Garben Logghe scite author profile

Garben Logghe

2Publications

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122Citation Statements Given

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Research Institute for Nature and Forest, Ghent University

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Local TGF-beta sequestration by fibrillin-1 regulates vascular wall homeostasis in the thoracic aorta

Deleeuw

Impe

Logghe

et al. 2022

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Background Aortic dissection and rupture is the main cause of early cardiovascular mortality in patients with Marfan syndrome (MFS). MFS is caused by a defect in fibrillin-1, a building block of microfibrils in the extracellular matrix which binds transforming growth factor beta (TGF-beta) via interaction with latent TGF-beta binding proteins (LTBPs). Multiple mouse models, both pharmaceutically induced and genetically manipulated, have been used to investigate the pathophysiology and biomechanical aspects of thoracic aortic aneurysms and dissections. However, the role of TGF-beta in MFS has been controversial, with earlier studies suggesting that excess release of TGF-beta due to decreased interaction with dysfunctional fibrillin-1 leads to aortic dilation and vascular damage, while other studies have shown an important protective effect of TGF-beta. Studying dedicated mouse models for MFS, with defects interfering with TGF-beta binding and -function may help resolve these discrepancies. Purpose This study aimed to reveal insights in the role of TGF-beta signaling in aneurysm formation and dissection in MFS. Methods Mice lacking the fibrillin-1 binding site for LTBPs (Fbn1H1Δ/+ and Fbn1H1Δ/H1Δ), mice with a truncated fibrillin-1 (Fbn1GT-8/+), and mice with a combination of both alleles (Fbn1GT-8/ H1Δ) were subjected to in vivo cardiac ultrasound analysis. Ex vivo phase-contrast synchrotron X-ray imaging was performed at the Paul Scherrer Institute to visualize the elastic lamellae architecture in the vascular wall of the entire excised thoracic aorta in a subset of mice from each group. Results Fbn1GT-8/+, Fbn1 H1Δ/+ and Fbn1H1Δ/H1Δ mice had a normal life span, but Fbn1GT-8/ H1Δ mice showed increased mortality due to aortic rupture starting at 4–5 months of age. The aortic root was dilated both in Fbn1GT-8/+ and Fbn1GT-8/ H1Δ mice at 6 months of age, but not in Fbn1H1D/+ or Fbn1H1Δ/H1Δ mice. Synchrotron images showed significant elastic lamellae fragmentation in the thoracic aortic wall of Fbn1GT-8/+ mice, and to a larger extent in Fbn1GT-8/ H1Δ mice. Surprisingly, localized elastin fragmentation was also found in the ascending thoracic aorta of Fbn1 H1Δ/+ and Fbn1H1Δ/H1Δ mice, despite a lack of aortic aneurysm formation. Moreover, Fbn1H1Δ/H1Δ mice displayed more severe aortic wall damage. The localized microdissections found in these mouse models were characterized by a severe alteration of the elastic fiber organization, cellular influx and increased collagen deposition, as confirmed by histological analysis. Conclusions Our data suggest that loss of LTBP binding to fibrillin-1 leads to the development of localized microdissections in the aorta in the absence of aortic aneurysm, and exacerbates the aortic wall morphology abnormalities in mice with truncated fibrillin-1. We therefore hypothesize that local TGF-beta sequestration is required to maintain aortic homeostasis. Funding Acknowledgement Type of funding sources: Public grant(s) – National budget only. Main funding source(s): Foundation for Cardiac Surgery (“VZW Fonds voor Hartchirurgie”), grant No. 489644Baillet-Latour Grant for Medical Research

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Arthropod food webs predicted from body size ratios are improved by incorporating prey defensive properties

Walle

Logghe

Haas

et al. 2023

Journal of Animal Ecology

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Trophic interactions are often deduced from body size differences, assuming that predators prefer prey smaller than themselves because larger prey are more difficult to subdue. This has mainly been confirmed in aquatic ecosystems, but rarely in terrestrial ecosystems, especially in arthropods. Our goal was to validate whether body size ratios can predict trophic interactions in a terrestrial, plant‐associated arthropod community and whether predator hunting strategy and prey taxonomy could explain additional variation. We conducted feeding trials with arthropods from marram grass in coastal dunes to test whether two individuals, of the same or different species, would predate each other. From the trial results, we constructed one of the most complete, empirically derived food webs for terrestrial arthropods associated with a single plant species. We contrasted this empirical food web with a theoretical web based on body size ratios, activity period, microhabitat, and expert knowledge. In our feeding trials, predator–prey interactions were indeed largely size‐based. Moreover, the theoretical and empirically based food webs converged well for both predator and prey species. However, predator hunting strategy, and especially prey taxonomy improved predictions of predation. Well‐defended taxa, such as hard‐bodied beetles, were less frequently consumed than expected based on their body size. For instance, a beetle of average size (measuring 4 mm) is 38% less vulnerable than another average arthropod with the same length. Body size ratios predict trophic interactions among plant‐associated arthropods fairly well. However, traits such as hunting strategy and anti‐predator defences can explain why certain trophic interactions do not adhere to size‐based rules. Feeding trials can generate insights into multiple traits underlying real‐life trophic interactions among arthropods.

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Garben Logghe

Local TGF-beta sequestration by fibrillin-1 regulates vascular wall homeostasis in the thoracic aorta

Arthropod food webs predicted from body size ratios are improved by incorporating prey defensive properties

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