Functional Tissue Engineering of Myocardium Through Cell Tri-culture

Iyer, Rohin

22 August 2012

Cardiac tissue engineering promises to create therapeutic tissue replacements for repair of diseased native myocardium. The main goals of this thesis were four-fold: 1) to evaluate cardiac tissues engineered using multiple cell types including endothelial cells (EC), fibroblasts (FB), and cardiomyocytes (CM); 2) to spatiotemporally track cells in organoids and optimize their seeding percentages for improved function; 3) to enhance vascular cord formation through sequential versus simultaneous seeding of ECs and FBs; and 4) to perform mechanistic studies to elucidate the role of soluble factors in cell-cell communication. Microscale templates fabricated from photocrosslinkable poly(ethylene glycol) diacrylate (PEG-DA) were used for all studies for rapid screening. When ECs and FBs were precultured for two days prior to seeding enriched CMs, cells self-assembled into three-dimensional, beating organoids, compared to simultaneously tricultured EC/ FB / CM which formed non-contractile clusters. Fluorescent dyes were used to label and track each cell type for up to 4 days, demonstrating an even distribution of cells within precultured organoids versus EC clustering in simultaneous triculture. When ECs were seeded first, followed by FBs 24 hours later and CMs 48 hours later, vascular-like cords formed that persisted with time in a seeding density-dependent manner. Vascular endothelial growth factor (VEGF) signaling was quantified, showing higher endogenous VEGF secretion rates in sequential preculture (16.6 ng/mL/hr) compared to undetectable VEGF secretion in simultaneous triculture. Blocking of endogenous VEGF signaling through addition of VEGF antibody / VEGFR2 inhibitor resulted in a significant decrease in mRNA and protein expression of the key cardiac gap junctional marker connexin-43. These findings provide a foundation for future work into the mechanisms governing functional cardiac tissue engineering performance and may aid in the development of novel therapies for heart failure based on growth factor signaling and engineering of vascularized, clinically relevant cardiac tissue patches.

Tissue Engineering

Cardiac Tissue Engineering

Biomedical Engineering

Vascularization

Tri-culture

Microfabrication

Cell Tracking

VEGF

Connexin-43

Pre-culture

Milica Radisic

Rohin Iyer

Bioreactor

Microbioreactor

Soft Lithography

Cardiomyocyte

Fibroblast

Endothelial

Sequential Pre-culture

Pericyte

Cords

Endothelial Cord

0541

Functional Tissue Engineering of Myocardium Through Cell Tri-culture

Iyer, Rohin

22 August 2012

Cardiac tissue engineering promises to create therapeutic tissue replacements for repair of diseased native myocardium. The main goals of this thesis were four-fold: 1) to evaluate cardiac tissues engineered using multiple cell types including endothelial cells (EC), fibroblasts (FB), and cardiomyocytes (CM); 2) to spatiotemporally track cells in organoids and optimize their seeding percentages for improved function; 3) to enhance vascular cord formation through sequential versus simultaneous seeding of ECs and FBs; and 4) to perform mechanistic studies to elucidate the role of soluble factors in cell-cell communication. Microscale templates fabricated from photocrosslinkable poly(ethylene glycol) diacrylate (PEG-DA) were used for all studies for rapid screening. When ECs and FBs were precultured for two days prior to seeding enriched CMs, cells self-assembled into three-dimensional, beating organoids, compared to simultaneously tricultured EC/ FB / CM which formed non-contractile clusters. Fluorescent dyes were used to label and track each cell type for up to 4 days, demonstrating an even distribution of cells within precultured organoids versus EC clustering in simultaneous triculture. When ECs were seeded first, followed by FBs 24 hours later and CMs 48 hours later, vascular-like cords formed that persisted with time in a seeding density-dependent manner. Vascular endothelial growth factor (VEGF) signaling was quantified, showing higher endogenous VEGF secretion rates in sequential preculture (16.6 ng/mL/hr) compared to undetectable VEGF secretion in simultaneous triculture. Blocking of endogenous VEGF signaling through addition of VEGF antibody / VEGFR2 inhibitor resulted in a significant decrease in mRNA and protein expression of the key cardiac gap junctional marker connexin-43. These findings provide a foundation for future work into the mechanisms governing functional cardiac tissue engineering performance and may aid in the development of novel therapies for heart failure based on growth factor signaling and engineering of vascularized, clinically relevant cardiac tissue patches.

Tissue Engineering

Cardiac Tissue Engineering

Biomedical Engineering

Vascularization

Tri-culture

Microfabrication

Cell Tracking

VEGF

Connexin-43

Pre-culture

Milica Radisic

Rohin Iyer

Bioreactor

Microbioreactor

Soft Lithography

Cardiomyocyte

Fibroblast

Endothelial

Sequential Pre-culture

Pericyte

Cords

Endothelial Cord

0541

Insights Into Molecular Regulation Of Cardiomyocyte Differentiation Of Mouse Pluripotent Stem Cells

Abbey, Deepti

07 1900

Pluripotent stem cells (PSCs) are specialized cells, which have remarkable ability to maintain in an undifferentiated state and are capable of undergoing differentiation to three germ-layer lineage cell types, under differentiation-enabling conditions. PSCs include embryonic stem (ES)-cells, embryonal carcinoma (EC)-cells and embryonic germ (EG)-cells. ES-cells are derived from the inner cell mass (ICM) of day 3.5 blastocysts (mouse). On the other hand, EC- and EG-cells have different source of origin and exhibit some differences in terms of their differentiation abilities and culture requirements. These PSCs act as an ideal in-vitro model system to study early mammalian development and cell differentiation and, they could potentially be used for experimental cell-based therapy for a number of diseases. However, one of the problems encountered is the immune rejection of transplanted cells. For this, immune-matched induced pluripotent stem (iPS)-cells have been derived from somatic cells, by forced expression of a few stemness genes. Although, human PSCs lines are being experimented, their cell-therapeutic potential is still far from being thoroughly tested due to lack of our understanding regarding lineage-specific differentiation, homing and structural-functional integration of differentiated cell types in the host environment. To understand these mechanisms, it is desirable to have fluorescently-marked PSCs and their differentiated cell-types, which could facilitate experimental cell transplantation studies. In this regard, our laboratory has earlier generated enhanced green fluorescent protein (EGFP)-expressing FVB/N transgenic ‘green’ mouse: GU-3 line (Devgan et al., 2003). This transgenic mouse has been an excellent source of intrinsically green fluorescent cell types. Recently, we have derived a ‘GS-2’ ES-cell line from the GU-3 mouse line (Singh et al., 2012). Additionally, we envisaged the need for developing an iPS-cell line from the GU-3 mouse and then use them for studying cell differentiation. Thus, aims of the study described in the thesis are to: (1) develop an experimental system to derive EGFP-expressing fluorescently-marked iPS-cell line from a genetically non-permissive FVB/N mouse strain, characterize the established iPS-cell line and achieve differentiation of various cell types from EGFP-expressing iPS-cell line; (2) to study differentiation phenomenon, in particular to cardiac lineage, using select-cardiogenesis modulators and (3) to assess the gene-expression profiles and signaling system associated with cardiomyocyte differentiation of PSCs. This thesis is divided into four chapters with the 1st chapter being a review of literature followed by three data chapters. In the chapter I of the thesis, a comprehensive up-to¬date review of literature is provided pertaining to PSCs, their classification, derivation strategies especially for reprogramming of somatic cells for iPSC generation, their differentiation potential and characterization, particularly to cardiac lineage. Various molecular regulators involved in cardiac differentiation of PSCs with emphasis on epigenetic regulation involving DNA methylation and signaling pathways involved are described in detail. Subsequently, various approaches used for enhanced cardiac differentiation of PSCs and the therapeutic potential of PSC-derived differentiated cell types to treat disease(s) are discussed. Chapter-II describes the successful establishment of a permanent iPS-cell line (named ‘N9’ iPS-cell line) from the non-permissive FVB/N EGFP-transgenic GU-3 ‘green’ mouse. This chapter provides results pertaining to detailed derivation strategy and characterization of the ‘N9’ iPS-cell line which includes colony morphology, expansion (proliferation) efficiency, alkaline phosphatase staining, pluripotent markers’ expression analysis by qPCR and immunostaining approaches and karyotyping analysis. Further, in order to thoroughly assess the differentiation competence of the ‘N9’ iPS¬cell line, assessment of in-vitro and in-vivo differentiation potential of the ‘N9’ iPS-cell line by embryoid body (EB) formation and teratoma formation in nude mice and its detailed histological analysis showing three germ layer cell types and their derivatives were performed, followed by the generation of chimeric blastocysts by aggregation method. This established N9 iPS-cell line could potentially offer a suitable model system to study cardiac differentiation along with other established PSC lines such as the GS-2 and D3 ES-cell lines and the P19 EC-cell line. Following the establishment of the system to study cardiac differentiation of PSC lines, efforts were made to understand the biology of cardiac differentiation of PSCs (wild¬type and EGFP-transgenic PSC lines and P19 EC-cell line) using small molecules as modulators. Data pertaining to this is described in Chapter-III. The possible involvement of epigenetic regulation of cardiogenesis for example, DNA methylation changes in cardiogenesis-associated genes is studied using 5-aza cytidine as one of the chromatin modifiers. In order to understand the cardiac differentiation phenomenon, as a consequence of using 5-aza cytidine in cell culture, it was important to investigate its ability to induce/mediate cardiac differentiation. This involved an assessment by quantitating the cardiac beating phenotype and correlating this with enhanced cardiac-gene expression profiles. Further, DNA methylation regulation of cardiogenesis¬associated genes is described using various DNA methylation analysis techniques. Moreover, the possible involvement of other signaling members in mediating the cardiac differentiation is also studied using the P19 EC-cells. Results pertaining to the above findings are described in detail in the Chapter-III. Chapter-IV is focused on various efforts made towards investigating the ability of ascorbic acid to enhance cardiac differentiation of mouse ES-cells (GS-2 and D3 lines). Ascorbic acid has been implicated to be influencing cardiogenesis and it is reported to enhance differentiation of various cell types under certain culture conditions. Results pertaining to enhancement of cardiac differentiation of PSCs using ascorbic acid are presented in this chapter. This included assessment by quantitating cardiac beating phenotype and its correlation with enhanced cardiogenesis-associated gene expression profiles. Besides, estimation on the sorted cardiomyocyte population, derived from PSCs was also made using mature-cardiac marker. The possible underlying signaling mechanism involved was also studied in detail, using specific inhibitors for pERK (U0126), integrin signaling (pFAK; PP2) and collagen synthesis (DHP), in order to ascertain their involvement in ascorbic acid-mediated cardiac differentiation of mouse ES-cells. Subsequent to the three data chapters (II-IV), separate sections are provided for ‘Summary and Conclusion’ and for ‘Bibliography’, cited in the thesis. The overall scope of the study has been to understand the basic biology of cardiac differentiation from PSCs (EC-cells, iPS-cells and transgenic and wild-type ES-cells) and to assess, by using certain small molecules, whether PSCs could be coaxed to enhance the differentiation to a particular cell type (cardiac). The data contained in this thesis addresses the above theme.

Molecular Regulation

Cardiac Differentiation

Cell Differentiation

Pluripotent Stem Cells

Embryonic Stem Cells

Embryonal Carcinoma Cells

Cardiomyocytes

Cardiomyocyte Differentiation

Mouse Pluripotent Stem Cells

Pluripotent Stem Cells (PSCs)

Stem Cell Research

Embryonic Germ Cells

EC-cells

ES-cells

Molecular Biology

Non-human primate iPS cells for cell replacement therapies and human cardiovascular disease modeling

Rodriguez Polo, Ignacio

29 October 2019

No description available.

570

iPSC

Non-human primates

Cardiac regeneration

Genome editing

CRISPR/Cas

Human Disease Modeling

Rhesus macaque, Macaca mulatta

Marmoset monkey, Callithrix jacchus

Olive baboon, Papio anubis

Induced Pluripotent Stem Cells

Directed cardiomyocyte differentiation

Stem Cell Based Therapy

Biologie (PPN619462639)

IL-10 and TGF-beta Increase Connexin-43 Expression and Membrane Potential of HL-1 Cardiomyocytes Coupled With RAW 264.7 Macrophages

Cox, Cora B.

02 September 2021

No description available.

Microbiology

Immunology

Cardiomyocyte

macrophage

IL-10

TGF-beta

SOCS3

connexin-43

membrane potential

Di-8-ANEPPS

Confocal

F-4/80

myocardial infarction

bacterial infection of the heart

viral infection of the heart

COVID-19 infection of the heart

Etablierung der Rasterkraftmikroskopie an kardiovaskulär relevanten Zellen, Proteinen und Materialien

Richter, Christoph

20 October 2003

1981 entwickelten Gerd Binnig und Heinrich Rohrer bei IBM in Zürich das "Scanning Tunneling Microscope". Damit wurde erstmalig das lokal hochaufgelöste Erfassen (bis in den atomaren Auflösungsbereich) von Objekteigenschaften im Nahfeld inerter Oberflächen möglich. Dies und insbesondere die Weiterentwicklung der Technologie und die spätere (1986) Etablierung der Rasterkraftmikroskopie (Atomic Force Microscopy - AFM), die diese Auflösungsmöglichkeiten der Rastersondenmikroskope auch an Non-Konduktoren (nicht leitende Untersuchungsoberflächen) realisieren konnte, stellte die Geburtsstunde einer neuen mikroskopischen Ära auf dem Gebiet der biomedizinischen Grundlagenforschung dar (Kapitel 1.3). Das Studium der umfangreichen Literaturquellen zu diesem Thema und der direkte wissenschaftliche Kontakt und Erfahrungsaustausch mit anderen AFM- Arbeitsgruppen ließen im Initialstadium dieser vorliegenden Arbeit bereits erkennen, dass in der kardiovaskulären Grundlagenforschung zunehmend rasterkraftmikroskopische Versuchsansätze bearbeitet und kardiologisch interessante Fragestellungen mittels dieser Methode begleitend untersucht wurden (Kapitel 1.4). Das Ziel dieser vorliegenden Arbeit bestand darin, kardiovaskulär relevante Zellen und Einzelproteine in vivo und interventionelle Materialien (Stents) rasterkraftmikroskopisch zu untersuchen, wobei die Etablierung und technisch aufwendige Optimierung dieser neuen mikroskopischen (Kapitel 3.1) und der zellspezifisch präparatorischen Methoden (Kapitel 3.2) an diesen Untersuchungsobjekten im Mittelpunkt stehen sollte. Die im Rahmen dieser Arbeit untersuchten endothelialen Zellen und H9C2-Myozyten stammten aus, in unserem Forschungslabor etablierten, immortalen Kulturzelllinien. Die adulten und Kardiomyozyten neonataler Ratten, die kardial- fibrozytären Zellen sowie die Thrombozyten wurden primär isoliert und als Primärkulturzellen kultiviert (Kapitel 3.2.3 und 3.2.4). Außerdem wurden vitale aortale Endothelzellen unterschiedlicher Tiere (Ratte, Meerschwein, Kaninchen) im Gewebsverband der thorakalen Aorta untersucht (Kapitel 4.2). Die Zellen wurden initial, im Rahmen der Etablierungsphase mittels unterschiedlicher Methoden fixiert und nachfolgend rasterkraftmikroskopisch untersucht und dargestellt. Der Etablierungsprozess der Methodik begann mit der Abbildung luftgetrockneter Zellen (Kapitel 4.1.1) unter Raumbedingungen und setzte sich über verschiedene Modifikationen der Zellpräparation (z.B. Glutardialdehydfixation, Cryofixation), des Abbildungsmodus (Contact-, Non-Contact-, Tapping-Mode) und der Abbildungsbedingungen (Raumbedingungen, zellphysiologische Umgebung) fort, so dass schließlich die Abbildung vitaler Zellen (Kapitel 4.1.2 und Kapitel 4.2 - 4.5) in ihrer strukturellen und funktionellen Umgebung (z.B. aortale Endothelzellen im Gewebsverband) etabliert werden konnte und routinemäßig reproduzierbar war. An stabilen oder künstlich stabilisierten Strukturen der o.g. vitalen Zellen wurden erste orientierende Messungen der bioelastischen Eigenschaften (Kraft-Abstands-Kurven, Kapitel 4.1.2.1) durchgeführt. Außerdem haben wir im Einzelfall, wenn technisch und apparativ möglich, andere hochauflösende strukturanalytische Verfahren (z.B. TEM) als mikroskopische Referenzuntersuchungen herangezogen (Kapitel 4.1.2; 4.4.1; 4.6), wobei z.T. erstaunliche Übereinstimmung zwischen den AFM- Daten und den strukturanalytischen Daten der Referenzmethoden nachweisbar waren. Ein strukturell durch Elektronenmikroskopie und Röntgendiffraktionsanalyse sehr gut beschriebenes komplexes Funktionsprotein, das 20-S-Proteasom, wurde mittels der Rasterkraftmikroskopie abgebildet und vermessen und die so gewonnenen strukturanalytischen Daten mit den bekannten strukturellen Abmessungen des Proteins verglichen (Kapitel 4.6). Die hierbei detektierten dimensionalen Abweichungen zwischen den AFM- assoziierten Daten und den bekannten strukturanalytischen Daten der Elektronenmikroskopie wurden im Kontext der funktionellen Integrität des Proteins und hinsichtlich möglicher methodischer Fehlereinflüsse (Kapitel 3.1.4.3) diskutiert. Interventionelle Materialien (Stents), die in der täglichen kardiologischen Praxis Anwendung finden, sind hinsichtlich ihrer Ultrastruktur mittels dieser hochsensitiven Abbildungsmethode im Nahfeld von Objektoberflächen untersucht worden. Bezüglich ihrer nativen Oberflächenbeschaffenheit und ihrer mechanischen Alteration durch den Ballon- Dilatationsprozess wurden die Stents sehr detailliert qualitativ und quantitativ (Kapitel 4.7) beschrieben, wobei Prädilektionsstellen der prozedural- assoziierten mechanischen Beanspruchung der Stents durch die hier beschriebene, oberflächensensitive AFM- Methode sehr genau diskriminiert werden konnten. Die präparierten Stents wurden weiterführend mit humanen Thrombozytenkonzentraten inkubiert und die Zell- Stentoberflächenkontakte sowie mögliche Stentoberflächen- induzierte Veränderungen der Thrombozyten sind morphologisch ausführlich beschrieben worden. Letztendlich wurde im Rahmen der vorliegenden Arbeit die spezifische Aktivierung der vitalen Thrombozyten durch pharmakologische Stimulantien (z.B. ADP) mit der, durch den AFM-Abbildungsprozess induzierten Thrombozytenaktivierung (Kapitel 4.5) unter AFM-Bedingungen verglichen und diskutiert. Die Ergebnisse dieser Arbeit weisen, dass mit der AFM-Technologie und objektorientiert optimierten Mess- und Präparationsmethoden ein neues mikroskopisches Analyseverfahren vorliegt, dass zum einen real-dreidimensionale morphologische Bildgebung bis in den submolekularen Auflösungsbereich an vitalen Zellen und präparierten Proteinkomplexen, zum anderen aber gleichermaßen Funktionsanalytik in Form von Messungen zelldynamischer Prozesse wie Migrationsbewegungen und Kontraktionen sowie visko- elastische Quantifizierung von Zellmembranen erlaubt. Der Vorteil gegenüber den meisten gegenwärtig verfügbaren mikroskopischen Methoden liegt in der neu eröffneten Möglichkeit der seriellen, wiederholten und stabil reproduzierbaren Messung an vitalen Zellen und zellulären Substrukturen. Insofern könnte in Zukunft diese neue Technologie eine methodische Bereicherung der mikroskopisch-morphologisch und funktionell orientierten Analysetechnik darstellen. / In 1981 Binnig and Rohrer invented the "Scanning Tunneling Microscope". Thereby it became feasible to high-resolution record the surface-properties of specimens (up to atomic resolution) at the nearfield of inert surfaces. This and in detail the further development of this technology and the establishment of "Atomic Force Microscopy" (1986), that allows implementation of this resolution capabilities in non-conductors or insulating materials represent the birth of a new microscopic era in the field of biomedical basic research (chapter 1.3). The promise of atomic (scanning) force microscopy (AFM) for cardiovascular research is enormous. The perusal of the extensive literature concerning this topic and scientific contact with other researchers reveals initial the capabilities of this method in cardiovascular basic research. Intriguing questions of cardiology may investigate concomitantly with help of scanning-force-micoscopic approaches (chapter 1.4). The aim of this study was to investigate relevant cardiovascular cells and single proteins in-vivo and specific materials (coronary artery stents) with scanning-force-micoscopic setup. The establishment and expensive optimization of this new microscopic method (chapter 3.1) and of the cell specific preparatory methods (chapter 3.2) represented the center of interest of our inevestigations. The endothelial cells and H9C2-myocytes stem from established imortal cell culture lines. The adult cardiomyocytes and cardiomyocytes of neonatal rats, the fibrocytes and the thrombocytes were primarily cultivated (chapter 3.2.3 and 3.2.4). In addition we investigated aortic endothelial cells of intact aortic tissue of different animals (rat, guinea pig, rabbit - chapter 4.2). During the establish experiments cells underlied different methods of cell-fixation. The primary investigations was performed using air-dried cells (chapter 4.1.1) analyzed in room ambient conditions and were continued by different modifications of cell-preparation. (e.g. glutardialdehyde-fixation, cryo-fixation), of microscopic mode (contact-, non-contact-, tapping-mode) and of cell-specific environmental conditions (from room ambient to cellphysiological medium and temperature). As result we became enabled to investigate (reproducible and routinely) vital cells (chapter 4.1.2 and chapter 4.2 - 4.5) embedded in physiological normal structural und functional ambient conditions (e.g. endothelial cells of intact aortic tisue in-vivo). Additionally, we performed measurements of bio-elastic properties of stable or artificial stabilized structures of named cells (force-distances-curves - chapter 4.1.2.1). If posibble, depending of available technical equipment, we compared our microscopic results with other high-resolution analytical procedures of reference (e.g. TEM - Kapitel 4.1.2; 4.4.1; 4.6) and detected astonishing congruence between the data. Furthermore we analyzed the well-described (electron-microscopy and x-ray-diffraction data) complex 20-S-proteasome using a specific atomic force microscopic setup. Analytical and structural data of these AFM-scans and abovementioned methods were likened (chapter 4.6). The deviations concerning the detected proportions were discussed regarding functional integrity of the protein and with respect to potential methodically determined artifacts. (chapter 3.1.4.3). Assaying (qualitative and quantitative) the surface roughness properties of coronary artery stents, we found significant alterations of stent material induced by balloondilatation. We suppose, that changes in roughness of inner surface of coronary artery stents might induce clinical problems like acute stent-thrombosis and in-stent-restenosis. Finally these stents were coated with human thromboytes to investigate cell-stent-surface interactions. Surface-roughness correllated triggering of thrombocyte adhesion was evaluated by morphological analysis of AFM-scans. Finishing, we have investigated and concluding discussed the specific activation of vital thrombocytes by pharmacological substances (e.g. ADP) and by mechanical stimulation (due to AFM-associated tip-surface-interaction). The results of this work demonstrate, AFM-technology using optimized microscopic setup and object-specific adjusted measurement- and preparation- methods, is an new, powerful, microscopic technique, that allow real-3-dimensional morphological mapping up to submolecular range of resolution in vital cells and protein complexes. Moreover, this technology opens new dimensions in functional analytic of cell migration processes or cellular contractions and in evaluation of visco-elastic quantification of cell membranes. The advantage owed to the most currently available microscopic methods is the option of serial and reproducible measurement of vital cells and subcellular structures. In this respect, this new method might represent a methodical enrichment of the microscopic-morphological and functional oriented analysis-technique in future.

Endothelzellen

Stent

Rasterkraftmikroskopie

Rastersondenmikroskopie

AFM

in-vivo

kardiovaskuläre Zellen

Myozyten

Kardiomyozyten

Fibrozyten

Thrombozyten

aortale Endothelzellen

20S-Proteasom

endothelium

atomic force microscopy

scanning force microscopy

AFM

in-vivo

cardiovascular cells

myocyte

cardiomyocyte

fibrocyte

thrombocyte

aorta

20S-Proteasom

coronary stent

610 Medizin

33 Medizin

ddc:610

Einfluss der Calstabin2-Mutante FKBP12.6D37S in gesunden Mauskardiomyozyten und in einem transgenen Herzinsuffizienzmodell, das die Kalzium/Calmodulin-abhängige Proteinkinase IIδc überexprimiert / Influence of the calstabin2-mutante FKBPD37S in normal mice cardiomyocytes and in a transgenic heart failure modell overexpressing the calcium/calmodulin-kinase IIδc

Hellenkamp, Kristian

05 October 2011

No description available.

610 Medizin, Gesundheit

Medicine

44.85

MED 411: Kardiologie

In situ three-dimensional reconstruction of mouse heart sympathetic innervation by two-photon excitation fluorescence imaging

Freeman, Kim Renee

25 February 2014

Indiana University-Purdue University Indianapolis (IUPUI) / The sympathetic nervous system strongly modulates the contractile and electrical function of the heart. The anatomical underpinnings that enable a spatially and temporally coordinated dissemination of sympathetic signals within the cardiac tissue are only incompletely characterized. In this work we took the first step of unraveling the in situ 3D microarchitecture of the cardiac sympathetic nervous system. Using a combination of two-photon excitation fluorescence microscopy and computer-assisted image analyses, we reconstructed the sympathetic network in a portion of the left ventricular epicardium from adult transgenic mice expressing a fluorescent reporter protein in all peripheral sympathetic neurons. The reconstruction revealed several organizational principles of the local sympathetic tree that synergize to enable a coordinated and efficient signal transfer to the target tissue. First, synaptic boutons are aligned with high density along much of axon-cell contacts. Second, axon segments are oriented parallel to the main, i.e., longitudinal, axes of their apposed cardiomyocytes, optimizing the frequency of transmitter release sites per axon/per cardiomyocyte. Third, the local network was partitioned into branched and/or looped sub-trees which extended both radially and tangentially through the image volume. Fourth, sub-trees arrange to not much overlap, giving rise to multiple annexed innervation domains of variable complexity and configuration. The sympathetic network in the epicardial border zone of a chronic myocardial infarction was observed to undergo substantive remodeling, which included almost complete loss of fibers at depths >10 µm from the surface, spatially heterogeneous gain of axons, irregularly shaped synaptic boutons, and formation of axonal plexuses composed of nested loops of variable length. In conclusion, we provide, to the best of our knowledge, the first in situ 3D reconstruction of the local cardiac sympathetic network in normal and injured mammalian myocardium. Mapping the sympathetic network connectivity will aid in elucidating its role in sympathetic signal transmisson and processing.

Microscopy

Multi-photon

Two-Photon

TPLSM

Confocal

GFP

Sympathetic Nervous System

Cardiac

Neuron

Heart

Cardiomyocyte

Fluorescence microscopy -- Research

Multiphoton excitation microscopy

Confocal microscopy

Neurons

Cellular signal transduction

Muscle cells

Myocardial infarction -- Research

Myocardium

Heart -- Pathophysiology

Two-photon absorbing materials

Heart -- Imaging

Cardiovascular system -- Innervation

Neuromuscular transmission

Mice as laboratory animals -- Research

Funktionelle Untersuchungen von Ahnak durch Protein-Protein-Wechselwirkungen und in Ahnak-Defizienzmodellen

Petzhold, Daria

14 December 2007

Ahnak ist ein ubiquitäres Protein, das an einer Vielzahl biologischer Prozesse beteiligt ist. In der Herzmuskelzelle ist Ahnak überwiegend am Sarkolemma lokalisiert und bindet an Aktin und an die regulatorischen Beta2-Untereinheit des L-Typ-Kalzium-Kanals. Das Ziel dieser Arbeit war die Funktion von Ahnak im Herzen mit Hilfe eines Knock-out-Maus-Modells und in Bindungsstudien zu untersuchen. Morphologische Untersuchungen zeigten, dass das Längenwachstum adulter Kardiomyozyten bei Ahnakdefizienz signifikant reduziert war. Die Kontraktionseigenschaften adulter isolierter Ahnak-defizienter Kardio-myozyten (im Alter von 6 Monaten) waren ebenfalls verändert. Die Kontraktions- und Relaxaktionsgeschwindigkeiten waren erhöht. Eine Erhöhung des diastolischen Kalzium-Spiegels zeigten die Kardiomyozyten schon im Alter von 3 Monaten. Diese beobachteten phänotypischen Veränderungen lassen vermuten, dass die Aktivität des L-Typ-Kalzium-Kanals erhöht ist. In dieser Arbeit konnte das PXXP-Motiv, in der C-terminalen Ahnak-Domäne, als die hochaffine Beta2-Bindungsstelle (KD ~ 60 nM) identifiziert werden. Substitution von Prolin gegen Alanin verringerte zwar die Bindung zur Beta2-Untereinheit dramatisch (KD ~ 1 µM), hob sie aber nicht auf. In weiteren Bindungsstudien zeigte sich, dass die natürlich vorkommende Missensmutation I5236T die Bindung zur regulatorischen Beta2-Untereinheit verstärkte, dagegen verminderte die PKA-abhängige Phosphorylierung der beiden Proteinpartner die Bindung. Experimente am ganzen isoliert perfundierten Herzen zeigten, dass Ahnak-Knock-Out-Herzen geringer Beta-adrenerg stimulierbar waren. Ahnak scheint wie eine physiologische Bremse des kardialen Kalzium-Kanals zu wirken. / Ahnak is an ubiquitous protein with in unique structure, which has been implicated in cell type specific functions. In cardiomyocytes, ahnak is predominantly localized at the sarcolemma and is associated with actin and with the regulatory beta2 subunit of the L-type calcium-channel. The aim of this work was to unravel the function of ahnak in the heart, using a knock-out-mouse model and binding studies. Morphological studies showed a significant decrease in the cell-length of ahnak deficient cardiomyocytes. The contractile parameters of isolated adult ahnak deficient cardiomyocytes (in the age of 6 month) were altered. The development of tension and relaxation were increased. An increase of diastolic calcium was already observed at the age of 3 month. In general the observed phenotypic changes suggested an increased activity of the L-type calcium-channel. In this study, a PXXP-motif, which locates in ahnaks C-terminus, was identified as the high affinity beta2 subunit binding site (KD ~ 60 nM). Substitution of both proline residues by alanine reduced, but did not abolish the binding (KD ~ 1 µM). Further binding studies revealed that the natural occurring ahnak missense mutation I5236T increases the binding affinity to the regulatory beta2 subunit. By contrast PKA dependant phosphorylation of both protein partners decreases the interaction. In studies with isolated perfused working heart preparations, the ahnak deficient hearts were less beta-adrenergic stimulated than hearts from wild type. Taken together ahnak seems to be a physiological brake of the cardiac calcium-channel.

Ahnak

Ahnak-Knock-Out-Maus

Beta-adrenerge Stimulierung

Beta2 Untereinheit

Kalzium-Transient

elektromechanische Kopplung

Kardiomyozyten

L-Typ-Kalzium-Kanal

Missensmutationen

Proteinbindungen

PXXP-Motiv

PKA-abhängige Phosphorylierung

ahnak

ahnak-knock-out-mouse

beta-adrenergic stimulation

beta2 subunit

calcium-transient

excitation-contraction-coupling

cardiomyocyte

L-type-calcium-channel

missense mutation

protein binding

PXXP-motif

PKA-dependant phosphorylation

570 Biowissenschaften, Biologie

32 Biologie

WW 4120

WW 7700

ddc:570

Über die differentielle Regulation von Ionenkanälen in spezifischen Nanodomänen atrialer und ventrikulärer Kardiomyozyten / Differential Regulation of Ion Channels in Specific Nanodomains of Atrial and Ventricular Cardiomyocytes

Brandenburg, Sören

29 June 2017

No description available.

610

Kardiomyozyte

Atrium

Ventrikel

Axialer Tubulus

T-Tubulus

Transversal-axiales Tubulussystem

TATS

Ryanodinrezeptor

RyR2

Calciumkanal

Cav1.2

Proteinkinase A

PKA

Calcium/Calmodulin-abhängige Kinase II

CaMKII

Calciumfreisetzung

Calcium Sparks

hochphosphoryliert

Super-hub

beta-adrenerge Stimulation

Aortenstenose

TAC

ATP-sensitive Kaliumkanäle

KATP

Coatomer

COPI

14-3-3

Arg-basiertes Retentionssignal

Cardiomyocyte

Atrium

Ventricle

Axial tubule

T-tubule

TATS

Ryanodin receptor

RyR2

Calcium channel

Cav1.2

Protein kinase A

PKA

Calcium/calmodulin-dependent kinase II

Calcium release

Calcium sparks

highly-phosphorylated

Super-hub

Beta-adrenergic stimulation

Transverse-axial tubule system

Aortic stenosis

TAC

ATP-sensitive potassium channels

KATP

Coatomer

COPI

14-3-3

Arg-based retrieval signal

CaMKII

Medizin (PPN619874732)

Kardiologie (PPN619875755)

Physiologische Chemie

Biochemie

Physiologie