scholarly journals Telomere Roles in Fungal Genome Evolution and Adaptation

2021 ◽  
Vol 12 ◽  
Author(s):  
Mostafa Rahnama ◽  
Baohua Wang ◽  
Jane Dostart ◽  
Olga Novikova ◽  
Daniel Yackzan ◽  
...  
Keyword(s):  
Protein Complexes ◽  
Repeated Sequence ◽  
Strand Break ◽  
Telomere Maintenance ◽  
Fungal Genome ◽  
Sequence Motifs ◽  
Rapid Accumulation ◽  
Telomere Function ◽  
Linear Chromosomes ◽  
Frequent Presence

Telomeres form the ends of linear chromosomes and usually comprise protein complexes that bind to simple repeated sequence motifs that are added to the 3′ ends of DNA by the telomerase reverse transcriptase (TERT). One of the primary functions attributed to telomeres is to solve the “end-replication problem” which, if left unaddressed, would cause gradual, inexorable attrition of sequences from the chromosome ends and, eventually, loss of viability. Telomere-binding proteins also protect the chromosome from 5′ to 3′ exonuclease action, and disguise the chromosome ends from the double-strand break repair machinery whose illegitimate action potentially generates catastrophic chromosome aberrations. Telomeres are of special interest in the blast fungus, Pyricularia, because the adjacent regions are enriched in genes controlling interactions with host plants, and the chromosome ends show enhanced polymorphism and genetic instability. Previously, we showed that telomere instability in some P. oryzae strains is caused by novel retrotransposons (MoTeRs) that insert in telomere repeats, generating interstitial telomere sequences that drive frequent, break-induced rearrangements. Here, we sought to gain further insight on telomeric involvement in shaping Pyricularia genome architecture by characterizing sequence polymorphisms at chromosome ends, and surrounding internalized MoTeR loci (relics) and interstitial telomere repeats. This provided evidence that telomere dynamics have played historical, and likely ongoing, roles in shaping the Pyricularia genome. We further demonstrate that even telomeres lacking MoTeR insertions are poorly preserved, such that the telomere-adjacent sequences exhibit frequent presence/absence polymorphism, as well as exchanges with the genome interior. Using TERT knockout experiments, we characterized chromosomal responses to failed telomere maintenance which suggested that much of the MoTeR relic-/interstitial telomere-associated polymorphism could be driven by compromised telomere function. Finally, we describe three possible examples of a phenomenon known as “Adaptive Telomere Failure,” where spontaneous losses of telomere maintenance drive rapid accumulation of sequence polymorphism with possible adaptive advantages. Together, our data suggest that telomere maintenance is frequently compromised in Pyricularia but the chromosome alterations resulting from telomere failure are not as catastrophic as prior research would predict, and may, in fact, be potent drivers of adaptive polymorphism.

scholarly journals G-Quadruplexes at Telomeres: Friend or Foe?

Molecules ◽  
2020 ◽  
Vol 25 (16) ◽  
pp. 3686 ◽  
Author(s):  
Tracy M. Bryan
Keyword(s):  
Tandem Repeats ◽  
Genome Instability ◽  
Protein Complexes ◽  
Telomere Maintenance ◽  
Telomeric Dna ◽  
Positive Role ◽  
Telomere Biology ◽  
Linear Chromosomes

Telomeres are DNA-protein complexes that cap and protect the ends of linear chromosomes. In almost all species, telomeric DNA has a G/C strand bias, and the short tandem repeats of the G-rich strand have the capacity to form into secondary structures in vitro, such as four-stranded G-quadruplexes. This has long prompted speculation that G-quadruplexes play a positive role in telomere biology, resulting in selection for G-rich tandem telomere repeats during evolution. There is some evidence that G-quadruplexes at telomeres may play a protective capping role, at least in yeast, and that they may positively affect telomere maintenance by either the enzyme telomerase or by recombination-based mechanisms. On the other hand, G-quadruplex formation in telomeric DNA, as elsewhere in the genome, can form an impediment to DNA replication and a source of genome instability. This review summarizes recent evidence for the in vivo existence of G-quadruplexes at telomeres, with a focus on human telomeres, and highlights some of the many unanswered questions regarding the location, form, and functions of these structures.

Metallocluster transactions: dynamic protein interactions guide the biosynthesis of Fe–S clusters in bacteria

2018 ◽  
Vol 46 (6) ◽  
pp. 1593-1603 ◽  
Author(s):  
Chenkang Zheng ◽  
Patricia C. Dos Santos
Keyword(s):  
Protein Interactions ◽  
Protein Complexes ◽  
Specific Protein ◽  
Biological Synthesis ◽  
Cluster Assembly ◽  
Sequence Motifs ◽  
Protein Protein Interactions ◽  
Cysteine Desulfurase ◽  
Wide Range ◽  
Domains Of Life

Iron–sulfur (Fe–S) clusters are ubiquitous cofactors present in all domains of life. The chemistries catalyzed by these inorganic cofactors are diverse and their associated enzymes are involved in many cellular processes. Despite the wide range of structures reported for Fe–S clusters inserted into proteins, the biological synthesis of all Fe–S clusters starts with the assembly of simple units of 2Fe–2S and 4Fe–4S clusters. Several systems have been associated with the formation of Fe–S clusters in bacteria with varying phylogenetic origins and number of biosynthetic and regulatory components. All systems, however, construct Fe–S clusters through a similar biosynthetic scheme involving three main steps: (1) sulfur activation by a cysteine desulfurase, (2) cluster assembly by a scaffold protein, and (3) guided delivery of Fe–S units to either final acceptors or biosynthetic enzymes involved in the formation of complex metalloclusters. Another unifying feature on the biological formation of Fe–S clusters in bacteria is that these systems are tightly regulated by a network of protein interactions. Thus, the formation of transient protein complexes among biosynthetic components allows for the direct transfer of reactive sulfur and Fe–S intermediates preventing oxygen damage and reactions with non-physiological targets. Recent studies revealed the importance of reciprocal signature sequence motifs that enable specific protein–protein interactions and consequently guide the transactions between physiological donors and acceptors. Such findings provide insights into strategies used by bacteria to regulate the flow of reactive intermediates and provide protein barcodes to uncover yet-unidentified cellular components involved in Fe–S metabolism.

scholarly journals DNA Damage-Induced Phosphorylation of TRF2 Is Required for the Fast Pathway of DNA Double-Strand Break Repair

2009 ◽  
Vol 29 (13) ◽  
pp. 3597-3604 ◽  
Author(s):  
Nazmul Huda ◽  
Hiromi Tanaka ◽  
Marc S. Mendonca ◽  
David Gilley
Keyword(s):  
Dna Damage ◽  
Dna Damage Response ◽  
Functional Role ◽  
Strand Break ◽  
Telomere Maintenance ◽  
Telomeric Dna ◽  
Dsb Repair ◽  
Dna Double Strand Break ◽  
Damage Response ◽  
Fast Pathway

ABSTRACT Protein kinases of the phosphatidylinositol 3-kinase-like kinase family, originally known to act in maintaining genomic integrity via DNA repair pathways, have been shown to also function in telomere maintenance. Here we focus on the functional role of DNA damage-induced phosphorylation of the essential mammalian telomeric DNA binding protein TRF2, which coordinates the assembly of the proteinaceous cap to disguise the chromosome end from being recognized as a double-stand break (DSB). Previous results suggested a link between the transient induction of human TRF2 phosphorylation at threonine 188 (T188) by the ataxia telangiectasia mutated protein kinase (ATM) and the DNA damage response. Here, we report evidence that X-ray-induced phosphorylation of TRF2 at T188 plays a role in the fast pathway of DNA DSB repair. These results connect the highly transient induction of human TRF2 phosphorylation to the DNA damage response machinery. Thus, we find that a protein known to function in telomere maintenance, TRF2, also plays a functional role in DNA DSB repair.

Sequences from sea urchin TU transposons are conserved among multiple eucaryotic species, including humans

1986 ◽  
Vol 6 (1) ◽  
pp. 218-226
Author(s):  
D Liebermann ◽  
B Hoffman-Liebermann ◽  
A B Troutt ◽  
L Kedes ◽  
S N Cohen
Keyword(s):  
Sea Urchin ◽  
Repeat Unit ◽  
Regulation Of Gene Expression ◽  
Direct Repeat ◽  
Repeated Sequence ◽  
Sequence Motifs ◽  
Transcription Control ◽  
Sequence Comparisons ◽  
Cellular Genes ◽  
Outer Domain

Sequences homologous to various structural domains of the Strongylocentrotus purpuratus TU family of transposons are present in sea urchin species closely related to S. purpuratus and were found in close proximity to each other in linkage patterns that differed for different species. Sequence homologs of the inverted repeat outer domain (IVR-OD) segment were, in addition, present in a sea urchin related only distantly to S. purpuratus and in all other eucaryotic organisms surveyed. In humans, a polymorphic hybridization pattern was seen for genomic DNA obtained from different individuals. Sequence comparisons revealed that repeated sequence motifs similar to those making up the 15-base-pair direct repeat unit of the IVR-OD domain of the TU elements exist in the IVRs of transposons identified in Drosophila melanogaster and maize and in the transcription control regions of certain eucaryotic viral and cellular genes. The remarkable evolutionary conservation of IVR-OD homologs may reflect a biological role for these sequences in DNA transposition, the regulation of gene expression, or both.

scholarly journals Genetic Requirements for RAD51- andRAD54-Independent Break-Induced Replication Repair of a Chromosomal Double-Strand Break

2001 ◽  
Vol 21 (6) ◽  
pp. 2048-2056 ◽  
Author(s):  
Laurence Signon ◽  
Anna Malkova ◽  
Maria L. Naylor ◽  
Hannah Klein ◽  
James E. Haber
Keyword(s):  
Saccharomyces Cerevisiae ◽  
Homologous Recombination ◽  
Gene Conversion ◽  
Strand Break ◽  
Double Strand Break ◽  
Telomere Maintenance ◽  
Diploid Cells ◽  
Break Induced Replication ◽  
In Cells

ABSTRACT Broken chromosomes can be repaired by several homologous recombination mechanisms, including gene conversion and break-induced replication (BIR). In Saccharomyces cerevisiae, an HO endonuclease-induced double-strand break (DSB) is normally repaired by gene conversion. Previously, we have shown that in the absence ofRAD52, repair is nearly absent and diploid cells lose the broken chromosome; however, in cells lacking RAD51, gene conversion is absent but cells can repair the DSB by BIR. We now report that gene conversion is also abolished when RAD54, RAD55, and RAD57 are deleted but BIR occurs, as withrad51Δ cells. DSB-induced gene conversion is not significantly affected when RAD50, RAD59, TID1(RDH54), SRS2, or SGS1 is deleted. Various double mutations largely eliminate both gene conversion and BIR, including rad51Δ rad50Δ, rad51Δ rad59Δ, andrad54Δ tid1Δ. These results demonstrate that there is aRAD51- and RAD54-independent BIR pathway that requires RAD59, TID1, RAD50, and presumablyMRE11 and XRS2. The similar genetic requirements for BIR and telomere maintenance in the absence of telomerase also suggest that these two processes proceed by similar mechanisms.

scholarly journals Structural Features of Nucleoprotein CST/Shelterin Complex Involved in the Telomere Maintenance and Its Association with Disease Mutations

Cells ◽  
2020 ◽  
Vol 9 (2) ◽  
pp. 359 ◽  
Author(s):  
Mohd. Amir ◽  
Parvez Khan ◽  
Aarfa Queen ◽  
Ravins Dohare ◽  
Mohamed F. Alajmi ◽  
...  
Keyword(s):  
Genome Stability ◽  
Tandem Repeats ◽  
Structural Features ◽  
Premature Aging ◽  
Telomere Maintenance ◽  
Clear Understanding ◽  
Disease Mutations ◽  
Damage Response ◽  
Linear Chromosomes ◽  
Lagging Strand

Telomere comprises the ends of eukaryotic linear chromosomes and is composed of G-rich (TTAGGG) tandem repeats which play an important role in maintaining genome stability, premature aging and onsets of many diseases. Majority of the telomere are replicated by conventional DNA replication, and only the last bit of the lagging strand is synthesized by telomerase (a reverse transcriptase). In addition to replication, telomere maintenance is principally carried out by two key complexes known as shelterin (TRF1, TRF2, TIN2, RAP1, POT1, and TPP1) and CST (CDC13/CTC1, STN1, and TEN1). Shelterin protects the telomere from DNA damage response (DDR) and regulates telomere length by telomerase; while, CST govern the extension of telomere by telomerase and C strand fill-in synthesis. We have investigated both structural and biochemical features of shelterin and CST complexes to get a clear understanding of their importance in the telomere maintenance. Further, we have analyzed ~115 clinically important mutations in both of the complexes. Association of such mutations with specific cellular fault unveils the importance of shelterin and CST complexes in the maintenance of genome stability. A possibility of targeting shelterin and CST by small molecule inhibitors is further investigated towards the therapeutic management of associated diseases. Overall, this review provides a possible direction to understand the mechanisms of telomere borne diseases, and their therapeutic intervention.

Control of genome stability by Slx protein complexes

2009 ◽  
Vol 37 (3) ◽  
pp. 495-510 ◽  
Author(s):  
John Rouse
Keyword(s):  
Dna Damage ◽  
Dna Replication ◽  
Protein Interactions ◽  
Cellular Response ◽  
Genome Stability ◽  
Molecular Mechanisms ◽  
Excision Repair ◽  
Protein Complexes ◽  
Alkylating Agents ◽  
Strand Break

The six Saccharomyces cerevisiae SLX genes were identified in a screen for factors required for the viability of cells lacking Sgs1, a member of the RecQ helicase family involved in processing stalled replisomes and in the maintenance of genome stability. The six SLX gene products form three distinct heterodimeric complexes, and all three have catalytic activity. Slx3–Slx2 (also known as Mus81–Mms4) and Slx1–Slx4 are both heterodimeric endonucleases with a marked specificity for branched replication fork-like DNA species, whereas Slx5–Slx8 is a SUMO (small ubiquitin-related modifier)-targeted E3 ubiquitin ligase. All three complexes play important, but distinct, roles in different aspects of the cellular response to DNA damage and perturbed DNA replication. Slx4 interacts physically not only with Slx1, but also with Rad1–Rad10 [XPF (xeroderma pigmentosum complementation group F)–ERCC1 (excision repair cross-complementing 1) in humans], another structure-specific endonuclease that participates in the repair of UV-induced DNA damage and in a subpathway of recombinational DNA DSB (double-strand break) repair. Curiously, Slx4 is essential for repair of DSBs by Rad1–Rad10, but is not required for repair of UV damage. Slx4 also promotes cellular resistance to DNA-alkylating agents that block the progression of replisomes during DNA replication, by facilitating the error-free mode of lesion bypass. This does not require Slx1 or Rad1–Rad10, and so Slx4 has several distinct roles in protecting genome stability. In the present article, I provide an overview of our current understanding of the cellular roles of the Slx proteins, paying particular attention to the advances that have been made in understanding the cellular roles of Slx4. In particular, protein–protein interactions and underlying molecular mechanisms are discussed and I draw attention to the many questions that have yet to be answered.

scholarly journals TEL2, an essential gene required for telomere length regulation and telomere position effect in Saccharomyces cerevisiae.

1996 ◽  
Vol 16 (6) ◽  
pp. 3094-3105 ◽  
Author(s):  
K W Runge ◽  
V A Zakian
Keyword(s):  
Saccharomyces Cerevisiae ◽  
Dna Sequences ◽  
Transcriptional Repression ◽  
Protein Complexes ◽  
Essential Gene ◽  
Position Effect ◽  
Repeated Sequence ◽  
Telomeric Dna ◽  
Telomere Position Effect ◽  
Telomere Lengthening

The DNA-protein complexes at the ends of linear eukaryotic chromosomes are called the telomeres. In Saccharomyces cerevisiae, telomeric DNA consists of a variable length of the short repeated sequence C1-3A. The length of yeast telomeres can be altered by mutation, by changing the levels of telomere binding proteins, or by increasing the amount of C1-3A DNA sequences. Cells bearing the tel1-1 or tel2-1 mutations, known previously to have short telomeres, did not respond to perturbations that caused telomere lengthening in wild-type cells. The transcription of genes placed near yeast telomeres is reversibly repressed, a phenomenon called the telomere position effect. The tel2-1 mutation reduced the position effect but did not affect transcriptional repression at the silent mating type cassettes, HMRa and HML alpha. The TEL2 gene was cloned, sequenced, and disrupted. Cells lacking TEL2 function died, with some cells arresting as large cells with three or four small protrusions or "blebs."

scholarly journals DNA Strand Break-Sensing Molecule Poly(ADP-Ribose) Polymerase Cooperates with p53 in Telomere Function, Chromosome Stability, and Tumor Suppression

2001 ◽  
Vol 21 (12) ◽  
pp. 4046-4054 ◽  
Author(s):  
Wei-Min Tong ◽  
M. Prakash Hande ◽  
Peter M. Lansdorp ◽  
Zhao-Qi Wang
Keyword(s):  
Strand Break ◽  
Cell Cycle Checkpoints ◽  
High Rate ◽  
Loss Of Function ◽  
Li Fraumeni Syndrome ◽  
Dna Strand Break ◽  
Telomere Function ◽  
Dna Strand ◽  
High Degree ◽  
Mutant Cells

ABSTRACT Genomic instability is often caused by mutations in genes that are involved in DNA repair and/or cell cycle checkpoints, and it plays an important role in tumorigenesis. Poly(ADP-ribose) polymerase (PARP) is a DNA strand break-sensing molecule that is involved in the response to DNA damage and the maintenance of telomere function and genomic stability. We report here that, compared to single-mutant cells, PARP and p53 double-mutant cells exhibit many severe chromosome aberrations, including a high degree of aneuploidy, fragmentations, and end-to-end fusions, which may be attributable to telomere dysfunction. While PARP−/− cells showed telomere shortening and p53−/− cells showed normal telomere length, inactivation of PARP in p53−/− cells surprisingly resulted in very long and heterogeneous telomeres, suggesting a functional interplay between PARP and p53 at the telomeres. Strikingly, PARP deficiency widens the tumor spectrum in mice deficient in p53, resulting in a high frequency of carcinomas in the mammary gland, lung, prostate, and skin, as well as brain tumors, reminiscent of Li-Fraumeni syndrome in humans. The enhanced tumorigenesis is likely to be caused by PARP deficiency, which facilitates the loss of function of tumor suppressor genes as demonstrated by a high rate of loss of heterozygosity at the p53 locus in these tumors. These results indicate that PARP and p53 interact to maintain genome integrity and identify PARP as a cofactor for suppressing tumorigenesis.

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