Epigenomic Mechanisms of Centromere Function and Chromosome Rearrangements

Stimpson Woodlief, Kaitlin Marie

January 2012

<p>The centromere is essential for chromosome segregation and genome stability. It is the site of kinetochore assembly and chromosome attachment to the spindle microtubules, and it is important for chromosome movement during mitosis and meiosis. Normal human chromosomes have one centromere, but genome rearrangements that occur with instability, aging, and disease often result in chromosomes with two centromeres, called dicentrics. Nearly seventy-five years ago, Barbara McClintock demonstrated that dicentric chromosomes in plants are associated with instability through mitotic "breakage-fusion-bridge" cycles. However, human dicentrics are unusually stable due to the poorly understood phenomenon of centromere inactivation. Centromere inactivation has been primarily studied in patient-derived dicentrics, limiting the derivation of a molecular pathway. Key centromere and kinetochore proteins are not present at inactive centromeres, but beyond these observations, the process of centromere inactivation is unclear. Epigenetic and sequence-dependent factors are known to contribute to centromere specification, but requirements for centromere assembly, maintenance, and suppression remain obscure. The aims of this research were to (1) determine the mechanism(s) by which de novo dicentric chromosomes are stabilized, (2) ascertain the factors influencing the involvement of specific chromosomes in de novo fusions, and (3) establish the epigenomic, temporal, and mechanistic basis of centromere inactivation. To uncover the mechanistic foundations of these processes, we developed in vitro cell culture systems to study the formation and stabilization of de novo dicentrics. We demonstrate that transient disruption of human telomere structure non-randomly produces dicentric fusions involving acrocentric chromosomes. This finding is notable since the most prevalent rearrangement in humans involves the acrocentrics and is called Robertsonian translocation (ROB). In some cases, centromere inactivation occurs by an apparently epigenetic mechanism. In other dicentrics, the size of the centromeric DNA array is reduced compared to the same array before dicentric formation. Many functional dicentrics persist for months after formation. Our results indicate that dicentric human chromosomes undergo alternative fates after formation across a broad temporal window. During transient telomere disruption, we observed a dramatic change in nucleolar appearance. Nucleolar proteins did not coalesce into condensed structures, but appeared dispersed throughout the nucleus. This surprising alteration in nucleolar organization and nuclear architecture suggests remodeling of the nucleolus and subsequent effects on nucleolar-associated chromosomes, such as the acrocentrics, could contribute to the high incidence of ROB formation. Further studies and development of additional cell culture systems will allow us to evaluate current models of centromere assembly and disassembly and the importance of chromatin organization to centromere function and genome architecture.</p> / Dissertation

Genetics

Molecular biology

Centromere

Chromosome stability

Dicentrics

Nuclear organization

Nucleoli

Telomeres

Deciphering the Role of Aft1p in Chromosome Stability

Hamza, Akil

25 January 2012

The Saccharomyces cerevisiae iron-responsive transcription factor, Aft1p, has a well established role in regulating iron homeostasis through the transcriptional induction of iron-regulon genes. However, recent studies have implicated Aft1p in other cellular processes independent of iron-regulation such as chromosome stability. In addition, chromosome spreads and two-hybrid data suggest that Aft1p interacts with and co-localizes with kinetochore proteins, however the cellular implications of this have not been established. Here, we demonstrate that Aft1p associates with the kinetochore complex through Iml3p. Furthermore, we show that Aft1p, like Iml3p, is required for the increased association of cohesin with the pericentromere and that aft1Δ cells display sister chromatid cohesion defects in both mitosis and meiosis. Our work defines a new role for Aft1p in the sister chromatid cohesion pathway.

Aft1

Iml3

kinetochore

cohesion

cohesin

centromere

chromosome stability

Ctf19

Chl4

Scc1

mitosis

meiosis

Rec8

budding yeast

Deciphering the Role of Aft1p in Chromosome Stability

Hamza, Akil

25 January 2012

The Saccharomyces cerevisiae iron-responsive transcription factor, Aft1p, has a well established role in regulating iron homeostasis through the transcriptional induction of iron-regulon genes. However, recent studies have implicated Aft1p in other cellular processes independent of iron-regulation such as chromosome stability. In addition, chromosome spreads and two-hybrid data suggest that Aft1p interacts with and co-localizes with kinetochore proteins, however the cellular implications of this have not been established. Here, we demonstrate that Aft1p associates with the kinetochore complex through Iml3p. Furthermore, we show that Aft1p, like Iml3p, is required for the increased association of cohesin with the pericentromere and that aft1Δ cells display sister chromatid cohesion defects in both mitosis and meiosis. Our work defines a new role for Aft1p in the sister chromatid cohesion pathway.

Aft1

Iml3

kinetochore

cohesion

cohesin

centromere

chromosome stability

Ctf19

Chl4

Scc1

mitosis

meiosis

Rec8

budding yeast

Deciphering the Role of Aft1p in Chromosome Stability

Hamza, Akil

25 January 2012

The Saccharomyces cerevisiae iron-responsive transcription factor, Aft1p, has a well established role in regulating iron homeostasis through the transcriptional induction of iron-regulon genes. However, recent studies have implicated Aft1p in other cellular processes independent of iron-regulation such as chromosome stability. In addition, chromosome spreads and two-hybrid data suggest that Aft1p interacts with and co-localizes with kinetochore proteins, however the cellular implications of this have not been established. Here, we demonstrate that Aft1p associates with the kinetochore complex through Iml3p. Furthermore, we show that Aft1p, like Iml3p, is required for the increased association of cohesin with the pericentromere and that aft1Δ cells display sister chromatid cohesion defects in both mitosis and meiosis. Our work defines a new role for Aft1p in the sister chromatid cohesion pathway.

Aft1

Iml3

kinetochore

cohesion

cohesin

centromere

chromosome stability

Ctf19

Chl4

Scc1

mitosis

meiosis

Rec8

budding yeast

Deciphering the Role of Aft1p in Chromosome Stability

Hamza, Akil

January 2012

The Saccharomyces cerevisiae iron-responsive transcription factor, Aft1p, has a well established role in regulating iron homeostasis through the transcriptional induction of iron-regulon genes. However, recent studies have implicated Aft1p in other cellular processes independent of iron-regulation such as chromosome stability. In addition, chromosome spreads and two-hybrid data suggest that Aft1p interacts with and co-localizes with kinetochore proteins, however the cellular implications of this have not been established. Here, we demonstrate that Aft1p associates with the kinetochore complex through Iml3p. Furthermore, we show that Aft1p, like Iml3p, is required for the increased association of cohesin with the pericentromere and that aft1Δ cells display sister chromatid cohesion defects in both mitosis and meiosis. Our work defines a new role for Aft1p in the sister chromatid cohesion pathway.

Aft1

Iml3

kinetochore

cohesion

cohesin

centromere

chromosome stability

Ctf19

Chl4

Scc1

mitosis

meiosis

Rec8

budding yeast

The support of undifferentiated human embryonic stem cell lines by different matrices

Khadun, Shalinee

January 2014

The future of human embryonic stem cell (hESC) research with regards to their applicability in a therapeutic setting, relies on the development and standardisation of consistent and robust methods to demonstrate their defining characteristics; their pluripotent ability to form all three germ layers and their capacity for self-renewal. Although much research has been carried out to investigate new methods of culturing hESCs, many of these studies have not robustly concluded the impact of prolonged culture on genetic and genomic stability nor have they examined in any comparative detail the impact of the culture conditions such as differences in feeders used or the media composition in which the stem cells are cultured in. The aim of this thesis therefore was to investigate and evaluate methods for improving the uniform and robust culture and characterisation of hESCs over prolonged periods in culture. Four hESC lines ( RH5, HUES9, SHEF1 and NCL5) were chosen on the basis that they had not previously been well characterised and therefore could potentially benefit the wider stem cell community by increasing diversity, rather than continue to use the already small subset of well publicised lines. The RH5, HUES9, SHEF1 and NCL5 cells were subjected to long term passaging using recombinant enzyme TrypLE™ Express, on human feeders, mouse feeders and feeder free matrix Matrigel in combination with defined media mTeSR1, for uniform scale up. Changes in characteristic stem cell surface markers were compared using two techniques; flow cytometry and quantitative in situ fluorescence microscopy. Genomic stability was assessed by real time PCR. Chromosomal integrity was monitored using array genomic hybridisation (aCGH). Array genomic hybridisation analysis of cells cultured for 20 passages by enzymatic passaging revealed changes in copy number variations in all the stem cell lines. Aberrations on chromosomes 12, 17 and 20, appeared most commonly as a result of long term culture. Although no significant differences were seen between hESCs cultured on mouse and human feeders, cultures on Matrigel showed fewer detected chromosomal aberrations. Expression of cell surface stemness markers SSEA3, SSEA4, TRA1-60 and TRA1-81 were maintained by hESC cultured on all matrices and confirmed by the use of flow cytometry and high throughput quantitative immunofluorescence imaging using the TissueFaxs™ cell analysis microscopy system. In depth imaging revealed subtle but important differences in the way in which hESCs attach and proliferate on different matrices. Genetic profiling of each of the stem cell lines using Taqman Low density array cards to assess the expression of 96 genes by Real Time PCR, demonstrated the continued expression of stemness genes 21 at late passage, and low level expression of differentiation genes, inherent to particular stem cell lines. Although both mouse and human feeders and Matrigel support the undifferentiated growth of hESCs, subtle differences from the hESCs were seen as a result of their use, most obviously, changes in morphology and how they proliferate. This was further explored in the stem cell line NCL5, as it demonstrated a readiness to adapt to new matrices, better chromosomal stability and higher expression of cell surface markers compared with the other hESC lines. Using in vitro differentiation assays to all three germ layers, NCL5 cultured to late passage (p+20) on human feeder iMRC5, mouse feeder iMEF and feeder free matrix Matrigel, demonstrated the ability to differentiate to ectoderm, endoderm and mesoderm progenitors after induction using three 7 day flat based directed differentiation protocols. Altered differentiation patterns were detected by Real Time PCR and TissueFaxs™ imaging and quantitative analysis, as a consequence of the prolonged culture on the specific matrices used. Such key findings allude to the strong influences of microenvironment and will help to improve the standardisation of in vitro differentiation assays. From these studies, chromosomal changes had no impact on NCL5 stem cell lines‘ ability to form progenitors, however small genetic instabilities may still play a role in terminal differentiation of germ lineage specific cell types. The findings of the programme of work described has led to the successful culture methods and characterisation testing validated in this project being incorporated into routine culture and banking of research grade hESCs at the UK Stem Cell Bank. These protocols will now be made more widely available and should assist stem cell researchers in adopting the most suitable and optimum conditions for culturing stem cells in the undifferentiated and stable state. With the huge surge in stem cell research over the past decade, the development of robust characterisation and culture methods will undoubtedly have significant impact on the exploitation of these cells for regenerative medicine and to assist with this a future aim of the stem cell bank will be to standardise methodologies for clinical grade banking.

616.02

Elucidation of the Role of Nse1, a RING Domain Containing Component of Smc5/6 complex, in Maintenance of Chromosome Stability in Saccharomyces cerevisiae

Wani, Saima Masood

January 2017

Structural Maintenance of Chromosomes (SMC) proteins are a highly conserved class of proteins required for the maintenance of genome stability and regulate nearly all aspects of chromosome biology. Eukaryotes, such as the budding yeast Saccharomyces cerevisiae, have six Smc proteins that form three SMC complexes in association with non-SMC proteins, i.e., the cohesin complex, the condensin complex and the Smc5/6 complex. The yeast Smc5/6 complex consists of Smc5, Smc6 and six non-Smc elements (Nse1-6) that are all essential for the survival of cells. Nse1 is the first non-smcelement that was identified associated with the Smc5/6 complex. Nse1 has a C-terminal RING-domain, which is a characteristic feature of some E3 ubiquitin ligases. A RING domain consists of eight conserved Zn-coordinating residues arranged in a cross-brace conformation. To understand the importance of this domain, we created site directed mutations in conserved residues identified by sequence alignment of the budding yeast Nse1 RING domain with that of other species. We found a new RING domain mutant nse1-103that was temperature sensitive at 37°C and showed an increased sensitivity towards genotoxic agents such as hydroxyurea (HU), methyl methane sulfonate (MMS) and ultraviolet (UV) radiation. Thense1-103 mutant cells are slow growing and show delayed chromosomal replication at the restrictive temperature. Genetic interactions with replication factors such as RRM3, TOF1 etc. revealed thatnse1-103shows a synthetic sick growth defect in combination with rrm3∆ that is partially suppressed by deletion of TOF1. We found an enhancement in chromosome loss in nse1-103 compared to wild type cells. This was accompanied by a slight reduction in cohesion between the sister chromatids in nse1-103,suggesting a plausible mechanism for the chromosome destabilization observed in the mutant. Since Nse1 forms part of a trimeric sub-complex with Nse3 and Nse4 in the Smc5/6 complex, we performed a yeast two hybrid assay to test the interaction of nse1-103 with Nse3 or Nse4, and found a defect in interaction of nse1-103 with Nse3 and Nse4. In addition, a defect in association of nse1-103 with Smc5 or Smc6 could be observed by performing co-immunoprecipitation from yeast cell lysates, suggesting that the integrity of the RING-domain is critical for the interaction of Nse1 with other subunits of the Smc5/6 complex. However, there was no defect in the interaction between Nse3 and Smc5 in nse1-103, indicating that the interaction of these components within the complex isindependent of Nse1. We also identified a novel sequence motif near the RING domain of Nse1, deletion of which leads to an increased sensitivity towards genotoxic stressors and higher temperature. Biochemical characterization of this mutant also suggests a defect ininteraction with Nse3 or Nse4, and also with Smc5. The nse1 mutants also showed defects in post translational modification of Smc5 and other proteins. Since the Smc5/6 complex also has a SUMO E3 ligase, Mms21/Nse2, we also investigated genetic interactions between the RING domain mutant,nse1-103 and the SUMO ligase RING domain defective mutant,mms21∆sl, and found an exacerbation of the drug sensitive phenotypes in thense1-103 mms21∆sl double mutant relative to either of the single mutants nse1-103 or mms21∆sl, indicating that the two proteins contribute independently to the function of Smc5/6 complex in resisting genotoxic stress. In conclusion, the present study emphasizes the role of the RING domain of budding yeast Nse1 in resisting genotoxic stress and maintaining chromosome stability and reveals that the integrity of the RING-domain is critical for interactions of Nse1 with Nse3 and other Smc5/6 complex components. In addition, we report identification of another novel sequence motif in Nse1 that is also crucial for its interaction with other subunits of the Smc5/6 complex and for maintenance of post-translational modifications of some cellular proteins.

Saccharomyces Cerevisiae - Nse1

DNA Binding

DNA Repair

Smc5/6 Complex

Nse1

Biochemistry