Browsing by Subject "brain"

Now showing 1 - 7 of 7

Embargo
Cell Type Specific Responses to Codon Usage Bias in Two Stem Cell Lineages
(2024) Stewart, Rebeccah
The redundancy inherent in the genetic code allows for multiple codons to encode for a single amino acid. These synonymous codons are used at different frequencies in the genome, with some being used more frequently than others. This phenomenon is known as codon bias. Although codon bias was not originally thought to affect gene expression, we now know that it impacts nearly every step of the central dogma. Previous work identified two Drosophila tissues that express genes enriched in rarely used codons: the larval brain and adult testes. Both tissues contain numerous stem cells which divide many times to produce specialized progeny. In my thesis work, I investigated codon bias regulation in these tissues at the cellular level. In the brain, I found that neural stem cells express very little protein from a rare-codon enriched reporter, while their progeny, the neurons, have high protein expression from the rare-codon enriched reporter. Next, through a targeted genetic screen, I identified a regulator of this response in neurons: the RNA binding protein Orb2. Orb2 stabilizes mRNA from the rare-codon-enriched reporter specifically in neurons, but not in neural progenitors. I then used RNA sequencing to identify mGluR as an endogenous rare codon-enriched gene that requires Orb2 for high mRNA expression and function in social activity. My work suggests that the convergence of rare codons and Orb2 regulation in an mRNA allows precise tuning of gene expression in neurons. Further work during my thesis revealed stage-specific regulation of codon usage during spermatogenesis, and pinpointed specific testis tRNA regulation that likely underlies tissue-specific codon regulation. My work has revealed that codon usage unlocks another layer of gene expression regulation, which is leveraged by the cell to direct temporal and spatial expression regulation during development and function of specialized cell types.
Open Access
Endovascular middle cerebral artery embolic stroke model: a novel approach.
(Journal of neurointerventional surgery, 2021-06-17) Gonzalez, L Fernando; Warner, David S; Sheng, Huaxing; Chaparro, Eduardo
A video (video 1) describing a novel murine endovascular embolic stroke model is presented. Traditional middle cerebral artery (MCA) occlusion models include a blind insertion of a monofilament string12 into the common or external carotid artery with the expectation to selectively occlude the MCA. However, significant mortality occurs due to subarachnoid hemorrhage and variability in stroke size, possibly related to the filament's malposition-for example, external carotid or proximal internal carotid artery (ICA). Additionally, while the string is in place, it occludes the entire extracranial ICA affecting also the collateral pial circulation.neurintsurg;neurintsurg-2021-017370v1/V1F1V1Video 1Our model includes tail artery access, which tolerates several procedures facilitating survival studies. This model uses autologous blood3 4 clot deployed directly into the MCA, resembling what occurs in clinical practice. Autologous thrombi could be lysed with IA/IV tissue plasminogen activator.In summary, we describe a novel model that resembles real practice, permits multiple catheterizations, results in reliable embolization under fluoroscopic guidance and allows therapeutic interventions not available with traditional models.
Open Access
Improved delineation of short cortical association fibers and gray/white matter boundary using whole-brain three-dimensional diffusion tensor imaging at submillimeter spatial resolution.
(Brain Connect, 2014-11) Song, Allen W; Chang, Hing-Chiu; Petty, Christopher; Guidon, Arnaud; Chen, Nan-Kuei
Recent emergence of human connectome imaging has led to a high demand on angular and spatial resolutions for diffusion magnetic resonance imaging (MRI). While there have been significant growths in high angular resolution diffusion imaging, the improvement in spatial resolution is still limited due to a number of technical challenges, such as the low signal-to-noise ratio and high motion artifacts. As a result, the benefit of a high spatial resolution in the whole-brain connectome imaging has not been fully evaluated in vivo. In this brief report, the impact of spatial resolution was assessed in a newly acquired whole-brain three-dimensional diffusion tensor imaging data set with an isotropic spatial resolution of 0.85 mm. It was found that the delineation of short cortical association fibers is drastically improved as well as the definition of fiber pathway endings into the gray/white matter boundary-both of which will help construct a more accurate structural map of the human brain connectome.
Open Access
Progress and challenges in the biology of FNDC5 and irisin.
(Endocrine reviews, 2021-01-25) Maak, Steffen; Norheim, Frode; Drevon, Christian A; Erickson, Harold P
In 2002, a transmembrane protein now known as FNDC5 was discovered and shown to be expressed in skeletal muscle, heart and brain. It was virtually ignored for 10 years, until a study in 2012 proposed that, in response to exercise, the ectodomain of skeletal muscle FNDC5 was cleaved,traveled to white adipose tissue and induced browning. The wasted energy of this browning raised the possibility that this myokine, named irisin, might mediate some beneficial effects of exercise. Since then, more than 1,000 papers have been published exploring the roles of irisin. A major interest has been on adipose tissue and metabolism, following up the major proposal from 2012. Many studies correlating plasma irisin levels with physiological conditions are questioned for use of flawed assays for irisin concentration. However, experiments altering irisin levels by injecting recombinant irisin or by gene knockout are more promising. Recent discoveries have suggested potential roles of irisin to bone remodeling and to brain, with effects potentially related to Alzheimer's disease. We also discuss some discrepancies between research groups and mechanisms that need to be determined. Some important questions raised in the initial discovery of irisin like the role of the mutant start codon of human FNDC5, the mechanism of ectodomain cleavage remain to be answered. Apart from these specific questions, a promising new tool has been developed - mice with a global or tissue-specific knockout of FNDC5. In this review, we critically examine the current knowledge and delineate potential solutions to resolve existing ambiguities.
Open Access
Resting-State Functional Connectivity and Cognition After Major Cardiac Surgery in Older Adults without Preoperative Cognitive Impairment: Preliminary Findings.
(J Am Geriatr Soc, 2017-01) Browndyke, Jeffrey N; Berger, Miles; Harshbarger, Todd B; Smith, Patrick J; White, William; Bisanar, Tiffany L; Alexander, John H; Gaca, Jeffrey G; Welsh-Bohmer, Kathleen; Newman, Mark F; Mathew, Joseph P
OBJECTIVES: To look for changes in intrinsic functional brain connectivity associated with postoperative changes in cognition, a common complication in seniors undergoing major surgery, using resting-state functional magnetic resonance imaging. DESIGN: Objective cognitive testing and functional brain imaging were prospectively performed at preoperative baseline and 6 weeks after surgery and at the same time intervals in nonsurgical controls. SETTING: Academic medical center. PARTICIPANTS: Older adults undergoing cardiac surgery (n = 12) and nonsurgical older adult controls with a history of coronary artery disease (n = 12); no participants had cognitive impairment at preoperative baseline (Mini-Mental State Examination score >27). MEASUREMENTS: Differences in resting-state functional connectivity (RSFC) and global cognitive change relationships were assessed using a voxel-wise intrinsic connectivity method, controlling for demographic factors and pre- and perioperative cerebral white matter disease volume. Analyses were corrected for multiple comparisons (false discovery rate P < .01). RESULTS: Global cognitive change after cardiac surgery was significantly associated with intrinsic RSFC changes in regions of the posterior cingulate cortex and right superior frontal gyrus-anatomical and functional locations of the brain's default mode network (DMN). No statistically significant relationships were found between global cognitive change and RSFC change in nonsurgical controls. CONCLUSION: Clinicians have long known that some older adults develop postoperative cognitive dysfunction (POCD) after anesthesia and surgery, yet the neurobiological correlates of POCD are not well defined. The current results suggest that altered RSFC in specific DMN regions is positively correlated with global cognitive change 6 weeks after cardiac surgery, suggesting that DMN activity and connectivity could be important diagnostic markers of POCD or intervention targets for potential POCD treatment efforts.
Open Access
Task-related changes in degree centrality and local coherence of the posterior cingulate cortex after major cardiac surgery in older adults.
(Hum Brain Mapp, 2017-11-21) Browndyke, Jeffrey N; Berger, Miles; Smith, Patrick J; Harshbarger, Todd B; Monge, Zachary A; Panchal, Viral; Bisanar, Tiffany L; Glower, Donald D; Alexander, John H; Cabeza, Roberto; Welsh-Bohmer, Kathleen; Newman, Mark F; Mathew, Joseph P; Duke Neurologic Outcomes Research Group (NORG)
OBJECTIVES: Older adults often display postoperative cognitive decline (POCD) after surgery, yet it is unclear to what extent functional connectivity (FC) alterations may underlie these deficits. We examined for postoperative voxel-wise FC changes in response to increased working memory load demands in cardiac surgery patients and nonsurgical controls. EXPERIMENTAL DESIGN: Older cardiac surgery patients (n = 25) completed a verbal N-back working memory task during MRI scanning and cognitive testing before and 6 weeks after surgery; nonsurgical controls with cardiac disease (n = 26) underwent these assessments at identical time intervals. We measured postoperative changes in degree centrality, the number of edges attached to a brain node, and local coherence, the temporal homogeneity of regional functional correlations, using voxel-wise graph theory-based FC metrics. Group × time differences were evaluated in these FC metrics associated with increased N-back working memory load (2-back > 1-back), using a two-stage partitioned variance, mixed ANCOVA. PRINCIPAL OBSERVATIONS: Cardiac surgery patients demonstrated postoperative working memory load-related degree centrality increases in the left dorsal posterior cingulate cortex (dPCC; p < .001, cluster p-FWE < .05). The dPCC also showed a postoperative increase in working memory load-associated local coherence (p < .001, cluster p-FWE < .05). dPCC degree centrality and local coherence increases were inversely associated with global cognitive change in surgery patients (p < .01), but not in controls. CONCLUSIONS: Cardiac surgery patients showed postoperative increases in working memory load-associated degree centrality and local coherence of the dPCC that were inversely associated with postoperative global cognitive outcomes and independent of perioperative cerebrovascular damage.
Open Access
The NKI-Rockland Sample: A Model for Accelerating the Pace of Discovery Science in Psychiatry.
(Front Neurosci, 2012) Nooner, Kate Brody; Colcombe, Stanley J; Tobe, Russell H; Mennes, Maarten; Benedict, Melissa M; Moreno, Alexis L; Panek, Laura J; Brown, Shaquanna; Zavitz, Stephen T; Li, Qingyang; Sikka, Sharad; Gutman, David; Bangaru, Saroja; Schlachter, Rochelle Tziona; Kamiel, Stephanie M; Anwar, Ayesha R; Hinz, Caitlin M; Kaplan, Michelle S; Rachlin, Anna B; Adelsberg, Samantha; Cheung, Brian; Khanuja, Ranjit; Yan, Chaogan; Craddock, Cameron C; Calhoun, Vincent; Courtney, William; King, Margaret; Wood, Dylan; Cox, Christine L; Kelly, AM Clare; Di Martino, Adriana; Petkova, Eva; Reiss, Philip T; Duan, Nancy; Thomsen, Dawn; Biswal, Bharat; Coffey, Barbara; Hoptman, Matthew J; Javitt, Daniel C; Pomara, Nunzio; Sidtis, John J; Koplewicz, Harold S; Castellanos, Francisco Xavier; Leventhal, Bennett L; Milham, Michael P
The National Institute of Mental Health strategic plan for advancing psychiatric neuroscience calls for an acceleration of discovery and the delineation of developmental trajectories for risk and resilience across the lifespan. To attain these objectives, sufficiently powered datasets with broad and deep phenotypic characterization, state-of-the-art neuroimaging, and genetic samples must be generated and made openly available to the scientific community. The enhanced Nathan Kline Institute-Rockland Sample (NKI-RS) is a response to this need. NKI-RS is an ongoing, institutionally centered endeavor aimed at creating a large-scale (N > 1000), deeply phenotyped, community-ascertained, lifespan sample (ages 6-85 years old) with advanced neuroimaging and genetics. These data will be publically shared, openly, and prospectively (i.e., on a weekly basis). Herein, we describe the conceptual basis of the NKI-RS, including study design, sampling considerations, and steps to synchronize phenotypic and neuroimaging assessment. Additionally, we describe our process for sharing the data with the scientific community while protecting participant confidentiality, maintaining an adequate database, and certifying data integrity. The pilot phase of the NKI-RS, including challenges in recruiting, characterizing, imaging, and sharing data, is discussed while also explaining how this experience informed the final design of the enhanced NKI-RS. It is our hope that familiarity with the conceptual underpinnings of the enhanced NKI-RS will facilitate harmonization with future data collection efforts aimed at advancing psychiatric neuroscience and nosology.