Valéria Garrido scite author profile

Type 2 diabetes mellitus (T2DM) is a highly prevalent disease worldwide. Cardiovascular disorders generated as a consequence of T2DM are a major cause of death related to this disease. Diabetic cardiomyopathy (DCM) is characterized by the morphological, functional and metabolic changes in the heart produced as a complication of T2DM. This cardiac disorder is characterized by constant high blood glucose and lipids levels which eventually generate oxidative stress, defective calcium handling, altered mitochondrial function, inflammation and fibrosis. In this context, insulin is of paramount importance for cardiac contractility, growth and metabolism and therefore, an impaired insulin signaling plays a critical role in the DCM development. However, the exact pathophysiological mechanisms leading to DCM are still a matter of study. Despite the numerous questions raised in the study of DCM, there have also been important findings, such as the role of micro-RNAs (miRNAs), which can not only have the potential of being important biomarkers, but also therapeutic targets. Furthermore, exosomes also arise as an interesting variable to consider, since they represent an important inter-cellular communication mechanism and therefore, they may explain many aspects of the pathophysiology of DCM and their study may lead to the development of therapeutic agents capable of improving insulin signaling. In addition, adenosine and adenosine receptors (ARs) may also play an important role in DCM. Moreover, the possible cross-talk between insulin and ARs may provide new strategies to reverse its defective signaling in the diabetic heart. This review focuses on DCM, the role of insulin in this pathology and the discussion of new molecular insights which may help to understand its underlying mechanisms and generate possible new therapeutic strategies.

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Sarcoplasmic reticulum and calcium signaling in muscle cells: Homeostasis and disease

Bravo-Sagua

Parra

Muñoz-Cordova

et al. 2020

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Ca 2 + cell physiology in smooth muscle 221 4.1 Smooth muscle cell classification 221 4.2 Ca 2 + homeostasis 223 4.3 Ca 2 + release channels in ER 225 4.4 Ca 2 + refill mechanisms in ER 227 4.5 Excitation-contraction coupling 228 5. SR/ER dysfunction and diseases 230 5.1 SR dysfunction and cardiac hypertrophy 230 5.2 SR and insulin resistance in skeletal muscle cells 236 5.3 ER in smooth muscle cell and hypertension 240 6. Concluding remarks 241 Acknowledgments 243 References 243

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Synthesis, antiviral activity and molecular modeling of oxoquinoline derivatives

Santos

Abreu

Castro

et al. 2009

Bioorganic & Medicinal Chemistry

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In the present article, we describe the synthesis, anti-HIV1 profile and molecular modeling evaluation of 11 oxoquinoline derivatives. The structure-activity relationship analysis revealed some stereoelectronic properties such as LUMO energy, dipole moment, number of rotatable bonds, and of hydrogen bond donors and acceptors correlated with the potency of compounds. We also describe the importance of substituents R(2) and R(3) for their biological activity. Compound 2j was identified as a lead compound for future investigation due to its: (i) high activity against HIV-1, (ii) low cytotoxicity in PBMC, (iii) low toxic risks based on in silico evaluation, (iv) a good theoretical oral bioavailability according to Lipinski 'rule of five', (v) higher druglikeness and drug-score values than current antivirals AZT and efavirenz.

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