Microtubule End-binding Protein Research Articles

The GhEB1C gene mediates resistance of cotton to Verticillium wilt.

The GhEB1C gene of the EB1 protein family functions as microtubule end-binding protein and may be involved in the regulation of microtubule-related pathways to enhance resistance to Verticillium wilt. The expression of GhEB1C is induced by SA, also contributing to Verticillium wilt resistance. Cotton, as a crucial cash and oil crop, faces a significant threat from Verticillium wilt, a soil-borne disease induced by Verticillium dahliae, severely impacting cotton growth and development. Investigating genes associated with resistance to Verticillium wilt is paramount. We identified and performed a phylogenetic analysis on members of the EB1 family associated with Verticillium wilt in this work. GhEB1C was discovered by transcriptome screening and was studied for its function in cotton defense against V. dahliae. The RT-qPCR analysis revealed significant expression of the GhEB1C gene in cotton leaves. Subsequent localization analysis using transient expression demonstrated cytoplasmic localization of GhEB1C. VIGS experiments indicated that silencing of the GhEB1C gene significantly increased susceptibility of cotton to V. dahliae. Comparative RNA-seq analysis showed that GhEB1C silenced plants exhibited altered microtubule-associated protein pathways and flavonogen-associated pathways, suggesting a role for GhEB1C in defense mechanisms. Overexpression of tobacco resulted in enhanced resistance to V. dahliae as compared to wild-type plants. Furthermore, our investigation into the relationship between the GhEB1C gene and plant disease resistance hormones salicylic axid (SA) and jasmonic acid (JA) revealed the involvement of GhEB1C in the regulation of the SA pathway. In conclusion, our findings demonstrate that GhEB1C plays a crucial role in conferring immunity to cotton against Verticillium wilt, providing valuable insights for further research on plant adaptability to pathogen invasion.

The GTP-tubulin cap is not the determinant of microtubule end stability in cells.

Microtubules are dynamic cytoskeletal polymers essential for cell division, motility, and intracellular transport. Microtubule dynamics are characterized by dynamic instability-the ability of individual microtubules to switch between phases of growth and shrinkage. Dynamic instability can be explained by the GTP-cap model, suggesting that a "cap" of GTP-tubulin subunits at the growing microtubule end has a stabilizing effect, protecting against microtubule catastrophe-the switch from growth to shrinkage. Although the GTP-cap is thought to protect the growing microtubule end, whether the GTP-cap size affects microtubule stability in cells is not known. Notably, microtubule end-binding proteins, EBs, recognize the nucleotide state of tubulin and display comet-like localization at growing microtubule ends, which can be used as a proxy for the GTP-cap. Here, we employ high spatiotemporal resolution imaging to compare the relationship between EB comet size and microtubule dynamics in interphase LLC-PK1 cells to that measured in vitro. Our data reveal that the GTP-cap size in cells scales with the microtubule growth rate in the same way as in vitro. However, we find that microtubule ends in cells can withstand transition to catastrophe even after the EB comet is lost. Thus, our findings suggest that the presence of the GTP-cap is not the determinant of microtubule end stability in cells.

EB-SUN, a New Microtubule Plus-End Tracking Protein in Drosophila.

Microtubule (MT) regulation is essential for oocyte development. In Drosophila, MT stability, polarity, abundance, and orientation undergo dynamic changes across developmental stages. In our effort to identify novel microtubule-associated proteins (MAPs) that regulate MTs in the Drosophila ovary, we identified a previously uncharacterized gene, CG18190, encoding a novel MT end-binding (EB) protein, which we propose to name EB-SUN. We show that EB-SUN colocalizes with EB1 at growing microtubule plus-ends in Drosophila S2 cells. Tissue-specific and developmental expression profiles from Paralog Explorer reveal that EB-SUN is predominantly expressed in the ovary and early embryos, while EB1 is ubiquitously expressed. Furthermore, as early as oocyte determination, EB-SUN comets are highly concentrated in oocytes during oogenesis. EB-SUN knockout (KO) results in a decrease in MT density at the onset of mid-oogenesis (Stage 7) and delays oocyte growth during late mid-oogenesis (Stage 9). Combining EB-SUN KO with EB1 knockdown (KD) in germ cells significantly further reduced MT density at Stage 7. Notably, all eggs from EB-SUN KO/EB1 KD females fail to hatch, unlike single gene depletion, suggesting a functional redundancy between these two EB proteins during embryogenesis. Our findings indicate that EB-SUN and EB1 play distinct roles during early embryogenesis.

Abstract 513: Intra-tubular damage is targeted by maytansinoids and rescued by NF1: Revisiting mechanism and biomarkers of an established ADC payload

Abstract There is great interest in the identification of biomarkers to guide development of antibody-drug conjugates (ADC). We previously showed that loss of Neurofibromatosis 1 (NF1), a gene frequently mutated across cancers, enhances the activity of DM1, the maytansinoid payload of T-DM1, through a novel function in regulating microtubule (MT) dynamics. Maytansinoids are puzzlingly more effective in cells (in the nanomolar range) vs in vitro (in the micromolar range). Since maytansinoids bind at the interface between tubulin dimers, they are thought to only bind soluble tubulin dimers or MT ends, which would suggest very few binding sites available for pharmacological interaction in vivo, at odds with data. Here we investigated the interaction of DM1 with NF1 and MTs, using cellular and reductionist in vitro systems. To measure in vivo MT dynamics, we transiently transfected the MT end-binding protein EB3-GFP and reconstructed MT trajectories by live-cell imaging. Upon DM1 treatment, KO cells showed a highly significant reduction in MT speed, demonstrating a direct role for NF1 on MT dynamics in cells. In turbidity-based tubulin polymerization assays, recombinant NF1 greatly accelerated polymerization, and completely rescued DM1-induced inhibition. Visual inspection of fluorescent MTs showed that NF1 induced significant MT bundling, a defining feature of many MT-associated proteins, which generates signal indistinguishable from true MT polymerization in turbidity assays. To follow the dynamics of individual microtubules, we applied Total Internal Reflection (TIRF) microscopy on glass-immobilized MTs. As expected, polymerization in the presence of NF1 led to a significant increase in MT dynamics (elongation speed, rescue and catastrophe rate). Expectedly, DM1 led to significant reduction in the fraction of elongating MTs and speed, but these defects were completely or partially rescued by NF1. Importantly, DM1 did not only lead to MT shortening (as proposed by the current model), but also to clear and frequent MT fracturing, indicating that the drug is not only engaging MT ends but also intra-tubular binding sites. This is consistent with recent models of MT formation which incorporate the frequent presence of areas of discontinuity or damage induced by mechanical stress, exposing intra-tubular DM1 binding sites. Interestingly, adding NF1 to DM1-treated MTs generated areas of de novo intra-tubular tubulin insertion, coincident with damaged sites, suggesting an entirely novel role for NF1 in MT repair.In conclusion, we provide evidence for a model in which maytansinoids bind not only to soluble tubulin dimers and MT ends, but also to intra-tubular damaged sites. Thus, the number of binding sites in cells would be proportional to MT damage, suggesting a mechanism for differential efficacy across tumor types and a potential avenue for combinatorial drug development. Citation Format: Eleonora Messuti, Bruno Achutti Duso, Alessia Castiglioni, Giulia Tini, Emanuele Bonetti, Giuseppe Ciossani, Silvia Monzani, Daria Khuntsariya, Zdeněk Lánský, Marcus Braun, Luigi Scietti, Luca Mazzarella. Intra-tubular damage is targeted by maytansinoids and rescued by NF1: Revisiting mechanism and biomarkers of an established ADC payload [abstract]. In: Proceedings of the American Association for Cancer Research Annual Meeting 2024; Part 1 (Regular Abstracts); 2024 Apr 5-10; San Diego, CA. Philadelphia (PA): AACR; Cancer Res 2024;84(6_Suppl):Abstract nr 513.

The Microtubule End Binding Protein Mal3 Is Essential for the Dynamic Assembly of Microtubules during Magnaporthe oryzae Growth and Pathogenesis.

Cytoskeletal microtubules (MTs) play crucial roles in many aspects of life processes in eukaryotic organisms. They dynamically assemble physiologically important MT arrays under different cell conditions. Currently, aspects of MT assembly underlying the development and pathogenesis of the model plant pathogenic fungus Magnaporthe oryzae (M. oryzae) are unclear. In this study, we characterized the MT plus end binding protein MoMal3 in M. oryzae. We found that knockout of MoMal3 results in defects in hyphal polar growth, appressorium-mediated host penetration and nucleus division. Using high-resolution live-cell imaging, we further found that the MoMal3 mutant assembled a rigid MT in parallel with the MT during hyphal polar growth, the cage-like network in the appressorium and the stick-like spindle in nuclear division. These aberrant MT organization patterns in the MoMal3 mutant impaired actin-based cell growth and host infection. Taken together, these findings showed that M. oryzae relies on MoMal3 to assemble elaborate MT arrays for growth and infection. The results also revealed the assembly mode of MTs in M. oryzae, indicating that MTs are pivotal for M. oryzae growth and host infection and may be new targets for devastating fungus control.

The Role of MAPRE2 and Microtubules in Maintaining Normal Ventricular Conduction.

Brugada syndrome is associated with loss-of-function SCN5A variants, yet these account for only ≈20% of cases. A recent genome-wide association study identified a novel locus within MAPRE2, which encodes EB2 (microtubule end-binding protein 2), implicating microtubule involvement in Brugada syndrome. A mapre2 knockout zebrafish model was generated using CRISPR/Cas9 (clustered regularly interspaced short palindromic repeats/clustered regularly interspaced short palindromic repeat-associated protein 9) and validated by Western blot. Larval hearts at 5 days post-fertilization were isolated for voltage mapping and immunocytochemistry. Adult fish hearts were used for ECG, patch clamping, and immunocytochemistry. Morpholinos were injected into embryos at 1-cell stage for knockdown experiments. A transgenic zebrafish line with cdh2 tandem fluorescent timer was used to study adherens junctions. Microtubule plus-end tracking and patch clamping were performed in human induced pluripotent stem cell derived cardiomyocytes (iPSC-CMs) with MAPRE2 knockdown and knockout, respectively. Voltage mapping of mapre2 knockout hearts showed a decrease in ventricular maximum upstroke velocity of the action potential and conduction velocity, suggesting loss of cardiac voltage-gated sodium channel function. ECG showed QRS prolongation in adult knockout fish, and patch clamping showed decreased sodium current density in knockout ventricular myocytes and arrhythmias in knockout iPSC-CMs. Confocal imaging showed disorganized adherens junctions and mislocalization of mature Ncad (N-cadherin) with mapre2 loss of function, associated with a decrease of detyrosinated tubulin. MAPRE2 knockdown in iPSC-CMs led to an increase in microtubule growth velocity and distance, indicating changes in microtubule dynamics. Finally, knockdown of ttl encoding tubulin tyrosine ligase in mapre2 knockout larvae rescued tubulin detyrosination and ventricular maximum upstroke velocity of the action potential. Genetic ablation of mapre2 led to a decrease in voltage-gated sodium channel function, a hallmark of Brugada syndrome, associated with disruption of adherens junctions, decrease of detyrosinated tubulin as a marker of microtubule stability, and changes in microtubule dynamics. Restoration of the detyrosinated tubulin fraction with ttl knockdown led to rescue of voltage-gated sodium channel-related functional parameters in mapre2 knockout hearts. Taken together, our study implicates microtubule dynamics in the modulation of ventricular conduction.

The role of MAPRE2 and microtubules in Brugada syndrome pathogenesis

Abstract Background Brugada syndrome (BrS) is associated with loss-of-function variants in SCN5A (encoding NaV1.5), which are found in only ∼20% of patients. Recent genome-wide association studies identified a novel locus within an intron of MAPRE2 (encoding microtubule end-binding protein 2, EB2), implicating microtubule (MT) involvement in BrS. Purpose To understand the role of MAPRE2 and MT in BrS pathogenesis. Methods A mapre2 knock-out (KO) zebrafish model was generated using CRISPR/Cas9 and validated by western blot. Larval hearts at 5 day-post-fertilization (dpf) were isolated for voltage mapping and immunohistochemistry with confocal imaging. Morpholino targeting mapre2 or ttl (encoding tubulin tyrosine ligase) were injected into zebrafish embryos at the one-cell stage. A transgenic zebrafish line with cdh2 (encoding N-cadherin) tandem fluorescent timer (tFT) was used to study adherens junction. MT plus-end tracking experiments were performed in iPSC-derived cardiomyocytes (CM) with MAPRE2 knockdown (KD) using siRNA. ECG was recorded in adult fish. Results Voltage mapping of larval hearts (14 WTs vs. 19 KOs) showed a significant decrease in ventricular conduction velocity (17.4±1.5 vs. 13.4±0.8 mm/s; p<0.05) and action potential upstroke velocity (Vmax; 86.1±3.6 vs. 73.9±3.2 1/s; p<0.05), suggesting loss of cardiac NaV function. Correspondingly, ECG of adult fish (11 WTs vs. 10 KOs) showed a significant increase in QRS duration (27.8±0.5 vs. 32.3±0.7 ms; p<0.0001). Confocal imaging of KO hearts showed disorganized adherens junction based on N-cadherin staining. Similarly, morpholino KD of mapre2 in the cdh2 tFT line showed ∼40% mislocalization of mature N-cadherin relative to ZO-1 staining in larval ventricles (8 KDs vs 9 control hearts; p<0.05), suggesting disruption of adherens junction. In terms of MT, immunohistochemistry showed a 23% decrease of detyrosinated tubulin relative to total alpha tubulin in KO hearts (16 vs. 8 WT hearts; p<0.01). MAPRE2 KD in iPSC-CM (337 control vs. 285 KD MT in 4 sets of cells) showed an increase in MT velocity (7.9±0.2 vs. 8.8±0.2 µm/min; p<0.001), distance (5.8±0.2 vs. 7.1±0.2 µm; p<0.0001), and duration (46.2±1.4 vs. 52.2±1.6 s; p<0.001), suggesting changes to MT dynamics. Finally, morpholino KD of ttl in mapre2 KO embryos restored the fraction of detyrosinated tubulin (46% increase; 16 controls vs. 16 KDs; p<0.01) as well as Vmax (74.3±3.0 vs. 88.3±2.1 1/s; 13 controls vs. 9 KDs; p<0.01) to WT levels. Conclusion Genetic ablation of mapre2 led to a decrease in cardiac NaV function, a hallmark of BrS. This is associated with disruption of adherens junction, a decrease of detyrosinated tubulin as a marker of MT stability, and changes in MT dynamics. Restoration of detyrosinated tubulin fraction with ttl KD led to a rescue of NaV function in zebrafish larval hearts. Taken together, MAPRE2 loss-of-function may contribute to BrS pathogenesis by disruption of adherens junction via changes in MT dynamics.

Intracellular transport: Finding the motor that will take you where you need to go

The Golgi complex is a busy production hub. A new study reveals that a microtubule end-binding (EB) protein enriched at the trans-Golgi network in neurons is needed to pair dense core vesicles with a kinesin motor for transport to axons.

Phase separation of +TIP networks regulates microtubule dynamics

Regulation of microtubule dynamics is essential for diverse cellular functions, and proteins that bind to dynamic microtubule ends can regulate network dynamics. Here, we show that two conserved microtubule end-binding proteins, CLIP-170 and EB3, undergo phase separation and form dense liquid networks. When CLIP-170 and EB3 act together, the multivalency of the network increases, which synergistically increases the amount of protein in the dense phase. In vitro and in cells, these liquid networks can concentrate tubulin. In vitro, in the presence of microtubules, phase separation of EB3/CLIP-170 can enrich tubulin all along the microtubule. In this condition, microtubule growth speed increases up to twofold and the frequency of depolymerization events are strongly reduced compared to conditions in which there is no phase separation. Our data show that phase separation of EB3/CLIP-170 adds an additional layer of regulation to the control of microtubule growth dynamics.

PO-02-153 THE ROLE OF MAPRE2 AND MICROTUBULES IN CARDIAC ELECTROPHYSIOLOGY AND BRUGADA SYNDROME

Brugada syndrome (BrS) is associated with loss-of-function variants in SCN5A (encoding NaV1.5), yet these are only found in ∼20% of probands. Recent genome-wide association studies identified a novel locus within an intron of MAPRE2 (encoding microtubule end-binding protein 2, EB2), which implicates microtubule (MT) involvement in BrS. To understand the role of MAPRE2 and MT in cardiac electrophysiology and BrS pathogenesis. Using CRISPR/Cas9, a mapre2 knock-out (KO) mutant was generated in zebrafish and validated by western blot. Morpholino targeting ttl (encoding tubulin tyrosine ligase) was injected into zebrafish embryos at the one-cell stage. Larval hearts at 5 day-post-fertilization (dpf) were isolated for voltage mapping and immunohistochemistry. MT plus-end tracking experiments were performed in iPSC-derived cardiomyocytes with MAPRE2 knockdown (KD) using siRNA. ECG was recorded in adult fish. Voltage mapping of larval hearts (14 WTs vs. 19 KOs) showed a significant decrease in ventricular conduction velocity (17.4±1.5 vs. 13.4±0.8 mm/s; p<0.05) and action potential upstroke velocity (Vmax; 86.1±3.6 vs. 73.9±3.2 1/s; p<0.05), suggesting loss of cardiac NaV function. Correspondingly, ECG of adult fish (11 WTs vs. 10 KOs) showed a significant increase in QRS duration (27.8±0.5 vs. 32.3±0.7 ms; p<0.0001). Immunohistochemistry showed a 23% decrease of detyrosinated (glu) tubulin relative to total alpha tubulin in KO hearts (16 vs. 8 WT hearts; p<0.01). MT plus-end tracking experiments (337 control vs. 285 KD MT in 4 sets of cells) showed an increase in MT velocity (7.9±0.2 vs. 8.8±0.2 μm/min; p<0.001), distance (5.8±0.2 vs. 7.1±0.2 μm; p<0.0001), and duration (46.2±1.4 vs. 52.2±1.6 s; p<0.001) with MAPRE2 KD, suggesting changes to MT dynamics. Finally, morpholino KD of ttl in mapre2 KO embryos restored the fraction of glu-tubulin (46% increase; 16 controls vs. 16 ttl KDs; p<0.01) and Vmax (74.3±3.0 vs. 88.3±2.1 1/s; 13 controls vs. 9 KDs; p<0.01) to WT levels. Genetic ablation of mapre2 led to a decrease in NaV function, a hallmark of BrS. This is associated with a decrease in glu-tubulin as a marker of MT stability and changes in MT dynamics. Restoration of glu-tubulin fraction with ttl KD led to a rescue of NaV function in zebrafish larval hearts. Taken together, MAPRE2 loss-of-function may contribute to BrS pathogenesis via a novel paradigm of disrupting MT stability and dynamics.

A novel davunetide (NAPVSIPQQ to NAPVSIPQE) point mutation in activity-dependent neuroprotective protein (ADNP) causes a mild developmental syndrome.

NAP (NAPVSIPQ, drug candidate name, davunetide) is the neuroprotective fragment of activity-dependent neuroprotective protein (ADNP). Recent studies identified NAPVSIP as a Src homology 3 (SH3) domain-ligand association site, responsible for controlling signalling pathways regulating the cytoskeleton. Furthermore, the SIP motif in NAP/ADNP was identified as crucial for direct microtubule end-binding protein interaction facilitating microtubule dynamics and Tau microtubule interaction, at the microtubule end-binding protein site EB1 and EB3. Most de novo ADNP mutations reveal heterozygous STOP or frameshift STOP aberrations, driving the autistic/intellectual disability-related ADNP syndrome. Here, we report for the first time on a de novo missense mutation, resulting in ADNP containing NAPVISPQE instead of NAPVSIPQQ, in a child presenting developmental hypotonia, possibly associated with inflammation affecting food intake in early life coupled with fear of peer interactions and suggestive of a novel case of the ADNP syndrome. In silico modelling showed that the mutation Q (polar side chain) to E (negative side chain) affected the electrostatic characteristics of ADNP (reducing, while scattering the electrostatic positive patch). Comparison with the most prevalent pathogenic ADNP mutation, p.Tyr719*, indicated a further reduction in the electrostatic patch. Previously, exogenous NAP partially ameliorated deficits associated with ADNP p.Tyr719* mutations in transfected cells and in CRISPR/Cas9 genome edited cell and mouse models. These findings stress the importance of the NAP sequence in ADNP and as a future putative therapy for the ADNP syndrome.

The microtubule end-binding proteins EB1 and Patronin modulate the spatiotemporal dynamics of myosin and pattern pulsed apical constriction.

Apical constriction powers amnioserosa contraction during Drosophila dorsal closure. The nucleation, movement and dispersal of apicomedial actomyosin complexes generates pulsed apical constrictions during early closure. Persistent apicomedial and circumapical actomyosin complexes drive unpulsed constrictions that follow. Here, we show that the microtubule end-binding proteins EB1 and Patronin pattern constriction dynamics and contraction kinetics by coordinating the balance of actomyosin forces in the apical plane. We find that microtubule growth from moving Patronin platforms governs the spatiotemporal dynamics of apicomedial myosin through the regulation of RhoGTPase signaling by transient EB1-RhoGEF2 interactions. We uncover the dynamic reorganization of a subset of short non-centrosomally nucleated apical microtubules that surround the coalescing apicomedial myosin complex, trail behind it as it moves and disperse as the complex dissolves. We demonstrate that apical microtubule reorganization is sensitive to Patronin levels. Microtubule depolymerization compromised apical myosin enrichment and altered constriction dynamics. Together, our findings uncover the importance of reorganization of an intact apical microtubule meshwork, by moving Patronin platforms and growing microtubule ends, in enabling the spatiotemporal modulation of actomyosin contractility and, through it, apical constriction.

SH3- and actin-binding domains connect ADNP and SHANK3, revealing a fundamental shared mechanism underlying autism.

De novo heterozygous mutations in activity-dependent neuroprotective protein (ADNP) cause autistic ADNP syndrome. ADNP mutations impair microtubule (MT) function, essential for synaptic activity. The ADNP MT-associating fragment NAPVSIPQ (called NAP) contains an MT end-binding protein interacting domain, SxIP (mimicking the active-peptide, SKIP). We hypothesized that not all ADNP mutations are similarly deleterious and that the NAPV portion of NAPVSIPQ is biologically active. Using the eukaryotic linear motif (ELM) resource, we identified a Src homology 3 (SH3) domain-ligand association site in NAP responsible for controlling signaling pathways regulating the cytoskeleton, namely NAPVSIP. Altogether, we mapped multiple SH3-binding sites in ADNP. Comparisons of the effects of ADNP mutations p.Glu830synfs*83, p.Lys408Valfs*31, p.Ser404* on MT dynamics and Tau interactions (live-cell fluorescence-microscopy) suggested spared toxic function in p.Lys408Valfs*31, with a regained SH3-binding motif due to the frameshift insertion. Site-directed-mutagenesis, abolishing the p.Lys408Valfs*31 SH3-binding motif, produced MT toxicity. NAP normalized MT activities in the face of all ADNP mutations, although, SKIP, missing the SH3-binding motif, showed reduced efficacy in terms of MT-Tau interactions, as compared with NAP. Lastly, SH3 and multiple ankyrin repeat domains protein 3 (SHANK3), a major autism gene product, interact with the cytoskeleton through an actin-binding motif to modify behavior. Similarly, ELM analysis identified an actin-binding site on ADNP, suggesting direct SH3 and indirect SHANK3/ADNP associations. Actin co-immunoprecipitations from mouse brain extracts showed NAP-mediated normalization of Shank3-Adnp-actin interactions. Furthermore, NAP treatment ameliorated aberrant behavior in mice homozygous for the Shank3 ASD-linked InsG3680 mutation, revealing a fundamental shared mechanism between ADNP and SHANK3.

The CLIP-170 N-terminal domain binds directly to both F-actin and microtubules in a mutually exclusive manner

The cooperation between the actin and microtubule (MT) cytoskeletons is important for cellular processes such as cell migration and muscle cell development. However, a full understanding of how this cooperation occurs has yet to be sufficiently developed. The MT plus-end tracking protein CLIP-170 has been implicated in this actin–MT coordination by associating with the actin-binding signaling protein IQGAP1 and by promoting actin polymerization through binding with formins. Thus far, the interactions of CLIP-170 with actin were assumed to be indirect. Here, we demonstrate using high-speed cosedimentation assays that CLIP-170 can bind to filamentous actin (F-actin) directly. We found that the affinity of this binding is relatively weak but strong enough to be significant in the actin-rich cortex, where actin concentrations can be extremely high. Using CLIP-170 fragments and mutants, we show that the direct CLIP-170–F-actin interaction is independent of the FEED domain, the region that mediates formin-dependent actin polymerization, and that the CLIP-170 F-actin-binding region overlaps with the MT-binding region. Consistent with these observations, in vitro competition assays indicate that CLIP-170–F-actin and CLIP-170–MT interactions are mutually exclusive. Taken together, these observations lead us to speculate that direct CLIP-170–F-actin interactions may function to reduce the stability of MTs in actin-rich regions of the cell, as previously proposed for MT end-binding protein 1.

Abstract 13171: The Role of Novel Brugada Syndrome Gene MAPRE2 in Maintaining Normal Cardiac Electrophysiology

Introduction: Brugada syndrome (BrS) is a significant cause of sudden cardiac death yet only ~20% of patients are found with a loss-of-function variant in SCN5A encoding the cardiac Na + channel, leaving ~80% genetically undiagnosed. A recent genome-wide association study found 12 loci associated with BrS, including one in MAPRE2 encoding microtubule end-binding protein 2 (EB2). Hypothesis: MAPRE2 loss-of-function contributes to BrS and is necessary in maintaining normal cardiac electrophysiology (EP). Methods: Using CRISPR/Cas9, we generated two mapre2 loss-of-function mutants in zebrafish: a full knock-out and a mutant lacking the unique N-terminus of EB2 (delN). Cardiac EP was assessed using optical mapping in larvae, surface ECG in adults, and patch clamping in ventricular myocytes. Cardiac structure was assessed using videomicroscopy, histology, and confocal microscopy. Transcriptional changes were assessed using RNA-seq. Results: No gross changes in cardiac structure were observed with mapre2 loss-of-function. However, in both mutants, voltage mapping showed decreased ventricular conduction velocity and action potential upstroke velocity (V max ) and ECGs showed prolonged QRS, P wave, and corrected QT. Patch clamp of delN ventricular myocytes revealed reduced Na + current density without changes in gating properties consistent with the reduced V max . RNA-seq of larvel hearts suggested disruption of cell adhesion, confirmed by confocal microscopy, whereas Ca 2+ imaging found an increase in Ca 2+ transient amplitude. RNA-seq of adult hearts showed disruption in the Wnt signaling pathway and treatment with GSK3β inhibitor SB217673 rescued mutant ECG abnormalities. Conclusions: Our study supports MAPRE2 as a novel contributing gene in BrS pathogenesis and conduction slowing in general. Beyond its effect on Na + channel function, mapre2 and in particularly its unique N-terminal segment may play a broader role in cellular organization via the microtubule network affecting cellular EP in multiple ways. Our study also implicates for the first time the Wnt signaling pathway in BrS, suggesting not only shared biology with arrhythmogenic cardiomyopathies, but also the possibility of GSK3β modulation as a novel therapeutic approach.

Parkinson Disease-Modification Encompassing Rotenone and 6-Hydroxydopamine Neurotoxicity by the Microtubule-Protecting Drug Candidate SKIP.

Encompassing live cell imaging and morphometrics at the microscopical level, we showed here, for the first time, protection of neuronal-like cells by thenovel drug candidate, SKIP, against the Parkinson's disease-related neurotoxin, rotenone. Mechanistically, rotenone disrupted microtubule dynamics,which SKIP partially repaired through microtubule end-binding proteins, coupled with increasing neurite branch length. Given the previous association ofrotenone toxicity with increased dopaminergic cell death hallmarking Parkinson's disease, we chose an established rat model of 6-hydroxydopamine (6-OHDA) toxicity to initially evaluate SKIP in vivo. SKIP pretreatment showed protection against nigral dopaminergic cell degeneration and improved motorbehavior in the forelimb asymmetry test. With Parkinson's disease being a major neurodegenerative disorder, afflicting millions of people globally, and withdisease modification challenges, SKIP may hold promise for future therapeutic development.

Introducing ADNP and SIRT1 as new partners regulating microtubules and histone methylation.

Activity-dependent neuroprotective protein (ADNP) is essential for brain formation and function. As such, de novo mutations in ADNP lead to the autistic ADNP syndrome and somatic ADNP mutations may drive Alzheimer's disease (AD) tauopathy. Sirtuin 1 (SIRT1) is positively associated with aging, the major risk for AD. Here, we revealed two key interaction sites for ADNP and SIRT1. One, at the microtubule end-binding protein (EB1 and EB3) Tau level, with EB1/EB3 serving as amplifiers for microtubule dynamics, synapse formation, axonal transport, and protection against tauopathy. Two, on the DNA/chromatin site, with yin yang 1, histone deacetylase 2, and ADNP, sharing a DNA binding motif and regulating SIRT1, ADNP, and EB1 (MAPRE1). This interaction was linked to sex- and age-dependent altered histone modification, associated with ADNP/SIRT1/WD repeat-containing protein 5, which mediates the assembly of histone modification complexes. Single-cell RNA and protein expression analyses as well as gene expression correlations placed SIRT1-ADNP and either MAPRE1 (EB1), MAPRE3 (EB3), or both in the same mouse and human cell; however, while MAPRE1 seemed to be similarly regulated to ADNP and SIRT1, MAPRE3 seemed to deviate. Finally, we demonstrated an extremely tight correlation for the gene transcripts described above, including related gene products. This correlation was specifically abolished in affected postmortem AD and Parkinson's disease brain select areas compared to matched controls, while being maintained in blood samples. Thus, we identified an ADNP-SIRT1 complex that may serve as a new target for the understanding of brain degeneration.

HIV-1 capsids mimic a microtubule regulator to coordinate early stages of infection.

While the microtubule end-binding protein, EB1 facilitates early stages of HIV-1 infection, how it does so remains unclear. Here, we show that beyond its effects on microtubule acetylation, EB1 also indirectly contributes to infection by delivering the plus-end tracking protein (+TIP), cytoplasmic linker protein 170 (CLIP170) to the cell periphery. CLIP170 bound to intact HIV-1 cores or invitro assembled capsid-nucleocapsid complexes, while EB1 did not. Moreover, unlike EB1 and several other +TIPs, CLIP170 enhanced infection independently of effects on microtubule acetylation. Capsid mutants and imaging revealed that CLIP170 bound HIV-1 cores in a manner distinct from currently known capsid cofactors, influenced by pentamer composition or curvature. Structural analyses revealed an EB-like +TIP-binding motif within the capsid major homology region (MHR) that binds SxIP motifs found in several +TIPs, and variability across this MHR sequence correlated with the extent to which different retroviruses engage CLIP170 to facilitate infection. Our findings provide mechanistic insights into the complex roles of +TIPs in mediating early stages of retroviral infection, and reveal divergent capsid-based EB1 mimicry across retroviral species.

Intrinsically Disordered Domain of Kinesin-3 Kif14 Enables Unique Functional Diversity

In addition to their force-generating motor domains, kinesin motor proteins feature various accessory domains enabling them to fulfill a variety of functions in the cell. Human kinesin-3, Kif14, localizes to the midbody of the mitotic spindle and is involved in the progression of cytokinesis. The specific motor properties enabling Kif14's cellular functions, however, remain unknown. Here, we show invitro that the intrinsically disordered N-terminal domain of Kif14 enables unique functional diversity of the kinesin. Using single molecule TIRF microscopy, we found that Kif14 exists either as a diffusible monomer or as processive dimer and that the disordered domain (1) enables diffusibility of the monomeric Kif14, (2) renders the dimeric Kif14 super-processive and enables the kinesin to pass through highly crowded areas, (3) enables robust, autonomous Kif14 tracking of growing microtubule tips, independent of microtubule end-binding (EB) proteins, and (4) is sufficient to enable crosslinking of parallel microtubules and necessary to enable Kif14-driven sliding of antiparallel ones. We explain these features of Kif14 by the observed diffusible interaction of the disordered domain with the microtubule lattice and the observed increased affinity of the disordered domain for GTP-bound tubulin. We suggest that the disordered domain tethers the motor domain to the microtubule providing a diffusible foothold and a regulatory hub, tuning the kinesin's interaction with microtubules. Our findings thus exemplify pliable protein tethering as a fundamental mechanism of molecular motor regulation.

NMR resonance assignment and structure prediction of the C-terminal domain of the microtubule end-binding protein 3.

End-binding proteins (EBs) associate with the growing microtubule plus ends to regulate microtubule dynamics as well as the interaction with intracellular structures. EB3 contributes to pathological vascular leakage through interacting with the inositol 1,4,5-trisphosphate receptor 3 (IP3R3), a calcium channel located at the endoplasmic reticulum membrane. The C-terminal domain of EB3 (residues 200-281) is functionally important for this interaction because it contains the effector binding sites, a prerequisite for EB3 activity and specificity. Structural data for this domain is limited. Here, we report the backbone chemical shift assignments for the human EB3 C-terminal domain and computationally explore its EB3 conformations. Backbone assignments, along with computational models, will allow future investigation of EB3 structural dynamics, interactions with effectors, and will facilitate the development of novel EB3 inhibitors.