Cytoplasmic dynein: a key player in neurodegenerative and neurodevelopmental diseases

Cytoplasmic dynein is the most important molecular motor driving the movement of a wide range of cargoes towards the minus ends of microtubules.As a molecular motor protein,dynein performs a variety of basic cellular functions including organelle transport and centrosome assembly.In the nervous system,dynein has been demonstrated to be responsible for axonal retrograde transport.Many studies have revealed direct or indirect evidence of dynein in neurodegenerative diseases such as amyotrophic lateral sclerosis,Charcot-Marie-Tooth disease,Alzheimer’s disease,Parkinson’s disease and Huntington’s disease.Among them,a number of mutant proteins involved in various neurodegenerative diseases interact with dynein.Axonal transport disruption is presented as a common feature occurring in neurodegenerative diseases.Dynein heavy chain mutant mice also show features of neurodegenerative diseases.Moreover,defects of dynein-dependent processes such as autophagy or clearance of aggregation-prone proteins are found in most of these diseases.Lines of evidence have also shown that dynein is associated with neurodevelopmental diseases.In this review,we focus on dynein involvement in different neurological diseases and discuss potential underlying mechanisms.     

Antisense RNA Inhibition of the β Subunit of the Dictyostelium discoideum Mitochondrial Processing Peptidase Induces the Expression of Mitochondrial Proteins

We cloned and characterized a cDNA encoding the Dictyostelium discoideum β subunit of mitochondrial processing peptidase (Ddβ-MPP). Western blot analysis of the mitochondrial subfractions revealed that Ddβ-MPP is located in the mitochondrial matrix and membrane, whereas Ddα-MPP, another subunit of DdMPP, is located only in the matrix. Although expression of Ddβ-MPP mRNA is down-regulated during early development, the level of the Ddβ-MPP protein is constant throughout the Dictyostelium life cycle. In a transformant expressing the antisense RNA of the β-MPP gene, unexpectedly, the β-MPP protein increased about 1.8-fold relative to the wild type, and its mRNA increased 4.5-fold. Expression of other mitochondrial proteins, α-MPP and Cox IV, was also induced. These results suggest that antisense RNA inhibition of the β-MPP gene induces gene expression of mitochondrial proteins, presumably in a retrograde signaling manner. This is the pathway of the transfer of information from the mitochondria to the nucleus.     

Injury-associated induction of GAP-43 expression displays axon branch specificity in rat dorsal root ganglion neurons

Peripheral nerve injury results in the increased synthesis and axonal trasnport of the growth-associated protein GAP-43 in dorsal root ganglion (DRG) neurons, coincident with regenerative growth of the injured peripheral axon branches. To determine wheter the injury-associated signalling mechanism which leads to GAP-43 induction also operates through the central branches of DRG axons, we used immunocytochemistry to compare the expression of GAP-43 in adult rat DRG neurons 2 weeks after dorsal root crush lesions (central axotomy) or peripheral nerve crush lesions (peripheral axotomy). In uninjured ganglia, a subpopulation of smaller DRG neurons expresses moderate levels of GAP-43, whereas larger neurons generally do not. At 2 weeks following peripheral axotomy, virtually all axotomized neurons, large and small, express high levels of GAP-43. At 2 weeks following dorsal root lesions, no increase in GAP-43 expression is detected. Thus, the injury-associated up-regulation of GAP-43 expression in DRG neurons is triggered by a mechanism that is responsive to injury of only the peripheral, and not the central, axon branches. These findings support the hypothesis that GAP-43 induction in DRG neurons is caused by disconnection from peripheral target tissue, not by axon injury per se. © 1993 John Wiley & Sons, Inc.     

Cerebellar afferents in the frogs,Rana esculenta and Rana temporaria

Summary Afferents to the cerebellum in frogs (Rana esculenta, Rana temporaria) were studied by use of retrograde transport of horseradish peroxidase. Following injections restricted to the molecular layer of the cerebellum cell labelling was found in the contralateral inferior olive and the ventral portion of the caudal medullary raphe. Injections involving the granular layer resulted in labelling in the ventral horn of the cervical spinal cord, the caudal spinal trigeminal nucleus, the nucleus caudalis and the medial portion of the nucleus ventralis of the vestibular nerve, the inferior reticular nucleus and the nucleus of the fasciculus longitudinalis medialis. Following larger injections, which may have spread significantly into the cerebellar, secondary gustatory, trigeminal or vestibular nuclei, labelled cell bodies were also found in the nucleus ruber, nucleus solitarius, the rostral spinal trigeminal nucleus and the rostral rhombencephalic reticular formation. It is unclear whether the fibers from these latter areas innervate the cerebellum of the frog, as they do in mammals, or only reach the underlying areas. This situation emphasizes a limitation of the HRP technique when applied to small structures as is often the case in lower vertebrates.Supported by Grant Gr 276 to U. G.-C. from the Deutsche Forschungsgemeinschaft.     

Migration patterns of sympathetic preganglionic neurons in embryonic rat spinal cord

The displacement of immature neurons from their place of origin in the germinal epithelium toward their adult positions in the nervous system appears to involve migratory pathways or guides. While the importance of radial glial fibers in this process has long been recognized, data from recent investigations have suggested that other mechanisms might also play a role in directing the movement of young neurons. We have labeled autonomic preganglionic cells by microinjections of horseradish peroxidase (HRP) into the sympathetic chain ganglia of embryonic rats in order to study the migration and differentiation of these spinal cord neurons. Our results, in conjunction with previous observations, suggest that the migration pattern of preganglionic neurons can be divided into three distinct phases. In the first phase, the autonomic motor neurons arise in the ventral ventricular zone and migrate radially into the ventral horn of the developing spinal cord, where, together with somatic motor neurons, they form a single, primitive motor column (Phelps P. E., Barber R. P., and Vaughn J. E. (1991). J. Comp. Neurol. 307:77–86). During the second phase, the autonomic motor neurons separate from the somatic motor neurons and are displaced dorsally toward the intermediate spinal cord. When the preganglionic neurons reach the intermediolateral (IML) region, they become progressively more multipolar, and many of them undergo a change in alignment, from a dorsoventral to a mediolateral orientation. In the third phase of autonomic motor neuron development, some of these cells are displaced medially, and occupy sites between the IML and central canal. The primary and tertiary movements of the preganglionic neurons are in alignment with radial glial processes in the embryonic spinal cord, an arrangement that is consistent with a hypothesis that glial elements might guide autonomic motor neurons during these periods of development. In contrast, during the second phase, the dorsal translocation of preganglionic neurons occurs in an orientation perpendicular to radial glial fibers, indicating that glial elements are not involved in the secondary migration of these cells. The results of previous investigations have provided evidence that, in addition to glial processes, axonal pathways might provide a substrate for neuronal migration. Logically, therefore, it is possible that the secondary dorsolateral translocation of autonomic preganglionic neurons could be directed along early forming circumferential axons of spinal association interneurons, and this hypothesis is supported by the fact that such fibers are appropriately arrayed in both developmental time and space to guide this movement.     

狗急性心肌缺血早期冠脉侧支血流量与血液流变学变化的关系

本实验在14只麻醉开胸狗身上观察了急性心肌缺血早期冠脉侧支血流量与血液流变学变化的关系。动物均分为两组:Ⅰ组,在不控制血压的情况下,观察心肌缺血早期单位压力差下冠脉侧支血管流量(CVC)的变化;Ⅱ组,在保持主动脉血压不变的条件下,根据 Wyatt 等公式计算流经缺血区末梢血管的有效侧支血流量(ECF)。实验结果表明,阻断冠脉血流30min时,低切变率下全血比粘度已明显增高,随后继续增加,60min 时Ⅰ、Ⅱ两组分别较对照值增高19.0%和11.4%(均为P<0.01)。血液粘度增高时,CVC 仅轻度降低(p>0.05),但 ECF却随着血液粘度的增高而逐渐明显降低,缺血60min 时较对照值降低12.1±2.6%(P<0.01)。血液粘度变化与 ECF 变化之间呈明显负相关(r=-0.796,p<002)。上述结果提示,心肌缺血早期血液流变学的异常变化虽然对冠脉侧支血管的血流阻力影响较小,但却使流经缺血区末梢血管的有效侧支血流量明显减少而加重心肌缺血。     

Genome-Wide Screening of Aluminum Tolerance in <Emphasis Type="Italic">Saccharomyces cerevisiae</Emphasis>

Genome-wide screening has identified 37 Al-tolerance genes in Saccharomyces cerevisiae. These genes can be roughly categorised into three groups on the basis of function, i.e., genes related to vesicle transport processes, signal transduction pathways, and protein mannosylation. The largest group is composed of genes related to vesicle transport processes; severe Al sensitivity was found in yeast strains lacking these genes. The retrograde transport of endosome-derived vesicles back to the Golgi apparatus is an important factor in determining the Al tolerance of the vesicle transport system. The PKC1-MAPK cascade signalling pathway is important in the Al tolerance of signal transduction. The lack of the gene implicated in this process leads to weakened cell wall architecture, rendering the yeast Al-sensitive. Alternatively, Al might attack the cell wall and/or plasma membrane, and, as signalling is prevented in cells devoid of the genes related to signalling processes, the cells may be unable to alleviate the damage. The genes for protein mannosylation are also associated with Al tolerance, demonstrating the importance of cell wall architecture. These genes are involved in cell integrity processes. An erratum to this article is available at .     

Bile duct brushings cytology – improving sensitivity of diagnosis using the ThinPrep® technique: a review of 113 cases

OBJECTIVE: Common bile duct (CBD) brushings have been recognized as a technique of moderate sensitivity and high specificity in identifying carcinoma of the ampulla and pancreatico-biliary regions. This study evaluated the increase in sensitivity of this technique using the ThinPrep technique of specimen preparation when compared with conventional cytology smears. METHODS: A total of 113 bile duct brushings were included in the study (38 conventional smears and 75 slides prepared using the ThinPrep technique). All slides were reviewed by one cytologist. Five categories of reporting were used: inadequate, negative, atypia, suspicious and malignant. RESULTS: The inadequate category of reporting disappeared in the ThinPrep group with improved specimen fixation and preparation and hence reduced artefact. Sensitivity of diagnosis of malignancy increased from 39% in conventional smears to 53% in the ThinPrep group. Specificity, positive and negative predictive values and accuracy were 100%, 100%, 60% and 68% for conventional smears and were 100%, 100%, 60% and 72%, respectively, for ThinPrep specimens. CONCLUSIONS: ThinPrep technique was associated with increased sensitivity of diagnosis, in part due to improved specimen fixation and reduced artefact. Cytology of bile duct brushings is an important diagnostic tool for sites from which it can be difficult to obtain a histology biopsy. It may therefore provide the only opportunity for tissue diagnosis of carcinoma from these sites, hence the importance of optimizing sensitivity.