scholarly journals The Ku Heterodimer Performs Separable Activities at Double-Strand Breaks and Chromosome Termini

2003 ◽  
Vol 23 (22) ◽  
pp. 8202-8215 ◽  
Author(s):  
Alison A. Bertuch ◽  
Victoria Lundblad
Keyword(s):  
Telomere Length ◽  
Large Subunit ◽  
Double Strand Breaks ◽  
Detailed Characterization ◽  
Strand Breaks ◽  
Functional Differences ◽  
Length Regulation ◽  
Telomere Length Regulation ◽  
Dna Ends

ABSTRACT The Ku heterodimer functions at two kinds of DNA ends: telomeres and double-strand breaks. The role that Ku plays at these two classes of termini must be distinct, because Ku is required for accurate and efficient joining of double-strand breaks while similar DNA repair events are normally prohibited at chromosome ends. Toward defining these functional differences, we have identified eight mutations in the large subunit of the Saccharomyces cerevisiae Ku heterodimer (YKU80) which retain the ability to repair double-strand breaks but are severely impaired for chromosome end protection. Detailed characterization of these mutations, referred to as yku80tel alleles, has revealed that Ku performs functionally distinct activities at subtelomeric chromatin versus the end of the chromosome, and these activities are separable from Ku's role in telomere length regulation. While at the chromosome terminus, we propose that Ku participates in two different activities: it facilitates telomerase-mediated G-strand synthesis, thereby contributing to telomere length regulation, and it separately protects against resection of the C-strand, thereby contributing to protection of chromosome termini. Furthermore, we propose that the Ku heterodimer performs discrete sets of functions at chromosome termini and at duplex subtelomeric chromatin, via separate interactions with these two locations. Based on homology modeling with the human Ku structure, five of the yku80tel alleles mutate residues that are conserved between the yeast and human Ku80 proteins, suggesting that these mutations probe activities that are shared between yeast and humans.

scholarly journals Mechanisms of the Evolutionary Chromosome Plasticity: Integrating the ‘Centromere-from-Telomere' Hypothesis with Telomere Length Regulation

2016 ◽  
Vol 148 (4) ◽  
pp. 268-278 ◽  
Author(s):  
Predrag Slijepcevic
Keyword(s):  
Telomere Length ◽  
Length Distribution ◽  
Adaptive Responses ◽  
Eukaryotic Chromosome ◽  
Free Dna ◽  
Length Regulation ◽  
Telomere Length Regulation ◽  
Dna Ends ◽  
Size Gradient ◽  
Insight Into

The ‘centromere-from-telomere' hypothesis proposed by Villasante et al. [2007a] aims to explain the evolutionary origin of the eukaryotic chromosome. The hypothesis is based on the notion that the process of eukaryogenesis was initiated by adaptive responses of the symbiont eubacterium and its archaeal host to their new conditions. The adaptive responses included fragmentation of the circular genome of the host into multiple linear fragments with free DNA ends. The action of mobile genetic elements stabilized the free DNA ends resulting in the formation of proto-telomeres. Sequences next to the proto-telomeres, the subtelomeric sequences, were immediately targeted as the new cargo by the tubulin-based cytoskeleton, thus becoming proto-centromeres. A period of genomic instability followed. Eventually, functioning centromeres and telomeres emerged heralding the arrival of the eukaryotic chromosome in the evolution. This paper expands the ‘centromere-from-telomere' hypothesis by integrating it with 2 sets of data: chromosome-specific telomere length distribution and chromomere size gradient. The integration adds a new dimension to the hypothesis but also provides an insight into the mechanisms of chromosome plasticity underlying karyotype evolution.

scholarly journals Telomere length regulation by Rif1 protein from Hansenula polymorpha

2021 ◽  
Author(s):  
Alexander N. Malyavko ◽  
Olga A. Petrova ◽  
Maria I. Zvereva ◽  
Vladimir Polshakov ◽  
Olga A. Dontsova
Keyword(s):  
Telomere Length ◽  
Yeast Species ◽  
Hansenula Polymorpha ◽  
Functional Characterization ◽  
Strand Break ◽  
Telomere Elongation ◽  
Intrinsically Disordered ◽  
Length Regulation ◽  
Telomere Length Regulation

Rif1 is a large multifaceted protein involved in various processes of DNA metabolism – from telomere length regulation and replication to double-strand break repair. The mechanistic details of its action, however, are often poorly understood. Here, we report functional characterization of the Rif1 homologue from methylotrophic thermotolerant budding yeast Hansenula polymorpha DL-1. We show that, similar to other yeast species, H. polymorpha Rif1 suppresses telomerase-dependent telomere elongation. We uncover two novel modes of Rif1 recruitment at H. polymorpha telomeres: via direct DNA binding and through the association with the Ku heterodimer. Both of these modes (at least partially) require the intrinsically disordered N-terminal extension – a region of the protein present exclusively in yeast species. We also demonstrate that Rif1 binds Stn1 and promotes its accumulation at telomeres in H. polymorpha.

scholarly journals Rif1 regulates telomere length through conserved HEAT repeats

2021 ◽  
Vol 49 (7) ◽  
pp. 3967-3980
Author(s):  
Calla B Shubin ◽  
Rini Mayangsari ◽  
Ariel D Swett ◽  
Carol W Greider
Keyword(s):  
Dna Binding ◽  
Telomere Length ◽  
Functional Role ◽  
Conserved Residues ◽  
Binding Interface ◽  
Binding Function ◽  
Length Regulation ◽  
Telomere Length Regulation ◽  
Telomere Regulation ◽  
Conserved Amino Acids

AbstractIn budding yeast, Rif1 negatively regulates telomere length, but the mechanism of this regulation has remained elusive. Previous work identified several functional domains of Rif1, but none of these has been shown to mediate telomere length. To define Rif1 domains responsible for telomere regulation, we localized truncations of Rif1 to a single specific telomere and measured telomere length of that telomere compared to bulk telomeres. We found that a domain in the N-terminus containing HEAT repeats, Rif1177–996, was sufficient for length regulation when tethered to the telomere. Charged residues in this region were previously proposed to mediate DNA binding. We found that mutation of these residues disrupted telomere length regulation even when Rif1 was tethered to the telomere. Mutation of other conserved residues in this region, which were not predicted to interact with DNA, also disrupted telomere length maintenance, while mutation of conserved residues distal to this region did not. Our data suggest that conserved amino acids in the region from 436 to 577 play a functional role in telomere length regulation, which is separate from their proposed DNA binding function. We propose that the Rif1 HEAT repeats region represents a protein-protein binding interface that mediates telomere length regulation.

scholarly journals Cdc13 N-Terminal Dimerization, DNA Binding, and Telomere Length Regulation

2010 ◽  
Vol 30 (22) ◽  
pp. 5325-5334 ◽  
Author(s):  
Meghan T. Mitchell ◽  
Jasmine S. Smith ◽  
Mark Mason ◽  
Sandy Harper ◽  
David W. Speicher ◽  
...  
Keyword(s):  
Dna Binding ◽  
Telomere Length ◽  
Functional Characterization ◽  
Point Mutations ◽  
Telomeric Dna ◽  
Dna Binding Domains ◽  
Binding Domains ◽  
Length Regulation ◽  
Telomere Length Regulation

ABSTRACT The essential yeast protein Cdc13 facilitates chromosome end replication by recruiting telomerase to telomeres, and together with its interacting partners Stn1 and Ten1, it protects chromosome ends from nucleolytic attack, thus contributing to genome integrity. Although Cdc13 has been studied extensively, the precise role of its N-terminal domain (Cdc13N) in telomere length regulation remains unclear. Here we present a structural, biochemical, and functional characterization of Cdc13N. The structure reveals that this domain comprises an oligonucleotide/oligosaccharide binding (OB) fold and is involved in Cdc13 dimerization. Biochemical data show that Cdc13N weakly binds long, single-stranded, telomeric DNA in a fashion that is directly dependent on domain oligomerization. When introduced into full-length Cdc13 in vivo, point mutations that prevented Cdc13N dimerization or DNA binding caused telomere shortening or lengthening, respectively. The multiple DNA binding domains and dimeric nature of Cdc13 offer unique insights into how it coordinates the recruitment and regulation of telomerase access to the telomeres.

scholarly journals Autophosphorylation of DNA-PKCS regulates its dynamics at DNA double-strand breaks

2007 ◽  
Vol 177 (2) ◽  
pp. 219-229 ◽  
Author(s):  
Naoya Uematsu ◽  
Eric Weterings ◽  
Ken-ichi Yano ◽  
Keiko Morotomi-Yano ◽  
Burkhard Jakob ◽  
...  
Keyword(s):  
Kinase Activity ◽  
Laser System ◽  
Double Strand Breaks ◽  
Dependent Manner ◽  
Dna Double Strand Breaks ◽  
End Joining ◽  
Dsb Repair ◽  
Strand Breaks ◽  
Dna Ends

The DNA-dependent protein kinase catalytic subunit (DNA-PKCS) plays an important role during the repair of DNA double-strand breaks (DSBs). It is recruited to DNA ends in the early stages of the nonhomologous end-joining (NHEJ) process, which mediates DSB repair. To study DNA-PKCS recruitment in vivo, we used a laser system to introduce DSBs in a specified region of the cell nucleus. We show that DNA-PKCS accumulates at DSB sites in a Ku80-dependent manner, and that neither the kinase activity nor the phosphorylation status of DNA-PKCS influences its initial accumulation. However, impairment of both of these functions results in deficient DSB repair and the maintained presence of DNA-PKCS at unrepaired DSBs. The use of photobleaching techniques allowed us to determine that the kinase activity and phosphorylation status of DNA-PKCS influence the stability of its binding to DNA ends. We suggest a model in which DNA-PKCS phosphorylation/autophosphorylation facilitates NHEJ by destabilizing the interaction of DNA-PKCS with the DNA ends.

How damaged is the biologically active subpopulation of transfected DNA?

1984 ◽  
Vol 4 (3) ◽  
pp. 387-398
Author(s):  
C T Wake ◽  
T Gudewicz ◽  
T Porter ◽  
A White ◽  
J H Wilson
Keyword(s):  
Simian Virus 40 ◽  
Simian Virus ◽  
Double Strand Breaks ◽  
Biologically Active ◽  
Exact Nature ◽  
Dna Molecules ◽  
Base Pairs ◽  
Strand Breaks ◽  
Dna Ends ◽  
Prevalent Form

Relatively little is known about the damage suffered by transfected DNA molecules during their journey from outside the cell into the nucleus. To follow selectively the minor subpopulation that completes this journey, we devised a genetic approach using simian virus 40 DNA transfected with DEAE-dextran. We investigated this active subpopulation in three ways: (i) by assaying reciprocal pairs of mutant linear dimers which differed only in the arrangement of two mutant genomes; (ii) by assaying a series of wild-type oligomers which ranged from 1.1 to 2.0 simian virus 40 genomes in length; and (iii) by assaying linear monomers of simian virus 40 which were cleaved within a nonessential region to leave either sticky, blunt, or mismatched ends. We conclude from these studies that transfected DNA molecules in the active subpopulation are moderately damaged by fragmentation and modification of ends. As a whole, the active subpopulation suffers about one break per 5 to 15 kilobases, and about 15 to 20% of the molecules have one or both ends modified. Our analysis of fragmentation is consistent with the random introduction of double-strand breaks, whose cause and exact nature are unknown. Our analysis of end modification indicated that the most prevalent form of damage involved deletion or addition of less than 25 base pairs. In addition we demonstrated directly that the efficiencies of joining sticky, blunt, or mismatched ends are identical, verifying the apparent ability of cells to join nearly any two DNA ends and suggesting that the efficiency of joining approaches 100%. The design of these experiments ensured that the detected damage preceded viral replication and thus should be common to all DNAs transfected with DEAE-dextran and not specific for viral DNA. These measurements of damage within transfected DNA have important consequences for studies of homologous and nonhomologous recombination in somatic cells as is discussed.

scholarly journals Genetic Separation of Sae2 Nuclease Activity from Mre11 Nuclease Functions in Budding Yeast

2017 ◽  
Vol 37 (24) ◽  
Author(s):  
Sucheta Arora ◽  
Rajashree A. Deshpande ◽  
Martin Budd ◽  
Judy Campbell ◽  
America Revere ◽  
...  
Keyword(s):  
Nuclease Activity ◽  
Double Strand Breaks ◽  
Endonuclease Activity ◽  
Dna Double Strand Breaks ◽  
Dna Breaks ◽  
Content Type ◽  
Strand Breaks ◽  
Dna Ends

ABSTRACT Sae2 promotes the repair of DNA double-strand breaks in Saccharomyces cerevisiae. The role of Sae2 is linked to the Mre11/Rad50/Xrs2 (MRX) complex, which is important for the processing of DNA ends into single-stranded substrates for homologous recombination. Sae2 has intrinsic endonuclease activity, but the role of this activity has not been assessed independently from its functions in promoting Mre11 nuclease activity. Here we identify and characterize separation-of-function mutants that lack intrinsic nuclease activity or the ability to promote Mre11 endonucleolytic activity. We find that the ability of Sae2 to promote MRX nuclease functions is important for DNA damage survival, particularly in the absence of Dna2 nuclease activity. In contrast, Sae2 nuclease activity is essential for DNA repair when the Mre11 nuclease is compromised. Resection of DNA breaks is impaired when either Sae2 activity is blocked, suggesting roles for both Mre11 and Sae2 nuclease activities in promoting the processing of DNA ends in vivo. Finally, both activities of Sae2 are important for sporulation, indicating that the processing of meiotic breaks requires both Mre11 and Sae2 nuclease activities.

scholarly journals Regulating telomere length from the inside out: The replication fork model

2016 ◽  
Author(s):  
Carol W Greider
Keyword(s):  
Telomere Length ◽  
Alternative Model ◽  
Replication Fork ◽  
Molecular Level ◽  
Origin Firing ◽  
Length Regulation ◽  
Telomere Length Regulation ◽  
Inside Out ◽  
Counting Model

Telomere length is regulated around an equilibrium set point. Telomeres shorten during replication and are lengthened by telomerase. Disruption of the length equilibrium leads to disease, thus it is important to understand the mechanisms that regulate length at the molecular level. The prevailing protein counting model for regulating telomerase access to elongate the telomere does not explain accumulating evidence of a role of DNA replication in telomere length regulation. Here I present an alternative model: the replication fork model that can explain how passage of a replication fork and regulation of origin firing affect telomere length.

scholarly journals The Drosophila melanogaster Ortholog of RFWD3 Functions Independently of RAD51 During DNA Repair

2020 ◽  
Vol 10 (3) ◽  
pp. 999-1004
Author(s):  
Juan Carvajal-Garcia ◽  
Evan R. Gales ◽  
Dale A. Ramsden ◽  
Jeff Sekelsky
Keyword(s):  
Dna Repair ◽  
Drosophila Melanogaster ◽  
Ring Finger ◽  
Double Strand Breaks ◽  
Specific Gene ◽  
Genetic Screens ◽  
Strand Breaks ◽  
Ancestral Function ◽  
Human Ortholog

Repair of damaged DNA is required for the viability of all organisms. Studies in Drosophila melanogaster, driven by the power of genetic screens, pioneered the discovery and characterization of many genes and pathways involved in DNA repair in animals. However, fewer than half of the alleles identified in these screens have been mapped to a specific gene, leaving a potential for new discoveries in this field. Here we show that the previously uncharacterized mutagen sensitive gene mus302 codes for the Drosophila melanogaster ortholog of the E3 ubiquitin ligase RING finger and WD domain protein 3 (RFWD3). In human cells, RFWD3 promotes ubiquitylation of RPA and RAD51 to facilitate repair of collapsed replication forks and double-strand breaks through homologous recombination. Despite the high similarity in sequence to the human ortholog, our evidence fails to support a role for Mus302 in the repair of these types of damage. Last, we observe that the N-terminal third of RFWD3 is only found in mammals, but not in other vertebrates or invertebrates. We propose that the new N-terminal sequence accounts for the acquisition of a new biological function in mammals that explains the functional differences between the human and the fly orthologs, and that Drosophila Mus302 may retain the ancestral function of the protein.

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