Your search keyword '"Sanchez-Gomez, Diana B."' showing total 7 results

1. Spatiotemporal expression and transcriptional perturbations by long noncoding RNAs in the mouse brain

Author

Goff, Loyal A., Groff, Abigail F., Sauvageau, Martin, Trayes-Gibson, Zachary, Sanchez-Gomez, Diana B., Morse, Michael, Martin, Ryan D., Elcavage, Lara E., Liapis, Stephen C., Gonzalez-Celeiro, Meryem, Plana, Olivia, Li, Eric, Gerhardinger, Chiara, Tomassy, Giulio S., Arlotta, Paola, and Rinn, John L.

Published

2015

2. Spatiotemporal expression and transcriptional perturbations by long noncoding RNAs in the mouse brain

Author

Massachusetts Institute of Technology. Computer Science and Artificial Intelligence Laboratory, Goff, Loyal A., Groff, Abigail F., Sauvageau, Martin, Trayes-Gibson, Zachary, Sanchez-Gomez, Diana B., Morse, Michael, Martin, Ryan D., Elcavage, Lara E., Liapis, Stephen C., Gonzalez-Celeiro, Meryem, Plana, Olivia, Li, Eric, Gerhardinger, Chiara, Tomassy, Giulio S., Arlotta, Paola, Rinn, John L., Massachusetts Institute of Technology. Computer Science and Artificial Intelligence Laboratory, Goff, Loyal A., Groff, Abigail F., Sauvageau, Martin, Trayes-Gibson, Zachary, Sanchez-Gomez, Diana B., Morse, Michael, Martin, Ryan D., Elcavage, Lara E., Liapis, Stephen C., Gonzalez-Celeiro, Meryem, Plana, Olivia, Li, Eric, Gerhardinger, Chiara, Tomassy, Giulio S., Arlotta, Paola, and Rinn, John L.

Abstract

Long noncoding RNAs (lncRNAs) have been implicated in numerous cellular processes including brain development. However, the in vivo expression dynamics and molecular pathways regulated by these loci are not well understood. Here, we leveraged a cohort of 13 lncRNA-null mutant mouse models to investigate the spatiotemporal expression of lncRNAs in the developing and adult brain and the transcriptome alterations resulting from the loss of these lncRNA loci. We show that several lncRNAs are differentially expressed both in time and space, with some presenting highly restricted expression in only selected brain regions. We further demonstrate altered regulation of genes for a large variety of cellular pathways and processes upon deletion of the lncRNA loci. Finally, we found that 4 of the 13 lncRNAs significantly affect the expression of several neighboring protein-coding genes in a cis-like manner. By providing insight into the endogenous expression patterns and the transcriptional perturbations caused by deletion of the lncRNA locus in the developing and postnatal mammalian brain, these data provide a resource to facilitate future examination of the specific functional relevance of these genes in neural development, brain function, and disease., National Science Foundation (U.S.) (Postdoctoral Research Fellowship in Biology DBI-0905973)

Published

2016

3. In Vivo Characterization of Linc-p21 Reveals Functional cis -Regulatory DNA Elements

Author

Groff, Abigail F., primary, Sanchez-Gomez, Diana B., additional, Soruco, Marcela M.L., additional, Gerhardinger, Chiara, additional, Barutcu, A. Rasim, additional, Li, Eric, additional, Elcavage, Lara, additional, Plana, Olivia, additional, Sanchez, Lluvia V., additional, Lee, James C., additional, Sauvageau, Martin, additional, and Rinn, John L., additional

Published

2016

4. Multiple knockout mouse models reveal lincRNAs are required for life and brain development

Author

Massachusetts Institute of Technology. Computer Science and Artificial Intelligence Laboratory, Massachusetts Institute of Technology. Department of Electrical Engineering and Computer Science, Goff, Loyal, Kellis, Manolis, Sauvageau, Martin, Lodato, Simona, Bonev, Boyan, Groff, Abigail F., Gerhardinger, Chiara, Sanchez-Gomez, Diana B., Hacisuleyman, Ezgi, Li, Eric, Spence, Matthew, Liapis, Stephen C., Mallard, William, Morse, Michael, Swerdel, Mavis R., D'Ecclessis, Michael F., Moore, Jennifer C., Lai, Venus, Gong, Guochun, Yancopoulos, George D., Frendewey, David, Hart, Ronald P., Valenzuela, David M., Arlotta, Paola, Rinn, John L., Massachusetts Institute of Technology. Computer Science and Artificial Intelligence Laboratory, Massachusetts Institute of Technology. Department of Electrical Engineering and Computer Science, Goff, Loyal, Kellis, Manolis, Sauvageau, Martin, Lodato, Simona, Bonev, Boyan, Groff, Abigail F., Gerhardinger, Chiara, Sanchez-Gomez, Diana B., Hacisuleyman, Ezgi, Li, Eric, Spence, Matthew, Liapis, Stephen C., Mallard, William, Morse, Michael, Swerdel, Mavis R., D'Ecclessis, Michael F., Moore, Jennifer C., Lai, Venus, Gong, Guochun, Yancopoulos, George D., Frendewey, David, Hart, Ronald P., Valenzuela, David M., Arlotta, Paola, and Rinn, John L.

Abstract

Many studies are uncovering functional roles for long noncoding RNAs (lncRNAs), yet few have been tested for in vivo relevance through genetic ablation in animal models. To investigate the functional relevance of lncRNAs in various physiological conditions, we have developed a collection of 18 lncRNA knockout strains in which the locus is maintained transcriptionally active. Initial characterization revealed peri- and postnatal lethal phenotypes in three mutant strains (Fendrr, Peril, and Mdgt), the latter two exhibiting incomplete penetrance and growth defects in survivors. We also report growth defects for two additional mutant strains (linc–Brn1b and linc–Pint). Further analysis revealed defects in lung, gastrointestinal tract, and heart in Fendrr[superscript −/−] neonates, whereas linc–Brn1b[superscript −/−] mutants displayed distinct abnormalities in the generation of upper layer II–IV neurons in the neocortex. This study demonstrates that lncRNAs play critical roles in vivo and provides a framework and impetus for future larger-scale functional investigation into the roles of lncRNA molecules., National Science Foundation (U.S.) (Postdoctoral Fellowship in Biology)

Published

2014

5. Multiple knockout mouse models reveal lincRNAs are required for life and brain development

Author

Sauvageau, Martin, primary, Goff, Loyal A, additional, Lodato, Simona, additional, Bonev, Boyan, additional, Groff, Abigail F, additional, Gerhardinger, Chiara, additional, Sanchez-Gomez, Diana B, additional, Hacisuleyman, Ezgi, additional, Li, Eric, additional, Spence, Matthew, additional, Liapis, Stephen C, additional, Mallard, William, additional, Morse, Michael, additional, Swerdel, Mavis R, additional, D’Ecclessis, Michael F, additional, Moore, Jennifer C, additional, Lai, Venus, additional, Gong, Guochun, additional, Yancopoulos, George D, additional, Frendewey, David, additional, Kellis, Manolis, additional, Hart, Ronald P, additional, Valenzuela, David M, additional, Arlotta, Paola, additional, and Rinn, John L, additional

Published

2013

6. In Vivo Characterization of Linc-p21Reveals Functional cis-Regulatory DNA Elements

Author

Groff, Abigail F., Sanchez-Gomez, Diana B., Soruco, Marcela M.L., Gerhardinger, Chiara, Barutcu, A. Rasim, Li, Eric, Elcavage, Lara, Plana, Olivia, Sanchez, Lluvia V., Lee, James C., Sauvageau, Martin, and Rinn, John L.

Abstract

The Linc-p21locus, encoding a long non-coding RNA, plays an important role in p53 signaling, cell-cycle regulation, and tumor suppression. However, despite extensive study, confusion exists regarding its mechanism of action: is activity driven by the transcript acting in trans, in cis, or by an underlying functional enhancer? Here, using a knockout mouse model and a massively parallel enhancer assay, we delineate the functional elements at this locus. We observe that, even in tissues with no detectable Linc-p21transcript, deletion of the locus significantly affects local gene expression, including of the cell-cycle regulator Cdkn1a. To characterize this RNA-independent regulatory effect, we systematically interrogated the underlying DNA sequence for enhancer activity at nucleotide resolution and confirmed the existence of multiple enhancer elements. Together, these data suggest that, in vivo, the cis-regulatory effects mediated by Linc-p21, in the presence or absence of transcription, are due to DNA enhancer elements.

Published

2016

7. In Vivo Phenotypic Characterization of the Long Non-Coding RNA Kantr

Author

Sanchez Gomez, Diana B.

Subjects

Biology, Genetics, Biology, Molecular, Biology, Neuroscience

Abstract

Non-coding regions of the human genome have just begun to be unraveled, and they hold the potential to be key regulators of biological mechanisms. The absence of a particular non-coding gene could be the answer to a disease that is not yet well understood. Neurological diseases are an example of those diseases that are not fully understood, because the brain is the most complex organ in the human body. Kantr is a long non-coding RNA that is expressed in the brain. Brain expression patterns using a lacz reporter gene were found to have Kantr expression in the hippocampus (C1, C2, C3), as well as the piriform cortex. Deletion of long non-coding RNA Kantr locus in mice reveled that it phenocopied human seizures. Using a device similar to the one used in humans to detect brain activity, we attached a mini-mouse size electroencephalogram (EEG) to detect mouse brain electrical activity. Through EEG recordings, we characterized the seizure activity of Kantr knockout mice. These mice had been identified as having increased seizure activity. The brain electrical activities of the Kantr knockout mice were recorded 2-5 times for 2 hours. We discovered that 89% of the Kantr knockout mice were presented with characteristic abscent seizures compared to 0% of the wild type mice. Abscent seizures are characteristic of increased spikes of electrical activity while the mouse is freezing state. Similar freezing features can be observed in a human while having an abscent seizure; thus deletions of the Kantr locus recapitulated a human phenotype.

Published

2017