Stable GDP-tubulin islands rescue dynamic microtubules.

Microtubules are dynamic polymers that interconvert between phases of growth and shrinkage, yet they provide structural stability to cells. Growth involves hydrolysis of GTP-tubulin to GDP-tubulin, which releases energy that is stored within the microtubule lattice and destabilizes it; a GTP cap at microtubule ends is thought to prevent GDP subunits from rapidly dissociating and causing catastrophe. Here, using in vitro reconstitution assays, we show that GDP-tubulin, usually considered inactive, can itself assemble into microtubules, preferentially at the minus end, and promote persistent growth. GDP-tubulin-assembled microtubules are highly stable, displaying no detectable spontaneous shrinkage. Strikingly, islands of GDP-tubulin within dynamic microtubules stop shrinkage events and promote rescues. Microtubules thus possess an intrinsic capacity for stability, independent of accessory proteins. This finding provides novel mechanisms to explain microtubule dynamics.

The mitotic role of adenomatous polyposis coli requires its bilateral interaction with tubulin and microtubules.

Adenomatous polyposis coli (APC) is a scaffold protein with tumour suppressor properties. Mutations causing the loss of its C-terminal domain (APC-C), which bears cytoskeleton-regulating sequences, correlate with colorectal cancer. The cellular roles of APC in mitosis are widely studied, but the molecular mechanisms of its interaction with the cytoskeleton are poorly understood. Here, we investigated how APC-C regulates microtubule properties, and found that it promotes both microtubule growth and shrinkage. Strikingly, APC-C accumulates at shrinking microtubule extremities, a common characteristic of depolymerases. Cryo-electron microscopy revealed that APC-C adopts an extended conformation along the protofilament crest and showed the presence of ring-like tubulin oligomers around the microtubule wall, which required the presence of two APC-C sub-domains. A mutant of APC-C that was incapable of decorating microtubules with ring-like tubulin oligomers exhibited a reduced effect on microtubule dynamics. Finally, whereas native APC-C rescued defective chromosome alignment in metaphase cells silenced for APC, the ring-incompetent mutant failed to correct mitotic defects. Thus, the bilateral interaction of APC-C with tubulin and microtubules likely contributes to its mitotic functions.

Peripheral astral microtubules ensure asymmetric furrow positioning in neural stem cells.

Neuroblast division is characterized by asymmetric positioning of the cleavage furrow, resulting in a large difference in size between the future daughter cells. In animal cells, furrow placement and assembly are governed by centralspindlin that accumulates at the equatorial cell cortex of the future cleavage site and at the spindle midzone. In neuroblasts, these two centralspindlin populations are spatially and temporally separated. A leading pool is located at the basal cleavage site and a second pool accumulates at the midzone before traveling to the cleavage site. The cortical centralspindlin population requires peripheral astral microtubules and the chromosome passenger complex for efficient recruitment. Loss of this pool does not prevent cytokinesis but enhances centralspindlin signaling at the midzone, leading to equatorial furrow repositioning and decreased size asymmetry. These data show that basal furrow positioning in neuroblasts results from a competition between different centralspindlin pools in which the cortical pool is dominant.

Adenomatous Polyposis Coli as a Scaffold for Microtubule End-Binding Proteins.

End-binding proteins (EBs), referred to as the core components of the microtubule plus-end tracking protein network, interact with the C-terminus of the adenomatous polyposis coli (APC) tumor suppressor. This interaction is disrupted in colon cancers expressing truncated APC. APC and EBs act in synergy to regulate microtubule dynamics during spindle formation, chromosome segregation and cell migration. Since EBs autonomously end-track microtubules and partially co-localize with APC at microtubule tips in cells, EBs have been proposed to direct APC to microtubule ends. However, the interdependency of EB and APC localization on microtubules remains elusive. Here, using in vitro reconstitution and single-molecule imaging, we have investigated the interplay between EBs and the C-terminal domain of APC (APC-C) on dynamic microtubules. Our results show that APC-C binds along the microtubule wall but does not accumulate at microtubule tips, even when EB proteins are present. APC-C was also found to enhance EB binding at the extremity of growing microtubules and on the microtubule lattice: APC-C promotes EB end-tracking properties by increasing the time EBs spend at microtubule growing ends, whereas a pool of EBs with a fast turnover accumulates along the microtubule surface. Overall, our results suggest that APC is a promoter of EB interaction with microtubules, providing molecular determinants to reassess the relationship between APC and EBs.

Tau can switch microtubule network organizations: from random networks to dynamic and stable bundles.

In neurons, microtubule networks alternate between single filaments and bundled arrays under the influence of effectors controlling their dynamics and organization. Tau is a microtubule bundler that stabilizes microtubules by stimulating growth and inhibiting shrinkage. The mechanisms by which tau organizes microtubule networks remain poorly understood. Here, we studied the self-organization of microtubules growing in the presence of tau isoforms and mutants. The results show that tau's ability to induce stable microtubule bundles requires two hexapeptides located in its microtubule-binding domain and is modulated by its projection domain. Site-specific pseudophosphorylation of tau promotes distinct microtubule organizations: stable single microtubules, stable bundles, or dynamic bundles. Disease-related tau mutations increase the formation of highly dynamic bundles. Finally, cryo-electron microscopy experiments indicate that tau and its variants similarly change the microtubule lattice structure by increasing both the protofilament number and lattice defects. Overall, our results uncover novel phosphodependent mechanisms governing tau's ability to trigger microtubule organization and reveal that disease-related modifications of tau promote specific microtubule organizations that may have a deleterious impact during neurodegeneration.

A TIRF microscopy assay to decode how tau regulates EB's tracking at microtubule ends.

Tau is a major microtubule-associated protein (MAP) mainly expressed in the brain. Tau binds the lattice of microtubules and favors their elongation and bundling. Recent studies have shown that tau is also a partner of end-binding proteins (EBs) in neurons. EBs belong to the protein family of the plus-end tracking proteins that preferentially associate with the growing plus-ends of microtubules and control microtubule end behavior and anchorage to intracellular organelles. Reconstituted cell-free systems using purified proteins are required to understand the precise mechanisms by which tau influences EB localization on microtubules and how the concerted activity of these two MAPs modulates microtubule dynamics. We developed an in vitro assay combining TIRF microscopy and site-directed mutagenesis to dissect the interaction of tau with EBs and to study how this interaction affects microtubule dynamics. Here, we describe the detailed procedures to purify proteins (tubulin, tau, and EBs), prepare the samples for TIRF microscopy, and analyze microtubule dynamics, and EB binding at microtubule ends in the presence of tau.

TIRF assays for real-time observation of microtubules and actin coassembly: Deciphering tau effects on microtubule/actin interplay.

Microtubule and actin cytoskeletons are key players in vital processes in cells. Although the importance of microtubule-actin interaction for cell development and function has been highlighted for years, the properties of these two cytoskeletons have been mostly studied separately. Thus we now need procedures to simultaneously assess actin and microtubule properties to decipher the basic mechanisms underlying microtubule-actin crosstalk. Here we describe an in vitro assay that allows the coassembly of both filaments and the real-time observation of their interaction by TIRF microscopy. We show how this assay can be used to demonstrate that tau, a neuronal microtubule-associated protein, is a bona fide actin-microtubule cross-linker. The procedure relies on the use of highly purified proteins and chemically passivated perfusion chambers. We present a step-by-step protocol to obtain actin and microtubule coassembly and discuss the major pitfalls. An ImageJ macro to quantify actin and microtubule interaction is also provided.

Tau antagonizes end-binding protein tracking at microtubule ends through a phosphorylation-dependent mechanism.

Proper regulation of microtubule dynamics is essential for cell functions and involves various microtubule-associated proteins (MAPs). Among them, end-binding proteins (EBs) accumulate at microtubule plus ends, whereas structural MAPs bind along the microtubule lattice. Recent data indicate that the structural MAP tau modulates EB subcellular localization in neurons. However, the molecular determinants of EB/tau interaction remain unknown, as is the effect of this interplay on microtubule dynamics. Here we investigate the mechanisms governing EB/tau interaction in cell-free systems and cellular models. We find that tau inhibits EB tracking at microtubule ends. Tau and EBs form a complex via the C-terminal region of EBs and the microtubule-binding sites of tau. These two domains are required for the inhibitory activity of tau on EB localization to microtubule ends. Moreover, the phosphomimetic mutation S262E within tau microtubule-binding sites impairs EB/tau interaction and prevents the inhibitory effect of tau on EB comets. We further show that microtubule dynamic parameters vary, depending on the combined activities of EBs and tau proteins. Overall our results demonstrate that tau directly antagonizes EB function through a phosphorylation-dependent mechanism. This study highlights a novel role for tau in EB regulation, which might be impaired in neurodegenerative disorders.

Negative regulation of EB1 turnover at microtubule plus ends by interaction with microtubule-associated protein ATIP3.

The regulation of microtubule dynamics is critical to ensure essential cell functions. End binding protein 1 (EB1) is a master regulator of microtubule dynamics that autonomously binds an extended GTP/GDP-Pi structure at growing microtubule ends and recruits regulatory proteins at this location. However, negative regulation of EB1 association with growing microtubule ends remains poorly understood. We show here that microtubule-associated tumor suppressor ATIP3 interacts with EB1 through direct binding of a non-canonical proline-rich motif. Results indicate that ATIP3 does not localize at growing microtubule ends and that in situ ATIP3-EB1 molecular complexes are mostly detected in the cytosol. We present evidence that a minimal EB1-interacting sequence of ATIP3 is both necessary and sufficient to prevent EB1 accumulation at growing microtubule ends in living cells and that EB1-interaction is involved in reducing cell polarity. By fluorescence recovery of EB1-GFP after photobleaching, we show that ATIP3 silencing accelerates EB1 turnover at microtubule ends with no modification of EB1 diffusion in the cytosol. We propose a novel mechanism by which ATIP3-EB1 interaction indirectly reduces the kinetics of EB1 exchange on its recognition site, thereby accounting for negative regulation of microtubule dynamic instability. Our findings provide a unique example of decreased EB1 turnover at growing microtubule ends by cytosolic interaction with a tumor suppressor.

Tau co-organizes dynamic microtubule and actin networks.

The crosstalk between microtubules and actin is essential for cellular functions. However, mechanisms underlying the microtubule-actin organization by cross-linkers remain largely unexplored. Here, we report that tau, a neuronal microtubule-associated protein, binds to microtubules and actin simultaneously, promoting in vitro co-organization and coupled growth of both networks. By developing an original assay to visualize concomitant microtubule and actin assembly, we show that tau can induce guided polymerization of actin filaments along microtubule tracks and growth of single microtubules along actin filament bundles. Importantly, tau mediates microtubule-actin co-alignment without changing polymer growth properties. Mutagenesis studies further reveal that at least two of the four tau repeated motifs, primarily identified as tubulin-binding sites, are required to connect microtubules and actin. Tau thus represents a molecular linker between microtubule and actin networks, enabling a coordination of the two cytoskeletons that might be essential in various neuronal contexts.

The serine protease domain of MASP-3: enzymatic properties and crystal structure in complex with ecotin.

Mannan-binding lectin (MBL), ficolins and collectin-11 are known to associate with three homologous modular proteases, the MBL-Associated Serine Proteases (MASPs). The crystal structures of the catalytic domains of MASP-1 and MASP-2 have been solved, but the structure of the corresponding domain of MASP-3 remains unknown. A link between mutations in the MASP1/3 gene and the rare autosomal recessive 3MC (Mingarelli, Malpuech, Michels and Carnevale,) syndrome, characterized by various developmental disorders, was discovered recently, revealing an unexpected important role of MASP-3 in early developmental processes. To gain a first insight into the enzymatic and structural properties of MASP-3, a recombinant form of its serine protease (SP) domain was produced and characterized. The amidolytic activity of this domain on fluorescent peptidyl-aminomethylcoumarin substrates was shown to be considerably lower than that of other members of the C1r/C1s/MASP family. The E. coli protease inhibitor ecotin bound to the SP domains of MASP-3 and MASP-2, whereas no significant interaction was detected with MASP-1, C1r and C1s. A tetrameric complex comprising an ecotin dimer and two MASP-3 SP domains was isolated and its crystal structure was solved and refined to 3.2 Å. Analysis of the ecotin/MASP-3 interfaces allows a better understanding of the differential reactivity of the C1r/C1s/MASP protease family members towards ecotin, and comparison of the MASP-3 SP domain structure with those of other trypsin-like proteases yields novel hypotheses accounting for its zymogen-like properties in vitro.

Biochemical and structural study of the homologues of the thiol-disulfide oxidoreductase DsbA in Neisseria meningitidis.

Bacterial virulence depends on the correct folding of surface-exposed proteins, a process catalyzed by the thiol-disulfide oxidoreductase DsbA, which facilitates the synthesis of disulfide bonds in Gram-negative bacteria. The Neisseria meningitidis genome possesses three genes encoding active DsbAs: DsbA1, DsbA2 and DsbA3. DsbA1 and DsbA2 have been characterized as lipoproteins involved in natural competence and in host interactive biology, while the function of DsbA3 remains unknown. This work reports the biochemical characterization of the three neisserial enzymes and the crystal structures of DsbA1 and DsbA3. As predicted by sequence homology, both enzymes adopt the classic Escherichia coli DsbA fold. The most striking feature shared by all three proteins is their exceptional oxidizing power. With a redox potential of -80 mV, the neisserial DsbAs are the most oxidizing thioredoxin-like enzymes known to date. Consistent with these findings, thermal studies indicate that their reduced form is also extremely stable. For each of these enzymes, this study shows that a threonine residue found within the active-site region plays a key role in dictating this extraordinary oxidizing power. This result highlights how residues located outside the CXXC motif may influence the redox potential of members of the thioredoxin family.

Engineering a G protein-coupled receptor for structural studies: stabilization of the BLT1 receptor ground state.

Structural characterization of membrane proteins is hampered by their instability in detergent solutions. We modified here a G protein-coupled receptor, the BLT1 receptor of leukotriene B(4), to stabilize it in vitro. For this, we introduced a metal-binding site connecting the third and sixth transmembrane domains of the receptor. This modification was intended to restrain the activation-associated relative movement of these helices that results in a less stable packing in the isolated receptor. The modified receptor binds its agonist with low-affinity and can no longer trigger G protein activation, indicating that it is stabilized in its ground state conformation. Of importance, the modified BLT1 receptor displays an increased temperature-, detergent-, and time-dependent stability compared with the wild-type receptor. These data indicate that stabilizing the ground state of this GPCR by limiting the activation-associated movements of the transmembrane helices is a way to increase its stability in detergent solutions; this could represent a forward step on the way of its crystallization.

Crystal structure of the IrrE protein, a central regulator of DNA damage repair in deinococcaceae.

Deinococcaceae are famous for their extreme radioresistance. Transcriptome analysis in Deinococcus radiodurans revealed a group of genes up-regulated in response to desiccation and ionizing radiation. IrrE, a novel protein initially found in D. radiodurans, was shown to be a positive regulator of some of these genes. Deinococcus deserti irrE is able to restore radioresistance in a D. radiodurans DeltairrE mutant. The D. deserti IrrE crystal structure reveals a unique combination of three domains: one zinc peptidase-like domain, one helix-turn-helix motif and one GAF-like domain. Mutant analysis indicates that the first and third domains are critical regions for radiotolerance. In particular, mutants affected in the putative zinc-binding site are as sensitive to gamma and UV irradiation as the DeltairrE bacteria, and radioresistance is strongly decreased with the H217L mutation present in the C-terminal domain. In addition, modeling of IrrE-DNA interaction suggests that the observed IrrE structure may not bind double-stranded DNA through its central helix-turn-helix motif and that IrrE is not a classic transcriptional factor that activates gene expression by its direct binding to DNA. We propose that the putative protease activity of IrrE could be a key element of transcription enhancement and that a more classic transcription factor, possibly an IrrE substrate, would link IrrE to transcription of genes specifically involved in radioresistance.

AdcAII, a new pneumococcal Zn-binding protein homologous with ABC transporters: biochemical and structural analysis.

Regulation of metal homeostasis is vital for pathogenic bacteria facing drastic metal concentration changes in various locations within the host during invasion. Metal-binding receptors (MBRs), one of the extracellular components of ATP-binding cassette transporters, have been shown to be essential in this process. Streptococcus pneumoniae expresses two characterized MBRs: PsaA and AdcA, two extracellular lipoproteins encoded by the psaABCD and adcRCBA operons, respectively. The Mn- and Zn-uptake functions of PsaA and AdcA, respectively, have been well established. Here we describe AdcAII as a third putative S. pneumoniae MBR. The analysis of a phylogenetic tree built from the sequence alignment of 68 proteins reveals a subgroup of members displaying an unusual genetic operon organisation. The adcAII gene belongs to a 6670-nucleotide-long transcript spanning the spr0903 to spr0907 loci encoding for the CcdA, thioredoxine, YfnA, AdcAII and PhtD proteins. Two adjacent repeats of imperfect AdcR-binding consensus sequence were identified upstream of the adcAII gene, suggesting a transcriptional co-regulation of adcAII and phtD genes. Biophysical and structural studies of recombinant AdcAII were performed to identify the metal specificity of the protein. Using electrospray mass spectrometry in native conditions, we found that Zn was bound to recombinant AdcAII. Screening of the effect of 10 cationic ions on the thermal stability of AdcAII revealed that Zn had the most pronounced stabilizing effect. The crystal structure of AdcAII has been solved to 2.4 A resolution. One Zn ion is bound to each AdcAII molecule in a symmetrical active site composed of three His and one Glu. The structure almost perfectly superimposed on the known MBR structures. The presence of a flexible 15-residue-long loop close to the metal-binding site is specific to those specialized in Zn transport. Taken together, these functional and structural data provide new perspectives related to the physiological role of AdcAII in pneumococcus Zn homeostasis.

Complex oligomeric structure of a truncated form of DdrA: a protein required for the extreme radiotolerance of Deinococcus.

In order to preserve their genome integrity, organisms have developed elaborate tactics for genome protection and repair. The Deinococcus radiodurans bacteria famous for their extraordinary tolerance toward high doses of radiations or long period of desiccation, possess some specific genes with unknown function which are related to their survival in such extreme conditions. Among them, ddrA is an orphan gene specific of Deinococcus genomes. DdrA, the product of this gene was suggested to be a component of the DNA end protection system. Here we provide a three-dimensional reconstruction of the Deinococcus deserti DdrA((1-160)) by electron microscopy. Although not functional in vivo, this truncated protein keeps its DNA binding ability at the wild-type level. DdrA((1-160)) has a complex three-dimensional structure based on a heptameric ring that can self-associate to form a larger molecular weight assembly. We suggest that the complex architecture of DdrA plays a role in the substrate specificity and favors an efficient DNA repair.

Preliminary crystallographic data of the three homologues of the thiol-disulfide oxidoreductase DsbA in Neisseria meningitidis.

Bacterial virulence depends on the correct folding of surface-exposed proteins, a process that is catalyzed by the thiol-disulfide oxidoreductase DsbA, which facilitates the synthesis of disulfide bonds in Gram-negative bacteria. Uniquely among bacteria, the Neisseria meningitidis genome possesses three genes encoding active DsbAs: DsbA1, DsbA2 and DsbA3. DsbA1 and DsbA2 have been characterized as lipoproteins involved in natural competence and in host-interactive biology, while the function of DsbA3 remains unknown. In an attempt to shed light on the reason for this multiplicity of dsbA genes, the three enzymes from N. meningitidis have been purified and crystallized in the presence of high concentrations of ammonium sulfate. The best crystals were obtained using DsbA1 and DsbA3; they belong to the orthorhombic and tetragonal systems and diffract to 1.5 and 2.7 A resolution, respectively.

New tensio-active molecules stabilize a human G protein-coupled receptor in solution.

Structural characterization of membrane proteins is hampered by the instability of the isolated proteins in detergent solutions. Here, we describe a new class of phospholipid-like surfactants that stabilize the G protein-coupled receptor, BLT1. These compounds, called C(13)U(9), C(13)U(19), C(15)U(25) and C(17)U(16), were synthesized by radical polymerization of Tris(hydroxymethyl) acrylamidomethane in the presence of thioglycerol, first endowed with two hydrocarbon chains with variable lengths (13-17 carbon atoms), as transfer reagent. C(13)U(19), C(17)U(16) or C(15)U(25) significantly enhanced the stability of BLT1 in solution compared to what was obtained with common detergents. These molecules therefore represent a promising step towards the structural characterization of BLT1 and possibly other membrane proteins.

Functional flexibility of Bacillus stearothermophilus formamidopyrimidine DNA-glycosylase.

The formamidopyrimidine-DNA glycosylase (Fpg) recognizes and eliminates efficiently 8-oxoguanine, an abundant mutagenic DNA lesion. The X-ray structure of the inactive E3Q mutant of Fpg from Bacillus stearothermophilus, complexed to an 8-oxoG-containing DNA, revealed a small peptide (called the alphaF-beta10 loop) involved in the recognition of the lesion via an interaction with the protonated N(7) atom. This region, which is disordered in the X-ray models where an abasic site-containing DNA is bound to Fpg, interacts tightly with the 8-oxoG which appears to be confined within the enzyme. Molecular dynamics simulations were performed on this mutant and the wild type derived model at 298 and 323K, to determine if this tight assembly around the 8-oxoG was due to the mutation and/or to an inappropriate experimental temperature. Differences in the relative orientation of the protein structural domains and in the architecture around the damaged base were observed, depending on the presence of the mutation and/or on the temperature. This data allowed us to show that the recognition of the damaged base by the wild type enzyme close to its optimal temperature might require significant movements of the enzyme, leading to conformational changes that could not be detected within the only X-ray structure. In addition, a dynamics performed with a normal guanine suggests that the alphaF-beta10 loop dynamics could be needed by the active Fpgs to distinguish a damaged guanine from a normal nucleotide.

Structural insights into abasic site for Fpg specific binding and catalysis: comparative high-resolution crystallographic studies of Fpg bound to various models of abasic site analogues-containing DNA.

Fpg is a DNA glycosylase that recognizes and excises the mutagenic 8-oxoguanine (8-oxoG) and the potentially lethal formamidopyrimidic residues (Fapy). Fpg is also associated with an AP lyase activity which successively cleaves the abasic (AP) site at the 3' and 5' sides by betadelta-elimination. Here, we present the high-resolution crystal structures of the wild-type and the P1G defective mutant of Fpg from Lactococcus lactis bound to 14mer DNA duplexes containing either a tetrahydrofuran (THF) or 1,3-propanediol (Pr) AP site analogues. Structures show that THF is less extrahelical than Pr and its backbone C5'-C4'-C3' diverges significantly from those of Pr, rAP, 8-oxodG and FapydG. Clearly, the heterocyclic oxygen of THF is pushed back by the carboxylate of the strictly conserved E2 residue. We can propose that the ring-opened form of the damaged deoxyribose is the structure active form of the sugar for Fpg catalysis process. Both structural and functional data suggest that the first step of catalysis mediated by Fpg involves the expulsion of the O4' leaving group facilitated by general acid catalysis (involving E2), rather than the immediate cleavage of the N-glycosic bond of the damaged nucleoside.