The Implications of Developmental and Evolutionary Relationships between Pancreatic Beta-cells and Neurons

Arntfield, Margot Elinor

06 December 2012

A pancreatic stem cell could provide the tissue necessary for widespread β-cell transplantation therapy for diabetes. It is disputed whether pancreatic stem cells or β-cell replication are responsible for maintenance and regeneration of endocrine cells. Evidence presented here shows that pancreatic stem cells express insulin and produce multiple endocrine, exocrine and neural cells in vitro and in vivo. The human pancreas also contains stem cells that produce functional β-cells capable of reducing blood sugar levels in a diabetic mouse. Initial studies of pancreatic stem cells grown clonally in vitro indicated that they produced large numbers of neurons, suggesting they may be derived from the neural crest. Evidence shows that there are at least two distinct developmental origins for stem cells in the pancreas; one from the pancreatic lineage that produces endocrine and exocrine cells and one from the neural crest lineage that produces neurons and Schwann cells. Furthermore, pancreatic stem cells require the developmental transcription factor, Pax6, for endocrine cell formation suggesting they are using expected differentiation pathways. There is an interesting evolutionary connection between pancreatic β-cells and neurons which was applied to the derivation of pancreatic stem cells from human embryonic stem cells by using a clonal neural stem cell assay. These pancreatic stem cells express pancreatic and neural markers, self-renew and differentiate into insulin-expressing cells. The overexpression of SOX17 in these cells increases stem cell formation and self-renewal but inhibits differentiation. Overall I will show that there is a genuine stem cell in the adult mammalian pancreas capable of producing functional β-cells, that this stem cell is derived from the pancreatic developmental lineage but the pancreas also contains stem cells from the neural crest lineage, and that the neural stem cell assays that have identified these adult stem cells can be applied to the derivation of a pancreatic stem cell from hESCs.

stem cells

pancreas

neural crest

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Mapping Genetic Interaction Networks in Yeast

Baryshnikova, Anastasija

19 March 2013

Global quantitative analysis of genetic interactions provides a powerful approach for deciphering the roles of genes and mapping functional relationships amongst path-ways. Using colony size as a proxy for fitness, I developed a method for measuring ge-netic interactions from high-density arrays of yeast double mutants generated by synthet-ic genetic array (SGA) technology. I identified several experimental sources of systematic variation and developed normalization strategies to obtain accurate fitness measurements. I used this scoring method to map quantitative genetic interactions among 5.4 million yeast double mutants and generated the first functionally unbiased genetic interaction map of a eukaryotic cell. My map produced an unprecedented view of the cell in which genes of similar biological processes cluster together in coherent subsets and functionally interconnected bioprocesses map next to each other. We discovered several physiological and evolutionary gene features that are characteristic of genetic interaction hubs, and explored the relationship between genetic and protein-protein interaction networks. In particular, by comparing quantitative single and double mutant phenotypes, we identified specific cases of positive genetic interactions, termed genetic suppression, and constructed a global network of suppression interactions among protein complexes. I also demonstrated that an extensive and unbiased mapping of genetic interactions provides a key for interpreting chemical-genetic interactions and identifying drug targets. In addition, I used genome-wide SGA data to map profiles of genetic linkage along all sixteen yeast chromosomes. These linkage profiles recapitulated previously identified recombination patterns and uncovered an unexpected correlation between chromosome length and the extent of centromere-related recombination repression. These findings suggest a chromosome size-dependent mechanism for ensuring proper chromosome segregation and highlight the SGA methodology as a unique approach for systematic analysis of yeast meiotic recombination.

genetic interactions

networks

yeast

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Population Structure and Genetic Diversity of Lake Sturgeon (Acipenser fulvescens) in Canada: Evaluation of Designatable Units for Conservation

Kjartanson, Shawna

22 September 2009

The lake sturgeon (Acipenser fulvescens), is a species with considerable ecological, social and economic value. Unfortunately, over-exploitation and habitat alteration have led to the collapse of lake sturgeon fisheries across North America. Based on conservation concerns, the Committee on the Status of Endangered Wildlife in Canada (COSEWIC) identified eight designatable units (DUs) among Canadian populations of lake sturgeon using the limited information available. These DUs are intended to represent taxonomically, genetically, geographically, or biogeographically distinct units below the species level. In this study, the genetic structuring among 20 lake sturgeon localities was examined using nine microsatellite loci. Lake sturgeon localities conformed to hierarchical partitioning of genetic diversity, with the greatest genetic divergence between localities in the Great Lakes and Hudson Bay drainages. Finally, minimal divergences among the current DUs warrant adjustment of lake sturgeon DU boundaries, to more appropriately reflect the distribution of genetic differentiation among lake sturgeon localities.

microsatellite DNA

conservation

lake sturgeon

COSEWIC

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The Effects of Population Density and Knock-downs of Llipid Metabolism Genes on the Expression of Cuticular Hydrocarbons in Drosophila melanogaser

Chu, Adrienne

07 August 2009

In Drosophila melanogaster, chemical cues in the form of cuticular hydrocarbons play an important role in reproductive behavior. The social and genetic processes that regulate their expression, however, are poorly understood. The social environment has been shown to influence hydrocarbon display. In this study, the effect of population density on the expression of hydrocarbons was evaluated. I demonstrate that the production of certain hydrocarbons depends on the population density in which the animal is reared. Individual hydrocarbons fluctuate in quantity independently from one another but the peaks during a light-dark cycle are static depending mostly on chain length. The regulation of fly hydrocarbons which are density-dependent is shown to be sexually dimorphic. The RNAi knockdown of various putative lipid metabolism genes was also used to study hydrocarbon expression. This study reveals that lipid metabolism genes which are not obvious mediators of HC synthesis influence cuticular hydrocarbon profiles.

hydrocarbons

Drosophila melanogaster

pheromone

population density

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Characterizing the Interactomes of ABC Transporters PXA1 and PXA2 using the Integrated Split-Ubiquitin Membrane Yeast Two-hybrid System

Chuk, Matthew

13 January 2010

The integrated Membrane Yeast Two-Hybrid technology (iMYTH) was employed to screen the ABCD family of ABC Transporters in S. cerevisiae. The two ABCD members, Pxa1p and Pxa2p were screened against yeast libraries which detected many interactors involved in expected biological processes in accordance with Pxa1p and Pxa2p’s annotated function (i.e. fatty acid metabolism), and unexpected new interactors that may elucidate a new role for the transporters (e.g. oxidative protection). Members of the glutaredoxins and thioredoxins, and associated proteins were found to interact with Pxa1p and Pxa2p. This may indicate that Pxa1p and Pxa2p also play a role in managing the redox environment, protecting against reactive oxygen species. The iMYTH technology was also used to show that Pxa2p is able to form homodimers, and that Pxa1p localization is directly or indirectly dependent on Pxa2p.

PXA1

PXA2

ABC Transporters

iMYTH

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Protein-protein Interaction Between Two Key Regulators of One-carbon Metabolism in Saccaharomyces cerevisiae.

Khan, Aftab

27 July 2010

One-carbon metabolism is an essential process that is conserved from yeast to humans. Glycine stimulates the expression of genes in one-carbon metabolism, whereas its withdrawal causes repression of these genes. The transcription factor Bas1p and the metabolic enzyme Shm2p have been implicated in this regulation. I have shown that Bas1p physically interacts with Shm2p through co-immunoprecipitation. Using chromatin immunoprecipitation (ChIP), I have also shown that the interaction between Bas1p and Shm2p occurs at the promoter of two genes in the one-carbon metabolism regulon and that the binding of Shm2p requires Bas1p. Using a yeast-two hybrid system, I have systematically truncated Bas1p from the C-terminal end to find a region responsible for the interaction with Shm2p. My data suggest that Shm2p is directly bound to Bas1p at the promoters of glycine regulated genes where it regulates the transcriptional activity of Bas1p in response to changes in glycine levels.

One-Carbon Metabolism

Gene Regulation

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Characterization of the E3 Ubiquitin ligase EEL-1 in DNA Damage-induced Germ Line Apoptosis in C. elegans

Ross, Ashley Jane

28 July 2010

E3 ubiquitin ligases are important regulators of several cellular processes, including apoptosis. To determine the extent to which E3 ligases regulate DNA damage-induced apoptotic signalling in C. elegans, a high-throughput RNAi screen was performed in our laboratory. We identified the E3 ubiquitin ligase EEL-1 as a positive regulator of DNA damage-induced germ cell apoptosis. ARF-BP1, the mammalian EEL-1 ortholog, negatively regulates both the tumour suppressor protein p53 and the anti-apoptotic protein Mcl-1. In C. elegans, we found that eel-1 regulates DNA damage-induced germ cell apoptosis by a mechanism downstream of cep-1/p53 and upstream of ced-9/mcl-1. My results show that unlike ARF-BP1, EEL-1 does not regulate CED-9/Mcl-1 protein levels, suggesting a novel mechanism of apoptosis regulation in C. elegans for this E3 ligase. Unexpectedly, eel-1 causes synthetic sterility in ced-9 loss-of-function mutants that is suppressed by ablation of the Apaf-1 orthologue ced-4, suggesting an additional role for these genes in oogenesis.

C. elegans

apoptosis

E3 ubiquitin ligases

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Genetic Variation in Bitter Taste Perception, Food Preference and Dietary Intake

Asik, Christine Rose

20 March 2012

The role of variation in the TAS2R50 bitter taste receptor gene is unknown, but may influence taste perception and dietary habits. Individuals (n=1171) aged 20 to 29, from the Toronto Nutrigenomics and Health Study, completed a food preference checklist and a semi-quantitative food frequency questionnaire to assess their preference and intake of potentially bitter foods and beverages. DNA was isolated from blood and genotyped for 3 polymorphisms in the TAS2R50 gene (rs2900554 A>C; rs10772397 A>G; rs1376251 A>G). Taste intensity was examined using taste strips infused with 3µg of naringin. The rs2900554 SNP was associated with naringin taste intensity, grapefruit preference and grapefruit intake in females. Homozygotes for the C allele reported the highest frequency of experiencing a high naringin taste intensity, disliking grapefruit and not consuming grapefruit. The rs10772397 and rs1376251 SNPs were associated with disliking grapefruit. These results suggest that naringin may be a ligand for the T2R50 receptor.

Bitter taste

Nutrigenomics

TAS2R50

Taste

0570

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Pho23 Regulates Gene Expression through Histone Methylation and an Mck1-controlled Pathway in Budding Yeast

Myers, Dennis

12 January 2011

Eukaryotic organisms utilize post-translational modifications of highly conserved histone proteins to control gene expression programs. Methylation of lysine 4 on histone H3 (H3K4me) in particular, is thought to be associated with actively transcribed DNA. Paradoxically, recent evidence has suggested that H3K4me has a repressive function as well. Pho23, a member of the highly conserved ING family of tumour suppressor proteins, binds H3K4me and is a component of the gene repressive complex, Rpd3L. My genetic analysis suggests that Pho23 controls transcriptional repression via H3K4me and that Pho23 is itself regulated by the sequence-specific DNA-binding protein Ume6. Moreover, this Ume6-regulated function appears to be governed by Ume6 phosphorylation by Mck1, an evolutionarily conserved kinase. Finally, while Ume6/Pho23 are known to function together with the histone deacteylase Rpd3, my findings suggest the existence of an Rpd3-independent function for Pho23.

Epigenetics

Mck1

Pho23

Yeast

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The Fanconi Anaemia Protein FANCJ is Involved in the Alternative Lengthening of Telomeres (ALT) Mechanism in Human Cells

Komosa, Martin

25 August 2011

Approximately 15% of human cancers utilize a recombination-based mechanism termed Alternative Lengthening of Telomeres (ALT) to maintain the lengths of their telomeres. The Fanconi anaemia protein FANCJ localizes to telomeric foci in human ALT cells, but not in telomerase-positive or primary cells. Telomere-associated FANCJ frequently localizes with FANCD2 and BRCA1, and primarily localizes to ALT-associated PML nuclear bodies. Depletion of FANCJ in human ALT cells causes the loss of BRCA1 at telomeric foci and a decrease in telomeric repeat DNA content primarily as a result of the loss of the brightest telomeric repeat DNA foci. In contrast, depletion of the FANCD2 results in increased telomeric repeat DNA synthesis and this is suppressed upon the codepletion of FANCJ. Together, data from this study suggest that FANCJ is required for telomeric repeat DNA synthesis in human ALT cells, which may or may not be dependent on BRCA1, and FANCD2 restrains this synthesis.

Fanconi anaemia

Telomeres

Cancer

FANCJ

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