Aidan Dineen scite author profile

The two GATA transcription factors ELT-2 and ELT-7 function in the differentiation of the C. elegans intestine. ELT-2 loss causes lethality. ELT-7 loss causes no obvious phenotype but enhances the elt-2(-) intestinal phenotype. Thus, ELT-2 and ELT-7 appear partially redundant, with ELT-2 being more influential. To investigate the different regulatory roles of ELT-2 and ELT-7, we compared the transcriptional profiles of pure populations of wild-type, elt-2(-), elt-7(-), and elt-7(-); elt-2(-) double mutant L1-stage larvae. Consistent with the mutant phenotypes, loss of ELT-2 had a>25 fold greater influence on the number of significantly altered transcripts compared to the loss of ELT-7; nonetheless, the levels of numerous transcripts changed upon loss of ELT-7 in the elt-2(-) background. The quantitative responses of individual genes revealed a more complicated behaviour than simple redundancy/partial redundancy. In particular, genes expressed only in the intestine showed three distinguishable classes of response in the different mutant backgrounds. One class of genes responded as if ELT-2 is the major transcriptional activator and ELT-7 provides variable compensatory input. For a second class, transcript levels increased upon loss of ELT-2 but decreased upon further loss of ELT-7, suggesting that ELT-7 actually overcompensates for the loss of ELT-2. For a third class, transcript levels also increased upon loss of ELT-2 but remained elevated upon further loss of ELT-7, suggesting overcompensation by some other intestinal transcription factor(s). In spite of its minor loss-of-function phenotype and its limited sequence similarity to ELT-2, ELT-7 expressed under control of the elt-2 promoter is able to rescue elt-2(-) lethality. Indeed, appropriately expressed ELT-7, like appropriately expressed ELT-2, is able to replace all other core GATA factors in the C. elegans endodermal pathway. Overall, this study focuses attention on the quantitative intricacies behind apparent redundancy or partial redundancy of two related transcription factors.

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The contribution of alternative splicing to genetic risk for psychiatric disorders

Reble

Dineen

Barr

2017

Genes Brain and Behavior

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A genetic contribution to psychiatric disorders has clearly been established and genome-wide association studies now provide the location of risk genes and genetic variants associated with risk. However, the mechanism by which these genes and variants contribute to psychiatric disorders is mostly undetermined. This is in part because non-synonymous protein coding changes cannot explain the majority of variants associated with complex genetic traits. Based on this, it is predicted that these variants are causing gene expression changes, including changes to alternative splicing. Genetic changes influencing alternative splicing have been identified as risk factors in Mendelian disorders; however, currently there is a paucity of research on the role of alternative splicing in complex traits. This stems partly from the difficulty of predicting the role of genetic variation in splicing. Alterations to canonical splice site sequences, nucleotides adjacent to splice junctions, and exonic and intronic splicing regulatory sequences can influence splice site choice. Recent studies have identified global changes in alternatively spliced transcripts in brain tissues, some of which correlate with altered levels of splicing trans factors.Disease-associated variants have also been found to affect cis-acting splicing regulatory sequences and alter the ratio of alternatively spliced transcripts. These findings are reviewed here, as well as the current datasets and resources available to study alternative splicing in psychiatric disorders. Identifying and understanding risk variants that cause alternative splicing is critical to understanding the mechanisms of risk as well as to pave the way for new therapeutic options.

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Cell Architecture: Surrounding Muscle Cells Shape Gland Cell Morphology in the Caenorhabditis elegans Pharynx

Raharjo

Ghai

Dineen

et al. 2011

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The acquisition and maintenance of shape is critical for the normal function of most cells. Here we investigate the morphology of the pharyngeal glands of Caenorhabditis elegans. These unicellular glands have long cellular processes that extend discrete lengths through the pharyngeal musculature and terminate at ducts connected to the pharyngeal lumen. From a genetic screen we identified several mutants that affect pharyngeal gland morphology. The most severe such mutant is an allele of sma-1, which encodes a β-spectrin required for embryonic elongation, including elongation of the pharynx. In sma-1 mutants, gland projections form normally but become increasingly abnormal over time, acquiring additional branches, outgrowths, and swelling, suggestive of hypertrophy. Rather than acting in pharyngeal glands, sma-1 functions in the surrounding musculature, suggesting that pharyngeal muscles play a critical role in maintenance of gland morphology by restricting their growth, and analysis of other mutants known to affect pharyngeal muscles supports this hypothesis. We suggest that gland morphology is maintained by a balance of forces from the muscles and the glands.

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Aidan Dineen

Quantitating transcription factor redundancy: The relative roles of the ELT-2 and ELT-7 GATA factors in the C. elegans endoderm

The contribution of alternative splicing to genetic risk for psychiatric disorders

Cell Architecture: Surrounding Muscle Cells Shape Gland Cell Morphology in the Caenorhabditis elegans Pharynx

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