Intranuclear relocation of the Plc β 3 sequence in cerebellar Purkinje neurons: temporal association with de novo expression during development

Martou, Glyka; Park, Paul C.; Boni, U. De

doi:10.1007/s00412-001-0179-8

Cited by 8 publications

(8 citation statements)

References 35 publications

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“…The distinct centromere proximity pattern of chromosomes 2 and 11 in Purkinje and granule neurons may indicate specific roles of these centromeres for neuron-specific function. The structural association of centromeres in Purkinje neurons may be associated with the de novo expression of specific gene sequences, as shown previously (Martou et al 2002). This also supports the concept that the centromeres of chromosomes may be sufficiently unique, as previously hypothesized (Karpen and Allshire 1997), and may indicate that these differences are recognized during the chromosomespecific formation of centromeres.…”

Section: Spatial Distribution Of Neuronal Centromeressupporting

confidence: 69%

“…Fluorescence in situ hybridization (FISH) studies showed that the Purkinje-neuron-specific Plcβ3 sequence is relocated within the nuclear space, temporally coincident with its de novo expression. In contrast, Rorα, a sequence that is not expressed during the same time frame, did not alter its spatial intranuclear position (Martou et al 2002). However, studies of the relative positioning between centromeric domains in neurons have not been reported.…”

Section: Introductionmentioning

confidence: 92%

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Cell-type specific proximity of centromeric domains of one homologue each of chromosomes 2 and 11 in nuclei of cerebellar Purkinje neurons

Vadakkan

Boni

2006

Chromosoma

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In Purkinje neurons of the mouse cerebellum, the centromeres of several chromosomes are placed in close proximity to form a distinct pattern of clusters and exhibit reproducible spatial redistributions during development. In granule neurons, an adjacent cell type in the cerebellum, the pattern, size, and number of centromeric aggregations are different from those of Purkinje neurons. The present work was undertaken to test the hypothesis that the same chromosomes form part of one aggregate in a cell-type-specific manner. Fluorescence in situ hybridization (FISH) with chromosome-specific paracentromeric probes was used to identify centromeric regions of individual chromosomes in cerebellar Purkinje and granule neurons of the adult mouse. When pairs of centromeric probes were used in two-color FISH, one homologue each of chromosomes 2 and 11 were routinely found close to each other in Purkinje neurons but not in granule neurons. This finding of specific proximity was limited to the pair 2 and 11, out of the ten chromosome pairs that were randomly selected and studied. Our results indicate that, in adult Purkinje neurons, a cell-type-specific spatial proximity is present between centromeric domains of one homologue each of chromosomes 2 and 11.

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Section: Spatial Distribution Of Neuronal Centromeressupporting

confidence: 69%

Section: Introductionmentioning

confidence: 92%

Cell-type specific proximity of centromeric domains of one homologue each of chromosomes 2 and 11 in nuclei of cerebellar Purkinje neurons

Vadakkan

Boni

2006

Chromosoma

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“…Individual chromosomes and gene loci have been shown to change their nuclear location upon stimuli, whether that be stimuli to induce differentiation [11,[33][34][35][36], signals that change growth status [10,37,38], environmental stimuli [12] or compounds to induce exogenous gene expression [39]. The consensus hypothesis in the field is that whole chromosomes are moved to allow some control over genes that are housed upon that chromosome, whether for expression or for repression.…”

Section: Repositioning Of Gene Loci and Whole Chromosomesmentioning

confidence: 99%

Chromobility: the rapid movement of chromosomes in interphase nuclei

Bridger

2011

Biochemical Society Transactions

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There are an increasing number of studies reporting the movement of gene loci and whole chromosomes to new compartments within interphase nuclei. Some of the movements can be rapid, with relocation of parts of the genome within less than 15 min over a number of microns. Some of these studies have also revealed that the activity of motor proteins such as actin and myosin are responsible for these long-range movements of chromatin. Within the nuclear biology field, there remains some controversy over the presence of an active nuclear acto-myosin motor in interphase nuclei. However, both actin and myosin isoforms are localized to the nucleus, and there is a requirement for rapid and directed movements of genes and whole chromosomes and evidence for the involvement of motor proteins in this relocation. The presence of nuclear motors for chromatin movement is thus an important and timely debate to have.

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“…Enhanced synaptic input certainly means increasing physiological activity of the developing PCs involving active transcription of PC-specific genes. Martou et al (2002) described an example of intranuclear sequence relocation correlated with onset of gene expression by showing radial relocation of the Plcß3 gene between P3 and P5 coincident with its de novo expression between P2 and P7. Whether changes in higher-order chromatin arrangements in postmitotic PCs during the postnatal development of the cerebellum are a causal necessity or a consequence of changes of the gene expression pattern remains an intriguing question.…”

Section: Changes Of Nuclear Architecture During Terminal Pc Differentmentioning

confidence: 99%

Positional changes of pericentromeric heterochromatin and nucleoli in postmitotic Purkinje cells during murine cerebellum development

Solovei

Grandi

Knoth

et al. 2004

Cytogenet Genome Res

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Previous studies revealed changes of pericentromeric heterochromatin arrangements in postmitotic Purkinje cells (PCs) during postnatal development in the mouse cerebellum (Manuelidis, 1985; Martou and De Boni, 2000). Here, we performed vibratome sections of mouse cerebellum (vermis) at P0 (day of birth), at various stages of the postnatal development (P2–P21), as well as in very young (P28) and 17-months-old adults. FISH was carried out on these sections with major mouse satellite DNA in combination with immunostaining of the nucleolar protein B23 (nucleophosmin). Laser confocal microscopy, 3D reconstructions and quantitative image analysis were employed to describe changes in the number and topology of chromocenters and nucleoli. At all stages of postnatal PC development heterochromatin clusters were typically associated either with nucleoli or with the nuclear periphery, while non-associated clusters were rare (<1% at P0 to P21 and about 3% in adult stages). At P0, about 2–4 nucleoli and 7–8 pericentromeric heterochromatin clusters were variably located within PC nuclei. The relative volume of heterochromatin clusters associated with the nucleoli (about 50%) was roughly equal to the volume of clusters associated with the nuclear periphery. Positional changes of both nucleoli and centromeres towards the nuclear center occurred between P0 and P6. At P6 the average number of chromocenters per PC nucleus had decreased to about five. In agreement with previous studies, one or occasionally two nucleoli were noted at the nuclear center surrounded by major perinucleolar heterochromatin clusters. The relative volume of these perinucleolar clusters increased to about 84%, while the volume of clusters in the nuclear periphery decreased to about 15%. At subsequent postnatal stages, the arrangement of most pericentromeric heterochromatin around a central nucleolus was maintained. In adult animals, however, we observed a partial redistribution of heterochromatin towards the nuclear periphery. The average total number of pericentromeric heterochromatin signals increased again to about ten. The volume of heterochromatin associated with the nuclear periphery roughly doubled (30%), while the volume of the perinucleolar heterochromatin decreased correspondingly.

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Intranuclear relocation of the Plc β 3 sequence in cerebellar Purkinje neurons: temporal association with de novo expression during development

Cited by 8 publications

References 35 publications

Cell-type specific proximity of centromeric domains of one homologue each of chromosomes 2 and 11 in nuclei of cerebellar Purkinje neurons

Cell-type specific proximity of centromeric domains of one homologue each of chromosomes 2 and 11 in nuclei of cerebellar Purkinje neurons

Chromobility: the rapid movement of chromosomes in interphase nuclei

Positional changes of pericentromeric heterochromatin and nucleoli in postmitotic Purkinje cells during murine cerebellum development

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