Allosteric regulation plays an important role in many biological processes, such as signal transduction, transcriptional regulation, and metabolism. Allostery is rooted in the fundamental physical properties of macromolecular systems, but its underlying mechanisms are still poorly understood. A collection of contributions to a recent interdisciplinary CECAM (Center Européen de Calcul Atomique et Moléculaire) workshop is used hereto provide an overview of the progress and remaining limitations in the understanding of the mechanistic foundations of allostery gained from computational and experimental analyses of real protein systems and model systems. The main conceptual frameworks instrumental in driving the field are discussed. We illustrate the role of these frameworks in illuminating molecular mechanisms and explaining cellular processes, and describe some of their promising practical applications in engineering molecular sensors and informing drug design efforts.
According to the World Health Organization, more than 1 billion people are at risk of or are affected by neglected tropical diseases. Examples of such diseases include trypanosomiasis, which causes sleeping sickness; leishmaniasis; and Chagas disease, all of which are prevalent in Africa, South America, and India. Our aim within the New Medicines for Trypanosomatidic Infections project was to use (1) synthetic and natural product libraries, (2) screening, and (3) a preclinical absorption, distribution, metabolism, and excretion–toxicity (ADME-Tox) profiling platform to identify compounds that can enter the trypanosomatidic drug discovery value chain. The synthetic compound libraries originated from multiple scaffolds with known antiparasitic activity and natural products from the Hypha Discovery MycoDiverse natural products library. Our focus was first to employ target-based screening to identify inhibitors of the protozoan Trypanosoma brucei pteridine reductase 1 ( TbPTR1) and second to use a Trypanosoma brucei phenotypic assay that made use of the T. brucei brucei parasite to identify compounds that inhibited cell growth and caused death. Some of the compounds underwent structure-activity relationship expansion and, when appropriate, were evaluated in a preclinical ADME-Tox assay panel. This preclinical platform has led to the identification of lead-like compounds as well as validated hits in the trypanosomatidic drug discovery value chain.
The optimization
of compounds with multiple targets is a difficult
multidimensional problem in the drug discovery cycle. Here, we present
a systematic, multidisciplinary approach to the development of selective
antiparasitic compounds. Computational fragment-based design of novel
pteridine derivatives along with iterations of crystallographic structure
determination allowed for the derivation of a structure–activity
relationship for multitarget inhibition. The approach yielded compounds
showing apparent picomolar inhibition of
T. brucei
pteridine reductase 1 (PTR1), nanomolar inhibition of
L.
major
PTR1, and selective submicromolar inhibition of parasite
dihydrofolate reductase (DHFR) versus human DHFR. Moreover, by combining
design for polypharmacology with a property-based on-parasite optimization,
we found three compounds that exhibited micromolar EC
50
values against
T. brucei brucei
while retaining
their target inhibition. Our results provide a basis for the further
development of pteridine-based compounds, and we expect our multitarget
approach to be generally applicable to the design and optimization
of anti-infective agents.
There is a need for improved and generally applicable scoring functions for fragment-based approaches to ligand design. Here, we evaluate the performance of a computationally efficient model for inhibitory activity estimation, which is composed only of multipole electrostatic energy and dispersion energy terms that approximate long-range ab initio quantum mechanical interaction energies. We find that computed energies correlate well with inhibitory activity for a compound series with varying substituents targeting two subpockets of the binding site of Trypanosoma brucei pteridine reductase 1. For one subpocket, we find that the model is more predictive for inhibitory activity than the ab initio interaction energy calculated at the MP2 level. Furthermore, the model is found to outperform a commonly used empirical scoring method. Finally, we show that the results for the two subpockets can be combined, which suggests that this simple nonempirical scoring function could be applied in fragment–based drug design.Electronic supplementary materialThe online version of this article (doi:10.1007/s10822-017-0035-4) contains supplementary material, which is available to authorized users.
Mitochondrial fatty acid synthesis (mtFAS) is essential for respiratory function. MtFAS generates the octanoic acid precursor for lipoic acid synthesis, but the role of longer fatty acid products has remained unclear. The structurally well-characterized component of mtFAS, human 2E-enoyl-ACP reductase (MECR) rescues respiratory growth and lipoylation defects of a Saccharomyces cerevisiae Δetr1 strain lacking native mtFAS enoyl reductase. To address the role of longer products of mtFAS, we employed in silico molecular simulations to design a MECR variant with a shortened substrate binding cavity. Our in vitro and in vivo analyses indicate that the MECR G165Q variant allows synthesis of octanoyl groups but not long chain fatty acids, confirming the validity of our computational approach to engineer substrate length specificity. Furthermore, our data imply that restoring lipoylation in mtFAS deficient yeast strains is not sufficient to support respiration and that long chain acyl-ACPs generated by mtFAS are required for mitochondrial function.
The Neglected Tropical Diseases (NTDs) are a group of 17 pathologies, recognized by the World Health Organization (WHO), which are endemic in 149 countries of tropical and subtropical areas of the globe, and affect more than one billion people overall (Feasey et al. 2010). The pathologies are all caused by microparasites or macroparasites. Among the diseases provoked by microparasites, three are caused by kinetoplastidae, a group of flagellated protozoa transmitted by insect vectors: Chagas disease, Human African Trypanosomiasis and leishmaniasis. The focus of the present chapter is on the identification of new drugs for the treatment of trypanosomatidic infections such as Chagas disease, caused by Trypanosoma cruzi, and Human African Trypanosomiasis, caused by Trypanosoma brucei (Filardy et al. 2018).
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