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1. Impact of sub-acute acrolein inhalation on the molecular regulation of mitochondrial metabolism in rat lung

Author

Tulen, C.B.M., Leermakers, P.A., Schrieder, S.E., van Schooten, F.J., Opperhuizen, A., Remels, A.H.V., Farmacologie en Toxicologie, and RS: NUTRIM - R3 - Respiratory & Age-related Health

Subjects
Inflammation, LABORATORY-ANIMALS, STRESS, Chronic obstructive pulmonary disease, Respiratory toxicity, General Medicine, Toxicology, TOXICITY, MECHANISMS, RELEVANCE, Mitochondrial metabolism, SENESCENCE, MITOPHAGY, EXPOSURE, Acrolein, RESPONSES
Abstract

Nowadays, mitochondria are recognized as key players in the pathogenesis of a variety of smoking-associated lung diseases. Acrolein, a component of cigarette smoke, is a known driver of biological mechanisms underly-ing smoking-induced respiratory toxicity. The impact of sub-acute acrolein inhalation in vivo on key processes controlling mitochondrial homeostasis in cells of the airways however is unknown. In this study, we investigated the activity/abundance of a myriad of molecules critically involved in mitochondrial metabolic pathways and mitochondrial quality control processes (mitochondrial biogenesis and mitophagy) in the lungs of Sprague-Dawley rats that were sub-acutely exposed to filtered air or 3 ppm acrolein by whole-body inhalation (5 h/ day, 5 days/week for 4 weeks). Acrolein exposure induced a general inflammatory response in the lung as gene expression analysis revealed an increased expression of Icam1 and Cinc1 (p < 0.1; p < 0.05). Acrolein signifi-cantly decreased enzyme activity of hydroxyacyl-Coenzyme A dehydrogenase (p < 0.01), and decreased Pdk4 transcript levels (p < 0.05), suggestive of acrolein-induced changes in metabolic processes. Investigation of constituents of the mitochondrial biogenesis pathways and mitophagy machinery revealed no pronounced al-terations. In conclusion, sub-acute inhalation of acrolein did not affect the regulation of mitochondrial meta-bolism and quality control, which is in contrast to more profound changes after acute exposure in other studies.

Published
2023
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2. Butyrate reduces cellular magnesium absorption independently of metabolic regulation in Caco-2 human colon cells

Author

Gommers, L.M.M., Leermakers, P.A., Wijst, J.A.J. van der, Roig, S.R., Adella, A., Wal, M.A.E. van de, Bindels, R.J.M., Baaij, J.H.F. de, Hoenderop, J.G.J., Gommers, L.M.M., Leermakers, P.A., Wijst, J.A.J. van der, Roig, S.R., Adella, A., Wal, M.A.E. van de, Bindels, R.J.M., Baaij, J.H.F. de, and Hoenderop, J.G.J.

Abstract

Contains fulltext : 285278.pdf (Publisher’s version ) (Open Access)

Published
2022

4. Placental Mitochondrial Abnormalities in Preeclampsia.

Author

Vangrieken, P., Al-Nasiry, S., Bast, A., Leermakers, P.A., Tulen, C.B.M., Schiffers, P.M.H., Schooten, F.J. van, Remels, A.H.V., Vangrieken, P., Al-Nasiry, S., Bast, A., Leermakers, P.A., Tulen, C.B.M., Schiffers, P.M.H., Schooten, F.J. van, and Remels, A.H.V.

Abstract

01 augustus 2021, Item does not contain fulltext, Preeclampsia complicates 5-8% of all pregnancies worldwide, and although its pathophysiology remains obscure, placental oxidative stress and mitochondrial abnormalities are considered to play a key role. Mitochondrial abnormalities in preeclamptic placentae have been described, but the extent to which mitochondrial content and the molecular pathways controlling this (mitochondrial biogenesis and mitophagy) are affected in preeclamptic placentae is unknown. Therefore, in preeclamptic (n = 12) and control (n = 11) placentae, we comprehensively assessed multiple indices of placental antioxidant status, mitochondrial content, mitochondrial biogenesis, mitophagy, and mitochondrial fusion and fission. In addition, we also explored gene expression profiles related to inflammation and apoptosis. Preeclamptic placentae were characterized by higher levels of oxidized glutathione, a higher total antioxidant capacity, and higher mRNA levels of the mitochondrial-located antioxidant enzyme manganese-dependent superoxide dismutase 2 compared to controls. Furthermore, mitochondrial content was significantly lower in preeclamptic placentae, which was accompanied by an increased abundance of key constituents of glycolysis. Moreover, mRNA and protein levels of key molecules involved in the regulation of mitochondrial biogenesis were lower in preeclamptic placentae, while the abundance of constituents of the mitophagy, autophagy, and mitochondrial fission machinery was higher compared to controls. In addition, we found evidence for activation of apoptosis and inflammation in preeclamptic placentae. This study is the first to comprehensively demonstrate abnormalities at the level of the mitochondrion and the molecular pathways controlling mitochondrial content/function in preeclamptic placentae. These aberrations may well contribute to the pathophysiology of preeclampsia by upregulating placental inflammation, oxidative stress, and apoptosis. Graphical Abstract.

Published
2021

5. Hypoxia-induced mitochondrial abnormalities in cells of the placenta.

Author

Vangrieken, P., Al-Nasiry, S., Bast, A., Leermakers, P.A., Tulen, C.B.M., Janssen, G.M.C., Kaminski, I., Geomini, I., Lemmens, T., Schiffers, P.M.H., Schooten, F.J. van, Remels, A.H.V., Vangrieken, P., Al-Nasiry, S., Bast, A., Leermakers, P.A., Tulen, C.B.M., Janssen, G.M.C., Kaminski, I., Geomini, I., Lemmens, T., Schiffers, P.M.H., Schooten, F.J. van, and Remels, A.H.V.

Abstract

Contains fulltext : 238786.pdf (Publisher’s version ) (Open Access), INTRODUCTION: Impaired utero-placental perfusion is a well-known feature of early preeclampsia and is associated with placental hypoxia and oxidative stress. Although aberrations at the level of the mitochondrion have been implicated in PE pathophysiology, whether or not hypoxia-induced mitochondrial abnormalities contribute to placental oxidative stress is unknown. METHODS: We explored whether abnormalities in mitochondrial metabolism contribute to hypoxia-induced placental oxidative stress by using both healthy term placentae as well as a trophoblast cell line (BeWo cells) exposed to hypoxia. Furthermore, we explored the therapeutic potential of the antioxidants MitoQ and quercetin in preventing hypoxia-induced placental oxidative stress. RESULTS: Both in placental explants as well as BeWo cells, hypoxia resulted in reductions in mitochondrial content, decreased abundance of key molecules involved in the electron transport chain and increased expression and activity of glycolytic enzymes. Furthermore, expression levels of key regulators of mitochondrial biogenesis were decreased while the abundance of constituents of the mitophagy, autophagy and mitochondrial fission machinery was increased in response to hypoxia. In addition, placental hypoxia was associated with increased oxidative stress, inflammation, and apoptosis. Moreover, experiments with MitoQ revealed that hypoxia-induced reactive oxygen species originated from the mitochondria in the trophoblasts. DISCUSSION: This study is the first to demonstrate that placental hypoxia is associated with mitochondrial-generated reactive oxygen species and significant alterations in the molecular pathways controlling mitochondrial content and function. Furthermore, our data indicate that targeting mitochondrial oxidative stress may have therapeutic benefit in the management of pathologies related to placental hypoxia.

Published
2021

7. Pulmonary inflammation-induced alterations in key regulators of mitophagy and mitochondrial biogenesis in murine skeletal muscle.

Author

Leermakers, P.A., Remels, A.H.V., Langen, R.C.J., Schols, A.M., Gosker, H.R., Leermakers, P.A., Remels, A.H.V., Langen, R.C.J., Schols, A.M., and Gosker, H.R.

Abstract

Contains fulltext : 225996.pdf (publisher's version ) (Open Access), BACKGROUND: Both mitophagy, a selective mechanism for clearance of mitochondria, and mitochondrial biogenesis are key processes determining mitochondrial content and oxidative capacity of the musculature. Abnormalities in these processes could therefore contribute to deterioration of peripheral muscle oxidative capacity as observed in e.g. chronic obstructive pulmonary disease. Although it has been suggested that inflammatory mediators can modulate both mitophagy and mitochondrial biogenesis, it is unknown whether acute pulmonary inflammation affects these processes in oxidative and glycolytic skeletal muscle in vivo. Therefore, we hypothesised that molecular signalling patterns of mitochondrial breakdown and biogenesis temporally shift towards increased breakdown and decreased biogenesis in the skeletal muscle of mice exposed to one single bolus of IT-LPS, as a model for acute lung injury and pulmonary inflammation. METHODS: We investigated multiple important constituents and molecular regulators of mitochondrial breakdown, biogenesis, dynamics, and mitochondrial content in skeletal muscle over time in a murine (FVB/N background) model of acute pulmonary- and systemic inflammation induced by a single bolus of intra-tracheally (IT)-instilled lipopolysaccharide (LPS). Moreover, we compared the expression of these constituents between gastrocnemius and soleus muscle. RESULTS: Both in soleus and gastrocnemius muscle, IT-LPS instillation resulted in molecular patterns indicative of activation of mitophagy. This coincided with modulation of mRNA transcript abundance of genes involved in mitochondrial fusion and fission as well as an initial decrease and subsequent recovery of transcript levels of key proteins involved in the molecular regulation of mitochondrial biogenesis. Moreover, no solid differences in markers for mitochondrial content were found. CONCLUSIONS: These data suggest that one bolus of IT-LPS results in a temporal modulation of mitochondrial clearance and

Published
2020

8. Iron deficiency-induced loss of skeletal muscle mitochondrial proteins and respiratory capacity; the role of mitophagy and secretion of mitochondria-containing vesicles.

Author

Leermakers, P.A., Remels, A.H.V., Zonneveld, M.I., Rouschop, K.M., Schols, A.M., Gosker, H.R., Leermakers, P.A., Remels, A.H.V., Zonneveld, M.I., Rouschop, K.M., Schols, A.M., and Gosker, H.R.

Abstract

Contains fulltext : 225972.pdf (Publisher’s version ) (Open Access), Iron homeostasis is essential for mitochondrial function, and iron deficiency has been associated with skeletal muscle weakness and decreased exercise capacity in patients with different chronic disorders. We hypothesized that iron deficiency-induced loss of skeletal muscle mitochondria is caused by increased mitochondrial clearance. To study this, C2C12 myotubes were subjected to the iron chelator deferiprone. Mitochondrial parameters and key constituents of mitophagy pathways were studied in presence or absence of pharmacological autophagy inhibition or knockdown of mitophagy-related proteins. Furthermore, it was explored if mitochondria were present in extracellular vesicles (EV). Iron chelation resulted in an increase in BCL2/Adenovirus E1B 19 kDa protein-interacting protein 3 (BNIP3) and BNIP3-like gene and protein levels, and the appearance of mitochondria encapsulated by lysosome-like vesicular structures in myotubes. Moreover, mitochondria were secreted via EV. These changes were associated with cellular mitochondrial impairments. These impairments were unaltered by autophagy inhibition, knockdown of mitophagy-related proteins BNIP3 and BNIP3L, or knockdown of their upstream regulator hypoxia-inducible factor 1 alpha. In conclusion, mitophagy is not essential for development of iron deficiency-induced reductions in mitochondrial proteins or respiratory capacity. The secretion of mitochondria-containing EV could present an additional pathway via which mitochondria can be cleared from iron chelation-exposed myotubes.

Published
2020

9. Depletion of ATP Limits Membrane Excitability of Skeletal Muscle by Increasing Both ClC1-Open Probability and Membrane Conductance.

Author

Leermakers, P.A., Dybdahl, K.L.T., Husted, K.S., Riisager, A., Paoli, F.V. de, Pinós, T., Vissing, J., Krag, T.O.B., Pedersen, T.H., Leermakers, P.A., Dybdahl, K.L.T., Husted, K.S., Riisager, A., Paoli, F.V. de, Pinós, T., Vissing, J., Krag, T.O.B., and Pedersen, T.H.

Abstract

Contains fulltext : 225945.pdf (publisher's version ) (Open Access), Activation of skeletal muscle contractions require that action potentials can be excited and propagated along the muscle fibers. Recent studies have revealed that muscle fiber excitability is regulated during repeated firing of action potentials by cellular signaling systems that control the function of ion channel that determine the resting membrane conductance (G (m) ). In fast-twitch muscle, prolonged firing of action potentials triggers a marked increase in G (m) , reducing muscle fiber excitability and causing action potential failure. Both ClC-1 and K(ATP) ion channels contribute to this G (m) rise, but the exact molecular regulation underlying their activation remains unclear. Studies in expression systems have revealed that ClC-1 is able to bind adenosine nucleotides, and that low adenosine nucleotide levels result in ClC-1 activation. In three series of experiments, this study aimed to explore whether ClC-1 is also regulated by adenosine nucleotides in native skeletal muscle fibers, and whether the adenosine nucleotide sensitivity of ClC-1 could explain the rise in G (m) muscle fibers during prolonged action potential firing. First, whole cell patch clamping of mouse muscle fibers demonstrated that ClC-1 activation shifted in the hyperpolarized direction when clamping pipette solution contained 0 mM ATP compared with 5 mM ATP. Second, three-electrode G (m) measurement during muscle fiber stimulation showed that glycolysis inhibition, with 2-deoxy-glucose or iodoacetate, resulted in an accelerated and rapid >400% G (m) rise during short periods of repeated action potential firing in both fast-twitch and slow-twitch rat, and in human muscle fibers. Moreover, ClC-1 inhibition with 9-anthracenecarboxylic acid resulted in either an absence or blunted G (m) rise during action potential firing in human muscle fibers. Third, G (m) measurement during repeated action potential firing in muscle fibers from a murine McArdle disease model suggest that the rise in G (m)

Published
2020

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