Tobias S. Ulmer

Structural determinants of integrin recognition by talin.

The binding of cytoplasmic proteins, such as talin, to the cytoplasmic domains of integrin adhesion receptors mediates bidirectional signal transduction. Here we report the crystal structure of the principal integrin binding and activating fragment of talin, alone and in complex with fragments of the beta 3 integrin tail. The FERM (four point one, ezrin, radixin, and moesin) domain of talin engages integrins via a novel variant of the canonical phosphotyrosine binding (PTB) domain-NPxY ligand interaction that may be a prototype for FERM domain recognition of transmembrane receptors. In combination with NMR and mutational analysis, our studies reveal the critical interacting elements of both talin and the integrin beta 3 tail, providing structural paradigms for integrin linkage to the cell interior.

The structure of the integrin αIIbβ3 transmembrane complex explains integrin transmembrane signalling

Heterodimeric integrin adhesion receptors regulate cell migration, survival and differentiation in metazoa by communicating signals bi‐directionally across the plasma membrane. Protein engineering and mutagenesis studies have suggested that the dissociation of a complex formed by the single‐pass transmembrane (TM) segments of the α and β subunits is central to these signalling events. Here, we report the structure of the integrin αIIbβ3 TM complex, structure‐based site‐directed mutagenesis and lipid embedding estimates to reveal the structural event that underlies the transition from associated to dissociated states, that is, TM signalling. The complex is stabilized by glycine‐packing mediated TM helix crossing within the extracellular membrane leaflet, and by unique hydrophobic and electrostatic bridges in the intracellular leaflet that mediate an unusual, asymmetric association of the 24‐ and 29‐residue αIIb and β3 TM helices. The structurally unique, highly conserved integrin αIIbβ3 TM complex rationalizes bi‐directional signalling and represents the first structure of a heterodimeric TM receptor complex.

Comparison of Structure and Dynamics of Micelle-bound Human α-Synuclein and Parkinson Disease Variants

Three point mutations (A30P, E46K, and A53T) as well as gene triplication genetically link the 140-residue protein α-synuclein (aS) to the development of Parkinson disease. Here, the structure and dynamics of micelle-bound aS(A30P) and aS(A53T) are described and compared with wild-type aS, in addition to describing the aS-micelle interaction. A53T is sensed only by directly adjacent residues and leaves the backbone structure and dynamics indistinguishable from the wild type. A30P interrupts one helix turn (Val26–Ala29) and destabilizes the preceding one. A shift in helix register following A30P disturbs the canonical succession of polar and hydrophobic residues for at least two turns. The shortened helix-N adopts a slightly higher helical content and is less bent, indicating that strain was present in the micelle-bound helix. In the vicinity of the A30P-induced perturbations, the underlying micelle environment has rearranged, but nevertheless all aS variants maintain similar interrelationships with the micelle. Moreover, aS-micelle immersion correlates well with fast and slow aS backbone dynamics, allowing a rare insight into protein-micelle interplay.

Structure of the integrin beta3 transmembrane segment in phospholipid bicelles and detergent micelles.

Integrin adhesion receptors transduce bidirectional signals across the plasma membrane, with the integrin transmembrane domains acting as conduits in this process. Here, we report the first high-resolution structure of an integrin transmembrane domain. To assess the influence of the membrane model system, structure determinations of the beta3 integrin transmembrane segment and flanking sequences were carried out in both phospholipid bicelles and detergent micelles. In bicelles, a 30-residue linear alpha-helix, encompassing residues I693-H772, is adopted, of which I693-I721 appear embedded in the hydrophobic bicelle core. This relatively long transmembrane helix implies a pronounced helix tilt within a typical lipid bilayer, which facilitates the snorkeling of K716s charged side chain out of the lipid core while simultaneously immersing hydrophobic L717-I721 in the membrane. A shortening of bicelle lipid hydrocarbon tails does not lead to the transfer of L717-I721 into the aqueous phase, suggesting that the reported embedding represents the preferred beta3 state. The nature of the lipid headgroup affected only the intracellular part of the transmembrane helix, indicating that an asymmetric lipid distribution is not required for studying the beta3 transmembrane segment. In the micelle, residues L717-I721 are also embedded but deviate from linear alpha-helical conformation in contrast to I693-K716, which closely resemble the bicelle structure.

Recognition of enhancer element–specific histone methylation by TIP60 in transcriptional activation

Many co-regulator proteins are recruited by DNA-bound transcription factors to remodel chromatin and activate transcription. However, mechanisms for coordinating actions of multiple co-regulator proteins are poorly understood. We demonstrate that multiple protein-protein interactions by the protein acetyltransferase TIP60 are required for estrogen-induced transcription of a subset of estrogen receptor alpha (ERα) target genes in human cells. Estrogen-induced recruitment of TIP60 requires direct binding of TIP60 to ERα and the action of chromatin-remodeling ATPase BRG1, leading to increased recruitment of histone methyltransferase MLL1 and increased monomethylation of histone H3 at Lys4. TIP60 recruitment also requires preferential binding of the TIP60 chromodomain to histone H3 containing monomethylated Lys4, which marks active and poised enhancer elements. After recruitment, TIP60 increases acetylation of histone H2A at Lys5. Thus, complex cooperation of TIP60 with ERα and other chromatin-remodeling enzymes is required for estrogen-induced transcription.

Basic amino-acid side chains regulate transmembrane integrin signalling

Side chains of Lys/Arg near transmembrane domain (TMD) membrane–water interfaces can ‘snorkel’, placing their positive charge near negatively charged phospholipid head groups; however, snorkelling’s functional effects are obscure. Integrin β TMDs have such conserved basic amino acids. Here we use NMR spectroscopy to show that integrin β3(Lys 716) helps determine β3 TMD topography. The αΙΙbβ3 TMD structure indicates that precise β3 TMD crossing angles enable the assembly of outer and inner membrane ‘clasps’ that hold the αβ TMD together to limit transmembrane signalling. Mutation of β3(Lys 716) caused dissociation of αΙΙbβ3 TMDs and integrin activation. To confirm that altered topography of β3(Lys 716) mutants activated αΙΙbβ3, we used directed evolution of β3(K716A) to identify substitutions restoring default state. Introduction of Pro(711) at the midpoint of β3 TMD (A711P) increased αΙΙbβ3 TMD association and inactivated integrin αΙΙbβ3(A711P,K716A). β3(Pro 711) introduced a TMD kink of 30 ± 1° precisely at the border of the outer and inner membrane clasps, thereby decoupling the tilt between these segments. Thus, widely occurring snorkelling residues in TMDs can help maintain TMD topography and membrane-embedding, thereby regulating transmembrane signalling.

A combinatorial NMR and EPR approach for evaluating the structural ensemble of partially folded proteins.

Partially folded proteins, characterized as exhibiting secondary structure elements with loose or absent tertiary contacts, represent important intermediates in both physiological protein folding and pathological protein misfolding. To aid in the characterization of the structural state(s) of such proteins, a novel structure calculation scheme is presented that combines structural restraints derived from pulsed EPR and NMR spectroscopy. The methodology is established for the protein alpha-synuclein (alphaS), which exhibits characteristics of a partially folded protein when bound to a micelle of the detergent sodium lauroyl sarcosinate (SLAS). By combining 18 EPR-derived interelectron spin label distance distributions with NMR-based secondary structure definitions and bond vector restraints, interelectron distances were correlated and a set of theoretical ensemble basis populations was calculated. A minimal set of basis structures, representing the partially folded state of SLAS-bound alphaS, was subsequently derived by back-calculating correlated distance distributions. A surprising variety of well-defined protein-micelle interactions was thus revealed in which the micelle is engulfed by two differently arranged antiparallel alphaS helices. The methodology further provided the population ratios between dominant ensemble structural states, whereas limitation in obtainable structural resolution arose from spin label flexibility and residual uncertainties in secondary structure definitions. To advance the understanding of protein-micelle interactions, the present study concludes by showing that, in marked contrast to secondary structure stability, helix dynamics of SLAS-bound alphaS correlate with the degree of protein-induced departures from free micelle dimensions.

Structure of the Integrin αIIb Transmembrane Segment

Integrin cell-adhesion receptors transduce signals bidirectionally across the plasma membrane via the single-pass transmembrane segments of each α and β subunit. While the β3 transmembrane segment consists of a linear 29-residue α-helix, the structure of the αIIb transmembrane segment reveals a linear 24-residue α-helix (Ile-966 -Lys-989) followed by a backbone reversal that packs Phe-992-Phe-993 against the transmembrane helix. The length of the αIIb transmembrane helix implies the absence of a significant transmembrane helix tilt in contrast to its partnering β3 subunit. Sequence alignment shows Gly-991-Phe-993 to be fully conserved among all 18 human integrin α subunits, suggesting that their unusual structural motif is prototypical for integrin α subunits. The αIIb transmembrane structure demonstrates a level of complexity within the membrane that is beyond simple transmembrane helices and forms the structural basis for assessing the extent of structural and topological rearrangements upon αIIb-β3 association, i.e. integrin transmembrane signaling.

α-Synuclein Populates Both Elongated and Broken Helix States on Small Unilamellar Vesicles

The misfolding of the protein α-synuclein (αS) has been implicated in the molecular chain of events leading to Parkinson disease. Physiologically, αS undergoes a transition from a random coil to helical conformation upon encountering synaptic vesicle membranes. On analogous small unilamellar vesicles (SUVs), the conformation of αS is dominated by a single elongated αS helix. However, alternative broken helix states have been postulated, mandating experimental clarification. Here, the upper limit for the free energy difference between elongated and broken helix conformations on SUVs resembling synaptic vesicles was determined to be 1.2 ± 0.4 kcal/mol, which amounts to a population ratio of 7.6:1 between both states (12% broken helices). In response to helix breaks at different positions, αS rearranged in an opportunistic manner, thereby minimizing helix abrogations to as little as one to two turns. Enthalpy and entropy measurements of gel state SUV-αS interactions indicated that broken helix states retain the ability to relieve membrane-packing stress. Thus, broken helix states are a distinct physiological feature of the vesicle-bound αS state, making it a “checkered” protein of multiple parallel conformations. A continuous interconversion between structural states may contribute to pathological αS misfolding.

Characterization of α-Synuclein Interactions with Selected Aggregation-Inhibiting Small Molecules†

The 140-residue protein alpha-synuclein (aS) has been implicated in the molecular chain of events leading to Parkinsons disease, which relates to the hierarchical aggregation of aS into soluble oligomers and insoluble fibrils. A number of small organic molecules have been reported to inhibit aS aggregation. Here, the interactions of chlorazole black E, Congo red, lacmoid, PcTS-Cu (2+), and rosmarinic acid with aS are examined by NMR spectroscopy to identify aS sequence elements that are masked by these compounds. Surprisingly, similar aS interaction sites, encompassing residues 3-18 and 38-51, were obtained for all molecules at equimolar small molecule:aS ratios. At higher ratios, virtually the entire amphiphilic region of aS (residues 2-92) is affected, revealing the presence of additional, lower affinity interaction sites. Upon rearranging the high-affinity interaction sites over the aS amphiphilic region in an aS mutant form, perturbations of the entire amphiphilic region were found to have already been obtained at equimolar ratios, indicating a high specificity for the original binding sites. CD spectroscopy reveals that, in the presence of the small molecules, the aS structure is still dominated by random-coil characteristics. The strongest effects are exerted by molecules that contain sulfonate groups adjacent to aromatic systems, often present in multiple copies in a symmetrical arrangement, suggesting that these elements are useful for developing an aS-specific chemical chaperone.