Identification of Oligomerization Motifs in the β3 Transmembrane Domain.

Blood ◽  
2007 ◽  
Vol 110 (11) ◽  
pp. 416-416
Author(s):  
Hua Zhu ◽  
Douglas G. Metcalf ◽  
Wei Li ◽  
Roman Gorelik ◽  
Cinque Soto ◽  
...  
Keyword(s):  
Transcriptional Activation ◽  
Transmembrane Domain ◽  
Chimeric Protein ◽  
Protein Domain ◽  
Platelet Surface ◽  
High Affinity ◽  
Fibrinogen Binding ◽  
Activated State ◽  
The Face ◽  
Tm Domain

Abstract The integrin heterodimer αIIbβ3 resides on the platelet surface in an equilibrium between inactive (low affinity) and active (high affinity) conformations. We have reported that the transmembrane (TM) domains of its αIIb and β3 subunits engage in specific heteromeric and homomeric interactions that define the αIIbβ3 activation state. Further, we have proposed a “push-pull” hypothesis to explain how αIIbβ3 activity is regulated. Thus, processes that disrupt the TM domain heterodimer stabilize the active αIIbβ3 conformation and “push” the low affinity/high affinity equilibrium toward the activated state. Conversely, interactions that either require separation of the TM domains or are more favorable when the TM domains are apart “pull” the equilibrium in the same direction. Moreover, as would be predicted by this hypothesis, we found that adding a soluble peptide corresponding to the β3 TM domain to suspensions of gel-filtered platelets induced signaling-independent, αIIbβ3-mediated platelet aggregation, confirming that disruption of the αIIb/β3 TM domain heterodimer activates αIIbβ3. To identify the motifs responsible for oligomerization of the β3 TM domain, we used the TOXCAT assay. In TOXCAT, a chimeric protein consisting of an N-terminal ToxR’ DNA binding domain, a C-terminal maltose-binding protein domain, and an interposed β3 TM domain was expressed in the inner membrane of E. coli. TM domain-mediated dimerization of the chimeric protein then drove the transcriptional activation of a reporter gene chloramphenicol acetyl transferase (CAT). We replaced each residue in the β3 TM domain with either Leu, Ala, Val or Ile and measured the effect on CAT synthesis. The results were then used to calculate a perturbation index that reflects the mean fold-change in observed CAT activity for each of the mutants. When analyzed in this way, TOXCAT revealed that β3 helices associate homomerically with a 4 residue periodicity and that the interactive side of the helix lies along residues 700, 704, 708, and 712. Next, based on the TOXCAT results, we introduced selected mutations into the β3 TM domain of full-length αIIbβ3 and measured their effect on FITC-fibrinogen binding to αIIbβ3 expressed in CHO cells. We found that the disruptive mutations M701L, I704L, L705L, L712A, and L713A, located on the interactive side of the β3 helix, induced constitutive fibrinogen binding to αIIbβ3, whereas mutation of the intervening residues did not. Lastly, the TOXCAT and fibrinogen binding results were applied to a model of the β3 TM helix, revealing that the residues involved in oligomerization of the β3 TM domain were present as a “sticky” stripe along one face of the helix. Our results indicate that the face of the β3 helix that mediates its homomeric interaction also mediates its interaction with the αIIb TM domain; that mutations at this interface disrupt both homomeric and heteromeric interactions, and that these mutations strongly induce fibrinogen binding to αIIbβ3. Thus, our findings indicate that disruption of the α/β TM domain interface alone is sufficient to activate αIIbβ3 and that homomeric β3 interactions by themselves are not required to induce fibrinogen binding to αIIbβ3.

Factors Influencing the Homomeric and Heteromeric Association of Platelet Integrin Transmembrane Domains.

Blood ◽  
2006 ◽  
Vol 108 (11) ◽  
pp. 212-212
Author(s):  
Bryan W. Berger ◽  
Roman Gorelik ◽  
William F. DeGrado ◽  
Joel S. Bennett
Keyword(s):  
Dna Binding ◽  
Transcriptional Activation ◽  
Chimeric Protein ◽  
Dominant Negative ◽  
Protein Domain ◽  
Dominant Negative Effect ◽  
Domain Interactions ◽  
The Face ◽  
Negative Effect ◽  
Tm Domain

Abstract Integrin are α/β heterodimers that mediate an array of cell-cell and cell-matrix interactions including platelet adhesion and aggregation. Integrins reside on cell surfaces in an equilibrium between inactive and active conformations that are regulated by transmembrane (TM) domain interactions: when integrins are inactive, the TM domains of their α and β subunits interact; the domains separate when integrins assume their active conformation. Platelets express five α subunits (α2, αIIb, αv, α5, and α6) and two β subunits (β1 and β3) that combine to form five adhesions receptors. Previously, we observed that the αIIb and β3 TM domains undergo both heteromeric and homomeric interactions and there is overlap of the interfaces that mediates these interactions. Less is known about the other platelet integrins. To study their interactions, we used the TOXCAT assay. In TOXCAT, a chimeric protein consisting of an N-terminal ToxR’ DNA binding domain, a C-terminal maltose-binding protein domain, and an interposed TM domain is expressed in the E. coli inner membrane. TM domain-mediated dimerization of the chimeric protein drives the transcriptional activation of a chloramphenicol acetyl transferase (CAT) reporter gene. To enable TOXCAT to measure heteromeric as well as homomeric interactions, we introduced an R68K mutation into the ToxR’ DNA-binding region, thereby preventing CAT synthesis without affecting protein expression. Thus, when both wild-type and disabled ToxR’ are concurrently expressed from the same plasmid, disabled ToxR’ exerts a dominant-negative effect on CAT synthesis. Using this assay, we found that the interaction of platelet integrin TM domains correlated with the presence of a small residue (sr)-xxx-small residue motif (sr-x3-sr) where x = any residue: α2, αIIb and β1, each of which contains a Gx3G motif, had the strongest tendency to undergo specific homomeric association, whereas α2+β1 and αIIb+β3 had the strongest tendency to form heterodimers. In the TM domains of αv, α5 and β3, one or more of the glycines in sr-x3-sr is replaced by Ser or Ala; as a result, homomeric interactions involving these subunits are substantially weaker. Moreover, mutating each of the small residues in sr-x3-sr to Leu precluded the formation of TM domain oligomers, emphasizing the importance of the sr-x3-sr motif. The dominant-negative TOXCAT assay was also used to screen for inactivating αIIbβ3 and αvβ3 mutations. By introducing random mutations into the β3 TM domain and selecting mutants based on a reduction in CAT synthesis, we identified mutations that enhanced heteromeric αIIbβ3 and αvβ3 association. It is noteworthy that mutations that enhanced the interaction of β3 with αIib were present along the face of the β3 TM helix containing the sr-x3-sr motif. By contrast, mutations enhancing αvβ3 association were distributed throughout the β3 TM helix and didn’t cluster around the sr-x3-sr motif. In summary, we have demonstrated that the TM domains of platelet integrin subunits, in addition to αIIb and β3, undergo specific heteromeric and homomeric interactions, suggesting that TM domain interactions may regulate the function of the integrins containing these subunits. Further, our results indicate that sr-x3-sr motifs play an essential role in the oligomerization of these subunits, suggesting that these motifs play a central role in regulating integrin function.

Heteromeric and Homomeric Transmembrane Domain Associations Regulate αIIbβ3 Function.

Blood ◽  
2004 ◽  
Vol 104 (11) ◽  
pp. 329-329
Author(s):  
Wei Li ◽  
Douglas Metcalf ◽  
Roman Gorelik ◽  
Renhao Li ◽  
Neal Mitra ◽  
...  
Keyword(s):  
Cho Cells ◽  
Transmembrane Domain ◽  
Fold Increase ◽  
Cho Cell ◽  
Platelet Surface ◽  
Activated State ◽  
Domain Interactions ◽  
Tm Domain ◽  
Activation Peptides ◽  
Heteromeric Association

Abstract The integrin αIIbβ3 resides on the platelet surface in an equilibrium between inactive and active conformations that can be shifted in either direction by altering the distance between the stalks that anchor αIIbβ3 in the platelet membrane. Accordingly, the αIIb and β3 transmembrane (TM) domains, located near the ends of the stalks, are in proximity when αIIbβ3 is inactive and separate upon αIIbβ3 activation. Peptides corresponding to these domains undergo both homomeric and heteromeric interactions in biological membranes. Thus, it is possible that the shift between inactive and active αIIbβ3 conformations is accompanied by a shift from heteromeric to homomeric αIIb and β3 TM domain interactions. Indeed, we reported that introducing Asn, a residue known to strengthen homomeric TM helix interactions, into the β3 TM domain shifts αIIbβ3 to an active state. As a further test of this model of αIIbβ3 regulation, we studied the effects of mutations of the αIIb TM domain. First, we placed Asn at 10 consecutive positions in the αIIb TM domain, extending from residues V969 to L978, and co-expressed each mutant with WT β3 in CHO cells. Only one of the mutants, G972N, was constitutively active, binding ~ 8-fold more fibrinogen than WT αIIbβ3. Moreover, G972N was expressed in non-uniform patches on the CHO cell surface, consistent with the formation of αIIbβ3 clusters. G972 is the first residue of a GxxxG motif that is essential for dimerization of the αIIb TM domain. Using the TOXCAT assay to assess TM domain dimerization, we observed that G972N results in a 55% decrease in TOXCAT activity. This implies that the effect of G972N on the αIIbβ3 activation state was not a result of increased homo-dimerization of αIIb, but it is more likely that the mutation disrupted its heteromeric interaction with β3. To test this suggestion, we introduced mutations known to disrupt αIIb homo-dimerization (G972L, G976A, and G976L) into αIIbβ3 and measured their effect on αIIbβ3 function. Like G972N, each mutation induced constitutive αIIbβ3 activation and clustering. Lastly, we measured the effect of L980A, a mutation in the αIIb TM domain that unlike G972N, results in a 2.5-fold increase in TOXCAT activity. CHO cells expressing L980A constitutively bound ~ 6.5-fold more fibrinogen than did cells expressing WT αIIbβ3. Taken together, our results suggest a mechanism for αIIbβ3 regulation that involves both the heteromeric and homomeric association of the αIIb and β3 TM domains. Any process that destabilizes the heteromeric association of the αIIb and β3 TM domains would be expected to allow dissociation of these domains with concomitant αIIbβ3 activation. Hence, mutations that disrupt the heteromeric αIIb/β3 TM domain interface “push” αIIbβ3 toward activation. Conversely, intermolecular interactions that either require separation of the αIIb and β3 TM domains or are more favorable when they dissociate, such as homo-oligomerization of the αIIb and β3 TM domains, will “pull” the equilibrium toward the activated state.

The Cleaved Peptide of PAR1 Results in a Redistribution of the Platelet Surface GPIb-IX-V Complex to the Surface-Connected Canalicular System

2000 ◽  
Vol 84 (11) ◽  
pp. 897-903 ◽  
Author(s):  
Mark Furman ◽  
Paquita Nurden ◽  
Michael Berndt ◽  
Alan Nurden ◽  
Stephen Benoit ◽  
...  
Keyword(s):  
Binding Site ◽  
Von Willebrand Factor ◽  
Binding Sites ◽  
Transmembrane Domain ◽  
Surface Expression ◽  
Thrombin Receptor ◽  
Platelet Surface ◽  
Fibrinogen Binding ◽  
Von Willebrand ◽  
Willebrand Factor

SummaryThe only known function of the 41 amino acid cleaved peptide (TR1-41) of the seven transmembrane domain thrombin receptor (PAR1) is to activate platelets (as determined by aggregation, surface P-selectin, and fibrinogen binding to activated GPIIb-IIIa). We now demonstrate that TR1-41 results in a concentration-dependent decrease in the platelet surface expression of each component of the GPIb-IX-V complex, as determined by flow cytometry with a panel of monoclonal antibodies (including 6D1, directed against the von Willebrand factor binding site on GPIbα, and TM60, directed against the thrombin binding site on GPIbα). TR1-41 also decreased ristocetin-induced platelet agglutination. Immunoblotting after incubation of platelets with TR1-41 revealed neither a loss of platelet GPIb nor increase in supernatant GPIb fragments. As demonstrated by immunoelectron microscopy, TR1-41 resulted in a redistribution of GPIb, GPIX, and GPV from the platelet surface to the surface-connected canalicular system (SCCS). In summary, the cleaved peptide (TR1-41) of PAR1 results in a redistribution of the platelet surface GPIb-IX-V complex to the SCCS, thereby negatively regulating the GPIbα binding sites for von Willebrand factor and thrombin.

Identification of Stalk Mutations That Stabilize the High Affinity Conformation of αIIbβ3 by Negative Design.

Blood ◽  
2009 ◽  
Vol 114 (22) ◽  
pp. 4017-4017
Author(s):  
Jason E. Donald ◽  
Hua Zhu ◽  
William F. DeGrado ◽  
Joel S. Bennett
Keyword(s):  
Crystal Structure ◽  
Protein Interactions ◽  
Energy Function ◽  
Transmembrane Domain ◽  
Conflicts Of Interest ◽  
Point Mutations ◽  
Full Length ◽  
Design Algorithm ◽  
Platelet Surface ◽  
High Affinity

Abstract Abstract 4017 Poster Board III-953 The integrin αIIbβ3 plays an essential role in platelet aggregation. Following platelet stimulation by agonists, αIIbβ3 on the platelet surface shifts from an inactive low affinity conformation unable to bind ligands to an active high affinity conformation that can bind fibrinogen and von Willebrand factor. These αIIbβ3-bound macromolecules then crosslink platelets into aggregates. αIIbβ3 is thought to be present on the platelet surface in a bent conformation that is maintained by interactions involving residues located in its cytoplasmic, transmembrane, and stalk domains. Crystal structures of αIIbβ3 and related integrin extracellular domains indicate that large conformational movements occur during activation and specific point mutations in the transmembrane domain and cytoplasmic domains lead to ligand binding, likely by disrupting the inactive state heterodimer interface. One region of αIIbβ3 that has not been studied in detail is the large intramolecular interface located in the stalk region. To test the hypothesis that the interface between the αIIb and β3 stalks observed in the crystal structure of the αIIbβ3 extracellular domain is an important part of the αIIbβ3 activation equilibrium, we employed a negative design strategy in which the Rosetta energy function was used to predict alanine mutations in β3 that would most destabilize the stalk interface. Negative design is a way to control the direction of protein interactions by introducing changes in protein structure that destabilize undesired interactions. In this case, the undesired interaction is the inactive heterodimer stalk interface. The Rosetta energy function used here has been shown to accurately predict the effect of alanine mutations at protein interfaces. Initially, mutations were predicted based on the available crystal structure of the αvβ3 heterodimer. Subsequently, a crystal structure for inactive αIIbβ3 was reported. The functional consequences of the predicted mutations were then tested by introducing the mutations into full-length β3 expressed in CHO cells. Two mutations, V664A and Y594A, were selected by the design algorithm as particularly disruptive in the interface and caused substantial constitutive αIIbβ3 activation when introduced into full-length β3. By contrast, the mutation, D552A, predicted to be slightly destabilizing in αVβ3, but not destabilizing in αIIbβ3, had essentially no effect on αIIbβ3 activity. These results confirm the utility of the negative design approach to identifying functionally significant regions in integrins. Further, they demonstrate that the stalk interface, much like the transmembrane domain interface, plays an important role in the equilibrium between active and inactive states of αIIbβ3. The large intermolecular stalk interface appears to be important for inside-out integrin signaling and deserves further study for its role in the transmission of signals from the intracelluar to the extracellular regions of integrins. Disclosures: No relevant conflicts of interest to declare.

The Effect of the Phospholipase Inhibitor Mepacrine on Platelet Aggregation, the Platelet Release Reaction and Fibrinogen Binding to the Platelet Surface

1981 ◽  
Vol 45 (03) ◽  
pp. 257-262 ◽  
Author(s):  
P D Winocour ◽  
R L Kinlough-Rathbone ◽  
J F Mustard
Keyword(s):  
Arachidonic Acid ◽  
Platelet Aggregation ◽  
Platelet Surface ◽  
Release Reaction ◽  
Fibrinogen Binding ◽  
Platelet Release

SummaryWe have examined whether inhibition by mepacrine of freeing of arachidonic acid from platelet phospholipids inhibits platelet aggregation to collagen, thrombin or ADP, and the release reaction induced by thrombin or collagen. Loss of arachidonic acid was monitored by measuring the amount of 14 C freed from platelets prelabelled with 14 C-arachidonic acid. Mepacrine inhibited 14 C loss by more than 80% but did not inhibit thrombin-induced platelet aggregation and had a small effect on release. ADP-induced platelet aggregation did not cause 14 C loss. Mepacrine inhibited ADP-induced platelet aggregation by inhibiting the association of fibrinogen with platelets during aggregation. The effect of mepacrine on fibrinogen binding could be considerably decreased by washing the platelets but the inhibition of 14 C loss persisted. Platelets pretreated with mepacrine and then washed show restoration of aggregation to collagen. Thus, mepacrine has two effects; 1. it inhibits phospholipases, 2. it inhibits fibrinogen binding. Freeing of arachidonic acid is not necessary for platelet aggregation or the release reaction.

THROMBOSPONDIN SPECIFICALLY INTERACTS WITH AMINO ACID SEQUENCES WITHIN THE A α- AND B β- CHAINS OF FIBRINOGEN

1987 ◽  
Author(s):  
Theresa Bacon-Baguley ◽  
Suzanne Kendra-Franczak ◽  
Daniel Walz
Keyword(s):  
Platelet Aggregation ◽  
Cyanogen Bromide ◽  
Gel Filtration ◽  
Amino Acid Sequences ◽  
Reverse Phase ◽  
Platelet Surface ◽  
Chain Component ◽  
Fibrinogen Binding ◽  
Platelet Aggregate ◽  
Single Peptide

Thrombospondin (TSP) is responsible for the secretion-dependent phase of platelet aggregation. The mechanism of this action is believed to be through the binding of TSP to fibrinogen, resulting in the stabilization of the platelet aggregate. It has been established that the binding of fibrinogen to the platelet surface is dependent upon peptide sequences present, respectively, in the Aa- and y-chains. We have hypothesized that the binding of TSP to fibrinogen is also dependent upon unique fibrinogen peptide sequences. To test this hypothesis we have examined the interaction of TSP and f.ih.r.inogen. using..a.-blat-b.inding assaLy of reduced fibrinogen, the separated fibrinogen chains, selected fibrinogen domains or peptides generated from cyanogen bromide cleaved chains. Iodinated TSP bound specifically to the Aα - and Bβ - chains. Binding to these chains was calcium independent, mutually exclusive and could be blocked either by preincubation of TSP with 9.4 μ M fibrinogen or by preincubation of fibrinogen with 1.1 nM thrombospondin. TSP bound to the D and DD plasmin fragment of fibrinogen; TSP interacted exclusively with the B-chain component of the DD fragment. The cyanogen bromide fragments of the separated Aα - and Bβ -chains were resolved through a combination of gel filtration and reverse-phase chromatography. TSP was found to bind to a single peptide within these fibrinogen chains. These studies demonstrate that thrombospondin interacts with at least two distinct sites on fibrinogen, and these sites differ from those already described for fibrinogen binding to platelets.

scholarly journals Attenuation of inhibitory PAS domain protein-induced cell death by synthetic peptides derived from Mcl-1 transmenbrane domain

2021 ◽  
Vol 7 (1) ◽  
Author(s):  
Shuya Kasai ◽  
Ken-ichi Yasumoto ◽  
Kazuhiro Sogawa
Keyword(s):  
Cell Death ◽  
Synthetic Peptides ◽  
Specific Binding ◽  
Neuronal Cell ◽  
Chimeric Protein ◽  
Substantia Nigra Pars Compacta ◽  
Pas Domain ◽  
Domain Protein ◽  
Tm Domain ◽  
Apoptotic Activity

AbstractExpression of Inhibitory PAS domain protein (IPAS) induces apoptosis by inhibiting the anti-apoptotic activity of mitochondrial pro-survival proteins including Bcl-xL and Mcl-1 through direct binding. Analysis to examine the IPAS-binding region in Bcl-xL demonstrated that the C-terminal transmembrane (TM) domain is indispensable for the specific binding. A chimeric protein composed of the TM domain of Mcl-1 fused to the C-terminus of Citrine also exhibited a binding affinity to IPAS, and markedly attenuated apoptosis caused by the overexpression of Cerulean-IPAS in SH-SY5Y cells. HIV-1 TAT cell-penetrating peptide-conjugated synthetic peptides that cover whole or parts of the Mcl-1 TM domain showed anti-apoptotic activity in the CoCl2-induced cell death in PC12 cells. Administration of these highly effective anti-apoptotic peptides to mice treated with 1-methyl-4-phenyl-1,2,3,6-tetrahydropyridine (MPTP) that produces a reliable mouse model of Parkinson’s disease (PD) decreased neuronal cell loss in the substantia nigra pars compacta. Therefore, the peptides may be considered promising therapeutic agents for neurodegenerative disorders such as PD and stroke.

Extracellular fibrinogen binding protein, Efb, from Staphylococcus aureus binds to platelets and inhibits platelet aggregation

2004 ◽  
Vol 91 (04) ◽  
pp. 779-789 ◽  
Author(s):  
Oonagh Shannon ◽  
Jan-Ingmar Flock
Keyword(s):  
Platelet Aggregation ◽  
Potent Inhibitor ◽  
Specific Binding ◽  
Binding Protein ◽  
Dependent Manner ◽  
Platelet Surface ◽  
Putative Receptor ◽  
Activated Platelets ◽  
Fibrinogen Binding ◽  
Dose Dependent

Summary S. aureus produces and secretes a protein, extracellular fibrinogen binding protein (Efb), which contributes to virulence in wound infection. We have shown here that Efb is a potent inhibitor of platelet aggregation. Efb can bind specifically to platelets by two mechanisms; 1) to fibrinogen naturally bound to the surface of activated platelets and 2) also directly to a surface localized component on the platelets. This latter binding of Efb is independent of fibrinogen. The specific binding of Efb to the putative receptor on the platelet surface results in a stimulated, non-functional binding of fibrinogen in a dose dependent manner, distinct from natural binding of fibrinogen to platelets. The natural binding of fibrinogen to GPIIb/IIIa on activated platelets could be blocked by a monoclonal antibody against this integrin, whereas the Efb-mediated fibrinogen binding could not be blocked. The enhanced Efb-dependent fibrinogen binding to platelets is of a nature that does not promote aggregation of the platelets; instead it inhibits aggregation. The anti-thrombotic action of Efb may explain the effect of Efb on wound healing, which is delayed in the presence of Efb.

scholarly journals Conformational clamping by a membrane ligand activates the EphA2 receptor

2021 ◽  
Author(s):  
Justin M Westerfield ◽  
Amita Sahoo ◽  
Daiane S Alves ◽  
Brayan Grau ◽  
Alayna Cameron ◽  
...  
Keyword(s):  
Drug Target ◽  
Transmembrane Domain ◽  
Binding Mode ◽  
Membrane Receptors ◽  
Binding Motif ◽  
Active Conformation ◽  
Dynamic Simulations ◽  
Membrane Peptide ◽  
Migration Assays ◽  
Tm Domain

The EphA2 receptor is a promising drug target for cancer treatment, since EphA2 activation can inhibit metastasis and tumor progression. It has been recently described that the TYPE7 peptide activates EphA2 using a novel mechanism that involves binding to the single transmembrane domain of the receptor. TYPE7 is a conditional transmembrane (TM) ligand, which only inserts into membranes at neutral pH in the presence of the TM region of EphA2. However, how membrane interactions can activate EphA2 is not known. We systematically altered the sequence of TYPE7 to identify the binding motif used to activate EphA2. With the resulting six peptides, we performed biophysical and cell migration assays that identified a new potent peptide variant. We also performed a mutational screen that determined the helical interface that mediates dimerization of the TM domain of EphA2 in cells. These results, together with molecular dynamic simulations, allowed to elucidate the molecular mechanism that TYPE7 uses to activate EphA2, where the membrane peptide acts as a molecular clamp that wraps around the TM dimer of the receptor. We propose that this binding mode stabilizes the active conformation of EphA2. Our data, additionally, provide clues into the properties that TM ligands need to have in order to achieve activation of membrane receptors.

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