Sarah A. Kessans

Genome-wide binding and mechanistic analyses of Smchd1-mediated epigenetic regulation

Significance Structural maintenance of chromosomes flexible hinge domain containing 1 (Smchd1) is a protein that plays an important role in maintaining gene silencing in many biological circumstances, including facioscapulohumeral muscular dystrophy; however, how it brings about gene silencing is unknown. Understanding the molecular mechanism by which Smchd1 contributes to stable transcriptional silencing is critical to appreciate how it functions in normal biology and when it is mutated in facioscapulohumeral muscular dystrophy. This study reveals, for the first time to our knowledge, where Smchd1 binds genome-wide, its hitherto unappreciated functional interaction with chromatin organizer CCCTC-binding factor in gene regulation, and which part of the protein is required for chromatin binding. These data lead to a new model of Smchd1 function, where it directly binds DNA to mediate 3D chromatin architecture. Structural maintenance of chromosomes flexible hinge domain containing 1 (Smchd1) is an epigenetic repressor with described roles in X inactivation and genomic imprinting, but Smchd1 is also critically involved in the pathogenesis of facioscapulohumeral dystrophy. The underlying molecular mechanism by which Smchd1 functions in these instances remains unknown. Our genome-wide transcriptional and epigenetic analyses show that Smchd1 binds cis-regulatory elements, many of which coincide with CCCTC-binding factor (Ctcf) binding sites, for example, the clustered protocadherin (Pcdh) genes, where we show Smchd1 and Ctcf act in opposing ways. We provide biochemical and biophysical evidence that Smchd1–chromatin interactions are established through the homodimeric hinge domain of Smchd1 and, intriguingly, that the hinge domain also has the capacity to bind DNA and RNA. Our results suggest Smchd1 imparts epigenetic regulation via physical association with chromatin, which may antagonize Ctcf-facilitated chromatin interactions, resulting in coordinated transcriptional control.

Conformational Dynamics and Allostery in Pyruvate Kinase.

Pyruvate kinase catalyzes the final step in glycolysis and is allosterically regulated to control flux through the pathway. Two models are proposed to explain how Escherichia coli pyruvate kinase type 1 is allosterically regulated: the “domain rotation model” suggests that both the domains within the monomer and the monomers within the tetramer reorient with respect to one another; the “rigid body reorientation model” proposes only a reorientation of the monomers within the tetramer causing rigidification of the active site. To test these hypotheses and elucidate the conformational and dynamic changes that drive allostery, we performed time-resolved electrospray ionization mass spectrometry coupled to hydrogen-deuterium exchange studies followed by mutagenic analysis to test the activation mechanism. Global exchange experiments, supported by thermostability studies, demonstrate that fructose 1,6-bisphosphate binding to the allosteric domain causes a shift toward a globally more dynamic ensemble of conformations. Mapping deuterium exchange to peptides within the enzyme highlight site-specific regions with altered conformational dynamics, many of which increase in conformational flexibility. Based upon these and mutagenic studies, we propose an allosteric mechanism whereby the binding of fructose 1,6-bisphosphate destabilizes an α-helix that bridges the allosteric and active site domains within the monomeric unit. This destabilizes the β-strands within the (β/α)8-barrel domain and the linked active site loops that are responsible for substrate binding. Our data are consistent with the domain rotation model but inconsistent with the rigid body reorientation model given the increased flexibility at the interdomain interface, and we can for the first time explain how fructose 1,6-bisphosphate affects the active site.

Ultra‐high resolution crystal structure of recombinant caprine β‐lactoglobulin

β‐Lactoglobulin (βlg) is the most abundant whey protein in the milks of ruminant animals. While bovine βlg has been subjected to a vast array of studies, little is known about the caprine ortholog. We present an ultra‐high resolution crystal structure of caprine βlg complemented by analytical ultracentrifugation and small‐angle X‐ray scattering data. In both solution and crystalline states caprine βlg is dimeric (K D < 5 μM); however, our data suggest a flexible quaternary arrangement of subunits within the dimer. These structural findings will provide insight into relationships among structural, processing, nutritional and immunological characteristics that distinguish cows and goats milk.

Cloning, expression, purification, crystallization and preliminary X-ray diffraction studies of N-acetylneuraminate lyase from methicillin-resistant Staphylococcus aureus

The enzyme N-acetylneuraminate lyase (EC 4.1.3.3) is involved in the metabolism of sialic acids. Specifically, the enzyme catalyzes the retro-aldol cleavage of N-acetylneuraminic acid to form N-acetyl-D-mannosamine and pyruvate. Sialic acids comprise a large family of nine-carbon amino sugars, all of which are derived from the parent compound N-acetylneuraminic acid. In recent years, N-acetylneuraminate lyase has received considerable attention from both mechanistic and structural viewpoints and has been recognized as a potential antimicrobial drug target. The N-acetylneuraminate lyase gene was cloned from methicillin-resistant Staphylococcus aureus genomic DNA, and recombinant protein was expressed and purified from Escherichia coli BL21 (DE3). The enzyme crystallized in a number of crystal forms, predominantly from PEG precipitants, with the best crystal diffracting to beyond 1.70 Å resolution in space group P2₁. Molecular replacement indicates the presence of eight monomers per asymmetric unit. Understanding the structural biology of N-acetylneuraminate lyase in pathogenic bacteria, such as methicillin-resistant S. aureus, will provide insights for the development of future antimicrobials.

Heterologous Biosynthesis of Nodulisporic Acid F

Nodulisporic acids comprise a group of valuable indole diterpenes that exhibit potent insecticidal activities. We report the identification of a gene cluster in the genome of the filamentous fungus Hypoxylon pulicicidum (Nodulisporium sp.) that contains genes responsible for the biosynthesis of nodulisporic acids. Using Penicillium paxilli as a heterologous host, and through pathway reconstitution experiments, we identified the function of four genes involved in the biosynthesis of the nodulisporic acid core compound, nodulisporic acid F (NAF). Two of these genes (nodM and nodW) are especially significant as they encode enzymes with previously unreported functionality: nodM encodes a 3-geranylgeranylindole epoxidase capable of catalyzing only a single epoxidation step to prime formation of the distinctive ring structure of nodulisporic acids, and nodW encodes the first reported gene product capable of introducing a carboxylic acid moiety to an indole diterpene core structure that acts as a reactive handle for further modification. Here, we present the enzymatic basis for the biosynthetic branch point that gives rise to nodulisporic acids.

Grappling with anisotropic data, pseudo‐merohedral twinning and pseudo‐translational noncrystallographic symmetry: a case study involving pyruvate kinase

Pyruvate kinase is a key regulatory enzyme involved in the glycolytic pathway. The crystal structure of Escherichia coli type I pyruvate kinase was first solved in 1995 at 2.5 Å resolution. However, the space group was ambiguous, being either primitive orthorhombic (P2(1)2(1)2(1)) or C-centred orthorhombic (C222(1)). Here, the structure determination and refinement of E. coli type I pyruvate kinase to 2.28 Å resolution are presented. Using the same crystallization conditions as reported previously, the enzyme was found to crystallize in space group P2(1). Determination of the space group was complicated owing to anisotropic data, pseudo-translational noncrystallographic symmetry and the pseudo-merohedrally twinned nature of the crystal, which was found to have very close to 50% twinning, leading to apparent orthorhombic symmetry and absences that were not inconsistent with P2(1)2(1)2(1). The unit cell contained two tetramers in the asymmetric unit (3720 residues) and, when compared with the orthorhombic structure, virtually all of the residues could be easily modelled into the density. Averaging of reflections into the lower symmetry space group with twinning provided tidier electron density that allowed ∼30 missing residues of the lid domain to be modelled for the first time. Moreover, residues in a flexible loop could be modelled and sulfate molecules are found in the allosteric binding domain, identifying the pocket that binds the allosteric activator fructose 1,6-bisphosphate in this isozyme for the first time. Lastly, we note the pedagogical benefits of difficult structures to emerging crystallographers.

Substrate‐mediated control of the conformation of an ancillary domain delivers a competent catalytic site for N‐acetylneuraminic acid synthase

N‐Acetylneuraminic acid (NANA) is the most common naturally occurring sialic acid and plays a key role in the pathogenesis of a select number of neuroinvasive bacteria such as Neisseria meningitidis. NANA is synthesized in prokaryotes via a condensation reaction between phosphoenolpyruvate and N‐acetylmannosamine. This reaction is catalyzed by a domain swapped, homodimeric enzyme, N‐acetylneuraminic acid synthase (NANAS). NANAS comprises two distinct domains; an N‐terminal catalytic (β/α)8 barrel linked to a C‐terminal antifreeze protein‐like (AFPL) domain. We have investigated the role of the AFPL domain by characterizing a truncated variant of NmeNANAS, which was discovered to be soluble yet inactive. Analytical ultracentrifugation and analytical size exclusion were used to probe the quaternary state of the NmeNANAS truncation, and revealed that loss of the AFPL domain destabilizes the dimeric form of the enzyme. The results from this study thereby demonstrate that the AFPL domain plays a critical role for both the catalytic function and quaternary structure stability of NANAS. Small angle X‐ray scattering, molecular dynamics simulations, and amino acid substitutions expose a complex hydrogen‐bonding relay, which links the roles of the catalytic and AFPL domains across subunit boundaries. Proteins 2014; 82:2054–2066.

The purification, crystallization and preliminary X-ray diffraction analysis of two isoforms of meso-diaminopimelate decarboxylase from Arabidopsis thaliana

Diaminopimelate decarboxylase catalyses the last step in the diaminopimelate-biosynthetic pathway leading to S-lysine: the decarboxylation of meso-diaminopimelate to form S-lysine. Lysine biosynthesis occurs only in microorganisms and plants, and lysine is essential for the growth and development of animals. Thus, the diaminopimelate pathway represents an attractive target for antimicrobial and herbicide treatments and has received considerable attention from both a mechanistic and a structural viewpoint. Diaminopimelate decarboxylase has only been characterized in prokaryotic species. This communication describes the first structural studies of two diaminopimelate decarboxylase isoforms from a plant. The Arabidopsis thaliana diaminopimelate decarboxylase cDNAs At3g14390 (encoding DapDc1) and At5g11880 (encoding DapDc2) were cloned from genomic DNA and the recombinant proteins were expressed and purified from Escherichia coli Rosetta (DE3) cells. The crystals of DapDc1 and DapDc2 diffracted to beyond 2.00 and 2.27 Å resolution, respectively. Understanding the structural biology of diaminopimelate decarboxylase from a eukaryotic species will provide insights for the development of future herbicide treatments, in particular.

The sodium sialic acid symporter from Staphylococcus aureus has altered substrate specificity.

Mammalian cell surfaces are decorated with complex glycoconjugates that terminate with negatively charged sialic acids. Commensal and pathogenic bacteria can use host-derived sialic acids for a competitive advantage, but require a functional sialic acid transporter to import the sugar into the cell. This work investigates the sodium sialic acid symporter (SiaT) from Staphylococcus aureus (SaSiaT). We demonstrate that SaSiaT rescues an Escherichia coli strain lacking its endogenous sialic acid transporter when grown on the sialic acids N-acetylneuraminic acid (Neu5Ac) or N-glycolylneuraminic acid (Neu5Gc). We then develop an expression, purification and detergent solubilization system for SaSiaT and demonstrate that the protein is largely monodisperse in solution with a stable monomeric oligomeric state. Binding studies reveal that SaSiaT has a higher affinity for Neu5Gc over Neu5Ac, which was unexpected and is not seen in another SiaT homolog. We develop a homology model and use comparative sequence analyses to identify substitutions in the substrate-binding site of SaSiaT that may explain the altered specificity. SaSiaT is shown to be electrogenic, and transport is dependent upon more than one Na+ ion for every sialic acid molecule. A functional sialic acid transporter is essential for the uptake and utilization of sialic acid in a range of pathogenic bacteria, and developing new inhibitors that target these transporters is a valid mechanism for inhibiting bacterial growth. By demonstrating a route to functional recombinant SaSiaT, and developing the in vivo and in vitro assay systems, our work underpins the design of inhibitors to this transporter.

A Pseudoisostructural Type II DAH7PS Enzyme from Pseudomonas aeruginosa: Alternative Evolutionary Strategies to Control Shikimate Pathway Flux

The shikimate pathway is responsible for the biosynthesis of key aromatic metabolites in microorganisms and plants. The enzyme 3-deoxy-d- arabino-heptulosonate 7-phosphate synthase (DAH7PS) catalyzes the first step of the pathway and DAH7PSs are classified as either type I or type II. The DAH7PSs from Pseudomonas aeruginosa are of particular interest as open reading frames encoding four putative DAH7PS isoenzymes, two classified as type Iα and two classified as type II, have been identified. Here, the structure of a type II DAH7PS enzyme from P. aeruginosa (PAO1) has been determined at 1.54 Å resolution, in complex with its allosteric inhibitor tryptophan. Structural differences in the extra-barrel elements, when compared to other type II DAH7PS enzymes, directly relate to the formation of a distinct quaternary conformation with consequences for allosteric function and the control of flux to branching pathways. In contrast to the well-characterized Mycobacterium tuberculosis type II DAH7PS, which binds multiple allosteric inhibitors, this PaeDAH7PSPA2843 is observed to be modestly allosterically inhibited by a single aromatic amino acid, tryptophan. In addition, structures in complex with tyrosine or with no allosteric ligand bound were determined. These structures provide new insights into the linkages between the active and allosteric sites. With four putative DAH7PS enzymes, P. aeruginosa appears to have evolved control of shikimate pathway flux at the genetic level, rather than control by multiple allosteric effectors to a single type II DAH7PS, as in M. tuberculosis. Type II DAH7PSs, thus, appear to have a more varied evolutionary trajectory than previously indicated.