Combinatorial assembly of neurons: from chromatin to dendrites

The generation and refinement of dendrites is essential for normal brain development and function. However, the molecular mechanisms that govern dendritic morphogenesis are poorly understood. Recent studies from the Crabtree laboratory have uncovered a requirement for the neuron-specific chromatin-remodeling enzyme nBAF in dendritic growth and branching in response to neuronal activity. These findings highlight the significance of epigenetic mechanisms in activity-dependent dendritic morphogenesis, with important implications in brain development and plasticity.     

Differentiated neurons retain the capacity to generate axons from dendrites

Cutting the axon of a morphologically polarized neuron (stage 3) close to the cell body causes another neurite to grow as an axon [1-3]. Stage 3 neurons still lack molecular segregation of axonal and dendritic proteins, however. Axonal and dendritic compartments acquire their distinct composition at stage 4 (4-5days in culture), when proteins such as the microtubule-associated protein 2 (MAP-2) and the glutamate receptor subunit GluR1 localize to the dendrites and disappear from the axon [4,5]. We investigated whether cultured hippocampal neurons retained axon/dendrite plasticity after axons and dendrites have created their distinct cytoskeletal architecture and acquired their specific membrane composition. We found that axotomy of stage 4 neurons transformed a dendrite into an axon. Using axonal and dendritic markers, we tested whether cytoskeletal changes could cause similar transformations, and found that actin depolymerization induced multiple axons in unpolarized neurons. Moreover, depletion of actin filaments from both morphologically and molecularly polarized cells also resulted in the growth of multiple axons from pre-existing dendrites. These results imply that dendrites retain the potential to become axons even after molecular segregation has occurred and that the dendritic fate depends on the integrity of the actin cytoskeleton.     

A novel calmodulin-binding protein, belonging to the WD-repeat family, is localized in dendrites of a subset of CNS neurons

A rat brain synaptosomal protein of 110,000 M(r) present in a fraction highly enriched in adenylyl cyclase activity was microsequenced (Castets, F., G. Baillat, S. Mirzoeva, K. Mabrouk, J. Garin, J. d'Alayer, and A. Monneron. 1994. Biochemistry. 33:5063-5069). Peptide sequences were used to clone a cDNA encoding a novel, 780-amino acid protein named striatin. Striatin is a member of the WD-repeat family (Neer, E.J., C.J. Schmidt, R. Nambudripad, and T.F. Smith. 1994. Nature (Lond.). 371:297-300), the first one known to bind calmodulin (CaM) in the presence of Ca++. Subcellular fractionation shows that striatin is a membrane-associated, Lubrol-soluble protein. As analyzed by Northern blots, in situ hybridization, and immunocytochemistry, striatin is localized in the central nervous system, where it is confined to a subset of neurons, many of which are associated with the motor system. In particular, striatin is conspicuous in the dorsal part of the striatum, as well as in motoneurons. Furthermore, striatin is essentially found in dendrites, but not in axons, and is most abundant in dendritic spines. We propose that striatin interacts, through its WD- repeat domain and in a CaM/Ca(++)-dependent manner, with one or several members of a surrounding cluster of molecules engaged in a Ca(++)- signaling pathway specific to excitatory synapses.     

Distribution pattern of connexin 43, a gap junctional protein, during the differentiation of mouse heart myocytes

In the cardiac muscle, the electrical coupling of myocytes by means of gap (or communicating) junctions, allows the action potentials to be propagated. Connexin 43 (CX 43) is the major constitutive protein of the gap junctions in the mammalian myocardium. In this organ, the abundance of CX 43 and of its messenger, as well as the spatial expression of this protein, are developmentally regulated. These findings are complemented by the results presented in this article, which deals with the distribution of CX 43 in the ventricular myocytes of mouse heart during differentiation, between the 11 days post coitum embryo stage and adulthood. By immunoelectron microscopy experiments on ultrathin sections of cardiac ventricular tissue of one-week-old mouse, we have provided confirmation that the anti-CX 43 antibodies used here specifically recognized the gap junctions. Double labeling immunofluorescence experiments have been undertaken to localize, within the same cells, either CX 43 and desmin, or CX 43 and Con A or WGA receptor sites. From the earliest stage investigated (11 days post coitum) onwards, expression of CX 43 is always associated with desmin-positive cells, that is, with the myocytes. Up to birth, there is in the ventricular wall a gradient of expression of CX 43 which is superimposable on a gradient of expression of desmin. Immunoreactivity to anti-CX 43 and anti-desmin antibodies is high in the sub-endocardial trabeculae and low (or even undetectable for CX 43, in the early stages) in the sub-epicardial cell layers. In the embryonic stages, the expression sites of CX 43 are visible in the form of small dots, whose abundance increases as development proceeds. During these stages, the immunoreactive sites are distributed in a relatively homogeneous pattern throughout the membrane of the myocytes. One week after birth, the CX 43 expression is restricted to the two ends of the myocytes (where the intercalated discs develop), and the adjacent lateral regions. This polarization of CX 43 is more pronounced at the two and three weeks post natal stages and in the fully differentiated ventricular myocytes (adult stage) CX 43 is only present in the intercalated discs.     

Ran,a GTP-binding protein involved in nucleocytoplasmic transport and microtubule nucleation,relocates from the manchette to the centrosome region during rat spermiogenesis

Ran, a Ras-related GTPase, is required for transporting proteins in and out of the nucleus during interphase and for regulating the assembly of microtubules. cDNA cloning shows that rat testis, like mouse testis, expresses both somatic and testis-specific forms of Ran-GTPase. The presence of a homologous testis-specific form of Ran-GTPase in rodents implies that the Ran-GTPase pathway plays a significant role during sperm development. This suggestions is supported by distinct Ran-GTPase immunolocalization sites identified in developing spermatids. Confocal microscopy demonstrates that Ran-GTPase localizes in the nucleus of round spermatids and along the microtubules of the manchette in elongating spermatids. When the manchette disassembles, Ran-GTPase immunoreactivity is visualized in the centrosome region of maturing spermatids. The circumstantial observation that fractionated manchettes, containing copurified centrin-immunoreactive centrosomes, can organize a three-dimensional lattice in the presence of taxol and GTP, points to the role of Ran-GTPase and associated factors in microtubule nucleation as well as the potential nucleating function of spermatid centrosomes undergoing a reduction process. Electron microscopy demonstrates the presence in manchette preparations of spermatid centrosomes, recognized as such by their association with remnants of the implantation fossa, a dense plate observed only at the basal surface of developing spermatid and sperm nuclei. In addition, we have found importin beta1 immunoreactivity in the nucleus of elongating spermatids, a finding that, together with the presence of Ran-GTPase in the nucleus of round spermatids and the manchette, suggest a potential role of Ran-GTPase machinery in nucleocytoplasmic transport. Our expression and localization analysis, correlated with functional observations in other cell systems, suggest that Ran-GTPase may be involved in both nucleocytoplasmic transport and microtubules assembly, two critical events during the development of functional sperm. In addition, the manchette-to-centrosome Ran-GTPase relocation, together with the similar redistribution of various proteins associated to the manchette, suggest the existence of an intramanchette molecular transport mechanism, which may share molecular analogies with intraflagellar transport.     

Relocalization of the dorsal protein from the cytoplasm to the nucleus correlates with its function

dorsal is one of the maternally active dorsal-ventral polarity genes of Drosophila and is homologous to the vertebrate proto-oncogene c-rel. In wild-type embryos, the dorsal protein is found in the cytoplasm during cleavage. After the nuclei migrate to the periphery of the embryo, a ventral-to-dorsal gradient of nuclear dorsal protein is established. The formation of the nuclear gradient is disrupted in mutant embryos from other maternally active dorsal-ventral polarity genes: in dorsalized embryos only cytoplasmic protein is observed, while in ventralized embryos the nuclear gradient is shifted dorsally. My findings suggest that nuclear localization is critical for dorsal to function as a morphogen and that the distribution of the dorsal protein determines cell fate along the dorsal-ventral axis.     

中心体蛋白centrin研究进展

Centrin是普遍存在于中心体上的蛋白成分 ,具有钙离子结合能力。Centrin家族包含多种同源蛋白 ,这些蛋白在结构上高度保守。研究表明centrin可能与细胞的分化 ,纤毛的生成定向和切断 ,精子尾部的生成 ,中心体复制及其结构维持有密切关系 ,同时也和细胞的癌变、生长及细胞周期调控有关 ,还有许多未知功能有待研究     

Mammalian NDR protein kinases: from regulation to a role in centrosome duplication

The NDR (nuclear Dbf2-related) family of kinases is highly conserved from yeast to human, and has been classified as a subgroup of the AGC group of protein kinases based on the sequence of the catalytic domain. Like all other members of the AGC class of protein kinases, NDR kinases require the phosphorylation of conserved Ser/Thr residues for activation. Importantly, NDR family members have two unique stretches of primary sequence: an N-terminal regulatory (NTR) domain and an insert of several residues between subdomains VII and VIII of the kinase domain. The kinase domain insert functions as an auto-inhibitory sequence (AIS), while binding of the co-activator MOB (Mps-one binder) proteins to the NTR domain releases NDR kinases from inhibition of autophosphorylation. However, despite such advances in our understanding of the molecular activation mechanism(s) and physiological functions of NDR kinases in yeast and invertebrates, most biological NDR substrates still remain to be identified. Nevertheless, by showing that the centrosomal subpopulation of human NDR1/2 is required for proper centrosome duplication, the first biological role of human NDR1/2 kinases has been defined recently. How far NDR-driven centrosome overduplication could actually contribute to cellular transformation will also be discussed.     

Heterogeneity of Tau proteins during mouse brain development and differentiation of cultured neurons.

Tau microtubule-associated proteins constitute a group of developmentally regulated neuronal proteins. Using the high-resolution two-dimensional polyacrylamide gel electrophoresis system, we have resolved more than 60 distinct Tau isoforms in the adult mouse brain. Tau protein heterogeneity increases drastically during the second week of brain development. In neuronal primary cell cultures, some of these developmental changes can be observed. The increase of Tau heterogeneity in culture is more limited and reaches a plateau after a period corresponding to the second week of development. Most, if not all, of the vast Tau heterogeneity can be attributed to intensive post-translational phosphorylation, which may affect the structure of the proteins.     

Rearrangement of microtubule polarity orientation during conversion of dendrites to axons in cultured pyramidal neurons

Axons and dendrites of neurons differ in the polarity orientation of their microtubules. Whereas the polarity orientation of microtubules in axons is uniform, with all plus ends distal, that in dendrites is nonuniform. The mechanisms responsible for establishment and maintenance of microtubule polarity orientation in neuronal processes remain unclear, however. We previously described a culture system in which dendrites of rat cortical neurons convert to axons. In the present study, we examined changes in microtubule polarity orientation in such dendrites. With the use of the hooking procedure and electron microscopy, we found that microtubule polarity orientation changed from nonuniform to uniform, with a plus end-distal arrangement, in dendrites that gave rise to axons during culture of neurons for 24 h. Microtubule polarity orientation remained nonuniform in dendrites that did not elongate. Axon regeneration at the dendritic tip thus triggered the disappearance of minus end-distal microtubules from dendrites. These minus end-distal microtubules also disappeared from dendrites during axon regeneration in the presence of inhibitors of actin polymerization, suggesting that actin-dependent transport of microtubules is not required for this process and implicating a previously unidentified mechanism in the establishment and maintenance of microtubule polarity orientation in neuronal processes.     

Role of PTB-like protein,a neuronal RNA-binding protein,during the differentiation of PC12 cells

PTB-like protein (PTBLP) is a new homologue of pyrimidine tract binding protein (PTB), and has been cloned as a possible autoantigen in cancer-associated retinopathy. PTBLP has two functional domains, the nuclear localization signal and the RNA recognition motifs (RRMs). Full-length PTBLP (PTBLP-L) has four RRMs, and its alternative splicing product (PTBLP-S) lacks the third and fourth RRMs. Although PTBLPs are expressed in neuronal tissues, the function of PTBLPs has not been determined. We have studed whether PTBLP plays a role in neuronal differentiation using PC12 cells. During the process of nerve growth factor-induced neuronal differentiation of PC12 cells, PTBLP-L was down-regulated whereas PTBLP-S was up-regulated. Transfection of PTBLP-L into PC12 cells led to the suppression of neuronal differentiation. In PTBLP-S transfected cells, however, this suppression was not evident. When both PTBLP-L and PTBLP-S were co-transfected, the suppressive effect of PTBLP-L decreased. In differentiated cells, PTBLP-S localized in the nucleus and PTBLP-L was found dispersed throughout the cytoplasm and neuronal growth cone. These findings suggest that PTBLP-L acts as a negative regulator of neuronal differentiation and PTBLP-S acts as a competitor of PTBLP-L.     

Specific expression of a gene encoding a novel calcium-binding protein, CAF-1, during transition of Dictyostelium cells from growth to differentiation

The gene expressions involved in the transition from cell proliferation to differentiation were analyzed, using synchronized Dictyostelium discoideum Ax-2 cells and the differential plaque hybridization method. As one of the genes (cDNA) specifically expressed when Ax-2 cells were starved just before the putative shift (PS)-point (putative shift point; a switchover point from growth to differentiation in the cell cycle), calfumirin-1 ( CAF-1 ) was cloned, which encoded a novel calcium-binding protein with E-F hand. Although CAF-1 mRNA was slightly expressed in vegetatively growing cells, the expression was markedly increased in response to starvation of cells just before the PS-point. Northern analysis using non-synchronized Ax-2 cells showed that the CAF-1 mRNA is predominantly expressed within a few hours of starvation. Such a starvation-induced early expression of the CAF-1 mRNA raised a possibility that CAF-1 might be one of Ca²⁺-binding proteins involved in the phase-shift of cells from growth to differentiation.     

Changes in mitochondrial protein composition during testicular differentiation in mouse and bull

The morphology of testicular mitochondria changes markedly during spermatogenesis from a form normally seen in somatic cells to a “germ cell” form in which the matrix is diffuse and vacuolated and finally to a form with a condensed matrix seen in spermatozoa. Colloidal silica gel gradients and high-resolution, two-dimensional gel electrophoresis were used to define the changes in density and polypeptide composition that occur in testicular mitochondria during spermatogenesis. Similar densities were observed for mitochondria isolated from the same bovine or murine tissue, but mitochondria from different tissues usually had different densities. Mitochondria from testis of calf, bull, or sexually mature mouse had densities of 1.06 gm/cm³ while liver mitochondria were more dense, having a density of 1.09 gm/cm³. “Somatic-type” testicular mitochondria from calf and “germ cell-type” mitochondria from sexually mature mouse or bull had similar densities, 1.06 gm/cm³, while the density of mitochondria from ejaculated spermatozoa differed, ρ = 1.08 gm/cm³. Analysis of polypeptide composition of somatic and germ cell mitochondria from testes of prepuberal and sexually mature animals and from highly enriched populations of pachytene primary spermatocytes and round spermatids revealed a staining pattern of mitochondrial proteins that was markedly constant throughout development with most polypeptides being conserved and a few specific spots changing in abundance. Marked differences were detected, however, when mitochondria from ejaculated spermatozoa were compared with those from testis with many minor and major polypeptides missing and several new polypeptides present at high concentration.     

Dephosphorylation of "abp38" protein during the differentiation of mouse myeloid leukemia cells

We have characterized the phosphorylation of "abp38" before and after the differentiation of mouse myeloid leukemic cells (M1 cells). The abp38 of both undifferentiated and differentiated M1 cells contained phosphoserine and phosphotyrosine. The extent of phosphorylation of abp38 decreased to about 30% of the value of undifferentiated cells during cell differentiation; phosphoserine and phosphotyrosine decreased to 41 and 11% of the values before differentiation, respectively.     

Inhibition of centrosome protein assembly leads to p53-dependent exit from the cell cycle

Previous evidence has indicated that an intact centrosome is essential for cell cycle progress and that elimination of the centrosome or depletion of individual centrosome proteins prevents the entry into S phase. To investigate the molecular mechanisms of centrosome-dependent cell cycle progress, we performed RNA silencing experiments of two centrosome-associated proteins, pericentriolar material 1 (PCM-1) and pericentrin, in primary human fibroblasts. We found that cells depleted of PCM-1 or pericentrin show lower levels of markers for S phase and cell proliferation, including cyclin A, Ki-67, proliferating cell nuclear antigen, minichromosome maintenance deficient 3, and phosphorylated retinoblastoma protein. Also, the percentage of cells undergoing DNA replication was reduced by >50%. At the same time, levels of p53 and p21 increased in these cells, and cells were predisposed to undergo senescence. Conversely, depletion of centrosome proteins in cells lacking p53 did not cause any cell cycle arrest. Inhibition of p38 mitogen-activated protein kinase rescued cell cycle activity after centrosome protein depletion, indicating that p53 is activated by the p38 stress pathway.