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Query: UNIPROT:P06889 (Mol)
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Studies of banding induced by restriction enzymes may provide insight into banding mechanisms and chromosome structure. We examined whether or not the sizes of chromosome-specific alphoid DNA fragments created by digestion with various restriction enzymes relate to the presence or absence of C-like bands produced by these same enzymes. We sized alphoid DNA fragments from five different chromosomes, digested with each of six different restriction enzymes. There was no obvious correlation between the length of alphoid restriction fragments at specific human centromeric regions and the production of C-like bands. We used the enzyme AluI and traditional staining (CBG) techniques to band centromeres with conformational alterations. These included dicentric chromosomes, chromosomes from a patient with Roberts syndrome, and 5-azacytidine-treated prometaphase chromosomes. In all cases bands produced by AluI resembled CBG banding. We found that markedly decondensed portions of centromeric regions induced by 5-azacytidine did not band. Our studies demonstrate that restriction endonuclease C-like banding is not strictly related to the presence of restriction sites in alphoid DNA, and the condensed chromatin conformation at the centromeric region may play a role in banding.
Mol Biol Med 1990 Aug
PMID:Characterization of human centromeric regions using restriction enzyme banding, alphoid DNA and structural alterations. 217 91

During prolonged in vivo mitotic multiplication of a Plasmodium berghei ANKA clone (8417HP), parasites that contained an enlarged version of chromosome 4 were observed. Restriction mapping and hybridization results demonstrated that the extra DNA present in the enlarged chromosome consists of 2.3-kb tandem repeats, known to be normally located in subtelomeric position at several chromosomal ends but absent in the original chromosome. The inserted 2.3-kb units appeared to interrupt one of the original telomeres and to create an internal (approximately 1-kb-long) telomeric sequence.
Mol Cell Biol 1990 Dec
PMID:Long insertions within telomeres contribute to chromosome size polymorphism in Plasmodium berghei. 217 15

Several (but not all) Plasmodium berghei chromosomes bear in the subtelomeric position a cluster of 2.3-kilobase (kb) tandem repeats. The 2.3-kb unit contains 160 base pairs of telomeric sequence. The resulting subtelomeric structure is one in which stretches of telomeric sequences are periodically spaced by a 2.1-kb reiterated sequence. This periodic organization of internal telomeric sequences might be related to chromosome-size polymorphisms involving the loss or addition of subtelomeric 2.3-kb units.
Mol Cell Biol 1990 May
PMID:Organization of subtelomeric repeats in Plasmodium berghei. 218 34

Ring-infected erythrocyte surface antigen-negative isolates of Plasmodium falciparum demonstrate a complex DNA rearrangement with inversion of 5' coding sequences, deletion of upstream and flanking sequences, and healing of the truncated chromosome by telomere addition. An inversion intermediate that results in the telomeric gene structure for RESA has been identified in the pathway. This inversion creates a mitotically stable substrate for the sequence-specific addition of telomere repeats at the deletion breakpoint.
Mol Cell Biol 1990 Jun
PMID:A and T homopolymeric stretches mediate a DNA inversion in Plasmodium falciparum which results in loss of gene expression. 218 11

A yeast artificial chromosome (YAC) was constructed with a native autonomous replicating sequence (ARS) flanked telomere at one end and a 50-bp synthetic oligonucleotide of C4A2 repeats at the other. This was done in order to determine whether the presence of the flanking ARS sequence is required for telomere function. This construct was introduced into two different yeast strains: one mutated in the recombination function RAD52 and the other wild type for this gene. Both strains gave rise to autonomously replicating artificial chromosomes. The molecules in the RAD52 strain were rearranged dimers terminating at both ends with Tetrahymena telomeres, whereas in the rad52 strain two classes of YACs were found: rearranged dimers and elements bearing an ARS-free telomere. The presence of the latter class of molecules confirmed the finding of Wellinger and Zakian (1989, Proc. Natl. Acad. Sci. USA 86, 973-977) that the flanking ARS is not required for telomere function. Furthermore, in this class of molecules the ARS-free telomeric end was shortened as a result of deletions that removed some distal pBR322 sequences and some C4A2 repeats. The size of the resulting YACs ranged from 7.7 to 9 kb, considerably below the size threshold found by Zakian et al. (1986, Mol. Cell. Biol. 6, 925-932) for CEN4 artificial plasmids. An explanation for the structural instability of the ARS-free end of the YACs is suggested.
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PMID:Functional telomere formation in yeast using synthetic C4A2 sequences. 219 Feb 43

The function of centromeric DNA in the yeast Saccharomyces cerevisiae has been studied in detail. Twelve of the sixteen S. cerevisiae centromeres have been sequenced to date, and a consensus sequence has been identified. This sequence consists of a central region 78 to 86bp in length which is greater than 90% A + T, usually in runs of As and runs of Ts. The central region is flanked on one side by a highly conserved 8bp sequence and on the other side by a highly conserved 25bp sequence which contains partial dyad symmetry around a central C/G base pair. Mutational analyses have been used to determine the importance of each subset of the consensus sequence to centromere function. A protein which binds to the 8bp sequence and at least one that binds to the 25bp sequence have been identified. The roles of these proteins in centromere function in mitosis and meiosis are currently under investigation.
Mol Microbiol 1990 Mar
PMID:Cis- and trans-acting factors involved in centromere function in Saccharomyces cerevisiae. 219 27

A theory is presented proposing that genetic regulation in mammalian cells is at least a two-tiered effect; that one level of regulation involves the transition between gene exposure and sequestration; that normal differentiation requires a different spectrum of genes to be exposed in each separate state of differentiation; that the fiber systems of the cell cytoskeleton and the nuclear matrix together control the degree of gene exposure; that specific phosphorylation of these elements causes them to assume a different organizational network and to impose a different pattern of sequestration and exposure on the elements of the genome; that the varied gene phosphorylation mechanisms in the cell are integrated in this function; that attachment of this network system to specific parts of the chromosomes brings about sequestration or exposure of the genes in their neighborhood in a fashion similar to that observed when microtubule elements attach through the kinetochore to the centromeric DNA; that one function of repetitive sequences is to serve as elements for the final attachment of this fibrous network to the specific chromosomal loci; and that at least an important part of the calcium manifestation as a metabolic trigger of different differentiation states involves its acting as a binding agent to centers of electronegativity, in particular proteins and especially phosphorylated groups, so as to change the conformation of the fiber network that ultimately controls gene exposure in the mammalian cell. It would appear essential to determine what abnormal gene exposures and sequestrations are characteristic of each type of cancer; which agonists, if any, will bring about reverse transformation; and whether these considerations can be used in therapy.
Somat Cell Mol Genet 1990 May
PMID:Genome regulation in mammalian cells. 219 4

By using T4 DNA polymerase rather than S1 or Bal31 nuclease to clone yeast telomeres, very little telomeric DNA is lost. These clones were used to determine the DNA sequence of virtually the entire telomeric tract. Our results demonstrated that a slightly modified version, C2-3A(CA)1-6, of the consensus derived from sequence analysis of more-internal regions (J. Shampay, J. W. Szostak, and E. H. Blackburn, Nature [London] 310:154-157, 1984) extends to the very end of the chromosome. The sequence analysis also suggests that yeast telomeres consist of two domains: the proximal 120 to 150 base pairs, which appear to be protected from processes such as recombination, degradation, and elongation, and the distal portion of the telomere, which is more susceptible to these events.
Mol Cell Biol 1990 Aug
PMID:Sequencing of Saccharomyces telomeres cloned using T4 DNA polymerase reveals two domains. 219 53

Saccharomyces cerevisiae centromeric DNA is packaged into a highly nuclease-resistant chromatin core of approximately 200 base pairs of DNA. The structure of the centromere in chromosome III is somewhat larger than a 160-base-pair nucleosomal core and encompasses the conserved centromere DNA elements (CDE I, II, and III). Extensive mutational analysis has revealed the sequence requirements for centromere function. Mutations affecting the segregation properties of centromeres also exhibit altered chromatin structures in vivo. Thus the structure, as delineated by nuclease digestion, correlated with functional centromeres. We have determined the contribution of histone proteins to this unique structural organization. Nucleosome depletion by repression of either histone H2B or H4 rendered the cell incapable of chromosome segregation. Histone repression resulted in increased nuclease sensitivity of centromere DNA, with up to 40% of CEN3 DNA molecules becoming accessible to nucleolytic attack. Nucleosome depletion also resulted in an alteration in the distribution of nuclease cutting sites in the DNA surrounding CEN3. These data provide the first indication that authentic nucleosomal subunits flank the centromere and suggest that nucleosomes may be the central core of the centromere itself.
Mol Cell Biol 1990 Nov
PMID:Nucleosome depletion alters the chromatin structure of Saccharomyces cerevisiae centromeres. 223 14

The timing of replication of centromere-associated human alpha satellite DNA from chromosomes X, 17, and 7 as well as of human telomeric sequences was determined by using density-labeling methods and fluorescence-activated cell sorting. Alpha satellite sequences replicated late in S phase; however, the alpha satellite sequences of the three chromosomes studied replicated at slightly different times. Human telomeres were found to replicate throughout most of S phase. These results are consistent with a model in which multiple initiations of replication occur at a characteristic time within the alpha satellite repeats of a particular chromosome, while the replication timing of telomeric sequences is determined by either telomeric origins that can initiate at different times during S phase or by replication origins within the flanking chromosomal DNA sequences.
Mol Cell Biol 1990 Dec
PMID:Replication timing of DNA sequences associated with human centromeres and telomeres. 224 59


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