TY  - JOUR
A1  - Dieterich, Peter
A1  - Lindemann, Otto
A1  - Moskopp, Mats Leif
A1  - Tauzin, Sebastien
A1  - Huttenlocher, Anna
A1  - Klages, Rainer
A1  - Chechkin, Aleksei V.
A1  - Schwab, Albrecht
T1  - Anomalous diffusion and asymmetric tempering memory in neutrophil chemotaxis
JF  - PLoS Computational Biology : a new community journal
N2  - Neutrophil granulocytes are essential for the first host defense. After leaving the blood circulation they migrate efficiently towards sites of inflammation. They are guided by chemoattractants released from cells within the inflammatory foci. On a cellular level, directional migration is a consequence of cellular front-rear asymmetry which is induced by the concentration gradient of the chemoattractants. The generation and maintenance of this asymmetry, however, is not yet fully understood. Here we analyzed the paths of chemotacting neutrophils with different stochastic models to gain further insight into the underlying mechanisms. Wildtype chemotacting neutrophils show an anomalous superdiffusive behavior. CXCR2 blockade and TRPC6-knockout cause the tempering of temporal correlations and a reduction of chemotaxis. Importantly, such tempering is found both in vitro and in vivo. These findings indicate that the maintenance of anomalous dynamics is crucial for chemotactic behavior and the search efficiency of neutrophils. 
The motility of neutrophils and their ability to sense and to react to chemoattractants in their environment are of central importance for the innate immunity. Neutrophils are guided towards sites of inflammation following the activation of G-protein coupled chemoattractant receptors such as CXCR2 whose signaling strongly depends on the activity of Ca2+ permeable TRPC6 channels. It is the aim of this study to analyze data sets obtained in vitro (murine neutrophils) and in vivo (zebrafish neutrophils) with a stochastic mathematical model to gain deeper insight into the underlying mechanisms. The model is based on the analysis of trajectories of individual neutrophils. Bayesian data analysis, including the covariances of positions for fractional Brownian motion as well as for exponentially and power-law tempered model variants, allows the estimation of parameters and model selection. Our model-based analysis reveals that wildtype neutrophils show pure superdiffusive fractional Brownian motion. This so-called anomalous dynamics is characterized by temporal long-range correlations for the movement into the direction of the chemotactic CXCL1 gradient. Pure superdiffusion is absent vertically to this gradient. This points to an asymmetric 'memory' of the migratory machinery, which is found both in vitro and in vivo. CXCR2 blockade and TRPC6-knockout cause tempering of temporal correlations in the chemotactic gradient. This can be interpreted as a progressive loss of memory, which leads to a marked reduction of chemotaxis and search efficiency of neutrophils. In summary, our findings indicate that spatially differential regulation of anomalous dynamics appears to play a central role in guiding efficient chemotactic behavior.
KW  - neutrophils
KW  - chemotaxis
KW  - autocorrelation
KW  - zebrafish
KW  - cell migration
KW  - covariance
KW  - brownian motion
KW  - stochastic processes
Y1  - 2022
U6  - https://doi.org/10.1371/journal.pcbi.1010089
SN  - 1553-734X
SN  - 1553-7358
VL  - 18
IS  - 5
PB  - PLoS
CY  - San Fransisco
ER  - 
TY  - JOUR
A1  - Bornhorst, Dorothee
A1  - Abdelilah-Seyfried, Salim
T1  - Strong as a Hippo’s Heart: Biomechanical Hippo Signaling During Zebrafish Cardiac Development
JF  - Frontiers in Cell and Developmental Biology
N2  - The heart is comprised of multiple tissues that contribute to its physiological functions. During development, the growth of myocardium and endocardium is coupled and morphogenetic processes within these separate tissue layers are integrated. Here, we discuss the roles of mechanosensitive Hippo signaling in growth and morphogenesis of the zebrafish heart. Hippo signaling is involved in defining numbers of cardiac progenitor cells derived from the secondary heart field, in restricting the growth of the epicardium, and in guiding trabeculation and outflow tract formation. Recent work also shows that myocardial chamber dimensions serve as a blueprint for Hippo signaling-dependent growth of the endocardium. Evidently, Hippo pathway components act at the crossroads of various signaling pathways involved in embryonic zebrafish heart development. Elucidating how biomechanical Hippo signaling guides heart morphogenesis has direct implications for our understanding of cardiac physiology and pathophysiology.
KW  - Hippo signaling
KW  - Yap1/Wwtr1 (Taz)
KW  - cardiac development
KW  - mechanobiology
KW  - endocardium
KW  - myocardium
KW  - zebrafish
KW  - intra-organ-communication
Y1  - 2021
U6  - https://doi.org/10.3389/fcell.2021.731101
SN  - 2296-634X
VL  - 9
SP  - 1
EP  - 10
PB  - Frontiers Media
CY  - Lausanne, Schweiz
ER  - 
TY  - GEN
A1  - Bornhorst, Dorothee
A1  - Abdelilah-Seyfried, Salim
T1  - Strong as a Hippo’s Heart: Biomechanical Hippo Signaling During Zebrafish Cardiac Development
T2  - Zweitveröffentlichungen der Universität Potsdam : Mathematisch-Naturwissenschaftliche Reihe
N2  - The heart is comprised of multiple tissues that contribute to its physiological functions. During development, the growth of myocardium and endocardium is coupled and morphogenetic processes within these separate tissue layers are integrated. Here, we discuss the roles of mechanosensitive Hippo signaling in growth and morphogenesis of the zebrafish heart. Hippo signaling is involved in defining numbers of cardiac progenitor cells derived from the secondary heart field, in restricting the growth of the epicardium, and in guiding trabeculation and outflow tract formation. Recent work also shows that myocardial chamber dimensions serve as a blueprint for Hippo signaling-dependent growth of the endocardium. Evidently, Hippo pathway components act at the crossroads of various signaling pathways involved in embryonic zebrafish heart development. Elucidating how biomechanical Hippo signaling guides heart morphogenesis has direct implications for our understanding of cardiac physiology and pathophysiology.
T3  - Zweitveröffentlichungen der Universität Potsdam : Mathematisch-Naturwissenschaftliche Reihe - 1236 
KW  - Hippo signaling
KW  - Yap1/Wwtr1 (Taz)
KW  - cardiac development
KW  - mechanobiology
KW  - endocardium
KW  - myocardium
KW  - zebrafish
KW  - intra-organ-communication
Y1  - 2022
U6  - http://nbn-resolving.de/urn/resolver.pl?urn:nbn:de:kobv:517-opus4-548731
SN  - 1866-8372
SP  - 1
EP  - 10
PB  - Universitätsverlag Potsdam
CY  - Potsdam
ER  - 
TY  - THES
A1  - Fontana, Federica
T1  - Antagonistic activities of Vegfr3/Flt4 and Notch1b fine-tune mechanosensitive signaling during zebrafish cardiac valvulogenesis
N2  - Cardiac valves are essential for the continuous and unidirectional flow of blood throughout the body. During embryonic development, their formation is strictly connected to the mechanical forces exerted by blood flow. The endocardium that lines the interior of the heart is a specialized endothelial tissue and is highly sensitive to fluid shear stress. Endocardial cells harbor a signal transduction machinery required for the translation of these forces into biochemical signaling, which strongly impacts cardiac morphogenesis and physiology. To date, we lack a solid understanding on the mechanisms by which endocardial cells sense the dynamic mechanical stimuli and how they trigger different cellular responses. In the zebrafish embryo, endocardial cells at the atrioventricular canal respond to blood flow by rearranging from a monolayer to a double-layer, composed of a luminal cell population subjected to blood flow and an abluminal one that is not exposed to it. These early morphological changes lead to the formation of an immature valve leaflet. While previous studies mainly focused on genes that are positively regulated by shear stress, the mechanisms regulating cell behaviors and fates in cells that lack the stimulus of blood flow are largely unknown. One key discovery of my work is that the flow-sensitive Notch receptor and Krüppel-like factor (Klf) 2, one of the best characterized flow-regulated transcriptional factors, are activated by shear stress but that they function in two parallel signal transduction pathways. Each of these two pathways is essential for the rearrangement of atrioventricular cells into an immature double-layered valve leaflets. A second key discovery of my study is the finding that both Notch and Klf2 signaling negatively regulate the expression of the angiogenesis receptor Vegfr3/Flt4, which becomes restricted to abluminal endocardial cells of the valve leaflet. Within these cells, Flt4 downregulates the expressions of the cell adhesion proteins Alcam and VE-cadherin. A loss of Flt4 causes abluminal endocardial cells to ectopically express Notch, which is normally restricted to luminal cells, and impairs valve morphology. My study suggests that abluminal endocardial cells that do not experience mechanical stimuli loose Notch expression and this triggers expression of Flt4. In turn, Flt4 negatively regulates Notch on the abluminal side of the valve leaflet. These antagonistic signaling activities and fine-tuned gene regulatory mechanisms ultimately shape cardiac valve leaflets by inducing unique differences in the fates of endocardial cells.
N2  - Herzklappen sind essentiell für den kontinuierlichen und gerichteten Blutfluss durch den Körper. Während der Embryonalentwicklung ist die Bildung der Herzklappen stark von vom Blutfluss generierten, mechanischen Kräften abhängig. Das Endokard, ein endotheliales Gewebe, das das Herz im Inneren auskleidet, reagiert sehr sensibel auf biomechanische Einwirkungen. Endokardzellen weisen eine Signaltransduktionsmaschinerie auf, welche die Umwandlung dieser Kräfte in biochemische und elektrische Signale ermöglicht und somit unverzichtbar für die Herzmorphogenese und -physiologie ist. Allerdings fehlt uns noch immer das Verständnis der Mechanismen, mit denen Endokardzellen dynamische, biomechanische Signale wahrnehmen und wie verschiedene zelluläre Antworten ausgelöst werden können. Im Zebrafischembryo reagieren Endokardzellen im atrioventrikulärem Kanal
auf Blutfluss induzierte Schubspannung mit einer Umorganisation, wobei sich aus einer Einzelschicht an Zellen eine Doppelschicht bildet. Letztere besteht aus einer luminalen Zellpopulation, die dem Blutstrom ausgesetzt ist und einer abluminalen Population, der der Kontakt zum Blut fehlt. Diese initialen morphologischen Veränderungen führen zur Ausbildung des frühen Herzklappensegels. Bisherige Studien berichteten im Besonderen über Gene die positiv von einer veränderten Schubspannung in Endokardzellen reguliert werden. Allerdings sind die Mechanismen, die das Verhalten und die Spezifizierung von den Zellen regulieren, die nicht in Kontakt mit dem Blutfluss sind, weitgehend unbekannt. Eine meiner Schlüsselentdeckungen in dieser Arbeit ist, dass zwei der am besten charakterisierten, durch Blutfluss transkriptional regulierten Faktoren, der Notch Rezeptor und der Krüppel-like factor (Klf) 2, durch Schubspannung aktiviert werden. Dies funktioniert auf zwei parallelen mechanosensitiven Signaltransduktionswegen und beide Kaskaden sind essentiell für die Umorganisation der atrioventrikulären Zellen während der Bildung der frühen zweischichtigen Klappensegeln. Eine zweite wichtige Entdeckung meiner Studien ist, dass die Expression des angiogenen Faktors Vegfr3/Flt4, die auf abluminale Endokardzellen im frühen Klappensegel beschränk ist, von beiden Signalwegen, Notch und KLf2, negativ reguliert wird. Außerdem veringert Flt4 die Expression der Zelladhäsionsproteine Alcam und VE-cadherin in abluminalen Zellen und führt die Herzklappenmorphogenese herbei. Der Verlust von Flt4 wiederum führt zu einer ektopischen Expression von Notch in abluminalen Endokardzellen, welche sonst nur in luminalen Zellen auftritt. Daher zeigt meine Arbeit, dass abluminale Endokardzellen, die keinem mechanischem Reiz ausgesetzt sind, Notch herunterregulieren und damit die Expression von Flt4 auslösen. Flt4 wiederum blockiert dann zusätzlich den Notch Signalweg in dieser Zellpopulation. Diese antagonistischen Signalaktivitäten und fein abgestimmte Genregulationsmechanismen sorgen für Unterschiede in der Spezifizierung der Endokardzellen und formen so schließlich die Segelklappen im Herz.
KW  - heart development
KW  - cardiac valves
KW  - zebrafish
KW  - mechanosensation
KW  - Herzklappe
KW  - Herzentwicklung
KW  - Mechanosensation
KW  - Zebrafisch
Y1  - 2020
U6  - http://nbn-resolving.de/urn/resolver.pl?urn:nbn:de:kobv:517-opus4-487517
ER  - 
TY  - JOUR
A1  - Rödel, Claudia Jasmin
A1  - Otten, Cecile
A1  - Donat, Stefan
A1  - Lourenço, Marta Sofia Rocha
A1  - Fischer, Dorothea
A1  - Kuropka, Benno
A1  - Paolini, Alessio
A1  - Freund, Christian
A1  - Abdelilah-Seyfried, Salim
T1  - Blood Flow Suppresses Vascular Anomalies in a Zebrafish Model of Cerebral Cavernous Malformations
JF  - Circulation Research
N2  - RATIONALE: Pathological biomechanical signaling induces vascular anomalies including cerebral cavernous malformations (CCM), which are caused by a clonal loss of CCM1/KRIT1 (Krev interaction trapped protein 1), CCM2/MGC4607, or CCM3/PDCD10. Why patients typically experience lesions only in lowly perfused venous capillaries of the cerebrovasculature is completely unknown. OBJECTIVE: In contrast, animal models with a complete loss of CCM proteins lack a functional heart and blood flow and exhibit vascular anomalies within major blood vessels as well. This finding raises the possibility that hemodynamics may play a role in the context of this vascular pathology. METHODS AND RESULTS: Here, we used a genetic approach to restore cardiac function and blood flow in a zebrafish model of CCM1. We find that blood flow prevents cardiovascular anomalies including a hyperplastic expansion within a large Ccm1-deficient vascular bed, the lateral dorsal aorta. CONCLUSIONS: This study identifies blood flow as an important physiological factor that is protective in the cause of this devastating vascular pathology.
KW  - animal models
KW  - cerebral cavernous malformations
KW  - endothelial cell
KW  - hemodynamics
KW  - zebrafish
Y1  - 2019
U6  - https://doi.org/10.1161/CIRCRESAHA.119.315076
SN  - 0009-7330
SN  - 1524-4571
VL  - 125
IS  - 10
SP  - E43
EP  - E54
PB  - Lippincott Williams & Wilkins
CY  - Philadelphia
ER  - 
TY  - JOUR
A1  - Lombardo, Veronica A.
A1  - Otten, Cecile
A1  - Abdelilah-Seyfried, Salim
T1  - Large-scale Zebrafish Embryonic Heart Dissection for Transcriptional Analysis
JF  - Journal of visualized experiments
N2  - The zebrafish embryonic heart is composed of only a few hundred cells, representing only a small fraction of the entire embryo. Therefore, to prevent the cardiac transcriptome from being masked by the global embryonic transcriptome, it is necessary to collect sufficient numbers of hearts for further analyses. Furthermore, as zebrafish cardiac development proceeds rapidly, heart collection and RNA extraction methods need to be quick in order to ensure homogeneity of the samples. Here, we present a rapid manual dissection protocol for collecting functional/beating hearts from zebrafish embryos. This is an essential prerequisite for subsequent cardiac-specific RNA extraction to determine cardiac-specific gene expression levels by transcriptome analyses, such as quantitative real-time polymerase chain reaction (RT-qPCR). The method is based on differential adhesive properties of the zebrafish embryonic heart compared with other tissues; this allows for the rapid physical separation of cardiac from extracardiac tissue by a combination of fluidic shear force disruption, stepwise filtration and manual collection of transgenic fluorescently labeled hearts.
KW  - Developmental Biology
KW  - Issue 95
KW  - zebrafish
KW  - embryo
KW  - heart
KW  - dissection
KW  - RNA
KW  - RT-qPCR
Y1  - 2015
U6  - https://doi.org/10.3791/52087
SN  - 1940-087X
IS  - 95
PB  - JoVE
CY  - Cambridge
ER  -