Összes szerző
Szabolcs Zoltán
az alábbi absztraktok szerzői között szerepel:
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Sulea Cristina
Fibrillin-1 microfibrils in Marfan syndrome: nanoscale structural characterization using atomic force microscopy -
Aug 29 - kedd
15:30 – 17:00
I. Poszterszekció
P27
Fibrillin-1 microfibrils in Marfan syndrome: nanoscale structural characterization using atomic force microscopy
Cristina M. Șulea1,2,3, Zsolt Mártonfalvi1, Csilla Csányi1, Dóra Haluszka1, Miklós Pólos2,3, Kálmán Benke2,3, Zoltán Szabolcs2,3 and Miklós S. Z. Kellermayer1
1 Department of Biophysics and Radiation Biology, Semmelweis University, 1094 Budapest, Hungary
2 Heart and Vascular Center, Semmelweis University, 1122 Budapest, Hungary
3 Hungarian Marfan Foundation, 1122 Budapest, Hungary
Fibrillin-1 microfibrils are essential elements of the extracellular matrix serving as a scaffold for the deposition of elastin and endowing connective tissues with tensile strength and elasticity. Mutations in the fibrillin-1 gene (FBN1) are linked to Marfan syndrome (MFS), a systemic connective tissue disorder that usually manifests in life-threatening aortic complications. The aortic involvement may be explained by a dysregulation in microfibrillar function and, conceivably, alterations in the microfibrils’ supramolecular structure.
The aim of the study was to perform a nanoscale structural characterization of fibrillin-1 microfibrils isolated from human aortic samples with different FBN1 gene mutations and to compare them with microfibrillar assemblies purified from non-MFS human aortic tissue.
Aortic wall samples were obtained from patients undergoing specific cardiovascular surgical interventions. Fibrillin-rich microfibrils were extracted by bacterial collagenase digestion and purified by size-exclusion chromatography. Atomic force microscopy was employed to visualize and study the microfibrillar assemblies.
Fibrillin-1 microfibrils displayed a characteristic “beads-on-a-string” appearance. The microfibrillar assemblies were investigated for bead geometry (height, length, and width), interbead region height, and periodicity. MFS fibrillin-1 microfibrils had a slightly higher mean bead height, but the bead length and width, as well as the interbead height, were significantly smaller in the MFS group. The mean periodicity varied around 50–52 nm among samples.
In conclusion, the data suggest an overall thinner and presumably more frail structure for the MFS fibrillin-1 microfibrils, which may play a role in the development of MFS-specific aortic symptomatology.
Acknowledgment
Funding sources: NRDI Office (ÚNKP-22-3-I-SE-49 to C.M.Ș.; K135360 to M.S.Z.K.; TKP2021-EGA-23), European Union (RRF-2.3.1-21-2022-00003 – National Cardiovascular Laboratory).
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Török György
Adaptive changes in the a-band region of the giant protein titin in diseased human cardiac sarcomere -
Aug 30 - szerda
15:30 – 17:00
II. Poszterszekció
P32
Adaptive changes in the A-band region of the giant protein titin in diseased human cardiac sarcomere
György Török1, Iliza Ramazanova1, Péter Dániel1, András Jámbor1, Dalma Kellermayer1,2, Cristina M. Șulea1,2, Zoltán Szabolcs2, Miklós S. Z. Kellermayer1 and Balázs Kiss1
1Department of Biophysics and Radiation Biology, Semmelweis University, Budapest, Hungary
2Heart and Vascular Center, Semmelweis University, Budapest, Hungary
Titin, the largest protein known, spans the half-sarcomere, the contractile unit of skeletal and cardiac muscle through its Z-disk to M-line and interacts with thin and thick filaments in the I- and A-band of the muscle sarcomere, respectively. Titin’s A-band segment is not well understood but is shown to be orders of magnitude less extensible than the I-band region of the molecule. Heterozygous truncating mutations (TTNtv) affecting A-band titin are often associated with dilated cardiomyopathy (DCM). Marfan syndrome (MFS), a connective tissue disorder caused by mutations of the matrix glycoprotein fibrillin is also associated with impaired cardiac contractility but its exact pathomechanism is largely unknown.
Here, we performed STED super-resolution microscopy on sections of stretched and fixed demembranated human cardiac myofibrils carrying heterozygous TTNtv mutations or on samples originated from MFS patients. Sequence-specific anti-titin antibodies included the 1) MIR, which labels titin at the ends of the thick filaments, 2) A170, labeling titin close to the M-line (this epitope is missing in TTNtv+). Sarcomere length-dependent anti-titin epitope position, shape and intensity analysis pointed at structural defects in the I/A junction and the M-band of TTNtv+ sarcomeres. Our experiments indicate that truncated titin is able to integrate into the cardiac sarcomere. We propose that the truncated titin cannot precisely register the ends of the thick filaments, and this can ultimately lead to the manifestation of DCM by disrupting the overlapping of thin and thick filaments. In MFS sarcomeres a pronounced, ~30 nm shift away from the M-line was found in the case of the A170 titin epitope suggesting that alterations in the M-band ultrastructure might be important contributors of the impaired cardiac contractility of MFS patients.