Cell signaling that culminates in posttranslational modifications directs protein activity. Here we report how multiple Ca 2+ -dependent phosphorylation sites within the transcription activator Ets-1 act additively to produce graded DNA binding affinity. Nuclear magnetic resonance spectroscopic analyses show that phosphorylation shifts Ets-1 from a dynamic conformation poised to bind DNA to a well-folded inhibited state. These phosphates lie in an unstructured flexible region that functions as the allosteric effector of autoinhibition. Variable phosphorylation thus serves as a “rheostat” for cell signaling to fine-tune transcription at the level of DNA binding.
The transcription factor Ets-1 is regulated by the allosteric coupling of DNA binding with the unfolding of an ␣-helix (HI-1) within an autoinhibitory module. To understand the structural and dynamic basis for this autoinhibition, we have used NMR spectroscopy to characterize Ets-1⌬N301, a partially inhibited fragment of Ets-1. The NMR-derived Ets-1⌬N301 structure reveals that the autoinhibitory module is formed predominantly by the hydrophobic packing of helices from the N-terminal (HI-1, HI-2) and C-terminal (H4, H5) inhibitory sequences, along with H1 of the intervening DNA binding ETS domain. The intramolecular interactions made by HI-1 in Ets-1⌬N301 are similar to the intermolecular contacts observed in the crystal structure of an Ets-1⌬N300 dimer, confirming that the latter represents a domain-swapped species.15 N relaxation studies demonstrate that the backbone of the N-terminal inhibitory sequence is mobile on the nanosecond-picosecond and millisecond-microsecond time scales. Furthermore, hydrogen exchange measurements reveal that amide protons in helices HI-1 and HI-2 exchange with water at rates only ϳ15-and ϳ75-fold slower, respectively, than predicted for an unfolded polypeptide. These findings indicate that inhibitory helices are only marginally stable even in the absence of DNA. The energetic coupling of DNA binding with the facile unfolding of the labile HI-1 provides a mechanism for modulating Ets-1 DNA binding activity via protein partnerships, post-translational modifications, or mutations. Ets-1 autoinhibition illustrates how conformational equilibria within structural domains can regulate macromolecular interactions.Gene expression can be controlled by modulating the DNA binding affinity of sequence specific transcription factors. Similar to several other transcription factors, the DNA binding of Ets-1 is modulated by an autoinhibitory module that provides a route to biological regulation (1). The Ets-1 inhibitory module is composed of sequences flanking the winged helix-turn-helix (HTH) 1 DNA binding ETS domain (2, 3). When these sequences are deleted, as in an alternatively spliced isoform of Ets-1, or when their structural elements are disrupted by mutations, as in the case of the oncogenic v-Ets, the affinity of Ets-1 for its target DNA sites is enhanced by 10-to 20-fold (4 -6). In a cellular context, this module is essential for response to different regulatory signals. DNA binding of Ets-1 is enhanced 10-to 20-fold through a partnership with the transcription factor RUNX1 (CBF␣2/AML1) (7). Conversely, in activated T-cells, phosphorylation of a serine-rich region (residues 244 -300) inhibits the DNA binding of Ets-1 by another ϳ50-fold (8). Importantly, these two effects require an intact inhibitory module.Mechanistic insight into autoinhibition has come from the observation that the Ets-1 inhibitory module changes conformation upon binding to DNA. Initial secondary structural studies performed in our laboratories demonstrated that this module is composed of four coupled ␣-helices, locat...
The influx of genomic sequence information has led to the concept of structural proteomics, the determination of protein structures on a genome-wide scale. Here we describe an approach to structural proteomics of small proteins using NMR spectroscopy. Over 500 small proteins from several organisms were cloned, expressed, purified, and evaluated by NMR. Although there was variability among proteomes, overall 20% of these proteins were found to be readily amenable to NMR structure determination. NMR sample preparation was centralized in one facility, and a distributive approach was used for NMR data collection and analysis. Twelve structures are reported here as part of this approach, which allowed us to infer putative functions for several conserved hypothetical proteins. S tructural proteomics, which aims to determine the threedimensional (3D) structures of all proteins, has become a major initiative within the biomedical community (see ref. 1 and other articles in the same issue). The large number of protein structures expected from these projects will yield valuable clues to the rules for predicting protein folding and understanding biochemical function. In these early stages of the structural proteomics effort, one of the main goals is to identify the best technologies and the most efficient processes to convert gene sequence into 3D structural information. One of the decisions will be to determine the optimal use of x-ray crystallography and NMR spectroscopy, which are the two techniques that will provide the majority of experimental data for these initiatives.X-ray crystallography currently is perceived as the potential workhorse for structural proteomics, because if provided with a well diffracting crystal it is possible to determine a 3D structure in hours. However, the throughput of structure determination using x-ray crystallography remains unclear, because the ratedetermining step continues to be the production of well diffracting crystals, a process that is unpredictable and can take between hours and months.NMR structure determination is limited currently by size constraints and lengthy data collection and analysis times (often months), and the method is best applied to proteins smaller than 250 amino acids. On the other hand, NMR experiments do not require crystals, and samples appropriate for structure determination can be identified within minutes of the protein being purified. In summary, x-ray crystallography and NMR spectroscopy seem to have complementary deficiencies, and the relative success of these methods in structural proteomics remains to be determined.We have shown previously that NMR spectroscopy can play a significant role in structural proteomics even with its current limitations (2). The initial pilot project, based on a limited number of proteins from the thermophilic archaebacterium Methanobacterium thermoautotrophicum (Mth) suggested that smaller proteins may be more amenable to structure analysis, because in this genome a higher proportion of smaller proteins were soluble compar...
Site-specific pK(a) values measured by NMR spectroscopy provide essential information on protein electrostatics, the pH-dependence of protein structure, dynamics and function, and constitute an important benchmark for protein pK(a) calculation algorithms. Titration curves can be measured by tracking the NMR chemical shifts of several reporter nuclei versus sample pH. However, careful analysis of these curves is needed to extract residue-specific pK(a) values since pH-dependent chemical shift changes can arise from many sources, including through-bond inductive effects, through-space electric field effects, and conformational changes. We have re-measured titration curves for all carboxylates and His 15 in Hen Egg White Lysozyme (HEWL) by recording the pH-dependent chemical shifts of all backbone amide nitrogens and protons, Asp/Glu side chain protons and carboxyl carbons, and imidazole protonated carbons and protons in this protein. We extracted pK(a) values from the resulting titration curves using standard fitting methods, and compared these values to each other, and with those measured previously by ¹H NMR (Bartik et al., Biophys J 1994;66:1180–1184). This analysis gives insights into the true accuracy associated with experimentally measured pK(a) values. We find that apparent pK(a) values frequently differ by 0.5–1.0 units depending upon the nuclei monitored, and that larger differences occasionally can be observed. The variation in measured pK(a) values, which reflects the difficulty in fitting and assigning pH-dependent chemical shifts to specific ionization equilibria, has significant implications for the experimental procedures used for measuring protein pK(a) values, for the benchmarking of protein pK(a) calculation algorithms, and for the understanding of protein electrostatics in general.
Summary Structure-based drug design traditionally uses static protein models as inspirations for focusing on “active” site targets. Allosteric regulation of biological macromolecules, however, is affected by both conformational and dynamic properties of the protein or protein complex, and can potentially lead to more avenues for therapeutic development. We discuss the advantages of searching for molecules that conformationally trap a macromolecule in its inactive state. Although multiple methodologies exist to probe protein dynamics and ligand binding, our current discussion highlights the use of nuclear magnetic resonance (NMR) spectroscopy in the drug discovery and design process.
Biohybrid antenna systems have been constructed that contain synthetic chromophores attached to 31mer analogues of the bacterial photosynthetic core light-harvesting (LH1) β-polypeptide. The peptides are engineered with a Cys site for bioconjugation with maleimide-terminated chromophores, which include synthetic bacteriochlorins (BC1, BC2) with strong near-infrared absorption and commercial dyes Oregon green (OGR) and rhodamine red (RR) with strong absorption in the blue-green to yellow-orange regions. The peptides place the Cys 14 (or 6) residues before a native His site that binds bacteriochlorophyll a (BChl-a) and, like the native LH proteins, have high helical content as probed by single-reflection IR spectroscopy. The His residue associates with BChl-a as in the native LH1 β-polypeptide to form dimeric ββ-subunit complexes [31mer(-14Cys)X/BChl](2), where X is one of the synthetic chromophores. The native-like BChl-a dimer has Q(y) absorption at 820 nm and serves as the acceptor for energy from light absorbed by the appended synthetic chromophore. The energy-transfer characteristics of biohybrid complexes have been characterized by steady-state and time-resolved fluorescence and absorption measurements. The quantum yields of energy transfer from a synthetic chromophore located 14 residues from the BChl-coordinating His site are as follows: OGR (0.30) < RR (0.60) < BC2 (0.90). Oligomeric assemblies of the subunit complexes [31mer(-14Cys)X/BChl](n) are accompanied by a bathochromic shift of the Q(y) absorption of the BChl-a oligomer as far as the 850-nm position found in cyclic native photosynthetic LH2 complexes. Room-temperature stabilized oligomeric biohybrids have energy-transfer quantum yields comparable to those of the dimeric subunit complexes as follows: OGR (0.20) < RR (0.80) < BC1 (0.90). Thus, the new biohybrid antennas retain the energy-transfer and self-assembly characteristics of the native antenna complexes, offer enhanced coverage of the solar spectrum, and illustrate a versatile paradigm for the construction of artificial LH systems.
Small molecule dimer disruptors that inhibit an essential dimeric protease of human Kaposi’s sarcoma-associated herpesvirus (KSHV) were identified by screening an α-helical mimetic library. Subsequently, a second generation of low micromolar inhibitors with improved potency and solubility was synthesized. Complementary methods including size exclusion chromatography and 1H-13C HSQC titration using selectively labeled 13C-Met samples revealed that monomeric protease is enriched in the presence of inhibitor. 1H-15N-HSQC titration studies mapped the inhibitor binding-site to the dimer interface, and mutagenesis studies targeting this region were consistent with a mechanism where inhibitor binding prevents dimerization through the conformational selection of a dynamic intermediate. These results validate the interface of herpesvirus proteases and other similar oligomeric interactions as suitable targets for the development of small molecule inhibitors.
Summary Binding of the transcription factor Ets-1 to DNA is allosterically regulated by a serine rich region (SRR) that modulates the dynamic character of the adjacent structured DNA-binding ETS domain and its flanking autoinhibitory elements. Multi-site phosphorylation of the flexible SRR in response to Ca+2 signaling mediates variable regulation of Ets-1 DNA-binding affinity. In this study, we further investigated the mechanism of this regulation. First, thermal and urea denaturation experiments demonstrated that phosphorylation of the predominantly unstructured SRR imparts enhanced thermodynamic stability on the well-folded ETS domain and its inhibitory module. We next identified a minimal fragment (residues 279–440) that exhibits both enhanced autoinhibition of Ets-1 DNA-binding and allosteric reinforcement by phosphorylation. To test for intramolecular interactions between the SRR and the rest of the fragment that were not detectable by 1H-1H NOE measurements, paramagnetic relaxation enhancements were performed using a Cu2+ bound to the N-terminal ATCUN motif. Increased relaxation detected for specific amides and methyls revealed a preferential interaction surface for the flexible SRR extending from the inhibitory module to the DNA binding interface. Phosphorylation enhanced the localization of the SRR to this surface. We therefore hypothesize that the positioning of the SRR at the DNA binding interface and its role in shifting Ets-1 to an inhibited conformation are linked. In particular, transient interactions dampen the conformational flexibility of the ETS domain and inhibitory module required for high affinity binding, as well as possibly occlude the DNA interaction site. Surprisingly, the phosphorylation-dependent effects were relatively insensitive to changes in ionic strength, suggesting that electrostatic forces are not the dominant mechanism for mediating these interactions. The results of this study highlight the role of flexibility and transient binding in the variable regulation of Ets-1 activity.
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