Structural insight into microtubule function

Do beta-tubulin mutations have a role in resistance to chemotherapy?

beta-tubulin is the target of various antitubulin agents used in the treatment of cancer. After beta tubulin was shown to confer resistance to antitubulin agents in established cell lines, several studies have investigated the DNA sequence of this compound in clinical samples. However, these findings are highly controversial, since sequencing experiments showed that the original clinical observation of mutations in the gene resulted from inclusion of non-functional beta-tubulin pseudogenes. At least nine such pseudogenes are known, and all share substantial sequence homology with the functional gene. Subsequent studies have concluded that beta-tubulin mutations in clinical samples are rare, and unlikely to contribute to drug resistance. Here, we overview the beta-tubulin gene family and summarise the results of studies done comparing beta-tubulin mutations with antitubulin drug resistance.

Microtubule inhibitory effects of various SJ compounds on tissue culture cells

SJ compounds (SJ8002 and related compounds) are a group of novel anticancer agents (Cho, Chung, Lee, Kwon, Kang, Joo, and Oh. PCT/KR02/00392). To explore the anticancer mechanism of these compounds, we examined the effect of SJ8002 on microtubules of six human cell lines. At a high concentration (2 microg/mL), SJ8002 effectively disrupted microtubules of the six cell lines within 1 h. At lower concentrations (0.05 to approximately 1.0 microg/mL), the antimicrotubule activity of SJ8002 varied defending on cell lines. The inhibition of in vitro polymerization of pure tubulin by SJ8002 suggested that SJ8002 acts on free tubulin, inhibits the polymerization of tubulin dimer into microtubules, and hence induces the depolymerization of microtubules.

Disorazol A1, a highly effective antimitotic agent acting on tubulin polymerization and inducing apoptosis in mammalian cells

Disorazol A1, a macrocyclic polyketide compound that is produced by the myxobacterium Sorangium cellulosum showed a remarkably high cytostatic activity. It inhibited the proliferation of different cancer cell lines including a multidrug-resistant KB line at low picomolar levels. In presence of disorazol A1, the nuclei of the cells increased in size and the cells often became multinucleate. Low concentrations of disorazol (<100 pM) induced an apoptotic process, characterized by enhanced capase-3 activity and DNA laddering, and abnormal, multipolar mitotic spindles. Low concentrations also induced an accumulation of p53 protein in the nucleus. At higher concentrations, we observed an accumulation of the cells in the G2/M-phase of the cell cycle, and a depletion of microtubules. In vitro, disorazol A1 inhibited the polymerization of tubulin in a concentration-dependent manner and independently of microtubule-associated proteins. Correspondingly it induced a complete depolymerization of microtubules prepared in vitro. Formation of defined degradation structures was not observed. Disorazol is a novel, highly effective antimitotic agent. Efforts are going on to develop it as an anticancer drug.

Complex formation with kinesin motor domains affects the structure of microtubules

Microtubules are highly dynamic components of the cytoskeleton. They are important for cell movement and they are involved in a variety of transport processes together with motor proteins, such as kinesin. The exact mechanism of these transport processes is not known and so far the focus has been on structural changes within the motor domains, but not within the underlying microtubule structure. Here we investigated the interaction between kinesin and tubulin and our experimental data show that microtubules themselves are changing structure during that process. We studied unstained, vitrified samples of microtubules composed of 15 protofilaments using cryo electron microscopy and helical image analysis. 3D maps of plain microtubules and microtubules decorated with kinesin have been reconstructed to approximately 17A resolution. The alphabeta-tubulin dimer could be identified and, according to our data, alpha- and beta-tubulin adopt different conformations in plain microtubules. Significant differences were detected between maps of plain microtubules and microtubule-kinesin complexes. Most pronounced is the continuous axial inter-dimer contact in the microtubule-kinesin complex, suggesting stabilized protofilaments along the microtubule axis. It seems, that mainly structural changes within alpha-tubulin are responsible for this observation. Lateral effects are less pronounced. Following our data, we believe, that microtubules play an active role in intracellular transport processes through modulations of their core structure.

Meiosis-specific failure of cell cycle progression in fission yeast by mutation of a conserved beta-tubulin residue

The microtubule cytoskeleton is involved in regulation of cell morphology, differentiation, and cell cycle progression. Precisely controlled dynamic properties are required for these microtubule functions. To better understand how tubulin's dynamics are embedded in its primary sequence, we investigated in vivo the consequences of altering a single, highly conserved residue in beta-tubulin that lies at the interface between two structural domains. The residue differs between the cold-adapted Antarctic fish and temperate animals in a manner that suggests a role in microtubule stability. Fungi, like the Antarctic fish, have a phenylalanine in this position, whereas essentially all other animals have tyrosine. We mutated the corresponding residue in fission yeast to tyrosine. Temperature effects were subtle, but time-lapse microscopy of microtubule dynamics revealed reduced depolymerization rates and increased stability. Mitotic exit signaled by breakdown of the mitotic spindle was delayed. In meiosis, microtubules displayed prolonged contact to the cell cortex during horsetail movement, followed by completion of meiosis I but frequent asymmetric failure of meiosis II spindle formation. Our results indicate that depolymerization dynamics modulated through interdomain motion may be important for regulating a subset of plus-end microtubule complexes in Schizosaccharomyces pombe.

Identification of human SEP1 as a glial cell line-derived neurotrophic factor-inducible protein and its expression in the nervous system

Glial cell line-derived neurotrophic factor (GDNF) signals through multisubunit receptor complex consisting of RET tyrosine kinase and a glycosylphosphatidylinositol-anchored coreceptor called GDNF family receptor alpha1 (GFRalpha1). In the current study, we cloned a human SEP1 gene as a GDNF-inducible gene using human neuroblastoma cells that express RET and GFRalpha1. The induction of the SEP1 gene showed two peaks at 0.5-2 h and 24-48 h after GDNF stimulation by Northern blotting and quantitative real-time reverse transcriptase polymerase chain reaction. The late induction was also confirmed at protein levels by Western blotting with anti-SEP1 antibody. Immunostaining revealed that the expression of the SEP1 protein was detected in cell body, elongated neurites and growth cone-like structure of neuroblastoma cells treated with GDNF. In addition, we found a high level of SEP1 expression in neurons of the dorsal root and superior cervical ganglia and motor neurons of the spinal cord of mice in which RET is also expressed. SEP1 was co-immunoprecipitated with alpha- and beta-tubulins from the lysate of mouse brain. These results thus suggested that SEP1 is a GDNF-inducible and microtubule-associated protein that may play a role in the nervous system.

The minus end in sight

Microtubules are intrinsically polar structures. A consequence of this polarity is that the two ends of the microtubule polymer exhibit different properties. The more dynamic plus ends and the mechanisms that regulate their behavior have been the focus of much recent attention. Here, we concentrate on the dynamics and regulation of minus ends, which play distinct but equally critical roles in microtubule function. In the first part of this review, we compare the in vitro and in vivo behavior of microtubules from a minus end perspective. This comparison suggests that cells possess conserved mechanisms to specifically inhibit minus end polymerization, and perhaps also to actively promote depolymerization. In the second part, we focus on the spatial positioning of minus ends, which is achieved by localized microtubule nucleation, minus end capping and minus end anchoring as well as by motor-dependent sorting. These mechanisms are used in different biological contexts to generate the diversity of organized microtubule arrays in cells.

2-methoxyestradiol alters cell motility, migration, and adhesion

The effect of 2-methoxyestradiol, 2ME2, an endogenous metabolite of 17beta-estradiol (E2), on cell growth and cytoskeletal functions in a BCR-ABL-transformed cell line model was investigated. We determined the interaction of 2ME2 with STI571 (Gleevec, imatinib mesylate) in STI571 drug-sensitive and -resistant cell lines. In cells expressing BCR-ABL, STI571 cooperated with 2ME2 in reducing cell growth, and STI571-resistant cells were sensitive to 2ME2 treatment. 2ME2 also inhibited growth of several cancer cell lines by a mechanism independent of BCR-ABL. BCR-ABL transformation leads to altered motility, increased adhesion, and spontaneous migration in different in vitro model systems. 2ME2 was found to specifically inhibit the spontaneous motility of BCRABL-transformed Ba/F3 cells and to change the morphology and volume of treated cells. Cells attached to fibronectin-coated surfaces showed a reduced number of filipodia and lamellipodia. In addition, 2ME2 significantly reduced BCRABL-mediated adhesion to fibronectin. The spontaneous migration of BCR-ABL-transformed cells through a transwell membrane also was found to be significantly decreased by 2ME2. Cytoskeletal changes were accompanied by alteration of tubulin formation, distinct from paclitaxel treatment. These results demonstrate that 2ME2 treatment of transformed cells strongly reduces cytoskeletal functions and may also be useful for the treatment of cancers with high metastatic potential. Combination of 2ME2 with other anticancer drugs may be beneficial to treatment of drug-resistant cancers.

The DCX-domain tandems of doublecortin and doublecortin-like kinase

The doublecortin-like domains (DCX), which typically occur in tandem, are novel microtubule-binding modules. DCX tandems are found in doublecortin, a 360-residue protein expressed in migrating neurons; the doublecortin-like kinase (DCLK); the product of the RP1 gene that is responsible for a form of inherited blindness; and several other proteins. Mutations in the gene encoding doublecortin cause lissencephaly in males and the 'double-cortex syndrome' in females. We here report a solution structure of the N-terminal DCX domain of human doublecortin and a 1.5 A resolution crystal structure of the equivalent domain from human DCLK. Both show a stable, ubiquitin-like tertiary fold with distinct structural similarities to GTPase-binding domains. We also show that the C-terminal DCX domains of both proteins are only partially folded. In functional assays, the N-terminal DCX domain of doublecortin binds only to assembled microtubules, whereas the C-terminal domain binds to both microtubules and unpolymerized tubulin.

Autonomous and phosphorylation-responsive microtubule-regulating activities of the N-terminus of Op18/stathmin

Op18 is the prototypical member of a family of phosphorylation-responsive regulators of microtubule (MT) dynamics. Previous dissection of Op18 has suggested that it has a functional dichotomy in which an intact N-terminus is required for catastrophe promotion (i.e. transition from growing to shrinking MTs), whereas an intact C-terminus is required for efficient ternary Op18-tubulin complex formation and the resultant tubulin-sequestering activity. Here we have expressed and functionally analyzed the properties of the N-terminus of Op18. The data show that the N-terminal 57 residues are sufficient for low-affinity tubulin interactions, as shown by inhibition of basal GTP hydrolysis of soluble heterodimers. In addition, high concentrations of the Op18 N-terminal portion increased the catastrophe rate during MT assembly in vitro. Overexpression of the N-terminus in a human cell line results in MT destabilization in interphase and phosphorylation-modulated accumulation of metaphase-arrested cells with dense short MTs. These results demonstrate that the N-terminus of Op18 has autonomous activity. Evidently, this activity is enhanced by the increase in tubulin affinity that is provided by the extended alpha-helical portion of native Op18.

The role of the cytoskeleton in the life cycle of viruses and intracellular bacteria: tracks, motors, and polymerization machines

Recent advances in microbiology implicate the cytoskeleton in the life cycle of some pathogens, such as intracellular bacteria, Rickettsia and viruses. The cellular cytoskeleton provides the basis for intracellular movements such as those that transport the pathogen to and from the cell surface to the nuclear region, or those that produce cortical protrusions that project the pathogen outwards from the cell surface towards an adjacent cell. Transport in both directions within the neuron is required for pathogens such as the herpesviruses to travel to and from the nucleus and perinuclear region where replication takes place. This trafficking is likely to depend on cellular motors moving on a combination of microtubule and actin filament tracks. Recently, Bearer et al. reconstituted retrograde transport of herpes simplex virus (HSV) in the giant axon of the squid. These studies identified the tegument proteins as the viral proteins most likely to recruit retrograde motors for the transport of HSV to the neuronal nucleus. Similar microtubule-based intracellular movements are part of the biological behavior of vaccinia, a poxvirus, and of adenovirus. Pathogen-induced surface projections and motility within the cortical cytoplasm also play a role in the life cycle of intracellular pathogens. Such motility is driven by pathogen-mediated actin polymerization. Virulence depends on this actin-based motility, since virulence is reduced in Listeria ActA mutants that lack the ability to recruit Arp2/3 and polymerize actin and in vaccinia virus mutants that cannot stimulate actin polymerization. Inhibition of intracellular movements provides a potential strategy to limit pathogenicity. The host cell motors and tracks, as well as the pathogen factors that interact with them, are potential targets for novel antimicrobial therapy.

Cloning and characterization of the 5'-flanking region of the rat neuron-specific Class III beta-tubulin gene

The promoter regions of several neuron-specific structural proteins (e.g. neurofilaments, peripherin, Talpha1-tubulin) have revealed potential regulatory elements that could contribute to the choice of a neuronal phenotype during development. We initiated study of the 5'-flanking region of the rat Class III neuron-specific beta-tubulin gene (betaIII-tubulin) because this gene is expressed at the time of terminal mitosis only in neurons and thus its promoter should be an excellent tool for studying neuron-specific gene expression during the transition from proliferative progenitor cell to early neuronal differentiation. We identified the minimal promoter region needed to drive expression of the betaIII-tubulin gene. This minimal region contains multiple putative binding sites for the transcription factors SP1 and AP2, as well as a central nervous system enhancer regulatory element and an E-box. A primer extension analysis identifies a single transcription start site. We highlight several putative regulatory elements that may modulate the expression of the betaIII-tubulin gene in a stage- and tissue-specific manner. In addition, we show that the first 490 bp of the promoter are sufficient to regulate betaIII-tubulin gene expression during neuronal differentiation of PCC7 cells.

Hsp70 and thermal pretreatment mitigate developmental damage caused by mitotic poisons in Drosophila

To assess the ability of the heat-inducible molecular chaperone heat-shock protein 70 (Hsp70) to mitigate a specific developmental lesion, we administered the antimicrotubule drugs vinblastine (VB) and colchicine (COL) to larvae of Drosophila engineered to express differing levels of Hsp70 after heat pretreatment (HP). VB and COL decreased survival during metamorphosis, disrupted development of the adult eye and other structures as well as their precursor imaginal disks, and induced chromosome nondisjunction in the wing imaginal disk as indicated by the somatic mutation and recombination test (SMART) assay. Hsp70-inducing HP reduced many of these effects. For the traits viability, adult eye morphology, eye imaginal disk morphology, cell death in the eye imaginal disks, and single and total mutant clone formation in the SMART assay, HP reduced the impact of VB to a greater extent in Drosophila with 6 hsp70 transgenes than in a sister strain from which the transgenes had been excised. Because the extra-copy strain has higher levels of Hsp70 than does the excision strain but is otherwise almost identical in genetic background to the excision strain, these outcomes are attributable to Hsp70. The hsp70 copy number had a variable interaction with HP and COL administration.