Ross G. Douglas scite author profile

Cell motility is essential for protozoan and metazoan organisms and typically relies on the dynamic turnover of actin filaments. In metazoans, monomeric actin polymerises into usually long and stable filaments, while some protozoans form only short and highly dynamic actin filaments. These different dynamics are partly due to the different sets of actin regulatory proteins and partly due to the sequence of actin itself. Here we probe the interactions of actin subunits within divergent actin filaments using a comparative dynamic molecular model and explore their functions using Plasmodium, the protozoan causing malaria, and mouse melanoma derived B16-F1 cells as model systems. Parasite actin tagged to a fluorescent protein (FP) did not incorporate into mammalian actin filaments, and rabbit actin-FP did not incorporate into parasite actin filaments. However, exchanging the most divergent region of actin subdomain 3 allowed such reciprocal incorporation. The exchange of a single amino acid residue in subdomain 2 (N41H) of Plasmodium actin markedly improved incorporation into mammalian filaments. In the parasite, modification of most subunit–subunit interaction sites was lethal, whereas changes in actin subdomains 1 and 4 reduced efficient parasite motility and hence mosquito organ penetration. The strong penetration defects could be rescued by overexpression of the actin filament regulator coronin. Through these comparative approaches we identified an essential and common contributor, subdomain 3, which drives the differential dynamic behaviour of two highly divergent eukaryotic actins in motile cells.

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Investigating the Domain Specificity of Phosphinic Inhibitors RXPA380 and RXP407 in Angiotensin-Converting Enzyme

Kröger

Douglas

O’Neill

et al. 2009

Biochemistry

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Human somatic angiotensin-converting enzyme (ACE) is a membrane-bound dipeptidyl carboxypeptidase that contains two extracellular domains (N and C). Although highly homologous, they exhibit different substrate and inhibition profiles. The phosphinic inhibitors RXPA380 and RXP407 are highly selective for the C- and N-domains, respectively. A number of residues, implicated by structural data, are likely to contribute to this selectivity. However, the extent to which these different interactions are responsible for domain selectivity is unclear. In this study, a series of C- and N-domain mutants containing conversions to corresponding domain residues were used to scrutinize the contribution of these residues to selective inhibitor binding. Enzyme kinetic analyses of the purified mutants indicated that the RXPA380 C-selectivity is particularly reliant on the interaction between the P2 substituent and Phe 391 (testis ACE numbering). Moreover, a C-domain mutant in which Phe 391 has been changed to a Tyr residue, in addition to containing an N-domain S2' pocket (S2'F/Y), displayed the greatest shift toward a more N-domain-like Ki. None of the single mutations within the N-domain caused a large shift in RXP407's affinity for these enzymes. However, the double mutant containing the Tyr 369 to Phe change as well as Arg 381 to Glu displayed a 100-fold decrease in binding affinity, confirming that the S2 pocket plays a major role in RXP407 selectivity. Taken together, these data advance our understanding regarding the molecular basis for the remarkable ACE domain selectivity exhibited by these inhibitors.

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Fragment-based design for the development of N-domain-selective angiotensin-1-converting enzyme inhibitors

Douglas

Sharma

Masuyer

et al. 2013

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ACE (angiotensin-1-converting enzyme) is a zinc metallopeptidase that plays a prominent role in blood pressure regulation and electrolyte homeostasis. ACE consists of two homologous domains that despite similarities of sequence and topology display differences in substrate processing and inhibitor binding. The design of inhibitors that selectively inhibit the N-domain (N-selective) could be useful in treating conditions of tissue injury and fibrosis due to build-up of N-domain-specific substrate Ac-SDKP (N-acetyl-Ser–Asp–Lys–Pro). Using a receptor-based SHOP (scaffold hopping) approach with N-selective inhibitor RXP407, a shortlist of scaffolds that consisted of modified RXP407 backbones with novel chemotypes was generated. These scaffolds were selected on the basis of enhanced predicted interaction energies with N-domain residues that differed from their C-domain counterparts. One scaffold was synthesized and inhibitory binding tested using a fluorogenic ACE assay. A molecule incorporating a tetrazole moiety in the P2 position (compound 33RE) displayed potent inhibition (Ki=11.21±0.74 nM) and was 927-fold more selective for the N-domain than the C-domain. A crystal structure of compound 33RE in complex with the N-domain revealed its mode of binding through aromatic stacking with His388 and a direct hydrogen bond with the hydroxy group of the N-domain specific Tyr369. This work further elucidates the molecular basis for N-domainselective inhibition and assists in the design of novel N-selective ACE inhibitors that could be employed in treatment of fibrosis disorders.

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Ross G. Douglas

Active migration and passive transport of malaria parasites

Inter-subunit interactions drive divergent dynamics in mammalian and Plasmodium actin filaments

Investigating the Domain Specificity of Phosphinic Inhibitors RXPA380 and RXP407 in Angiotensin-Converting Enzyme

Fragment-based design for the development of N-domain-selective angiotensin-1-converting enzyme inhibitors

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