281 |
Insight into Stc1-interactions bridging RNAi and chromatin modification in Schizosaccharomyces pombeSreedharan Pillai, Sreerekha January 2017 (has links)
Compact heterochromatin is essential for genome stability and hence cell survival. Studies in many organisms including humans underline the importance of pericentromeric heterochromatin in centromere function. Fission yeast centromeres share a common structural organisation with those of their metazoan counterparts. The fission yeast model has been pivotal in understanding many key events in the pathway leading to the assembly of pericentromeric heterochromatin. In particular, studies in this system have revealed that the RNA interference (RNAi) pathway connects with the chromatin modification machinery to impart proper heterochromatin formation. Transcription of the pericentromeres by RNA polymerase II (Pol II) produces double stranded RNA (ds RNA) which is processed by Dicer(Dcr1) into small interfering RNAs (siRNAs). These siRNAs are loaded onto the Argonaute protein Ago1, and target the Ago1- containing RITS (RNA-Induced Transcriptional Silencing) complex to the pericentromeres via complementary base-pairing of the siRNA to the nascent centromeric transcript. RITS then recruits the sole Histone H3-K9-methyl transferase, Clr4, as part of the Clr4-complex, CLRC. The resulting H3K9-methyl marks further result in the recruitment of downstream chromatin binding proteins including the HP1- homolgue Swi6 which plays a key role in cohesin retention. Additionally, the H3K9- methyl marks are required for stabilising the association of CLRC and RITS, thereby promoting a reinforcing loop within the RNAi-mediated heterochromatin pathway. Thus crosstalk between RITS and CLRC is important in establishing and maintaining silent chromatin at the pericentromeres. Stc1 has been proposed to act as a critical link that connects the RITS and CLRC complexes. Stc1 is required for heterochromatin establishment and maintenance at the pericentromere and association of RITS with CLRC is lost in the absence of Stc1. Moreover, Stc1 directly interacts with Ago1 and is essential for siRNA production. These and other previous observations (Bayne et al. 2010) highlight the key role played by Stc1 in the RNAi-mediated heterochromatin pathway. To understand how Stc1 mediates the specific cross-talk between RNAi and chromatin modification, I have investigated the nature of Stc1 interactions with the RNAi and chromatin modification machineries. Using in-vitro binding assays, I found that Stc1 directly interacts with the CLRC subunits Dos2 and Clr4. I also identified the RITS subunit Tas3 as a potential interactor of Stc1, in addition to Ago1. A collaborating research group elucidated the structure of Stc1 using NMR (He et al. 2013) and my study provides evidence for interactions via the distinct domains of Stc1. Stc1 utilises its disordered C-terminus to bind to Dos2 while the N-terminus, which contains a tandem zinc finger domain, acts as a multi-protein interaction interface binding the CLRC subunit Clr4 and RITS subunits Ago1 and Tas3, opening up possibilities for Stc1-containing distinct-complexes. My work provides new insights into the role of Stc1 and opens up future avenues of research key to understanding how heterochromatin domains are defined and maintained.
|
282 |
The chromatin landscape of barley : gene expression, evolution and epigeneticsBaker, Katie January 2015 (has links)
Barley (Hordeum vulgare) is an economically important crop species with a large diploid genome. Around a half of the barley genome and a fifth of the genes are constrained within a low-recombining pericentromeric (LR-PC) region. I explored the LR-PC gene component with a genomic investigation of gene expression, diversity and evolution. Chromatin environments were also explored in the LR and high recombining (HR) regions by surveying the genic and genomic distributions of nine histone modifications. Firstly, regions of HR and LR were identified and compared for gene evolution, expression and diversity. LR regions of the barley genome were found to be restrictive for gene evolution and diversity, but not gene expression. I employed a bioinformatics approach to identify ancient gene pairs in barley to determine the long-term effects of residency in those regions upon gene evolution. Gene pair loss in LR regions was found to be elevated relative to the HR regions. Applying the same method to rice and Brachypodium distachyon revealed the same situation, suggesting a universal process in the grasses for loss of gene pairs in LR regions. The chromosomal distributions of transposable elements (TEs) were also explored and examined for correlations with recombination rate. Secondly, I developed a chromatin immunoprecipitation followed by Next Generation Sequencing (ChIP-seq) protocol for the investigation of histone modifications in barley seedlings. A protocol was optimised for the fixation, extraction and sonication of barley chromatin. The protocol was applied using antibodies against 13 different histone modifications. Following DNA library construction and Illumina sequencing, a bioinformatics pipeline was devised to analyse the sequence data. NGS reads were mapped to a custom assembly of the barley cultivar Morex reference genome sequence before peak calling. Genomic and genic locations were determined for the covalently modified histones. Four modifications were discarded from further study on the basis of low peak numbers or unexpected chromosomal locations. The remaining nine modifications were classified into four groups based on chromosomal distributions. Groupings were closely mirrored by peak sharing relationships between the modifications except histone H3 lysine-27 tri-methylation (H3K27me3). In addition, chromatin states representing local chromatin environments were defined in the barley genome using the peak sharing data. Mapping the states onto the genome revealed a striking chromatin structure of the gene-rich chromosome arms. A telomere-proximal region bearing high levels of H3K27me3-containing states was found adjacent to an interior gene-rich region characterised by active chromatin states lacking H3K27me3. The LTR retroelement-rich interior was found to be associated with repressive chromatin states. The histone modification status of TE classes were also probed revealing unexpected differences relating to the genomic and genic distributions of these elements. Finally, a genome browser was created to host the information publicly.
|
283 |
Engineering and Delivery of Synthetic Chromatin EffectorsJanuary 2019 (has links)
abstract: Synthetic manipulation of chromatin dynamics has applications for medicine, agriculture, and biotechnology. However, progress in this area requires the identification of design rules for engineering chromatin systems. In this thesis, I discuss research that has elucidated the intrinsic properties of histone binding proteins (HBP), and apply this knowledge to engineer novel chromatin binding effectors. Results from the experiments described herein demonstrate that the histone binding domain from chromobox protein homolog 8 (CBX8) is portable and can be customized to alter its endogenous function. First, I developed an assay to identify engineered fusion proteins that bind histone post translational modifications (PTMs) in vitro and regulate genes near the same histone PTMs in living cells. This assay will be useful for assaying the function of synthetic histone PTM-binding actuators and probes. Next, I investigated the activity of a novel, dual histone PTM binding domain regulator called Pc2TF. I characterized Pc2TF in vitro and in cells and show it has enhanced binding and transcriptional activation compared to a single binding domain fusion called Polycomb Transcription Factor (PcTF). These results indicate that valency can be used to tune the activity of synthetic histone-binding transcriptional regulators. Then, I report the delivery of PcTF fused to a cell penetrating peptide (CPP) TAT, called CP-PcTF. I treated 2D U-2 OS bone cancer cells with CP-PcTF, followed by RNA sequencing to identify genes regulated by CP-PcTF. I also showed that 3D spheroids treated with CP-PcTF show delayed growth. This preliminary work demonstrated that an epigenetic effector fused to a CPP can enable entry and regulation of genes in U-2 OS cells through DNA independent interactions. Finally, I described and validated a new screening method that combines the versatility of in vitro transcription and translation (IVTT) expressed protein coupled with the histone tail microarrays. Using Pc2TF as an example, I demonstrated that this assay is capable of determining binding and specificity of a synthetic HBP. I conclude by outlining future work toward engineering HBPs using techniques such as directed evolution and rational design. In conclusion, this work outlines a foundation to engineer and deliver synthetic chromatin effectors. / Dissertation/Thesis / Doctoral Dissertation Biological Design 2019
|
284 |
Causes and consequences of crossing over variation in Drosophila melanogasterCruz Corchado, Johnny 01 December 2018 (has links)
Under most conditions, meiotic recombination is essential for ensuring that organisms adapt to ever changing biotic and abiotic conditions and, as such, it shapes evolutionary change within and between species. The interplay between selection and recombination plays a role shaping levels diversity within populations. Remarkably, recombination is itself an evolving trait that varies at many levels: between distant species of eukaryotes, between closely related species and among populations (and individuals) of the same species. Recombination rates also vary across genomes. Most of the causes and mechanisms of this plasticity in recombination rates and distribution are not clearly understood. Also, our understanding of how this variability in recombination rates influences levels of diversity within populations and across genomes is incomplete.
Here, I present a study combining molecular genetics with bioinformatic techniques to characterize recombination landscapes in Drosophila melanogaster. I present a model that accounts for a significant fraction of the variation in crossover rates across the genome of Drosophila melanogaster. Our predictive model suggests that crossover distribution is influenced by both meiosis-specific chromatin dynamics and very local constitutively open chromatin associated with DNA motifs that prevent nucleosome stabilization. I also present a novel method for genomic scans to identify recent events of adaptation in using nucleotide diversity data. In addition, I characterized variability in recombination rates in different populations of D. melanogaster and detected that the highest degree of variability in recombination rates across the genome is associated with intermediate genomic scales, and that this intermediate scale also plays a major role in explaining differences in recombination among populations. Our report is the first linking variation in recombination rates across genomes (genomic) and among populations (evolutionary), possibly suggesting a common mechanistic/genomic cause. Finally, I present preliminary data of the first large-scale project to study the effects of multiple environmental conditions in recombination rates at genome-wide level. In conclusion, these studies provide a new framework to investigate variation in recombination rates and to understand the genomic causes and evolutionary consequences.
|
285 |
Wnt-TCF7L2-dependent transcriptional and chromatin dynamics in cardiac regeneration, homeostasis and diseaseIyer, Lavanya Muthukrishnan 26 September 2018 (has links)
No description available.
|
286 |
Methods for Joint Normalization and Comparison of Hi-C dataStansfield, John C 01 January 2019 (has links)
The development of chromatin conformation capture technology has opened new avenues of study into the 3D structure and function of the genome. Chromatin structure is known to influence gene regulation, and differences in structure are now emerging as a mechanism of regulation between, e.g., cell differentiation and disease vs. normal states. Hi-C sequencing technology now provides a way to study the 3D interactions of the chromatin over the whole genome. However, like all sequencing technologies, Hi-C suffers from several forms of bias stemming from both the technology and the DNA sequence itself. Several normalization methods have been developed for normalizing individual Hi-C datasets, but little work has been done on developing joint normalization methods for comparing two or more Hi-C datasets. To make full use of Hi-C data, joint normalization and statistical comparison techniques are needed to carry out experiments to identify regions where chromatin structure differs between conditions.
We develop methods for the joint normalization and comparison of two Hi-C datasets, which we then extended to more complex experimental designs. Our normalization method is novel in that it makes use of the distance-dependent nature of chromatin interactions. Our modification of the Minus vs. Average (MA) plot to the Minus vs. Distance (MD) plot allows for a nonparametric data-driven normalization technique using loess smoothing. Additionally, we present a simple statistical method using Z-scores for detecting differentially interacting regions between two datasets. Our initial method was published as the Bioconductor R package HiCcompare [http://bioconductor.org/packages/HiCcompare/](http://bioconductor.org/packages/HiCcompare/).
We then further extended our normalization and comparison method for use in complex Hi-C experiments with more than two datasets and optional covariates. We extended the normalization method to jointly normalize any number of Hi-C datasets by using a cyclic loess procedure on the MD plot. The cyclic loess normalization technique can remove between dataset biases efficiently and effectively even when several datasets are analyzed at one time. Our comparison method implements a generalized linear model-based approach for comparing complex Hi-C experiments, which may have more than two groups and additional covariates. The extended methods are also available as a Bioconductor R package [http://bioconductor.org/packages/multiHiCcompare/](http://bioconductor.org/packages/multiHiCcompare/). Finally, we demonstrate the use of HiCcompare and multiHiCcompare in several test cases on real data in addition to comparing them to other similar methods (https://doi.org/10.1002/cpbi.76).
|
287 |
New transcriptional roles for the classic Drosophila insulator protein Suppressor of Hairy-wingSoshnev, Alexey Aleksandrovich 01 December 2012 (has links)
The Drosophila Suppressor of Hairy-wing [Su(Hw)] protein is a multi-zinc finger DNA binding factor required for the gypsy insulator function. At the gypsy element, Su(Hw) recruits partners Centrosomal Protein of 190 kD (CP190) and Modifier of mdg4 67.2 kD isoform (Mod67.2), which facilitate the enhancer blocking and barrier functions of the insulator. Our genome-wide studies have identified thousands of endogenous non-gypsy Su(Hw) binding sites (SBSs) in Drosophila genome, constitutively occupied throughout development. Yet, only a third of SBSs associate with CP190 and Mod67.2, suggesting that the endogenous function of Su(Hw) may not necessarily involve formation of a gypsy-like chromatin insulator.
To understand the function of endogenous SBSs, we investigated the requirement for Su(Hw) during female germline development. To this end, we performed genome-wide transcriptional analyses in su(Hw) mutant ovaries coupled with the genome-wide definition of ovary SBSs. We identified 49 direct targets of Su(Hw) regulation in the ovary, with 80% of these genes showing increased RNA accumulation when Su(Hw) is lost. Derepressed Su(Hw) targets are normally highly expressed in central nervous system, suggesting that Su(Hw) has a critical role in silencing neural genes in the non-neural tissues. We find that a single upregulated target gene is largely responsible for the female sterility of the su(Hw) mutants. This gene encodes an elav family factor RNA binding protein 9 (Rbp9), and Su(Hw)-mediated repression of Rbp9 is required at a specific stage of germline development. Decreasing the levels of Rbp9 restores female fertility of su(Hw) null mutants. Further, we demonstrate that Su(Hw) is required for transcriptional activation of pointed, gene involved in eggshell patterning during late embryogenesis. Importantly, both CP190 and Mod67.2 are dispensable for Rbp9 regulation, indicating that mechanism of Rbp9 repression is independent of the insulator function of Su(Hw).
Our studies extend the known transcriptional activities of Su(Hw), indicating that it can function as an insulator, activator and repressor, the latter function being essential for oogenesis. These findings highlight that insulator proteins are versatile transcriptional regulators, suggesting that tissue specific contributions to transcription result from direct regulation of individual genes.
|
288 |
Biologische Referenzstrukturen und Protokolloptimierung in der hochauflösenden Fluoreszenzmikroskopie mit dSTORM / Biological model structures and optimization of protocols in super-resolution fluorescence microscopy with dSTORMLöschberger, Anna January 2014 (has links) (PDF)
Die Lokalisationsmikroskopie ist eine neue, vielversprechende Methode der hochauflösenden Fluoreszenzmikroskopie. Sie ermöglicht detaillierte Einblicke in die Organisation und den strukturellen Aufbau von Zellen. Da die Vorbereitung der Proben und das Aufnehmen der Bilder im Vergleich zu herkömmlichen Methoden höhere Anforderungen stellt, mussten ihr Potential und ihre Zuverlässigkeit erst noch überzeugend gezeigt werden. Bis vor kurzem wurde das Auflösungsvermögen vor allem an Mikrotubuli gezeigt, deren filamentöse Struktur allerdings schon in konfokalen Bildern zu erkennen ist. Deswegen wurde in dieser Dissertation der Kernporenkomplex (NPC), dessen Struktur in der konventionellen Fluoreszenzmikroskopie nicht auflösbar ist, als Modellstruktur für die hochauflösende Fluoreszenzmikroskopie eingeführt.
Dazu wurden Kernporenkomplexe aus Kernhüllen von Xenopus laevis Oocyten mit dSTORM (direct stochastic optical reconstruction microscopy), einer Methode der Lokalisationsmikroskopie, hochaufgelöst. Damit konnte nun erstmals die Achtfachsymmetrie dieses Proteinkomplexes lichtmikroskopisch dargestellt werden. Desweiteren konnte der Zentralkanal mit einem Durchmesser von ca. 40 nm aufgelöst werden. Die Daten eigneten sich außerdem für eine automatisierte Bildanalyse nach dem sogenannten "particle averaging" - einer aus der Elektronenmikroskopie bekannten Methode, um eine Durchschnittsstruktur zu ermitteln.
Darüber hinaus wurden Zweifach-Färbungen von NPCs benutzt, um verschiedene Ansätze für Zweifarben-Aufnahmen mit dSTORM zu testen. Neben dem mittlerweile standardmäßig benutzten, sequentiellen Ansatz mit zwei spektral getrennten Farbstoffen, wurde auch ein simultaner Ansatz mit zwei spektral überlappenden Farbstoffen erfolgreich angewandt. Auch für 3D-Messungen mit den Ansätzen Biplane und Astigmatismus eignete sich die Markierung der Kernhülle. Hier wurden jedoch A6-Zellen benutzt und die Krümmung des Zellkerns über die gefärbten Kernporen dargestellt.
dSTORM-Messungen können nicht nur an fixierten, sondern auch in lebenden Zellen durchgeführt werden. Hierzu eignen sich vor allem sehr immobile Proteine, wie H2B oder Lamin C. Anhand von SNAP-Tag- und Halo-Tag-Konstrukten konnte gezeigt werden, dass sich kommerziell erhältliche, organische Farbstoffe auch in endogener zellulärer Umgebung schalten lassen, wodurch Lebendzell-Aufnahmen mit dSTORM möglich sind.
Ein weiterer Teil dieser Arbeit befasst sich mit korrelativen Aufnahmen aus dSTORM und Rasterelektronenmikroskopie (SEM). Hierzu wurden Xenopus laevis Kernhüllen zuerst mit dSTORM hochaufgelöst und danach für die EM präpariert. Anschließend wurden zugehörige Bereiche am Rasterelektronenmikroskop aufgenommen. Mit den erhaltenen korrelativen Bildern konnte gezeigt werden, dass sich dSTORM und SEM bei geeigneten Proben durchaus kombinieren lassen. Proteine können somit spezifisch markiert und im Rahmen ihrer strukturellen Umgebung mit nahezu molekularer Auflösung dargestellt werden.
Da hochwertige Aufnahmen eine ausgereifte Probenpräparation voraussetzen, darf deren Etablierung nicht zu kurz kommen. Unter dieser Prämisse wurde ein optimiertes Markierungsprotokoll mit dem Namen ClickOx entwickelt. Mit ClickOx bleibt bei der kupferkatalysierten Azid-Alkin-Cycloaddition die Feinstruktur von Aktinfilamenten, sowie die Fluoreszenz fluoreszierender Proteine, deutlich sichtbar erhalten. Während bei den klassischen Click-Protokollen auf Grund der Entstehung von reaktiven Sauerstoff-Spezies (ROS) feine zelluläre Strukturen, wie Aktinfilamente, angegriffen oder zerstört werden, schützt das neue Protokoll mit enzymatischem Sauerstoffentzug Proteine und somit Strukturen vor Reaktionen mit ROS. Das unterstreicht, wie wichtig es ist auch sogenannte "etablierte" Protokolle weiterzuentwickeln, denn bestimmte Nebeneffekte in Präparationen werden unter Umständen erstmals in der Hochauflösung sichtbar.
Ein weiterer Aspekt war die Untersuchung des Einflusses von D1 auf die Chromatinorganisation. Mit verschiedenen mikroskopischen Methoden konnten Hinweise auf eine mögliche DNA-Cross-Linking-Fähigkeit dieses Proteins gesammelt werden. Hier wurde die Einzelmolekülinformation der dSTORM-Filme genutzt, um unterschiedliche Grade von DNA- bzw. Chromatin-Akkumulation zu vergleichen. Die Ergebnisse deuten darauf hin, dass wildtypisches D1 DNA vernetzen kann. Dies erfolgt über die sogenannten AT-Haken-Motive. Sobald diese alle durch Mutation funktionsunfähig gemacht werden - wie bei der verwendeten R10xG-Mutante - lässt sich keine Akkumulation der DNA mehr beobachten. Neben der Chromatinaggregation durch D1-Expression konnte in FRAP-Experimenten gezeigt werden, dass nur die "echten" AT-Haken eine hohe Affinität zum Chromatin aufweisen, die sogenannten "potentiellen" hingegen nicht. / Localization microscopy is a new and promising imaging technique, which provides detailed insights into cellular organization and structural composition of cells with high spatial resolution. Due to the challenging preparation of samples and demanding imaging procedure, its potential and reliability had to be proven. Until recently the resolution has been shown mainly on microtubules, whose structure is already visible in confocal images. This thesis introduced the nuclear pore complex (NPC) as a more demanding model structure for super-resolution fluorescence microscopy as the structure of NPCs can not be resolved with conventional fluorescence microscopy.
For this purpose nuclear envelopes of Xenopus laevis oocytes were highly resolved with dSTORM (direct stochastic optical reconstruction microscopy). With this localization microscopy method it was further possible to resolve the eightfold symmetry of nuclear pore complexes with light microscopy for the first time. In addition the central channel could be resolved with a diameter of about 40 nm. Furthermore, the localizations were used for single particle averaging, a well known image analysis method from electron microscopy, to calculate an average structure.
Double staining of NPCs was used to check the potential of two-color imaging with dSTORM.
Beside the common way of sequential imaging with two clearly spectrally separated dyes, a spectral demixing approach with spectrally overlapping dyes was applied.
Labeling the nuclear envelope was also suitable for 3D measurements using two different approaches, i.e. biplane and astigmatism. In this case, labeled NPCs of Xenopus laevis A6-cells were used to illustrate the bending of the nucleus.
dSTORM can be applied not only in fixed but also in living cells. Immobile proteins such as H2B or lamin C are especially suitable for this approach. Using fusion proteins with SNAP-Tag or Halo-Tag, it was shown that photoswitching of commercially available organic dyes is possible in an endogenous cellular environment and thus enabeling dSTORM in living cells.
Another aspect of this work covers correlative microscopy using dSTORM and scanning electron microscopy (SEM). Therefor nuclear envelopes of Xenopus laevis were first imaged with dSTORM and then prepared for SEM. After that, corresponding areas were imaged with SEM. The resulting correlative images showed clearly that - assuming one has appropriate samples - dSTORM and SEM can be fairly combined. This way specifically labeled proteins can be imaged with nearly molecular resolution in the context of their structural environment.
Since the quality of localization microscopy strongly depends on sample preparation, ongoing developments of labeling protocols are required. On this premise an optimized labeling protocol called ClickOx was developed. ClickOx clearly preserves the fine structure of actin filaments and the fluorescence of fluorescent proteins when using copper-catalyzed azide-alkine-cycloaddition. Whereas fine cellular structures such as actin filaments are affected by reactive oxygen species (ROS) under standard clicking procedures, the new protocol, which contains an enzymatic oxygen scavenger, protects proteins and thus cellular structures from reactions with ROS. This demonstrates the importance of further developing even so called "well established" protocols, because some side effects may appear only in super-resolution.
Another aspect adressed the influence of D1 on chromatin organization. Hints for a possible DNA cross-linking ability of D1 were collected using different microscopic approaches. The single-molecule information of dSTORM measurements was used to analyse chromatin aggregation induced by D1 expression. The results indicate that wildtype D1 can cross-link DNA with its AT-hooks. Consequently the loss-of-function mutant R10xG is unable to aggregate chromatin. Furthermore FRAP experiments were performed to demonstrate that only "true" AT-hooks in D1 have a strong affinity to chromatin, but not the so called "potential" AT-hooks.
|
289 |
Molecular characterisation of chromatin introgressed from Hordeum bulbosum L. into Hordeum vulgare LJohnston, Paul Andrew, n/a January 2008 (has links)
Hordeum bulbosum L. (bulbous barley grass) is an important genetic resource for barley (Hordeum vulgare L.) improvement. As the sole member of the secondary genepool of Hordeum; H. bulbosum represents a relatively untouched source of genetic diversity which can provide novel allelic variation for traits critical to the future of barley breeding. In order to access this resource efficiently, a complete set of molecular marker resources is necessary to assist the introgression of chromatin from H. bulbosum into a barley genetic background.
For breeders to access traits from H. bulbosum for barley improvement, recombinant lines need to be developed to transfer regions of the H. bulbosum genome into a barley background for trait identification and for incorporation into elite barley breeding programs.
The chromosomal location of H. bulbosum introgressions in thirty eight unique recombinant lines was performed using RFLP analysis using mostly distal probes from barley genetic linkage maps However, this analysis was labour intensive, restrictive and prone to inconsistencies due to low intensity signals and complex banding in H. bulbosum.
Due to the low level of interspecific recombination detected between the two species, a retrotransposon-like marker, pSc119.1, was developed which could be used to quickly screen progeny from an interspecific cross to determine which lines possessed introgressions of chromatin from H. bulbosum.
After initial screening, putative recombinants were further characterised using co-dominant single locus PCR markers from throughout the genome. A focus was made on using the EST resources of barley and wheat, combined with the rice genome to create intron-spanning markers. Subsequent allele-sequencing revealed high frequencies of species-diagnostic single nucleotide polymorphisms (SNPs) in the intron regions of these markers, coupled with relatively low frequencies of species-diagnostic SNPs in the flanking exon regions. Overall, interspecific SNP frequencies were not significantly higher in intron-spanning markers than those consisting of exon-only sequence. However, species-diagnostic indels were more frequently discovered within intron sequence providing additional polymorphism.
Recombinant lines with phenotypes that differed from the barley parent allowed those traits to be assigned to particular chromosomal regions. These characterised recombinant lines will provide a resource for barley breeders to identify novel traits for barley improvement and allow identification of new alleles in different chromosomal locations for current traits, allowing greater flexibility for cultivar construction.
A targeted backcross population of the recombinant line 38P18/8/1/10 (possessing leaf rust resistance derived from H. bulbosum) was created. The introgressed region was saturated for PCR markers using a variety of marker types and techniques (AFLP, cDNA-AFLP). Two lines were subsequently identified with introgressions of reduced size relative to the parental recombinant line, both of which have retained the leaf rust resistance trait. The leaf rust resistance was finally linked to two co-dominant EST-based markers located on chromosome 2HL by using these two lines and the direct screening of progeny from interspecific hybrids possessing introgression junctions in the region of interest.
In general, recombinant material between barley and H. bulbosum suffers from certation effects which cause distorted segregation that favours heterozygous and homozygous barley genotypes. Two unique lines have been identified during this research that possess gametocidal-type loci that result in the absolute retention of H. bulbosum chromatin with the termination of gametes lacking the introgression (barley genotype only).
|
290 |
The Role of Brm, Brg-1, Snail 1 and Snail 2 in the Progression of Non-Melanoma Skin CancerBock, Vanessa Leonie January 2008 (has links)
Master of Medicine / Non-melanoma skin cancer (NMSC) is the most common human cancer worldwide. Squamous cell carcinoma (SCC) and basal cell carcinoma (BCC) make up almost all NMSC. SCC usually arises from actinic keratosis (AK) as a result of exposure to sunlight. SCC and AK provide a useful clinical model to investigate changes involved in the progression of NMSC. This project examines the expression of Brm, Brg-1, Snail 1 and Snail 2 in the progression of NMSC. Brm and Brg-1 are subunits of the SWI/SNF chromatin-remodelling complex which is involved in regulating the access of cell machinery to DNA by altering the structure of chromatin. It has been suggested that loss of this function is involved in carcinogenesis as the cell is unable to access to DNA normally in order to repair mutations or activate apoptosis. The loss of Brm or Brg-1 has been described in several human cancers. Snail 1 and Snail 2 are zinc-finger transcription factors that are known for their role in epithelial to mesenchymal transition (EMT), a process vital to embryological development. Increased expression of these factors leads to a loss of cell-cell adhesion and a migratory phenotype and has been described in some human cancers. In this project, double-label immunohistochemistry was used to determine the relative expression of these proteins in human SCC, BCC, AK and normal skin. The expression of Snail was unable to be determined due to poor specificity of the antibodies used. The expression of both Brm and Brg-1 proteins was found to be dramatically and consistently decreased in SCC and BCC when compared to normal skin and AK. This loss of Brm and Brg-1 occured as the tumour progressed from benign AK to malignant SCC. This finding suggests that the loss of either Brm or Brg-1 constitutes a key step in carcinogenesis. The results of this study identify Brm and Brg-1 as putative tumour suppressors involved in the progression of non-melanoma skin cancer from benign to malignant.
|
Page generated in 0.0735 seconds