53 research outputs found
Dimerization and Heme Binding Are Conserved in Amphibian and Starfish Homologues of the microRNA Processing Protein DGCR8
Human DiGeorge Critical Region 8 (DGCR8) is an essential microRNA (miRNA) processing factor that is activated via direct interaction with Fe(III) heme. In order for DGCR8 to bind heme, it must dimerize using a dimerization domain embedded within its heme-binding domain (HBD). We previously reported a crystal structure of the dimerization domain from human DGCR8, which demonstrated how dimerization results in the formation of a surface important for association with heme. Here, in an attempt to crystallize the HBD, we search for DGCR8 homologues and show that DGCR8 from Patiria miniata (bat star) also binds heme. The extinction coefficients (ε) of DGCR8-heme complexes are determined; these values are useful for biochemical analyses and allow us to estimate the heme occupancy of DGCR8 proteins. Additionally, we present the crystal structure of the Xenopus laevis dimerization domain. The structure is very similar to that of human DGCR8. Our results indicate that dimerization and heme binding are evolutionarily conserved properties of DGCR8 homologues not only in vertebrates, but also in at least some invertebrates
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Protonation state of glutamate 73 regulates the formation of a specific dimeric association of mVDAC1.
The voltage-dependent anion channel (VDAC) is the most abundant protein in the outer mitochondrial membrane and constitutes the primary pathway for the exchange of ions and metabolites between the cytosol and the mitochondria. There is accumulating evidence supporting VDAC's role in mitochondrial metabolic regulation and apoptosis, where VDAC oligomerization has been implicated with these processes. Herein, we report a specific pH-dependent dimerization of murine VDAC1 (mVDAC1) identified by double electron-electron resonance and native mass spectrometry. Intermolecular distances on four singly spin-labeled mVDAC1 mutants were used to generate a model of the low-pH dimer, establishing the presence of residue E73 at the interface. This dimer arrangement is different from any oligomeric state previously described, and it forms as a steep function of pH with an apparent pKa of 7.4. Moreover, the monomer-dimer equilibrium affinity constant was determined using native MS, revealing a nearly eightfold enhancement in dimerization affinity at low pH. Mutation of E73 to either alanine or glutamine severely reduces oligomerization, demonstrating the role of protonated E73 in enhancing dimer formation. Based on these results, and the known importance of E73 in VDAC physiology, VDAC dimerization likely plays a significant role in mitochondrial metabolic regulation and apoptosis in response to cytosolic acidification during cellular stress
Origin of Complexity in Hemoglobin Evolution
Most proteins associate into multimeric complexes with specific architectures, which often have functional properties such as cooperative ligand binding or allosteric regulation. No detailed knowledge is available about how any multimer and its functions arose during evolution. Here we use ancestral protein reconstruction and biophysical assays to elucidate the origins of vertebrate hemoglobin, a heterotetramer of paralogous α- and β-subunits that mediates respiratory oxygen transport and exchange by cooperatively binding oxygen with moderate affinity. We show that modern hemoglobin evolved from an ancient monomer and characterize the historical “missing link” through which the modern tetramer evolved—a noncooperative homodimer with high oxygen affinity that existed before the gene duplication that generated distinct α- and β-subunits. Reintroducing just two post-duplication historical substitutions into the ancestral protein is sufficient to cause strong tetramerization by creating favorable contacts with more ancient residues on the opposing subunit. These surface substitutions markedly reduce oxygen affinity and even confer cooperativity because an ancient linkage between the oxygen binding site and the multimerization interface was already an intrinsic feature of the protein’s structure. Our findings establish that evolution can produce new complex molecular structures and functions via simple genetic mechanisms that recruit existing biophysical features into higher-level architectures.
The interfaces that hold molecular complexes together typically involve sterically tight, electrostatically complementary interactions among many amino acids. Similarly, allostery and cooperativity usually depend on numerous residues that connect surfaces to active sites. The acquisition of such complicated machinery would seem to require elaborate evolutionary pathways. The classical explanation of this process, by analogy to the evolution of morphological complexity, is that multimerization conferred or enhanced beneficial functions, allowing selection to drive the many substitutions required to build and optimize new interfaces.
Whether this account accurately describes the evolution of any natural molecular complex requires a detailed reconstruction of the historical steps by which it evolved. Hemoglobin (Hb) is a useful model for this purpose, because the structural mechanisms that mediate its multimeric assembly, cooperative oxygen binding, and allosteric regulation are well established. Moreover, its subunits descend by duplication and divergence from the same ancestral proteins, so their history can be reconstructed in a single analysis. Despite considerable speculation, virtually nothing is known about the evolutionary origin of Hb’s heterotetrameric architecture and the functions that depend on it
Towards a Pharmacophore for Amyloid
Diagnosing and treating Alzheimer's and other diseases associated with amyloid fibers remains a great challenge despite intensive research. To aid in this effort, we present atomic structures of fiber-forming segments of proteins involved in Alzheimer's disease in complex with small molecule binders, determined by X-ray microcrystallography. The fiber-like complexes consist of pairs of β-sheets, with small molecules binding between the sheets, roughly parallel to the fiber axis. The structures suggest that apolar molecules drift along the fiber, consistent with the observation of nonspecific binding to a variety of amyloid proteins. In contrast, negatively charged orange-G binds specifically to lysine side chains of adjacent sheets. These structures provide molecular frameworks for the design of diagnostics and drugs for protein aggregation diseases
Quantifying the stabilizing effects of protein-ligand interactions in the gas phase
The effects of protein–ligand interactions on protein stability are typically monitored by a number of established solution-phase assays. Few translate readily to membrane proteins. We have developed an ion-mobility mass spectrometry approach, which discerns ligand binding to both soluble and membrane proteins directly via both changes in mass and ion mobility, and assesses the effects of these interactions on protein stability through measuring resistance to unfolding. Protein unfolding is induced through collisional activation, which causes changes in protein structure and consequently gas-phase mobility. This enables detailed characterization of the ligand-binding effects on the protein with unprecedented sensitivity. Here we describe the method and software required to extract from ion mobility data the parameters that enable a quantitative analysis of individual binding events. This methodology holds great promise for investigating biologically significant interactions between membrane proteins and both drugs and lipids that are recalcitrant to characterization by other means
Step toward Probing the Nonannular Belt of Membrane Proteins
Integral membrane proteins are embedded in the biological
membrane,
where they carry out numerous biological processes. Although lipids
present in the membrane are crucial for membrane protein function,
it remains difficult to characterize many lipid binding events to
membrane proteins, such as those that form the annular belt. Here,
we use native mass spectrometry along with the charge-reducing properties
of trimethylamine N-oxide (TMAO) to characterize
a large number of lipid binding events to the bacterial ammonia channel
(AmtB). In the absence of TMAO, significant peak overlap between neighboring
charge states is observed, resulting in erroneous abundances for different
molecular species. With the addition of TMAO, the weighted average
charge state (Zavg) was decreased. In
addition, the increased spacing between nearby charge states enabled
a higher number of lipid binding species to be observed while minimizing
mass spectral peak overlap. These conditions helped us to determine
the equilibrium binding constants (Kd)
for up to 16 lipid binding events. The binding constants for the first
few lipid binding events display the highest affinity, whereas the
binding constants for higher lipid binding events converge to a similar
value. These findings suggest a transition from nonannular to annular
lipid binding to AmtB
Double and triple thermodynamic mutant cycles reveal the basis for specific MsbA-lipid interactions
Structural and functional studies of the ATP-binding cassette transporter MsbA have revealed two distinct lipopolysaccharide (LPS) binding sites: one located in the central cavity and the other at a membrane-facing, exterior site. Although these binding sites are known to be important for MsbA function, the thermodynamic basis for these specific MsbA-LPS interactions is not well understood. Here, we use native mass spectrometry to determine the thermodynamics of MsbA interacting with the LPS-precursor 3-deoxy-D-manno-oct-2-ulosonic acid (Kdo)2-lipid A (KDL). The binding of KDL is solely driven by entropy, despite the transporter adopting an inward-facing conformation or trapped in an outward-facing conformation with adenosine 5’-diphosphate and vanadate. An extension of the mutant cycle approach is employed to probe basic residues that interact with KDL. We find the molecular recognition of KDL is driven by a positive coupling entropy (as large as –100 kJ/mol at 298 K) that outweighs unfavorable coupling enthalpy. These findings indicate that alterations in solvent reorganization and conformational entropy can contribute significantly to the free energy of protein-lipid association. The results presented herein showcase the advantage of native MS to obtain thermodynamic insight into protein-lipid interactions that would otherwise be intractable using traditional approaches, and this enabling technology will be instrumental in the life sciences and drug discovery
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