Sensory neuropathy in progressive motor neuronopathy (pmn) mice is associated with defects in microtubule polymerization and axonal transport

Motor neuron diseases such as amyotrophic lateral sclerosis (ALS) are now recognized as multi‐system disorders also involving various non‐motor neuronal cell types. The precise extent and mechanistic basis of non‐motor neuron damage in human ALS and ALS animal models remain however unclear. To address this, we here studied progressive motor neuronopathy (pmn) mice carrying a missense loss‐of‐function mutation in tubulin binding cofactor E (TBCE). These mice manifest a particularly aggressive form of motor axon dying back and display a microtubule loss, similar to that induced by human ALS‐linked TUBA4A mutations. Using whole nerve confocal imaging of pmn × thy1.2‐YFP16 fluorescent reporter mice and electron microscopy, we demonstrate axonal discontinuities, bead‐like spheroids and ovoids in pmn suralis nerves indicating prominent sensory neuropathy. The axonal alterations qualitatively resemble those in phrenic motor nerves but do not culminate in the loss of myelinated fibers. We further show that the pmn mutation decreases the level of TBCE, impedes microtubule polymerization in dorsal root ganglion (DRG) neurons and causes progressive loss of microtubules in large and small caliber suralis axons. Live imaging of axonal transport using GFP‐tagged tetanus toxin C‐fragment (GFP‐TTC) demonstrates defects in microtubule‐based transport in pmn DRG neurons, providing a potential explanation for the axonal alterations in sensory nerves. This study unravels sensory neuropathy as a pathological feature of mouse pmn, and discusses the potential contribution of cytoskeletal defects to sensory neuropathy in human motor neuron disease.     

The nuclear mitotic apparatus (NuMA) protein: localization and dynamics in human oocytes, fertilization and early embryos

The oocyte's meiotic spindle is a dynamic structure that relies on microtubule organization and regulation by centrosomes. Disorganization of centrosomal proteins, including the nuclear mitotic apparatus (NuMA) protein and the molecular motor complex dynein/dynactin, can lead to chromosomal instability and developmental abnormalities. The present study reports the distribution and function of these proteins in human oocytes, zygotes and early embryos. A total of 239 oocytes, 90 zygotes and discarded embryos were fixed and analyzed with confocal microscopy for NuMA and dynactin distribution together with microtubules and chromatin. Microtubule-associated dynein-dependent transport functions were explored by inhibiting phosphatase and ATPase activity with sodium-orthovanadate (SOV). At germinal vesicle (GV) stages, NuMA was dispersed across the nucleoplasm. After GV breaks down, NuMA became cytoplasmic before localizing at the spindle poles in metaphase I and II oocytes. Aberrant NuMA localization patterns were found during oocyte in vitro maturation. After fertilization, normal and abnormal pronuclear stage zygotes and embryos displayed translocation of NuMA to interphase nuclei. SOV treatment for up to 2 h induced lower maturation rates with chromosomal scattering and ectopic localization of NuMA. Accurate distribution of NuMA is important for oocyte maturation, zygote and embryo development in humans. Proper assembly of NuMA is likely necessary for bipolar spindle organization and human oocyte developmental competence.     

The ribosomal protein L10/QM-like protein is a component of the NIK-mediated antiviral signaling

The NIK (NSP-interacting kinase)-mediated antiviral signaling pathway was identified as a virulence target of the begomovirus nuclear shuttle protein (NSP). Here, we further characterized this layer of plant innate defense by identifying the ribosomal protein L10 (rpL10), a QM-like protein, as a downstream effector of the antiviral signaling. Although both ribosomal proteins rpL10 and rpL18 were found to associate with NIK1 through yeast two-hybrid screening, the NIK receptors specifically phosphorylated rpL10 in vitro. Furthermore, loss of rpL10 function significantly increased susceptibility to begomovirus infection, recapitulating the phenotype of nik knockout lines. Our results genetically linked rpL10 to the NIK-mediated antiviral signaling.     

Microtubule-binding protein CLIP-170 is a mediator of paclitaxel sensitivity

CLIP-170 is a microtubule-binding protein and participates in diverse microtubule-associated cellular activities by regulating microtubule dynamics. Here we provide evidence that CLIP-170 is a mediator of the sensitivity of the anti-microtubule drug paclitaxel in breast cancer. In vitro cell proliferation assays reveal that CLIP-170 expression in breast cancer cell lines correlates with their sensitivity to paclitaxel. In addition, CLIP-170 expression in clinical samples of breast cancer correlates with the pathological response of tumours to paclitaxel-containing chemotherapy. Mitotic index and caspase-3 activity analyses reveal that CLIP-170 increases the abilities of paclitaxel to block cell cycle progression at mitosis and to induce apoptosis in breast cancer cells. By microtubule sedimentation assay and binding affinity analysis, we further find that CLIP-170 promotes paclitaxel binding to microtubules. In vitro tubulin polymerization assay shows that CLIP-170 enhances the activity of paclitaxel to promote microtubule assembly. These results demonstrate that CLIP-170 mediates paclitaxel sensitivity in breast cancer via a microtubule-dependent mechanism.     

Kre29p is a novel nuclear protein involved in DNA repair and mitotic fidelity in Candida glabrata

Candida glabrata KRE29 is an ortholog of Saccharomyces cerevisiae KRE29. S. cerevisiae Kre29p has been identified by affinity purification as a subunit of the Smc5–Smc6 complex, which is required for DNA repair and chromosome segregation. However, mutant phenotypes of S. cerevisiae KRE29 have not been well characterized and none of its orthologs’ functions has been reported. Here we report phenotypic characteristics of a C. glabrata kre29 deletant. The absence of C. glabrata Kre29p resulted in decreased viability, exhibiting cell cycle arrest between late S-phase and metaphase even under normal growth conditions, and also caused an increase of plasmid loss rate, implying that Kre29p is required for mitotic chromosome transmission fidelity. The deletant showed increased sensitivity to high temperature as well as to DNA damaging agents including UV, gamma ray, 4-nitroquinoline-1-oxide and methyl methanesulfonate, and the phenotypes were restored in the KRE29 reintegrant. Consistent with the Δkre29 phenotypes, a Kre29p-GFP fusion protein was located in the nucleus. Furthermore, Kre29p-GFP became concentrated and formed distinct foci after exposure to 4-nitroquinoline-1-oxide. These results suggest the involvement of C. glabrata Kre29p in DNA repair. To our knowledge, this is the first report addressing a cellular protein involved in DNA repair in C. glabrata.     

The iguana/DZIP1 protein is a novel component of the ciliogenic pathway essential for axonemal biogenesis

Cilia play important roles in many developmental and physiological processes. However, the genetic and cell biological control of ciliogenesis remains poorly understood. Here, we show that the zebrafish iguana gene is required for differentiation of primary cilia. iguana encodes a zinc finger and coiled‐coil containing protein, previously implicated in Hedgehog signaling. We now argue that aberrant Hedgehog activity in iguana ‐deficient zebrafish arises from their profound lack of primary cilia. By contrast, the requirement of iguana for motile cilia formation is less obligatory. In the absence of iguana function, basal bodies can migrate to the cell surface and appear to engage with the apical membrane. However, formation of ciliary pits and axonemal outgrowth is completely inhibited. Iguana localizes to the base of primary and motile cilia, in the immediate vicinity or closely associated with the basal bodies. These findings identify the Iguana protein as a novel and critical component of ciliogenesis. Developmental Dynamics 239:527–534, 2010. © 2009 Wiley‐Liss, Inc.     

The tight-junction-specific protein ZO-1 is a component of the human and rat blood-brain barriers

Continuous tight junctions between vascular endothelial cells, the principal anatomical basis for the blood-brain barrier, have been investigated functionally and morphologically but their molecular components have not been defined. This communication reports that the protein ZO-1, a specific constituent of epithelial tight junctions, is found in human and rat brain vasculature. ZO-1-positive immunocytochemical staining forms a tightly banded pattern outlining individual endothelial cells in blood vessels of the human cerebral cortex. Rat brain exhibits a similar staining of blood vessels as well as ZO-1-positive staining around individual epithelial cells of the choroid plexus. The antiserum used for immunocytochemistry recognizes a protein of about 200 kDa in rat brain microvessels by Western blot. These findings indicate that ZO-1 is located at the interendothelial junctions of brain vasculature, implicating its importance as a component of the blood-brain barrier.     

Modulation of calcium currents is eliminated after cleavage of a strategic component of the mammalian secretory apparatus

Adenosine inhibits neurotransmitter secretion from motor nerves by an effect on the secretory apparatus in amphibia. In contrast, the inhibitory effect of adenosine is associated with decreases in calcium currents at mouse motor nerve endings. To determine if the action of adenosine in the mouse is mediated thorough a direct effect on calcium channels or through the secretory machinery, the effects of cleavage of the SNARE proteins on the action of adenosine were examined. Cleavage of the SNARE syntaxin with botulinum toxin type C (Botx/C) prevented the inhibitory effect of adenosine on nerve terminal calcium currents. Cleavage of the other SNAREs (synaptobrevin with Botx/D or SNAP-25 with Botx/A) failed to affect the inhibitory action of adenosine. The results provide evidence for an intimate coupling of nerve terminal calcium channels with a plasma membrane component of the SNARE complex, such that modulation of calcium currents by a G-protein coupled receptor cannot occur when syntaxin is cleaved.     

The budding yeast silencing protein Sir1 is a functional component of centromeric chromatin

In fission yeast and multicellular organisms, centromere-proximal regions of chromosomes are heterochromatic, containing proteins that silence gene expression. In contrast, the relationship between heterochromatin proteins and kinetochore function in the budding yeast Saccharomyces cerevisiae remains largely unexplored. Here we report that the yeast heterochromatin protein Sir1 is a component of centromeric chromatin and contributes to mitotic chromosome stability. Sir1 recruitment to centromeres occurred through a novel mechanism independent of its interaction with the origin recognition complex (ORC). Sir1 function at centromeres was distinct from its role in forming heterochromatin, because the Sir2-4 proteins were not associated with centromeric regions. Sir1 bound to Cac1, a subunit of chromatin assembly factor I (CAF-I), and helped to retain Cac1 at centromeric loci. These studies reveal that although budding yeast and mammalian cells use fundamentally different mechanisms of forming heterochromatin, they both use silencing proteins to attract the histone deposition factor CAF-I to centromeric chromatin.     

The role of motor proteins in establishing the microtubule arrays of axons and dendrites

Neurons generate two distinct types of processes called axons and dendrites, both of which rely on highly organized arrays of microtubules for their growth and maintenance. Axonal microtubules are uniformly oriented with their plus-ends distal to the cell body, while dendritic microtubules are nonuniformly oriented. In neither case are the microtubules attached to the centrosome or any detectable structure that could establish their distinct patterns of polarity orientation. Here I describe several lines of evidence from my laboratory that support a model for the establishment of these microtubule arrays based on microtubule transport by motor proteins. Microtubules destined for axons and dendrites are nucleated at the centrosome within the cell body of the neuron, and rapidly released. The released microtubules are then transported into the developing processes. Early in neuronal development, the microtubules are transported with their plus-ends-leading into the developing axon and into the immature processes that will develop into dendrites. In the case of the developing dendrites, the plus-end-distal microtubules are later joined by a population of microtubules that are transported into these processes with their minus-ends-leading. Implicit in this model is that there are molecular motor proteins that transport microtubules with the appropriate orientation into each type of process. There is precedent for molecular motor proteins transporting microtubules during mitosis, and our results suggest that the same or similar motors are utilized during the development of axons and dendrites after a neuroblast becomes terminally postmitotic.     

电磁脉冲辐照对海马神经元膜流动性的影响

目的应用自旋标记电子顺磁共振(SpinlabelESR)技术,探讨电磁脉冲对海马细胞膜流动性的影响.方法用5-氮氧自由基硬脂酸(5-doxylstearicacid)掺入到原代培养的海马神经细胞膜类脂区,用场强为6×104V/m(脉冲上升时间为20ns,脉宽25us)的电磁脉冲辐照2分钟后,观察电磁脉冲对序参数(S)旋转相关时间(L)的影响.结果电磁脉冲能改变膜腊的理化性质,膜脂序参数S值和旋转相关时间T.值都显著降低,说明膜的有序性有不同程度降低,膜流动性升高.结论电磁脉冲辐照后可引起海马神经元细胞膜的损伤,表现为膜的有序性降低,膜流动性升高.     

The extended haplotype of the microtubule associated protein tau gene is not associated with Pick's disease

Pick's disease (PiD) is a rare neurodegenerative condition and is a member of a heterogeneous group of disorders known as tauopathies, so-called because of the predominantly neuronal aberrant tau accumulations found in these diseases. The tauopathy, familial frontotemporal dementia (FTD), is caused by mutations in the tau gene. Moreover, progressive supranuclear palsy (PSP) is associated with the tau H1 haplotype. In certain familial forms of FTD and in PSP the microtubule-binding four repeat tau isoform principally accumulates in neuropathological lesions. However, in PiD three repeat tau accumulations are found. We therefore investigated whether either the tau H1 or H2 haplotype was associated with PiD. Our results indicate a slight increase in H2H2 frequency in Pick's cases which is not statistically significant.     

大鼠海马神经元PKCε特异性shRNA对神经元突起生长的影响

目的 构建shRNA特异性干扰海马神经元内PKCε,研究PKCε干扰后海马神经元突起长度的变化.方法 设计并构建PKCε的小分子干扰shRNA载体.分别在293T细胞中共转染PKCε和各干扰片段,Western blot验证干扰效果.将有干扰作用的载体转染海马神经元,用细胞免疫荧光法验证干扰内源PKCε的效果.激光共聚...     

Phosphorylation of the mitotic regulator Pds1/securin by Cdc28 is required for efficient nuclear localization of Esp1/separase

Sister chromatid separation at the metaphase-to-anaphase transition is induced by the proteolytic cleavage of one of the cohesin complex subunits. This process is mediated by a conserved protease called separase. Separase is associated with its inhibitor, securin, until the time of anaphase initiation, when securin is degraded in an anaphase-promoting complex/cyclosome (APC/C)-dependent manner. In budding yeast securin/Pds1 not only inhibits separase/Esp1, but also promotes its nuclear localization. The molecular mechanism and regulation of this nuclear targeting are presently unknown. Here we show that Pds1 is a substrate of the cyclin-dependent kinase Cdc28. Phosphorylation of Pds1 by Cdc28 is important for efficient binding of Pds1 to Esp1 and for promoting the nuclear localization of Esp1. Our results uncover a previously unknown mechanism for regulating the Pds1-Esp1 interaction and shed light on a novel role for Cdc28 in promoting the metaphase-to-anaphase transition in budding yeast.     

BiP inactivation due to loss of the deAMPylation function of FICD causes a motor neuron disease

PurposeThe chaperone protein BiP is the master regulator of the unfolded protein response in the endoplasmic reticulum. BiP chaperone activity is regulated by the post-translational modification AMPylation, exclusively provided by FICD. We investigated whether FICD variants identified in patients with motor neuron disease could interfere with BiP activity regulation.MethodsExome sequencing was performed to identify causative pathogenic variants associated with motor neuron diseases. Functional studies were conducted on fibroblasts from patients to explore the molecular mechanism of the disease.ResultsWe identified biallelic variants in FICD causing a neurodegenerative disease of upper and lower motor neurons. Affected individuals harbor a specific missense variant, Arg374His, positioned in the catalytic motif of the enzyme and important for adenosine triphosphate binding. The mutated residue abolishes intramolecular interaction with the regulatory residue Glu234, essential to inhibit AMPylation and to promote de-AMPylation by FICD. Consequently, fibroblasts from patients with FICD variants have abnormally increased levels of AMPylated and thus inactivated BiP.ConclusionLoss of BiP chaperone activity in patients likely results in a chronic impairment of the protein quality control system in the endoplasmic reticulum. These findings will guide the development of therapeutic strategies for motoneuron and related diseases linked to proteotoxic stress.