Fused dimerization increases expression, solubility, and activity of bacterial dehydratase enzymes.

FabA and FabZ are the two dehydratase enzymes in Escherichia coli that catalyze the dehydration of acyl intermediates in the biosynthesis of fatty acids. Both enzymes form obligate dimers in which the active site contains key amino acids from both subunits. While FabA is a soluble protein that has been relatively straightforward to express and to purify from cultured E. coli, FabZ has shown to be mostly insoluble and only partially active. In an effort to increase the solubility and activity of both dehydratases, we made constructs consisting of two identical subunits of FabA or FabZ fused with a naturally occurring peptide linker, so as to force their dimerization. The fused dimer of FabZ (FabZ-FabZ) was expressed as a soluble enzyme with an ninefold higher activity in vitro than the unfused FabZ. This construct exemplifies a strategy for the improvement of enzymes from the fatty acid biosynthesis pathways, many of which function as dimers, catalyzing critical steps for the production of fatty acids.

Trapping of the Enoyl-Acyl Carrier Protein Reductase-Acyl Carrier Protein Interaction.

An ideal target for metabolic engineering, fatty acid biosynthesis remains poorly understood on a molecular level. These carrier protein-dependent pathways require fundamental protein-protein interactions to guide reactivity and processivity, and their control has become one of the major hurdles in successfully adapting these biological machines. Our laboratory has developed methods to prepare acyl carrier proteins (ACPs) loaded with substrate mimetics and cross-linkers to visualize and trap interactions with partner enzymes, and we continue to expand the tools for studying these pathways. We now describe application of the slow-onset, tight-binding inhibitor triclosan to explore the interactions between the type II fatty acid ACP from Escherichia coli, AcpP, and its corresponding enoyl-ACP reductase, FabI. We show that the AcpP-triclosan complex demonstrates nM binding, inhibits in vitro activity, and can be used to isolate FabI in complex proteomes.

Strategies for crystallization and structure determination of very large macromolecular assemblies.

High-resolution structures of macromolecular assemblies are pivotal for our understanding of their biological functions in fundamental cellular processes. In the field of X-ray crystallography, recent methodological and instrumental advances have led to the structure determinations of macromolecular assemblies of increased size and complexity, such as those of ribosomal complexes, RNA polymerases, and large multifunctional enzymes. These advances include the use of robotic screening techniques that maximize the chances of obtaining well-diffracting crystals of large complexes through the fine sampling of crystallization space. Sophisticated crystal optimization and cryoprotection techniques and the use of highly brilliant X-ray beams from third-generation synchrotron light sources now allow data collection from weakly diffracting crystals with large asymmetric units. Combined approaches are used to derive phase information, including phases calculated from electron microscopy (EM) models, heavy atom clusters, and density modification protocols. New crystallographic software tools prove valuable for structure determination and model refinement of large macromolecular complexes.