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1 enes obtained in this screen were named CST (chromosome stability).
2 important roles of condensin in maintaining chromosome stability.
3 o facilitate telomere repeat replication and chromosome stability.
4 plex, required for the maintenance of normal chromosome stability.
5 a proteins in a cellular pathway controlling chromosome stability.
6 2p and/or Sir3p cause a profound decrease in chromosome stability.
7 ne acetylation and of chromatin structure on chromosome stability.
8 idual human autosomes, and are essential for chromosome stability.
9 replication origins, explaining submegabase chromosome stability.
10 uclear and cytoplasmic processes that affect chromosome stability.
11 ce of silent heterochromatin is required for chromosome stability.
12 C) seriation algorithms can inform models of chromosome stability.
13 DSBs, promoting HR, replication recovery and chromosome stability.
14 repair by homologous recombination (HR) and chromosome stability.
15 DNA transactions are also required for whole-chromosome stability.
16 ir of DNA interstrand cross-links (ICLs) and chromosome stability.
17 esses independent of iron regulation such as chromosome stability.
18 kinetochore-microtubule attachment to ensure chromosome stability.
19 and crosslinks (ICLs) and the maintenance of chromosome stability.
20 rtant mediators of epigenetic regulation and chromosome stability.
21 processes including the ability to maintain chromosome stability.
22 tial for maintaining telomerase activity and chromosome stability.
23 recombination intermediates and to maintain chromosome stability.
24 rocess important for both viral and cellular chromosome stability.
25 egulation is critical for the maintenance of chromosome stability.
26 between FANC and HRR proteins in maintaining chromosome stability.
27 ociated factors regulate gene expression and chromosome stability.
28 h we define as "telotype") are essential for chromosome stability.
29 lation network that is essential for mitotic chromosome stability.
30 unctions, ionizing radiation sensitivity and chromosome stability.
31 hosphorylation during mitosis in maintaining chromosome stability.
32 biquitin ligase implicated in the control of chromosome stability.
33 the end of chromosomes and are important for chromosome stability.
34 lied to a number of problems associated with chromosome stability.
35 e expression, recombination, DNA repair, and chromosome stability.
36 romeric chromatin and contributes to mitotic chromosome stability.
37 otal role in maintaining telomere length and chromosome stability.
38 ing protein with a critical role in ensuring chromosome stability.
39 al breakage, uncoupling fork protection, and chromosome stability.
40 plays a critical role in the maintenance of chromosome stability.
41 DNA double-strand breaks and in maintaining chromosome stability.
42 ng fully restores mitomycin-C resistance and chromosome stability.
43 in eukaryotic DNA repair, recombination and chromosome stability.
44 ve been used to identify genes important for chromosome stability and as large-fragment cloning vecto
45 eats (LCRs) are genomic features that affect chromosome stability and can produce disease-associated
46 tease Ulp2 is a nuclear protein required for chromosome stability and cell cycle restart after checkp
47 pose that Msc1 acts through H2A.Z to promote chromosome stability and cell survival following DNA dam
49 extensively studied, but the mechanisms for chromosome stability and diploidization in polyploids re
50 a role for maternal proteins in maintaining chromosome stability and euploidy in early-cleavage mous
51 d distinct areas of the protein required for chromosome stability and for limiting access to telomere
52 elomeres have been shown to be essential for chromosome stability and function and to shorten with ea
53 ength maintenance, an activity essential for chromosome stability and genome integrity, is regulated
55 n nuclear architecture, genome organization, chromosome stability and health remains poorly defined.
56 ed the effects of hippo signaling via YAP on chromosome stability and hepatocarcinogenesis in humans
57 in females for epigenetic control of meiotic chromosome stability and in males for haploid gene trans
58 DNA-PKcs in the maintenance of S/G(2)-phase chromosome stability and in the induction of cell cycle
59 e, a medically important enzyme required for chromosome stability and long-term cell proliferation.
60 l role of LIPT1 in regulating DNA damage and chromosome stability and may suggest a means to enhance
63 formation while both SPO11 and REC8 regulate chromosome stability and promote inter-homolog recombina
64 n play important roles in the maintenance of chromosome stability and regulation of gene expression,
66 Yeast cells lacking UFD2 exhibit altered chromosome stability and several spindle-related phenoty
67 cognized role for Shp2 in the maintenance of chromosome stability and suggest a new mechanism by whic
68 for DNAJA2 to regulate mitotic division and chromosome stability and suggests DNAJA2 as a potential
69 tant and P53-independent role in maintaining chromosome stability and suppressing tumor development.
72 ce suggests that such origins play a role in chromosome stability and tumor suppression, though the u
73 d breaks (DSBs) pose a significant threat to chromosome stability and, if left unrepaired, can result
74 ormal cell morphology, decreased plasmid and chromosome stability, and a severe sporulation defect.
75 he roles of Sir2 proteins in gene silencing, chromosome stability, and cell aging and imply that lysi
77 tical role for the CHK1 kinase in regulating chromosome stability, and in particular, common fragile
78 1) plays roles in transcription, DNA repair, chromosome stability, and limiting telomeric silencing.
80 such as gene expression, genomic imprinting, chromosome stability, and the development of the cell.
81 tations tested, yap4 (cin5) mutations affect chromosome stability, and they suppress the cold-sensiti
82 nduce a partial cell cycle arrest and retain chromosome stability are crucial for suppression of earl
84 Compelling links exist between DNMT3B and chromosome stability as emphasized by the mitotic defect
85 tion, identifying mitochondrial function and chromosome stability as key pathways affected by acquisi
87 ls and tumor tissues, suggesting its role in chromosome stability associated with MMR deficiency.
88 plays a critical role in the maintenance of chromosome stability at key stages of meiosis in the fem
89 pha-RMI1-RMI2 (BTR) complex, which maintains chromosome stability at the spindle assembly checkpoint
90 ochromatin (HC) is important for maintaining chromosome stability, but also delays the repair of DNA
92 es the end replication problem and maintains chromosome stability by adding telomeric DNA to the term
93 The DNA repair enzyme telomerase maintains chromosome stability by ensuring that telomeres regenera
94 the FA pathway acts more globally to ensure chromosome stability by promoting efficient end joining
95 CA1/BARD1 heterodimer is believed to enhance chromosome stability by promoting homology-directed repa
96 shelterin complex and functions to maintain chromosome stability by repressing the activation of abe
97 yeast pot1+ gene has an immediate effect on chromosome stability, causing rapid loss of telomeric DN
99 y and participates in cell proliferation and chromosome stability control by incompletely defined mec
101 on-coupled DSB repair and the maintenance of chromosome stability distinct from its role in the G1-S
102 act the genome of many organisms, regulating chromosome stability, gene expression, and DNA repair.
103 D+-dependent deacetylase enzymes involved in chromosome stability, gene silencing and cell aging in e
104 fidelity, as it allows the identification of chromosome stability genes that have not been detected i
106 ereby Sir2 controls phenotypic switching and chromosome stability in C.albicans by organizing chromat
107 epair mechanism that is critical to maintain chromosome stability in cells and to prevent tumor forma
112 some condensation, centromeric function, and chromosome stability in mammalian cells, and link these
121 ssential for maintaining telomere length and chromosome stability in stem cells, germline cells, and
123 e of the central requirements for eukaryotic chromosome stability is the maintenance of the simple se
124 olocomplex (Smc5/6) plays a critical role in chromosome stability maintenance, DNA replication, homol
125 ay include the regulation of peptide import, chromosome stability, meiosis, apoptosis and cardiovascu
127 nd unstable clones for relationships between chromosome stability, reproductive integrity, and apopto
128 condensin expression is necessary to ensure chromosome stability, the mechanisms that control its ex
129 nce that controls centrosome homeostasis and chromosome stability through FOXM1, revealing this pathw
130 oom syndrome DNA helicase BLM contributes to chromosome stability through its roles in double-strand
134 1 becomes indispensable for cell fitness and chromosome stability when the fidelity of DNA replicatio
135 the plasmid-encoded RNase HI contributes to chromosome stability, while the chromosomally encoded RN