Ependymin peptide mimetics that assuage ischemic damage increase gene expression of the anti-oxidative enzyme SOD

Parikh, Suchi Vipin.

January 2003

Thesis (M.S.)--Worcester Polytechnic Institute. / Keywords: Ependymin; anti-oxidative enzyme SOD. Includes bibliographical references (p. 65-69).

Caracterização ultraestrutural das células imunorreativas a 5-bromo-2-deoxiuridina (BRDU) na zona ventricular e sub-ventricular adulta e de sua relação com o peptideo regulador CART. / Ultrastructural characterization of 5-brome-2-deoxyuridine (BrdU) immunoreactives cells in adult ventricular and subventricular zone and its relationship with regulating peptide CART.

Haemmerle, Carlos Alexandre dos Santos

17 March 2015

O maior nicho neurogênico no encéfalo adulto está ao redor dos ventrículos laterais, mas a identificação das células que iniciam tal formação é controversa. Há uma inervação do peptídeo CART que pode abrir perspectivas para o entendimento de seu papel na modulação da neurogênese. Propormos estudar a citoarquitetura ultra-estrutural das células proliferativas na região periventricular e descrever a organização dessa região e sua inervação por axonios imunorreativos ao CART. Utilizamos ratos e camundongos adultos, preparados para análise ultraestrutural e neuroquímica em microscópios eletrônicos de transmissão e varredura de alta-resolução, de luz e laser confocal. O estudo da proliferação e inervação ocorreu com a administração do marcador de fase S BrdU e anticorpos anti-BrdU, anti-CART, anti-DCX, anti-GFAP e anti-GFP. Cada tipo celular do nicho neurogênico apresentou uma densidade própria de ir-BrdU. Identificamos células de revestimento ventricular inervadas por axônios. A maior densidade de inervação ir-CART ocorre ao longo do trajeto dos neurônios em formação. / The major neurogenic niche in adult brains surrounds the lateral ventricles, but the identity of the cell that initiates this process in controversial. There is an innervation made by the CART peptide that may lead to perspectives for understanding its role in modulation of neurogenesis. We propose to study the ultrastructural cytoarchitecture of proliferative cells in this region and its innervation by CART immunoreactive axons. We used adult rats and mice, prepared for ultrastructural and neurochemical analysis by transmission and high-resolution scanning electron, light and laser confocal microscopes. The proliferation and innervation studies occured with the S-phase marker BrdU and anti-Brdu, anti-CART, anti-DCX, anti-GFAP, anti-GFP antibodies. Each sort of cells in neurogenic niche presented a proper density of BrdU staining. We identified the cells lining the ventricle being innervated by axons. The major density of CART innervation occurs along the pathway of neurons in maturation process.

Axon

Axônio

Epêndima

Ependyma

Lateral ventricle

Neurogênese

Neurogenesis

Ventrículo lateral

Caracterização ultraestrutural das células imunorreativas a 5-bromo-2-deoxiuridina (BRDU) na zona ventricular e sub-ventricular adulta e de sua relação com o peptideo regulador CART. / Ultrastructural characterization of 5-brome-2-deoxyuridine (BrdU) immunoreactives cells in adult ventricular and subventricular zone and its relationship with regulating peptide CART.

Carlos Alexandre dos Santos Haemmerle

17 March 2015

O maior nicho neurogênico no encéfalo adulto está ao redor dos ventrículos laterais, mas a identificação das células que iniciam tal formação é controversa. Há uma inervação do peptídeo CART que pode abrir perspectivas para o entendimento de seu papel na modulação da neurogênese. Propormos estudar a citoarquitetura ultra-estrutural das células proliferativas na região periventricular e descrever a organização dessa região e sua inervação por axonios imunorreativos ao CART. Utilizamos ratos e camundongos adultos, preparados para análise ultraestrutural e neuroquímica em microscópios eletrônicos de transmissão e varredura de alta-resolução, de luz e laser confocal. O estudo da proliferação e inervação ocorreu com a administração do marcador de fase S BrdU e anticorpos anti-BrdU, anti-CART, anti-DCX, anti-GFAP e anti-GFP. Cada tipo celular do nicho neurogênico apresentou uma densidade própria de ir-BrdU. Identificamos células de revestimento ventricular inervadas por axônios. A maior densidade de inervação ir-CART ocorre ao longo do trajeto dos neurônios em formação. / The major neurogenic niche in adult brains surrounds the lateral ventricles, but the identity of the cell that initiates this process in controversial. There is an innervation made by the CART peptide that may lead to perspectives for understanding its role in modulation of neurogenesis. We propose to study the ultrastructural cytoarchitecture of proliferative cells in this region and its innervation by CART immunoreactive axons. We used adult rats and mice, prepared for ultrastructural and neurochemical analysis by transmission and high-resolution scanning electron, light and laser confocal microscopes. The proliferation and innervation studies occured with the S-phase marker BrdU and anti-Brdu, anti-CART, anti-DCX, anti-GFAP, anti-GFP antibodies. Each sort of cells in neurogenic niche presented a proper density of BrdU staining. We identified the cells lining the ventricle being innervated by axons. The major density of CART innervation occurs along the pathway of neurons in maturation process.

Axônio

Epêndima

Neurogênese

Ventrículo lateral

Axon

Ependyma

Lateral ventricle

Neurogenesis

Common features of neural progenitor cells and cortical organization revealed by single cell transcriptome analyses of ferret cortical development / フェレット大脳皮質の単一細胞トランスクリプトーム解析による複雑脳形成過程における神経前駆細胞パターンと皮質構築の共通性の解明

Bilgic, Merve

24 November 2023

京都大学 / 新制・課程博士 / 博士(生命科学) / 甲第24985号 / 生博第514号 / 新制||生||68(附属図書館) / 京都大学大学院生命科学研究科高次生命科学専攻 / (主査)教授 北島 智也, 教授 見学 美根子, 教授 今吉 格 / 学位規則第4条第1項該当 / Doctor of Philosophy in Life Sciences / Kyoto University / DFAM

brain development

truncated radial glia

ferret

ependyma

neurogenesis

460

Ependymin Peptide Mimetics That Assuage Ischemic Damage Increase Gene Expression of the Anti-Oxidative Enzyme SOD

Parikh, Suchi Vipin

29 April 2003

Ependymin (EPN) is a goldfish brain neurotrophic factor (NTF) previously shown to function in a variety of cellular events related to long-term memory formation and neuronal regeneration. Because of these functions, EPN and other NTFs have potential applications for treating neuro-degenerative conditions, including stroke. In previous experiments, our lab in collaboration with Victor Shashoua of Ceremedix Inc (Boston, MA), designed short synthetic peptide CMX-8933 (a proteolytic cleavage product of EPN) and CMX-9236 (an EPN-Calmodulin combination peptide) that mimic the action of full-length EPN. In a rat stroke model, administration of these peptides i.v. significantly lowered brain ischemic volume (Shashoua et al., 2003). Because oxidative stress is one of the primary mediators of cell damage following a stroke, we hypothesized that NTFs, and in particular our therapeutic peptides, may act in part by reducing neuronal oxidative stress. Thus, the purpose of this thesis was to determine whether CMX-8933 and CMX-9236 increase the cellular titers of anti-oxidative enzymes. A hybridization array was used as a“hypothesis generator" to obtain candidates for further analysis. This approach applied to rat primary brain cortical cells treated with CMX-8933 identified superoxide dismutase (SOD) as strongly upregulated. SOD immunoblots on whole cell lysates, and RT-PCR on total cellular RNA, were used to confirm this observation. In time-course and dose-response experiments, treatment of rat primary cortical cultures with either peptide showed an optimal 8.5 fold (N = 5, p < 0.001) increase in SOD protein, while administration of CMX-8933 to murine neuroblastoma cells caused a 6.5 fold (N = 3, p = 0.001) increase in SOD mRNA levels. Previous work in other laboratories indicated that systemic (i.v.) administration of full-length NTFs allows only an inefficient delivery across the blood brain barrier (BBB). We hypothesized that our short synthetic peptides may cross the BBB more efficiently. Immunoblot analysis of brains and hearts excised from mice treated i.v. with various doses of CMX-8933 confirmed the elevated SOD titers (10 fold in brain, and 8 fold in heart, at a 6 mg/kg dose for 5 hr; N = 5, p < 0.001). Furthermore, we hypothesized that conjugation of CMX-8933 to BBB carrier DHA, a natural neuronal membrane fatty acid shown previously to enhance the delivery of dopamine to the brain (Shashoua and Hesse, 1996), might further enhance the NTF therapy. Delivery of DHA-8933 increased SOD expression by 3 fold (N = 4, p < 0.001) relative to non-conjugated CMX-8933. Recently, the use of special incubators that allow the culture of cells under low oxygen conditions (anoxia) has been used as an in vitro model for stroke. When we tested our peptides in this new in vitro model, surprisingly SOD was upregulated 3 fold (N = 3, p = 0.003) in rat primary cortical cells cultured for 24 hr under oxygen deprivation, compared to normoxic conditions. This implies that these rat cultures may have an endogenous cellular system for responding to oxygen stress, a finding worthy of further investigation. Treatment of anoxic cells with CMX-8933 increased SOD levels another 2.8 fold (N = 3, p < 0.001) compared to the levels for anoxia alone (for a total of 8.5 fold relative to normoxic cells). Altogether, the data from this thesis illustrate that small NTF EPN peptide mimetics increase the cellular titers of the mRNA and protein for the anti-oxidative enzyme SOD, which may be an important step in their known therapeutic benefits.

Ependymin

Anti-Oxidative Enzyme SOD

Neurotrophic functions

Ependyma

Neuropeptides

Ischemia

Brain damage

Expression of Aquaporins in Mouse Choroid Plexus and Ependymal Cells

Patyal, Pankaj

01 September 2015

No description available.

Pharmacology

Choroid Plexus

Ependyma

CSF

Aquaporins

AQPs 4

7

and 9

NKCC1

Immunolabeling

Potassium Homeostasis

PDGF-C signaling is required for normal cerebellar development : An analysis of cerebellar malformations in PDGF-C impaired mice

Gillnäs, Sara

January 2021

Platelet-derived growth factor-C (PDGF-C) and its tyrosine kinase receptor PDGFRɑ have been shown to contribute to several key processes during central nervous system (CNS) development, including normal vascularization and formation of cerebral ventricles and basal membrane of the meninges. Due to redundancy between PDGF-C and PDGF-A, PDGF-C specific roles are sometimes masked and difficult to determine. Using the double mutant    Pdgfc-/-;PdgfraGFP/+ mouse (Mus musculus) strain we were able to detect and examine a new, undescribed phenotype of PDGF-C impaired mice, namely cerebellar malformations. These mutant mice displayed an upwards rotation of the cerebellar vermis with a severe posterior vermis hypoplasia and an enlarged fourth ventricle, suggesting PDGF-C/PDGFRɑ signaling as a novel candidate to induce Dandy-Walker malformation (DWM). Due to suspected cerebellar vascular malformation a quantification of diameter, density and number of vessels were performed. A significant increase (P &lt; 0.05) of the number and density of vascular bed in the cerebellar nuclei was detected, however the vessel diameter was not significantly different (P &gt; 0.05) in Pdgfc-/-;PdgfraGFP/+ mice in comparison with the control. Through immunofluorescence staining we detected discontinuation of the ependyma in the acute angle of the ventricular zone adjacent to the rhombic lip, interfacing the fourth ventricle and cerebellar anlagen. We further noted ectopic expression of rhombic lip derived cells in the ventricular zone, suggesting a misguided migration due to ablation of PDGF-C. We conclude that PDGF-C is an essential player in normal cerebellar development.

PDGF-C

Cerebellum

Development

PDGFRɑ

Ependyma

Neural migration

Developmental Biology

Utvecklingsbiologi

Spatio-temporal Approach to Transport Dynamics in the Mammalian Ventricular System

Faubel, Regina Johanna

22 November 2013

No description available.

570

clock

circadian

cilia

choroid plexus

ventricle

cerebrospinal fluid

fluid dynamics

transport

brain targeting

flow pattern

ependyma

cilia orientation

humoral communication

Biologie (PPN619462639)