Actin/microtubule crosstalk during platelet biogenesis in mice is critically regulated by Twinfilin1 and Cofilin1

Rearrangements of the microtubule (MT) and actin cytoskeleton are pivotal for platelet biogenesis. Hence, defects in actin- or MT-regulatory proteins are associated with platelet disorders in humans and mice. Previous studies in mice revealed that loss of the actin-depolymerizing factor homology (ADF-H) protein Cofilin1 (Cof1) in megakaryocytes (MKs) results in a moderate macrothrombocytopenia but normal MK numbers, whereas deficiency in another ADF-H protein, Twinfilin1 (Twf1), does not affect platelet production or function. However, recent studies in yeast have indicated a critical synergism between Twf1 and Cof1 in the regulation of actin dynamics. We therefore investigated platelet biogenesis and function in mice lacking both Twf1 and Cof1 in the MK lineage. In contrast to single deficiency in either protein, Twf1/Cof1 double deficiency (DKO) resulted in a severe macrothrombocytopenia and dramatically increased MK numbers in bone marrow and spleen. DKO MKs exhibited defective proplatelet formation in vitro and in vivo as well as impaired spreading and altered assembly of podosome-like structures on collagen and fibrinogen in vitro. These defects were associated with aberrant F-actin accumulation and, remarkably, the formation of hyperstable MT, which appears to be caused by dysregulation of the actin- and MT-binding proteins mDia1 and adenomatous polyposis coli. Surprisingly, the mild functional defects described for Cof1-deficient platelets were only slightly aggravated in DKO platelets suggesting that both proteins are largely dispensable for platelet function in the peripheral blood. In summary, these findings reveal critical redundant functions of Cof1 and Twf1 in ensuring balanced actin/microtubule crosstalk during thrombopoiesis in mice and possibly humans.Peer reviewe

Thymosin β4 is essential for thrombus formation by controlling the G-actin/F-actin equilibrium in platelets

Coordinated rearrangements of the actin cytoskeleton are pivotal for platelet biogenesis from megakaryocytes but also orchestrate key functions of peripheral platelets in hemostasis and thrombosis, such as granule release, the formation of filopodia and lamellipodia, or clot retraction. Along with profilin (Pfn) 1, thymosin β4 (encoded by Tmsb4x) is one of the two main G-actin-sequestering proteins within cells of higher eukaryotes, and its intracellular concentration is particularly high in cells that rapidly respond to external signals by increased motility, such as platelets. Here, we analyzed constitutive Tmsb4x knockout (KO) mice to investigate the functional role of the protein in platelet production and function. Thymosin β4 deficiency resulted in a macrothrombocytopenia with only mildly increased platelet volume and an unaltered platelet life span. Megakaryocyte numbers in the bone marrow and spleen were unaltered, however, Tmsb4x KO megakaryocytes showed defective proplatelet formation in vitro and in vivo. Thymosin β4-deficient platelets displayed markedly decreased G-actin levels and concomitantly increased F-actin levels resulting in accelerated spreading on fibrinogen and clot retraction. Moreover, Tmsb4x KO platelets showed activation defects and an impaired immunoreceptor tyrosine-based activation motif (ITAM) signaling downstream of the activating collagen receptor glycoprotein VI. These defects translated into impaired aggregate formation under flow, protection from occlusive arterial thrombus formation in vivo and increased tail bleeding times. In summary, these findings point to a critical role of thymosin β4 for actin dynamics during platelet biogenesis, platelet activation downstream of glycoprotein VI and thrombus stability

Coactosin-like 1 integrates signaling critical for shear-dependent thrombus formation in mouse platelets

Platelet aggregate formation is a multistep process involving receptor-mediated, as well as biomechanical, signaling cascades, which are highly dependent on actin dynamics. We have previously shown that actin depolymerizing factor (ADF)/n-cofilin and Twinfilin 2a, members of the ADF homology (ADF-H) protein family, have distinct roles in platelet formation and function. Coactosin-like 1 (Cotl1) is another ADF-H protein that binds actin and was also shown to enhance biosynthesis of pro-inflammatory leukotrienes (LT) in granulocytes. Here, we generated mice lacking Cotl1 in the megakaryocyte lineage (Cotl1−/−) to investigate its role in platelet production and function. Absence of Cotl1 had no impact on platelet counts, platelet activation or cytoskeletal reorganization under static conditions in vitro. In contrast, Cotl1 deficiency markedly affected platelet aggregate formation on collagen and adhesion to immobilized von Willebrand factor at high shear rates in vitro, pointing to an impaired function of the platelet mechanoreceptor glycoprotein (GP) Ib. Furthermore, Cotl1−/−platelets exhibited increased deformability at high shear rates, indicating that the GPIb defect may be linked to altered biomechanical properties of the deficient cells. In addition, we found that Cotl1 deficiency markedly affected platelet LT biosynthesis. Strikingly, exogenous LT addition restored defective aggregate formation of Cotl1−/− platelets at high shear in vitro, indicating a critical role of platelet-derived LT in thrombus formation. In vivo, Cotl1 deficiency translated into prolonged tail bleeding times and protection from occlusive arterial thrombus formation. Together, our results show that Cotl1 in platelets is an integrator of biomechanical and LT signaling in hemostasis and thrombosis

Zur Rolle von Aktin-bindenden Proteinen in der Bildung und der Funktion von Thrombozyten in der Maus

Platelet activation and aggregation at sites of vascular injury involves massive cytoskeletal re-organization, which is required for proper platelet function. Moreover, the cytoskeleton plays central roles in megakaryo- and thrombopoiesis. Thus, cytoskeletal protein aberrations can be the underlying reason for many pathological phenotypes. Although intensive research is carried out to identify the key players involved in cytoskeletal reorganization, the signaling cascades orchestrating these complex processes are still poorly understood. This thesis investigates the role of three actin-binding proteins, Coactosin-like (Cotl) 1, Profilin (Pfn) 1 and Thymosin (T) β4, in platelet formation and function using genetically modified mice. ADF-H-containing proteins such as Twinfilin or Cofilin are well characterized as regulators of thrombopoesis and cytoskeletal reorganization. Although Cotl1 belongs to the ADF-H protein family, lack of Cotl1 did not affect platelet count or cytoskeletal dynamics. However, Cotl1-deficiency resulted in significant protection from arterial thrombus formation and ischemic stroke in vivo. Defective GPIb-vWF interactions and altered second wave mediator release present potential reasons for the beneficial effect of Cotl1-deficiency. These results reveal an unexpected function of Cotl1 as a regulator of thrombosis and hemostasis, establishing it as a potential target for a safe therapeutic therapy to prevent arterial thrombosis or ischemic stroke. Recent studies showed that the organization of the circumferential actin cytoskeleton modulates calpain-mediated αIIbβ3 integrin closure, thereby also controlling αIIbβ3 integrin localization. The second part of this thesis identified the actin-sequestering protein Pfn1 as a central regulator of platelet integrin function as Pfn1-deficient platelets displayed almost abolished αIIbβ3 integrin signaling. This translated into a profound protection from arterial thrombus formation and prolonged tail bleeding times in vivo which was caused by enhanced calpain-dependent integrin closure. These findings further emphasize the importance of a functional actin cytoskeleton for intact platelet function in vitro and in vivo. Tβ4 is a moonlighting protein, acting as one of the major actin-sequestering proteins in cells of higher eukaryotes and exerting various paracrine functions including anti-inflammatory, immunomodulatory and pro-angiogenic effects. Although excessively studied, its role for cytoskeletal dynamics, the distinction between endo- and exogenous protein function and its uptake and release mechanisms are still poorly understood. Constitutive Tβ4-deficiency resulted in thrombocytopenia accompanied by a largely diminished G-actin pool in platelets and divergent effects on platelet reactivity. Pre-incubation of platelets with recombinant Tβ4 will help to understand the function of endo- and exogenous protein, which is under current investigation.Die Aktivierung und Aggregation von Thrombozyten bei Gefäßverletzungen zieht massive Umstrukturierungen des Zytoskeletts nach sich, die eine Voraussetzung für die intakte Funktion der Zellen darstellen. Des Weiteren nimmt das Zytoskelett eine zentrale Rolle in der Megakaryo- und Thrombopoese ein. Daher können Anomalien zytoskeletaler Proteine eine Vielzahl von Krankheitsbildern verursachen. Obwohl intensiv an den beteiligten Proteinen geforscht wird, sind die Signalkaskaden, die den komplexen Vorgang der Umstrukturierung des Zytoskeletts steuern, noch weitgehend unbekannt. In dieser Dissertation wurden drei Aktin-bindende Proteine, Coactosin-like (Cotl) 1, Profilin (Pfn) 1 und Thymosin (T) β4, hinsichtlich ihrer Rolle für die Bildung und Funktion von Thrombozyten mittels genetisch veränderter Mäuse untersucht. Proteine wie Twinfilin oder Cofilin, die ADF-H-Domänen enthalten, sind oftmals an der Thrombopoese sowie an zytoskeletaler Umstrukturierung beteiligt. Obgleich Cotl1 der ADF-H Proteinfamilie zugehörig ist, konnte in Cotl1-defizienten Mäusen weder eine Veränderung der Thrombozytenzahlen, noch der zytoskeletalen Dynamik festgestellt werden. Unerwarteter-weise zog eine Cotl1-Defizienz in vivo einen Schutz vor arterieller Thrombose und Schlaganfall nach sich. Defekte GPIb-vWF-Interaktionen sowie eine veränderte Freisetzung von sekundären intrazellulären Mediatoren zeigen mögliche Gründe für den schützenden Effekt einer Cotl1-Defizienz auf. Diese Ergebnisse verdeutlichen, dass Cotl1 ein zentraler Regulator von Thrombose und Hämostase ist und etabliert es damit als potentielle antithrombotische Zielstruktur für eine effektive und sichere Behandlung von kardio- und zerebrovaskulären Erkrankungen. Studien zeigten, dass die Organisation des kortikalen Aktin-Zytoskeletts die Calpain-vermittelte αIIbβ3-Integrin-Inaktivierung moduliert und dadurch die Lokalisation der Integrine kontrolliert. Der zweite Teil dieser Dissertation identifizierte das Aktin-komplexierende Molekül Pfn1 als zentralen Regulator der Integrinfunktion in Thrombozyten, da Pfn1-defiziente Thrombozyten eine stark verminderte Reaktivität nach αIIbβ3-Integrin Aktivierung zeigten. Dies führte zu einem profunden Schutz vor arterieller Thrombusbildung und verlängerten Blutungszeiten in vivo, der durch eine verstärkte Calpain-vermittelte Integrin-Inaktivierung verursacht wurde. Diese Befunde unterstreichen erneut die zentrale Bedeutung eines funktionales Aktin-Zytoskeletts für die Aufrechterhaltung der Thrombozytenfunktion in vitro und in vivo. Tβ4 ist ein bivalentes Protein, das einerseits eine Funktion als Aktin-komplexierendes Protein in Zellen höherer Eukaryoten ausübt und andererseits unterschiedliche parakrine Funktionen hat, zu denen entzündungshemmende, immunmodulierende und pro-angiogene Wirkungen zählen. Obwohl intensiv an Tβ4 geforscht wird, ist seine Bedeutung für die Dynamik des Zytoskeletts sowie die Unterscheidung zwischen endo- und exogener Proteinfunktion und seine Aufnahme- und Freisetzungsmechanismen kaum verstanden. Konstitutive Tβ4-Defizienz zog eine Thrombozytopenie, begleitet von einem stark verminderten G-Aktin-Gehalt in Thrombozyten und gegensätzlichen Effekten auf die Thrombozytenreaktivität, nach sich. Der Effekt von rekombinant exprimiertem Tβ4 auf Thrombozyten, der derzeit untersucht wird, wird zum besseren Verständnis der endo- und exogenen Proteinfunktion, beitragen

Carbon Sequestration in the New Jersey Pine Barrens Under Different Scenarios of Fire Management

The New Jersey Pine Barrens (NJPB) is the largest forested area along the northeastern coast of the United States. The NJPB are dominated by pine (Pinus spp.) and oak (Quercus spp.) stands that are fragmented and subject to frequent disturbance and forest management. Over long time periods (\u3e50 years), the balance between oak and pine dominance is determined by fire frequency. As a consequence, the ability of the NJPB to sequester carbon may be contingent upon management activities as well as patterns of historic land use. We simulated 100 years of carbon change using three scenarios: (1) contemporary management as reflected in the recent (1991–2006) fire records, (2) an increase in the fire ignitions within the wildland urban interface areas of the NJPB reflecting increased prescribed fires, and (3) a longer response time to wildfires, reflecting a more liberal burning policy by the New Jersey Forest Fire Service. We used the LANDIS-II model coupled with CENTURY and the Dynamic Fire and Dynamic Biomass Fuels extensions to estimate forest carbon sequestration based on these three scenarios. Calibration and validation via comparison to monthly flux tower data indicated that the model reasonably captured the timing and magnitude of net ecosystem exchange in the absence of Gypsy moth defoliation (r2 = 0.89). Under all scenarios, our simulations suggest that forests of the NJPB will continue to accumulate carbon over the next 100 years under current climatic conditions. Although above ground net primary productivity, live carbon, and detrital carbon were roughly constant or increased only modestly, soil organic carbon continued to increase through time for all forest types except the highly xeric pine plains. Our simulated changes in management reflected only minor alterations to the fire regime and thus management may have only minor effects on total forest carbon budgets in the immediate future particularly when compared to recovery from historic disturbance patterns

Generation of transgenic wheat (Triticum aestivum L.) accumulating heterologous endo-xylanase or ferulic acid esterase in the endosperm

Endo-xylanase (from Bacillus subtilis) or ferulic acid esterase (from Aspergillus niger) were expressed in wheat under the control of the endosperm specific 1DX5 glutenin promoter. Constructs both with and without the endoplasmic reticulum retention signal KDEL were used. Transgenic plants were recovered in all four cases but no qualitative differences could be observed whether KDEL was added or not. Endo-xylanase activity in transgenic grains was increased between two and three fold relative to wild type. The grains were shriveled and had a 25-33% decrease in mass. Extensive analysis of the cell walls showed a 10-15% increase in arabinose to xylose ratio, a 50% increase in the proportion of water extractable arabinoxylan, and a shift in the MW of the water extractable arabinoxylan from being mainly larger than 85 kD to being between 2 kD and 85 kD. Ferulic acid esterase expressing grains were also shriveled and the seed weight was decreased by 20-50%. No ferulic acid esterase activity could be detected in wild type grains whereas ferulic acid esterase activity was detected in transgenic lines. The grain cell walls had 15-40% increase in water unextractable arabinoxylan and a decrease in monomeric ferulic acid between 13 and 34%. In all the plants the observed changes are consistent with a plant response that serves to minimize the effect of the heterologously expressed enzymes by increasing arabinoxylan biosynthesis and cross-linking