scholarly journals Kindlin Assists Talin to Promote Integrin Activation

2019 ◽  
Author(s):  
Z. Haydari ◽  
H. Shams ◽  
Z. Jahed ◽  
M.R.K. Mofrad
Keyword(s):  
Molecular Mechanisms ◽  
Water Environment ◽  
Proximal Region ◽  
Salt Bridges ◽  
Integrin Activation ◽  
Integrin Αiibβ3 ◽  
Cytoplasmic Proteins ◽  
Predominant Type ◽  
Dynamics Simulations ◽  
Membrane Proximal Region

AbstractIntegrin αIIbβ3 is a predominant type of integrin abundantly expressed on the surface of platelets and its activation regulates the process of thrombosis. Talin and kindlin are cytoplasmic proteins that bind to integrin and modulate its affinity for extracellular ligands. While the molecular details of talin-mediated integrin activation are known, the mechanism of kindlin involvement in this process remains elusive. Here, we demonstrate that the interplay between talin and kindlin promotes integrin activation. Our all-atomic molecular dynamics simulations on complete transmembrane and cytoplasmic domains of integrin αIIbβ3, talin1 F2/F3 subdomains, and kindlin2 FERM domain in an explicit lipid-water environment over microsecond timescale, unraveled the role of kindlin as an enhancer of the talin interaction with the membrane proximal region of β–integrin. The cooperation of kindlin with talin results in a complete disruption of salt bridges between R995 on αIIb and D723/E726 on β3. Furthermore, kindlin modifies the molecular mechanisms of inside-out activation by decreasing the crossing angle between transmembrane helices of integrin αIIb-β3, which eventually results in parallelization of integrin dimer. In addition, our control simulation featuring integrin in complex with kindlin reveals that kindlin binding is not sufficient for unclasping the inner membrane and outer membrane interactions of integrin dimer, thus ruling out the possibility of solitary action of kindlin in integrin activation.Statement of SignificanceUsing the newly solved crystal structure of kindlin, we investigated, for the first time, the molecular mechanism of kindlin-mediated integrin activation through simultaneous binding of talin and kindlin. We demonstrate in atomist details how kindlin cooperates with talin to promote the activation of integrin αIIb-β3.

Integrin β3 Membrane-Proximal and -Distal Residues Cooperatively Regulate Talin-Mediated αIIbβ3 Activation.

Blood ◽  
2008 ◽  
Vol 112 (11) ◽  
pp. 1848-1848
Author(s):  
Jun Yamanouchi ◽  
Takaaki Hato ◽  
Hiroshi Fujiwara ◽  
Yoshihiro Yakushijin ◽  
Masaki Yasukawa
Keyword(s):  
Ligand Binding ◽  
Double Mutant ◽  
Distal Region ◽  
Proximal Region ◽  
Structural Rearrangements ◽  
Wild Type ◽  
Integrin Activation ◽  
Integrin Αiibβ3 ◽  
Membrane Proximal Region ◽  
Constitutively Active

Abstract Integrin αIIbβ3 exists in a low affinity state in resting platelets and requires activation for high affinity binding with soluble ligands. Activation of αIIbβ3 is tightly linked to structural rearrangements of the αIIbβ3 molecule that is initiated from the cytoplasmic tails of the αIIb and β3 subunits. The β3 membrane-distal region has been shown to interact with many signaling and cytoskeletal molecules, and considered as a trigger point of integrin activation. The interaction of the β3 tail with a cytoplasmic protein, talin, largely contributes to integrin activation. In view of the link between integrin activation and allosteric structural rearrangements of integrins, one would expect that structural changes in the β3 membrane-distal region containing binding sites for intracellular proteins would be relayed to the membrane-proximal region, leading to αIIbβ3 activation. However, there has been no evidence that structural rearrangement of the β3 membrane-distal region is directly linked to integrin activation. No activating mutation has so far been reported in the β3 membrane-distal region despite numerous reports of loss-of-function mutants in this region. In this context, a previously reported αIIbβ3 mutant in which the β3 tail was replaced by the β1 tail was noteworthy. This chimeric integrin, αIIbβ3/β1, was constitutively active. Because the β1 and β3 subunits have relatively high sequence homology in their membrane-proximal regions, we reasoned that the residues differing between the β1 and β3 membrane-distal regions may be responsible for αIIbβ3 activation. To identify such residues, we produced 13 αIIbβ3 mutants in which the individual or group residues in the β3 tail were substituted with the corresponding β1 tail residues. The αIIbβ3 mutants were expressed on the surface of CHO cells by cotransfection of mutant β3 and wild-type αIIb cDNAs, and were tested for binding of fibrinogen and PAC1, a ligand-mimetic anti-αIIbβ3 antibody. Among them, only β3I719M and E749S mutants bound significant PAC1 and fibrinogen binding without any stimulation and the RGDS peptide abolished binding of these ligands, indicating a constitutively active state. The similar effect was observed with I719A and E749A mutants. Moreover, the I719M/E749S double mutant showed more PAC1 binding than the single mutants, reaching the same ligand binding activity as αIIbβ3/β1. These β3 mutations also induced αVβ3 activation. Conversely, substitution of M719 or S749 in the β1 tail with the corresponding β3 tail residue (M719I or S749E) inhibited αIIbβ3/β1 activation, and the M719I/S749E double mutant inhibited ligand binding to a level comparable with that of the wild-type αIIbβ3. Knock down of talin by short hairpin RNA inhibited the I719M- and E749S-induced αIIbβ3 activation, indicating talin-mediated activation of mutant integrins. Since I719 is located at the β3 membrane-proximal region, it is likely that the I719 mutation disrupts the well-known membrane-proximal clasp to maintain integrins at a low affinity state. On the other hand, E749 is located at the β3 membrane-distal region. This result provides experimental evidence that structural perturbation of the β3 membrane-distal region is linked to integrin activation. Moreover, our result showed that the mutational effects of the membrane-proximal I719 and the membrane-distal E749 residues were additive and talin-dependent, suggesting that the β3 membrane-proximal and –distal regions cooperatively regulate talin-mediated αIIbβ3 activation. This finding is consistent with a recent model of talin-induced αIIbβ3 activation in which talin cooperatively interacts with the β3 membrane-proximal and distal regions.

scholarly journals The Dual Structural Roles of the Membrane Distal Region of α Integrin Cytoplasmic Tail in Integrin inside-out Activation

Blood ◽  
2014 ◽  
Vol 124 (21) ◽  
pp. 1431-1431
Author(s):  
Jieqing Zhu ◽  
Jiafu Liu ◽  
Yan-Qing Ma ◽  
Zhengli Wang
Keyword(s):  
Cytoplasmic Membrane ◽  
Cytoplasmic Tail ◽  
K562 Cells ◽  
Distal Region ◽  
Proximal Region ◽  
Integrin Activation ◽  
Membrane Proximal Region ◽  
Inside Out ◽  
Complete Deletion

Abstract Integrin inside-out activation is essential for platelet aggregation mediated by αIIbβ3 and leukocytes migration and arresting mediated by αLβ2. How integrin is activated by the inside-out stimulation is not completely understood. Integrin activation from inside the cell is regulated through the transmembrane and cytoplasmic domains. Mutagenesis and structural studies revealed that the inactive integrin conformation is maintained by the specific interactions at the transmembrane and cytoplasmic domains. Inside-out signals impinging on integrin cytoplasmic domain disturb the transmembrane and cytoplasmic associations, resulting in conformational change of extracellular domain that is required for binding ligands. Studies on the mechanism of integrin inside-out activation have been focused on β cytoplasmic tail that is relatively conserved and bears binding sites for the common intracellular activators including talin and kindlin. The integrin α cytoplasmic tails only share a conserved GFFKR motif at the membrane-proximal region that forms specific interface with the membrane-proximal region of β cytoplasmic tail. The membrane-distal regions after the GFFKR motif are diverse significantly both in length and sequence. Their roles in integrin activation have not been well characterized. In this study, by comprehensive mutagenesis, we defined the role of the membrane-distal region of α integrin cytoplasmic tail in maintaining integrin in the resting state and in integrin inside-out activation. We found that complete deletion of the αIIb cytoplasmic membrane-distal region greatly enhances αIIbβ3 activation induced by the active mutations such as β3-K716A and β3-G708L, indicating that the missing of membrane-distal region facilitates integrin activation, i.e. the αIIb membrane-distal region contributes to the inactive integrin conformation. On the other hand, complete deletion of the αIIb membrane-distal region abolished integrin activation induced by the active mutations of αIIb-R995 and β3-D723, indicating that the αIIb membrane-distal region also contributes to integrin inside-out activation. We demonstrated that deletion of the membrane-distal region of αIIb, αV, or αL integrin greatly diminished ligand binding induced by overexpression of talin-1 head and/or kindlin-2 or -3 in 293FT cells. We further confirmed the effect of α cytoplasmic membrane-distal region on integrin inside-out activation in K562 cells. In the absence of αIIb cytoplasmic membrane-distal region, PMA failed to induce ligand binding to αIIbβ3 integrin expressed in K562 cells. This effect was due to the lack of talin-1-head and kindlin-induced integrin conformational change (ectodomain extension and headpiece opening) in the absence of α cytoplasmic membrane-distal region as reported by the conformation-dependent monoclonal antibodies. Structural superposition of αIIbβ3 transmembrane-cytoplasmic heterodimer and talin-1-head/β-tail complex reveals steric clashes between talin-1 head and the αIIb membrane-distal residues (NR997) immediately follow the GFFKR motif, which has been suggested to play a role in talin-mediated integrin activation. To test this possibility, we retained two native residues, NR997 for the αIIb membrane-distal region and found that it partially restores talin-1-head-induced integrin activation. Replacing the NR997 with small amino acids, GG997 or AA997 has little effect, while with the bulky residues YY997 significantly reduced talin-1-head-induced αIIbβ3 activation. Interestingly, retaining two native residues for the membrane-distal region of αV or αL integrin failed to restore talin-1-head-induced αVβ3 or αLβ2 activation. Retaining as long as 8 native residues for the αL membrane-distal region is not sufficient to restore talin-1-head-induced αLβ2 activation to the level of intact αL. These data demonstrate that a steric clash might play a role but is not the sole mechanism by which the α cytoplasmic membrane-distal region participates in integrin inside-out activation. A proper length and amino acids of the membrane-distal region is required for talin-induced integrin activation. Our data established an essential role of the α integrin cytoplasmic membrane-distal region in integrin activation and provide new insight of how talin and kindlin induce the high affinity integrin conformation that is required for fully functional integrins. Disclosures No relevant conflicts of interest to declare.

scholarly journals Structure and Sequence Diversity of the Membrane Distal Region of α-Cytoplasmic Tail in Integrin Activation

Blood ◽  
2015 ◽  
Vol 126 (23) ◽  
pp. 3453-3453
Author(s):  
Aye Myat Myat Thinn ◽  
Jieqing Zhu
Keyword(s):  
Cytoplasmic Tail ◽  
Proximal Region ◽  
Sequence Diversity ◽  
Wild Type ◽  
Integrin Activation ◽  
Cytoplasmic Tails ◽  
Membrane Proximal Region ◽  
Inside Out ◽  
Α5β1 Integrin

Abstract Integrins are α/β heterodimeric cell adhesion receptors with each subunit comprising of a large extracellular domain, a single-spanning transmembrane domain, and usually a short cytoplasmic tail. Different combinations of 18 α and 8 β subunits make up 24 integrin members that recognize diverse extracellular ligands important in numerous biological functions such as immune responses, maintenance of hemostasis, and development. Abnormal activation of integrin is associated with many pathological conditions including thrombosis, inflammatory diseases, as well as tumor-driven cell growth, metastasis, and angiogenesis. Therefore, tight regulation is crucial in integrin activation. Recent structural and functional studies have shown that integrin activation is regulated by the cytoplasmic tails. Studies on the mechanism of integrin activation from inside the cell (namely inside-out activation) have been focused on the β cytoplasmic tail that is relatively conserved and bears binding sites for the common intracellular activators such as talin and kindlin. However, the role of α cytoplasmic tail in integrin activation remains elusive. The integrin α cytoplasmic tails share a conserved GFFKR motif at the membrane-proximal region that forms a specific interface with the membrane-proximal region of the β cytoplasmic tail. In contrast, the membrane-distal (MD) regions following the GFFKR motif are diverse significantly both in length, sequence and structure when reported, and their roles in integrin activation have not been well characterized. Our recent studies demonstrated that the α-MD region is required for talin and kindlin-induced activation of αIIb, αV, and αL integrins and suggest that the sequence diversity of the α-MD region might play a role in the regulation of integrin activation. In this study, we further examined the role of α-MD regions in integrin inside-out activation using αIIb, αL, and α5 integrins as platforms. Each MD region of αIIb, αL, and α5 was replaced with those of other α subunits that heterodimerize with β3, β2, and β1 integrins, respectively. β3 subunit forms heterodimers with αIIb and αV integrins. β2 subunit forms heterodimers with αL, αM, αD, and αX integrins. β1 subunit forms heterodimers with α1, α2, α3, α4, α5, α6, α7, α8, α9, α10, α11, and αV integrins. Thus, using these integrin α-chimeras, we were able to systemically study the role of 17 α-MD regions in integrin inside-out activation while retaining the native association of α and β subunits at the cytoplasmic domains. Ligand-mimetic mAb PAC-1, intercellular adhesion molecule-1 (ICAM-1), and human fibronectin were used to measure the talin-head-induced activation of αIIb, αL, and α5 chimeras co-expressed in HEK293FT cells with β3, β2, and β1 integrins, respectively. Conformation-specific monoclonal antibodies were used to report integrin conformational activation. The endogenous α5β1 integrin of HEK293FT cells were knocked out by the CRISPR/Cas9 technology. Our data showed that the chimeric α integrins had different levels of inside-out activation when compared with their corresponding wild-type integrins. Some chimeras such as αIIb-αV, αL-αX, αL-αD, αL-αM, α5-α2, α5-α4, and α5-α9 showed lower integrin activation than the wild types, while other chimeras such as α5-α7 and α5-α10 rendered α5β1 integrin more active than wild type. As a control, the αIIb-α1 and αIIb-αL chimeras all showed higher inside-out activation than wild-type αIIb. Our results suggest that specific amino acids of the α-MD region that immediately follow the GFFKR motif might contribute to integrin inside-out activation, probably through regulating the conformational change of the integrin α transmembrane and cytoplasmic domains. Our study demonstrates an important role of the α-MD region in integrin activation and indicates that structure and sequence diversity of the α-MD region might contribute to the diverse functions of integrins, which are determined by different integrin α subunits. Disclosures No relevant conflicts of interest to declare.

scholarly journals The intracellular lipid-binding domain of human Na+/H+ exchanger 1 forms a lipid-protein co-structure essential for activity

2020 ◽  
Vol 3 (1) ◽  
Author(s):  
Ruth Hendus-Altenburger ◽  
Jens Vogensen ◽  
Emilie Skotte Pedersen ◽  
Alessandra Luchini ◽  
Raul Araya-Secchi ◽  
...  
Keyword(s):  
Membrane Proteins ◽  
Lipid Membranes ◽  
Molecular Mechanisms ◽  
Lipid Binding ◽  
Proximal Region ◽  
Dynamic Interactions ◽  
Intrinsically Disordered ◽  
Nhe1 Activity ◽  
Dynamics Simulations ◽  
Membrane Anchoring

AbstractDynamic interactions of proteins with lipid membranes are essential regulatory events in biology, but remain rudimentarily understood and particularly overlooked in membrane proteins. The ubiquitously expressed membrane protein Na+/H+-exchanger 1 (NHE1) regulates intracellular pH (pHi) with dysregulation linked to e.g. cancer and cardiovascular diseases. NHE1 has a long, regulatory cytosolic domain carrying a membrane-proximal region described as a lipid-interacting domain (LID), yet, the LID structure and underlying molecular mechanisms are unknown. Here we decompose these, combining structural and biophysical methods, molecular dynamics simulations, cellular biotinylation- and immunofluorescence analysis and exchanger activity assays. We find that the NHE1-LID is intrinsically disordered and, in presence of membrane mimetics, forms a helical αα-hairpin co-structure with the membrane, anchoring the regulatory domain vis-a-vis the transport domain. This co-structure is fundamental for NHE1 activity, as its disintegration reduced steady-state pHi and the rate of pHi recovery after acid loading. We propose that regulatory lipid-protein co-structures may play equally important roles in other membrane proteins.

scholarly journals Talin-dependent integrin activation is required for fibrin clot retraction by platelets

Blood ◽  
2011 ◽  
Vol 117 (5) ◽  
pp. 1719-1722 ◽  
Author(s):  
Jacob R. Haling ◽  
Susan J. Monkley ◽  
David R. Critchley ◽  
Brian G. Petrich
Keyword(s):  
Actin Cytoskeleton ◽  
Cytoplasmic Domain ◽  
Fibrin Clot ◽  
Proximal Region ◽  
Integrin Activation ◽  
Clot Retraction ◽  
Genetic Deletion ◽  
Membrane Proximal Region ◽  
First Time ◽  
Fibrin Clots

Abstract Talin functions both as a regulator of integrin affinity and as an important mechanical link between integrins and the cytoskeleton. Using genetic deletion of talin, we show for the first time that the capacity of talin to activate integrins is required for fibrin clot retraction by platelets. To further dissect which talin functions are required for this process, we tested clot retraction in platelets expressing a talin1(L325R) mutant that binds to integrins, but exhibits impaired integrin activation ascribable to disruption of the interaction between talin and the membrane-proximal region (MPR) in the β-integrin cytoplasmic domain. Talin-deficient and talin1(L325R) platelets were defective in retracting fibrin clots. However, the defect in clot retraction in talin1(L325R) platelets, but not talin-deficient platelets, was rescued by extrinsically activating integrins with manganese, thereby proving that integrin activation is required and showing that talin1(L325R) can form functional links to the actin cytoskeleton.

scholarly journals Interdimer “zipping” in the chemoreceptor signaling domain revealed by molecular dynamics simulations

2019 ◽  
Author(s):  
Marharyta G. Petukh ◽  
Davi R. Ortega ◽  
Jerome Baudry ◽  
Igor B. Zhulin
Keyword(s):  
Molecular Dynamics ◽  
Molecular Dynamics Simulations ◽  
Electrostatic Interactions ◽  
Molecular Mechanisms ◽  
Hydrophobic Interactions ◽  
Salt Bridges ◽  
Compact Structure ◽  
Flagellar Motors ◽  
Signaling Domain ◽  
Dynamics Simulations

ABSTRACTChemoreceptors are principal components of the bacterial sensory system that modulates cellular motility. They detect changes in the environment and transmit information to CheA histidine kinase, which ultimately controls cellular flagellar motors. The prototypical Tsr chemoreceptor in E. coli is a homodimer containing two principal functional modules: (i) a periplasmic ligand-binding domain and (ii) a cytoplasmic signaling domain. Chemoreceptor dimers are arranged into a trimer of dimers at the tip of the signaling domain comprising a minimal physical unit essential for enhancing the CheA activity several hundredfold. Trimers of dimers are arranged into highly ordered hexagon arrays at the cell pole; however, the mechanism underlying the trimer-of-dimer and higher order array formation remains unclear. Furthermore, molecular mechanisms of signal transduction that are likely to involve inter-dimer interactions are not fully understood. Here we apply all-atom, microsecond-time scale molecular dynamics simulations of the Tsr trimer of dimers atomic model in order to obtain further insight into potential interactions within the chemoreceptor signaling unit. We show extensive interactions between homodimers at the hairpin tip of the signaling domain, where strong hydrophobic interactions maintain binding. A subsequent zipping of homodimers is facilitated by electrostatic interactions, in particular by polar solvation energy and salt bridges that stabilize the final compact structure, which extends beyond the kinase interacting subdomain. Our study provides evidence that interdimer interactions within the chemoreceptor signaling domain are more complex than previously thought.

scholarly journals Kindlin-2 (Mig-2): a co-activator of β3 integrins

2008 ◽  
Vol 181 (3) ◽  
pp. 439-446 ◽  
Author(s):  
Yan-Qing Ma ◽  
Jun Qin ◽  
Chuanyue Wu ◽  
Edward F. Plow
Keyword(s):  
Proximal Region ◽  
Integrin Activation ◽  
Binding Partner ◽  
Integrin Β3 ◽  
Synergistic Enhancement ◽  
Cytoplasmic Tails ◽  
And Migration ◽  
Sirna Knockdown ◽  
Membrane Proximal Region ◽  
Extracellular Environment

Integrin activation is essential for dynamically linking the extracellular environment and cytoskeletal/signaling networks. Activation is controlled by integrins' short cytoplasmic tails (CTs). It is widely accepted that the head domain of talin (talin-H) can mediate integrin activation by binding to two sites in integrin β's CT; in integrin β3 this is an NPLY747 motif and the membrane-proximal region. Here, we show that the C-terminal region of integrin β3 CT, composed of a conserved TS752T region and NITY759 motif, supports integrin activation by binding to a cytosolic binding partner, kindlin-2, a widely distributed PTB domain protein. Co-transfection of kindlin-2 with talin-H results in a synergistic enhancement of integrin αIIbβ3 activation. Furthermore, siRNA knockdown of endogenous kindlin-2 impairs talin-induced αIIbβ3 activation in transfected CHO cells and blunts αvβ3-mediated adhesion and migration of endothelial cells. Our results thus identify kindlin-2 as a novel regulator of integrin activation; it functions as a coactivator.

Insights into the roles of charged residues in substrate binding and mode of action of mannuronan C-5 epimerase AlgE4

Glycobiology ◽  
2021 ◽  
Author(s):  
Margrethe Gaardløs ◽  
Sergey A Samsonov ◽  
Marit Sletmoen ◽  
Maya Hjørnevik ◽  
Gerd Inger Sætrom ◽  
...  
Keyword(s):  
Optical Tweezers ◽  
Conformational Changes ◽  
Molecular Mechanisms ◽  
Hydrophobic Interactions ◽  
Substrate Binding ◽  
Interdisciplinary Approach ◽  
Product Formation ◽  
Titration Calorimetry ◽  
Binding Groove ◽  
Dynamics Simulations

Abstract Mannuronan C-5 epimerases catalyse the epimerization of monomer residues in the polysaccharide alginate, changing the physical properties of the biopolymer. The enzymes are utilized to tailor alginate to numerous biological functions by alginate-producing organisms. The underlying molecular mechanisms that control the processive movement of the epimerase along the substrate chain is still elusive. To study this, we have used an interdisciplinary approach combining molecular dynamics simulations with experimental methods from mutant studies of AlgE4, where initial epimerase activity and product formation were addressed with NMR spectroscopy, and characteristics of enzyme-substrate interactions were obtained with isothermal titration calorimetry and optical tweezers. Positive charges lining the substrate-binding groove of AlgE4 appear to control the initial binding of poly-mannuronate, and binding also seems to be mediated by both electrostatic and hydrophobic interactions. After the catalytic reaction, negatively charged enzyme residues might facilitate dissociation of alginate from the positive residues, working like electrostatic switches, allowing the substrate to translocate in the binding groove. Molecular simulations show translocation increments of two monosaccharide units before the next productive binding event resulting in MG-block formation, with the epimerase moving with its N-terminus towards the reducing end of the alginate chain. Our results indicate that the charge pair R343-D345 might be directly involved in conformational changes of a loop that can be important for binding and dissociation. The computational and experimental approaches used in this study complement each other, allowing for a better understanding of individual residues’ roles in binding and movement along the alginate chains.

scholarly journals Snails In Silico: A Review of Computational Studies on the Conopeptides

Marine Drugs ◽  
2019 ◽  
Vol 17 (3) ◽  
pp. 145 ◽  
Author(s):  
Rachael Mansbach ◽  
Timothy Travers ◽  
Benjamin McMahon ◽  
Jeanne Fair ◽  
S. Gnanakaran
Keyword(s):  
Posttranslational Modifications ◽  
High Throughput Screening ◽  
Molecular Mechanisms ◽  
Defense Mechanism ◽  
Docking Studies ◽  
Chemical Diversity ◽  
Machine Learning Techniques ◽  
Peptide Toxins ◽  
Dynamics Simulations ◽  
And Function

Marine cone snails are carnivorous gastropods that use peptide toxins called conopeptides both as a defense mechanism and as a means to immobilize and kill their prey. These peptide toxins exhibit a large chemical diversity that enables exquisite specificity and potency for target receptor proteins. This diversity arises in terms of variations both in amino acid sequence and length, and in posttranslational modifications, particularly the formation of multiple disulfide linkages. Most of the functionally characterized conopeptides target ion channels of animal nervous systems, which has led to research on their therapeutic applications. Many facets of the underlying molecular mechanisms responsible for the specificity and virulence of conopeptides, however, remain poorly understood. In this review, we will explore the chemical diversity of conopeptides from a computational perspective. First, we discuss current approaches used for classifying conopeptides. Next, we review different computational strategies that have been applied to understanding and predicting their structure and function, from machine learning techniques for predictive classification to docking studies and molecular dynamics simulations for molecular-level understanding. We then review recent novel computational approaches for rapid high-throughput screening and chemical design of conopeptides for particular applications. We close with an assessment of the state of the field, emphasizing important questions for future lines of inquiry.

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