The nucleoskeleton and the topology of transcription

Cook, Peter R.

doi:10.1111/j.1432-1033.1989.tb15141.x

Cited by 108 publications

(38 citation statements)

References 234 publications

Supporting

Mentioning

Contrasting

Unclassified

Order By: Relevance

“…Both sites of replication and transcription are apparently fixed and remain associated with the structures in nuclei after a nuclear matrix or nucleoskeleton preparation has been performed [18,19]. Replication and transcription patterns appear to be similar but localize to different compartments in the nucleus [20,21].…”

Section: Introductionmentioning

confidence: 99%

Nuclear RNAs confined to a reticular compartment between chromosome territories

Bridger

Kalla

Wodrich

et al. 2005

Experimental Cell Research

View full text Add to dashboard Cite

Section: Introductionmentioning

confidence: 99%

Nuclear RNAs confined to a reticular compartment between chromosome territories

Bridger

Kalla

Wodrich

et al. 2005

Experimental Cell Research

View full text Add to dashboard Cite

“…In the nuclei of eukaryotic cells, the DNA is organized into large loops fixed to the nuclear skeleton (1)(2)(3)(4)(5). The specificity of loop organization-i.e., the specificity of distribution of the loop borders in the genome-has been intensively studied but the experimental results remain controversial (1,4).…”

mentioning

confidence: 99%

Excision close to matrix attachment regions of the entire chicken alpha-globin gene domain by nuclease S1 and characterization of the framing structures.

Targa

Razin

Gallo

et al. 1994

Proc. Natl. Acad. Sci. U.S.A.

View full text Add to dashboard Cite

Nuclease Sl-hypersensitive sites in a 40-kb region of the chicken genome including the domain of the a-globin genes were mapped. Brief treatment of isolated chicken erythroid cell nudei with nuclease SI allowed separation ofan %20-kb genomic DNA fragment containing the whole a-globin gene duster. No Sl-hypersensitive sites were observed in the internal part of the domain. The upstream SI site was found in a DNA fragment of 1.7 kb where the origin of replication and several protein binding sites were identified previously. Precise mapping of the positions of SI cleavage in this fragment and "in vivo" footprinting of DNA-protein interactions in isolated nuclei showed a correspondence with some of these protein binding sites. The possible signfcance of all these observations is di in connection with the replication origin and the nuclear matrix attachment regions in the aming structures.In the nuclei of eukaryotic cells, the DNA is organized into large loops fixed to the nuclear skeleton (1-5). The specificity of loop organization-i.e., the specificity of distribution of the loop borders in the genome-has been intensively studied but the experimental results remain controversial (1,4 To investigate loop organization, we have now mapped, in interphase nuclei of erythroid cells, sites of preferential S1 cleavage within the chicken DNA fragment containing the domain of the a-globin genes. This domain represents one of the best studied genomic areas in higher eukaryotes in terms of the arrangement of up to 35 kb of DNA elements involved in chromatin structure, mechanisms of transcription, and control of gene expression. From a DNase I-hypersensitive site 14.5 kb upstream of the ir-,aD-, and aA-globin genes (8, 9) to a hypersensitive site 3 kb downstream of the gene cluster, multiple DNA elements such as matrix attachment regions (MARs) (8, 10, 11), topoisomerase II sites (6,8,12), a replication origin (13), enhancers (14-18), and a silencer (17) all thought to represent putative control elements, have been identified, in addition to the promoters of the individual genes (19,20) and repetitive DNA sequences (21). This region seems to be transcribed into a full-domain transcript which spans the entire domain between the most distal DNase I-hypersensitive sites (8,22,23), running right through all the DNA in the area between the external MARs, and also through an internal MAR placed upstream of the first gene.For the present investigation it was important that the positions of MARs (8,10) and topoisomerase II cleavage sites (24) had been mapped in this area and that multiple sites of protein-DNA interaction were identified within the 1.7-kb fragment including the putative origin of replication (13) and a replication-related MAR (10,11,25). We found that nuclease Sl-sensitive regions are located both upstream and downstream of the domain and that, in the upstream area, they coincided with the permanent site of DNA attachment to the nuclear matrix. In the upstream area, the exact positions of S1 cleavage and DNA-pro...

show abstract

“…A possible criticism of these results is that they have been obtained after introducing some modification in the native structure of the nuclei. Many different preparations of the nuclear matrix have been proposed, and possibly no one is immune from drawbacks [9]. Thus, for example, extraction of nuclei with high salt may cause a sliding of DNA over its attachment points or an exchange of the DNA-binding proteins, so that the original DNA-protein interactions are altered or lost.…”

Section: Introductionmentioning

confidence: 99%

Crosslinking of nuclear proteins to DNA by cis‐diammminedichloroplatinum in intact cells Involvement of nuclear matrix proteins

Ferraro¹,

Grandi²,

Eufemi³

et al. 1992

FEBS Letters

View full text Add to dashboard Cite

In order to detect the nuclear matrix proteins involved in DNA binding, avoiding possible artifacts derived from the disruption of nuclei. proteins were crosslinkcd to DNA by the action of cis-diammincdichloroplatinum on intact chicken liver cells and analyzed by twodimcnsional gel eleetrophoresis. At Icast eleven spccics ofcrosslinkcd proteins wcrc found to dcrivc from the nuclear matrix prepared from the same cell type, and live of these were found also among the proteins crosslinked to DNA in intact liver cells from ox and pig This subset ofcommon proteins, conserved in different animal species. is likely to have a fundamental role for the anchorage of DNA to the nuclear matrix.DNA: Nuclear protein; Nuclear matrix: cis-Diamminedichloroplatinum 1, INTRODUCTIONDNA in eukaryotic chromatin is organized into large loops, which are associated with histones and non-histone proteins, and anchored to the nuclear periphery and to an internal proteinaceous structural meshwork called the nuclear matrix or scaffold [l-3]. This is thought to be involved in processes such as DNA replication, t*:anscription, RNA splicing and transport (for reviews see Georgiev e:. al. [4] and Berezney [S]).To better understand both the structural and functional aspects of loops organization it is necessary to identify the DNA-protein interact!ons which occur in the loops-matrix anchoring points. A number of authors have described the scaffold-or matrix-attachment regions (SAR or MAR) of DNA and some of the proteins which appear to be involved in these interactions (reviewed in [6-83). A possible criticism of these results is that they have been obtained after introducing some modification in the native structure of the nuclei. Many different preparations of the nuclear matrix have been proposed, and possibly no one is immune from drawbacks [9]. Thus, for example, extraction of nuclei with high salt may cause a sliding of DNA over its attachment points or an exchange of the DNA-binding proteins, so that the original DNA-protein interactions are altered or lost. AWx!~~iuriotts: c/s-DDP, ris-diamminedicbloroplatinum (II); IEF, isoclectrofocusingCorreqon&ncc uddwss: C. Turano, Department of Biochemical Sciences, University La Sapien=, P. Aldo Moro. 00185 Rome, Italy.Mnilica and coworkers [ 10, 1 l] have demonstrated that heavy metals or their complexes are able to diffuse inside intact cells and nuclei and to crosslink DNA to proteins located nearby. On the basis of an immunoblotting staining an indication was provided that nuclear matrix proteins could be crosslinked to DNA by the use of this technique. Considering the interest in determining the proximity of DNA to proteins without disruption of the nuclear structure, we analyzed in greater detail the proteins crosslinked to DNA by cisdiamminedichloroplatinum II (cis-DDP) in intact, viable cells from mammalian and avian liver, with the aim of identifying the nuclear matrix components among the crosslinked proteins. EXPERIMENTALThe hepatic parenchymal cells preparation from chicken, pi& and ox,...

show abstract

The nucleoskeleton and the topology of transcription

Cited by 108 publications

References 234 publications

Nuclear RNAs confined to a reticular compartment between chromosome territories

Nuclear RNAs confined to a reticular compartment between chromosome territories

Excision close to matrix attachment regions of the entire chicken alpha-globin gene domain by nuclease S1 and characterization of the framing structures.

Crosslinking of nuclear proteins to DNA by cis‐diammminedichloroplatinum in intact cells Involvement of nuclear matrix proteins

Contact Info

Product

Resources

About