrio desulfuricans Norway tetra- and octaheme cytochromes c3, which have been assumed to be soluble periplasmic molecules, may be considered as extrinsic membrane proteins, unlike the D. vulgaris Hildenborough cytochrome c3 (Mr 13 000). The interfacial properties are discussed in terms of the available three-dimensional structural data, the electrostatic potential calculation, and the results obtained by hydrophobic cluster analysis of the cytochrome sequences. The very different behavior of the two cytochromes c3 (Mr 13 000) enlightens the role of a particular surface loop in the interaction with a model membrane. A functional interpretation is proposed assuming that the D. vulgaris Hildenborough Hmc and both cytochromes c3 (Mr 13 000) and (Mr 26 000) from the Norway strain might provide the link between periplasmic hydrogen oxidation and cytoplasmic sulfate reduction.

Drastic influence of a single heme axial ligand replacement on the thermostability of cytochrome c3.

The thermostability of wild type Desulfovibrio vulgaris Hildenborough tetraheme cytochrome c3 and its H22M, H25M, H35M and H70M mutants was studied by circular dichroism technique in the far UV and Soret regions. It was shown that wild type cytochrome is extremely thermostable and retains structural and functional properties up to 110 degrees C. Mutations do not change overall secondary structure and local structure of the hemes vicinity. All mutants are much more unstable to heat denaturation than the wild type cytochrome. Point mutation (His/Met replacement) results in extraordinary 30-45 degrees C decrease in the protein thermostability depending on the mutation. We may conclude therefore that the heme region is important not only for the functional properties of the cytochrome but also for the overall protein thermostability.

Characterization and oxidoreduction properties of cytochrome c3 after heme axial ligand replacements.

Cytochrome c3 (M(r) 13,000) is a tetrahemic cytochrome in which the four heme iron atoms are coordinated by 2 histidine residues at the axial positions. The presence of several oxidoreduction centers in the same molecule raises the question of their coupling. To investigate this mechanism, four single mutations were introduced in cytochrome c3 by site-directed mutagenesis, leading to the replacement of each histidine, the sixth axial ligand of the heme iron atom, by a methionine residue. Characterization of the new set of molecules using biochemical and biophysical techniques was carried out. The novel methionine was correctly coordinated to the iron atom of hemes 3 and 4 in H25M and H70M cytochromes c3, respectively, and this coordination induced a large increase in the oxidoreduction potential of the mutated heme. In contrast, in the case of H22M and H35M cytochromes c3, in which the corresponding methionine is in an oxidized form, only slight changes in redox potential values were observed. In H22M, H25M, and H35M cytochromes c3, two conformations of the molecule were possible, in which the methionine is either free or coordinated to the iron atom. The rate constants for the electron exchange reactions between the cytochrome mutants and the hydrogenase were measured using electrochemical techniques. Distinct behaviors were revealed depending on the mutation. The values of the rate constants for the electron exchange reactions are interpreted in terms of intramolecular electron exchange among the four hemes of the cytochrome.

Recent advances in the characterization of the hexadecahemic cytochrome c from Desulfovibrio.

The biochemical characterization of the high molecular mass cytochromes c (Hmc) isolated from Desulfovibrio vulgaris has led to some controversy as regards their molecular size and subunit structure as well as their heme content and redox properties. Recently developed genetic techniques have made it possible to reach some definite conclusions about the structural and functional properties of the cytochrome. The hexadecahemic Hmc comprises four domains which resemble the tetrahemic cytochrome c3: the structure-function relationship between these multihemic proteins is examined. An hypothesis is discussed according to which the Hmc might be a peripherally interacting protein associated with the outer face of the cytoplasmic membrane, where it might interact with periplasmic proteins - [Fe] hydrogenase - and membrane-bound components of the hmc operon.