- Browse by Author
Browsing by Author "Chernoff, Ellen"
Now showing 1 - 6 of 6
Results Per Page
Sort Options
Item Developmental Differences and Altered Gene Expression in the Ts65Dn Mouse Model of Down Syndrome(2012-03-20) Billingsley, Cherie Nicole; Roper, Randall J.; Chernoff, Ellen; Belecky-Adams, TeriTrisomy 21 occurs in approximately 1 out of 750 live births and causes brachycephaly, a small oral cavity, a shortened mid-face, and mental impairments in individuals with Down syndrome (DS). Craniofacial dysmorphology occurs in essentially all individuals with trisomy 21 and causes functional difficulties. Mouse models are commonly used to study the etiology of human disorders because of the conserved phenotypes between species. The Ts65Dn Down syndrome mouse model has triplicated homologues for approximately half the genes on human chromosome 21 and exhibits many phenotypes that parallel those found in individuals with DS. Specifically, newborn and adult Ts65Dn mice display similar craniofacial defects as humans with DS. Ts65Dn embryos also exhibit smaller mandibular precursors than their euploid littermates at embryonic day 9.5 (E9.5). Furthermore, Ts65Dn mice exhibit reduced birth weight which suggests a possible generalized delay in overall embryonic growth. Based on previous research at E9.5, it was hypothesized that Ts65Dn E13.5 embryos would have reduced mandibular precursors with altered gene expression. It was also hypothesized that other neural crest derived structures would be reduced in trisomic embryos. Using morphological measurements it was determined that the mandible, Meckel’s cartilage, and hyoid cartilage were significantly reduced in E13.5 trisomic embryos. The tongue was of similar size in trisomic and euploid embryos while cardiac and brain tissue volumes were not significantly different between genotypes. Analysis of total embryonic size at E9.5 and E13.5 revealed smaller trisomic embryos with developmental attenuation that was not related to maternal trisomy. A microarray analysis performed on the mandibular precursor revealed 155 differentially expressed non-trisomic genes. Sox9 was of particular interest for its role in cartilage condensation and endochondral ossification. It was hypothesized that the overexpression of Sox9 in the developing mandible would be localized to Meckel’s and hyoid cartilages. Immunohistochemistry performed on the mandibular precursor confirmed an overexpression of Sox9 in both Meckel’s and the hyoid cartilages. This research provides further insight into the development of trisomic tissues, both neural crest and non-neural crest-derived, and also the specific molecular mechanisms that negatively affect mandibular development in Ts65Dn mice and presumably individuals with Down syndrome.Item Functional Effects of Carbon Nanoparticles on Barrier Epithelial Cell Function(2011-12) Banga, Amiraj; Stauffacher, Cynthia; Blazer-Yost, Bonnie; Witzmann, F. A. (Frank A.); Chernoff, Ellen; Belecky-Adams, Teri; Atkinson, SimonAs mass production of carbon nanoparticles (CNPs) continues to rise, the likelihood of occupational and environmental exposure raises the potential for exposure‐related health hazards. Although many groups have studied the effects of CNPs on biological systems, very few studies have examined the effects of exposure of cells, tissues or organisms to low, physiologically relevant concentrations of CNPs. Three of the most common types of CNPs are single wall nanotubes (SWNT), multi wall nanotubes (MWNT) and fullerenes (C60). We used electrophysiological techniques to test the effects of CNP exposure (40 μg/cm2 – 4 ng/cm2) on barrier function and hormonal responses of well characterized cell lines representing barrier epithelia from the kidney (mpkCCDcl4) and airways (Calu‐3). mpkCCDcl4 is a cell line representing principal cell type that lines the distal nephron in an electrically tight epithelia that aids in salt and water homeostasis and Calu‐3 is one of the few cell lines that produces features of a differentiated, functional human airway epithelium in vivo. These cell lines respond to hormones that regulate salt/water reabsorption (mpkCCDcl4) and chloride secretion (Calu‐3). In mpkCCDcl4 cells, after 48 hour exposure, the transepithelial electrical resistance (TEER) was unaffected by high concentrations (40 – 0.4 μg/cm2) of C60 or SWNT while lower, more relevant levels (< 0.04 μg/cm2) caused a decrease in TEER. MWNT decreased TEER at both high and low concentrations. CNT exposure for 48 hour did not change the transepithelial ion transport in response to anti‐diuretic hormone (ADH). In Calu‐3 cells, after 48 h of exposure to CNPs, fullerenes did not show any effect on TEER whereas the nanotubes significantly decreased TEER over a range of concentrations (4 μg/cm2‐0.004 ng/cm2). The ion transport response to epinephrine was also significantly decreased by the nanotubes but not by fullerenes. To look at the effect of exposure times, airway cells were exposed to same concentrations of CNPs for 24 and 1h. While the 48 h and 24 h exposures exhibited similar effects, there was no effect seen after 1h in terms of TEER or hormonal responses. In both the cell lines the magnitude of the transepithelial resistance change does not indicate a decrease in cellular viability but would be most consistent with more subtle changes (e.g., modifications of the cytoskeleton or changes in the composition of the cellular membrane). These changes in both the cell lines manifested as an inverse relationship with CNP concentration, were further corroborated by an inverse correlation between dose and changes in protein expression as indicated by proteomic analysis. These results indicate a functional impact of CNPs on epithelial cells at concentrations lower than have been previously studied and suggest caution with regard to increasing CNP levels due to increasing environmental pollution.Item A Lateral Root Defect in the wag1-1/wag2-1 Double Mutant of Arabidopsis(2012-08-07) Rowland, Steven D.; Watson, John C., 1953-; Randall, Stephen Karl, 1953-; Chernoff, EllenThe root system architecture of higher plants plays an essential role in the uptake of water and nutrients as well as the production of hormones. These root systems are highly branched with the formation of post-embryonic organs such as lateral roots. The initiation and development of lateral roots has been well defined. WAG1 and WAG2 are protein-serine/threonine kinases from Arabidopsis that are closely related to PINOID and suppress root waving. The wag1;wag2 double mutants exhibit a strong root waving phenotype on vertical hard agar plates only seen in wild-type roots when the seedlings are grown on inclined plates. Here an additional root phenotype in the wag1;wag2 mutant is reported. The wag1;wag2 double mutant displays both an increased total number and density of emerged lateral roots (approximately 1.5-fold). An increased LRP density of 1.5-fold over wild-type is observed. To ascertain the role of WAG1 and WAG2 in lateral root development we examined promoter activity in the WAG1::GUS and WAG2::GUS lines. The WAG1 promoter showed no detectable activity at any stage of development. The WAG2 promoter was active in stage IV onward, however there was no detectable activity in the cell types associated with initiation events. The lateral root density and spatial patterning in wild-type, when grown on inclined hard agar plates, was similar to wag1;wag2 on vertical plates. Seedlings of both genotypes were treated with hormones such as auxin and MeJA, and inhibitors. Auxin response in wag1;wag2 was normal with a similar number of LR as the wild-type after treatment. Treatment with MeJA resulted in a similar induction of LRP in both genotypes, however the percent lateral root emergence in wag1;wag2 was reduced while Col-0 was increased compared to controls. Treatment with the calcium blocker tetracaine resulted in wag1;wag2 displaying a wild-type level of LR but had no significant effect on wild-type. Genetic analysis of the wag1;wag2 LR pathway revealed that WAG1 and WAG2 are acting in the same pathway as AUX1, AXR1and PGM1. pgm1-1 was not previously reported to have a LR defect but showed decreased LR formation here, while pgm1;wag1;wag2 had a similar LR density to wag1;wag2. TIR7 and ARG1 were both deduced to operate in separate pathways from WAG1 and WAG2. The data presented here shows that the wag1;wag2 double mutant has an increased number of LR compared to Col-0. This defect appears to be caused by increased pre-initiation events and seems to be tied to the root waving phenotype. However, the treatment with MeJA revealed a possible role for WAG1 or WAG2 in LRP development, potentially under stress conditions. Calcium also seems to play a significant role in the wag1;wag2 LR phenotype, possibly independent of the root waving phenotype.Item Molecular Basis and Modification of a Neural Crest Deficit in a Down Syndrome Mouse Model(2013-07-12) Deitz, Samantha L.; Roper, Randall J.; Chang, Hua-Chen; Chernoff, Ellen; Atkinson, SimonDown syndrome (DS) is the result of trisomy of human chromosome 21 (Hsa 21) and occurs in approximately 1/700 live births. Mouse models of DS have been crucial in understanding the gene-phenotype relationships that underlie many DS anomalies. The Ts65Dn mouse model, trisomic for half of the Hsa 21 orthologs replicates many DS phenotypes including craniofacial alterations such as a small, dysmorphic mandible, midface, and maxilla. Other mouse models, such as the Ts1Rhr which contains a triplication of 33 Hsa 21 orthologs, have been used to better understand the genes responsible for craniofacial alterations. Our laboratory has demonstrated that the postnatal mandibular phenotype found in Ts65Dn mice can be traced back to an original neural crest cell (NCc) deficit in the developing first pharyngeal arch (PA1) at embryonic day 9.5 (E9.5). Furthermore, evidence suggested that both a proliferation deficit in the PA1 and a migration deficit in the NCC from the neural tube (NT) could be the mechanism behind this deficit. However, the molecular mechanisms behind these deficits remain to be elucidated. Due to the involvement of the Hsa 21 genes DYRK1A and RCAN1 in regulation of signaling pathways including NFATc (NFAT2), a transcription factor known to influence cellular proliferation and, later, bone development, we hypothesized that dysregulation of these genes could underlie the cellular deficit in the PA1. Furthermore, we hypothesized that targeting Dyrk1a by decreasing activity or available protein could ameliorate the established deficits. Through the use of RNA isolation techniques and cell culture systems of cell from the PA1 and NT of E9.5 Ts65Dn, Ts1Rhr, and control embryos, we established that trisomic genes Dyrk1a and Rcan1 ara dysregulated in both structures and that these two genes may interact. Furthermore, we established that a proliferation deficit in the Ts65Dn PA1 and a migration deficit in the Ts65Dn PA1 and NT exists at E9.5 and can be rescued to euploid levels in vitro with the addition of the Dyrk1a inhibitor, EGCG, a green tea polyphenol. We also confirmed that harmine, a more highly studied and specific Dyrk1a inhibitor, is capable of similar effects on proliferation of PA1 cell from E9.5 Ts65Dn embryos. Furthermore, when Ts65Dn pregnant mothers were treated with EGCG in vivo, the cellular deficit found in the developing E9.5 embryonic PA1 was rescued to near euploid volume and NCC number. Treatment with EGCG did not adversely impact litter size or embryonic development. Interestingly, euploid embryonic volume increased with EGCG treatment. Expression analysis of the E9.5 PA1 of EGCG treated Ts65Dn and control embryos revealed dysregulation of several genes involved in craniofacial and developmental pathways including Dyrk1a, Rcan1, Ets2 and members of the sonic hedgehog pathways. Our novel results provide a foundation for better understanding the molecular mechanisms of craniofacial development and may provide evidence-based therapeutic options to improve the quality of life for individuals with DS.Item Pathobiology of neuroinflammation and basal ganglia circuitry in Parkinson’s Disease(2017-05) Wilson, Jonathan Matthew; Stauffacher, Cynthia; Belecky-Adams, Teri; Merchant, Kalpana; Wang, Hong; Baucum, Anthony; Chernoff, EllenParkinson’s disease (PD) is the second most common neurodegenerative disease worldwide and the most common movement disorder. A defining pathologic feature of PD is the progressive death of dopaminergic neurons in a basal ganglia nucleus termed the substantia nigra (SN). Another hallmark feature of PD pathology is the presence of Lewy bodies and Lewy neurites, which are cellular inclusions with aggregated protein depositions, representing pathology in neuronal cell bodies and neuritic processes. Recently, epidemiological and genetic studies support roles for neuroinflammation in the progression of PD. Two types of cells that play a critical role in regulating neuroinflammation are microglia and astrocytes, which are activated in the basal ganglia of PD patients. Studies within this dissertation characterized activation of microglial cells by alpha-synuclein (α-synuclein), the most abundant protein in Lewy bodies, which has been implicated in PD pathogenesis. To garner insights into molecular mechanisms associated with astrocyte proliferation and activation, genomic alterations during developmental stages of astrocytes were examined since they are likely to recapitulate the reactivity associated with gliosis in PD brain. The activation of these glial cells and pathology of neurons in the basal ganglia causes the hallmark symptoms of PD. The symptoms of PD are termed parkinsonism. These are thought to result, at least in part, from alterations in the balance of output of the neostriatal efferent neurons, due to the loss of dopaminergic neuronal innervation of these cells. Phosphodiesterase 10A (PDE10A) is preferentially expressed in neostriatal efferent pathways and PDE10A inhibitors (PDE10i) have been shown to target dopamine signaling mechanisms. Studies here have utilized PDE10i to understand the balance of activation of medium spiny neurons in the indirect pathway versus activation of the direct pathway, since recent findings show PDE10i lead to a decrease in thalamic drive to the motor cortex, a primary symptom of PD. In conclusion, the aims of this dissertation sought to identify neuroinflammatory mechanisms within activated microglia in response to α-synuclein and proliferating astrocytes. Also, this work evaluated an inhibition of PDE10A in neurons within a region important to the progression of PD.Item A retrospective analysis of comorbid traits affecting feeding in infants with Down syndrome(2012-07-03) Duvall, Nichole L.; Roper, Randall J.; Marrs, Kathleen A.; Chernoff, EllenDown syndrome (DS) is the most common aneuploidy to affect humans and occurs in approximately 1 of 750 live births. Individuals with DS present with a wide range of clinical phenotypes. Common craniofacial phenotypic expressions include a small mandible, protruding tongue, and a flattened nasal bridge. These traits may affect the feeding, breathing, and swallowing of individuals with DS. Because some complications may go unnoticed for longer periods of time, we hypothesize that significant cardiac and GI defects may be indicative of feeding and airway difficulties. In order to better understand the secondary phenotypes resulting from DS, we have implemented a retrospective chart review of 137 infants between zero and six months of age who were evaluated through the Down Syndrome Program at Riley Hospital for Children from August 2005 to August 2008. Data regarding cardiac, gastrointestinal, endocrine, airway, auditory, and feeding abnormalities have been collected and incedences and comorbidites of these traits has been examined. Comprehensive results indicate cardiac abnormalities occur in 80% of infants, 60% experience gastrointestinal complications, feeding difficulties occur in 46%, and airway complications occur in 38% of infants. Infants with DS were found to be breastfed less over time, with an increase in tube feeds. Notably, we have found all infants with videofluoroscopic evaluations had some type of dysphagia. The presence of gastrointestinal abnormalities closely correlate with the need for tube feeds, and the comorbidity between GI anomalies and muscle tone appear to indicate the likelihood of feeding difficulties and need for altered feeding strategies. Comorbidities between feeding difficulties were nearly significant with cardiac defects and significant with GI abnormalities. Identification of such associations will help healthcare providers determine the best course of treatment and recommended feeding methodology for infants with DS. In order to utilize an in vitro model to study the craniofacial dysmorphologies seen in individuals with DS, cranial neural crest cells (NC) have been cultured. With these, we have begun to investigate the mechanisms behind a smaller trisomic mandibular precursor as compared to the euploid. With this in vitro model, we will be able to test proliferation, migration, and senescence of NC in a culture system.