Your search keyword '"Karina Pasten-Hidalgo"' showing total 3 results

1. Protein-conformational diseases in childhood: Naturally-occurring hIAPP amyloid-oligomers and early β-cell damage in obesity and diabetes.

Author

Nelly F Altamirano-Bustamante, Eulalia Garrido-Magaña, Eugenia Morán, Aurora Calderón, Karina Pasten-Hidalgo, Rosa Angélica Castillo-Rodríguez, Gerardo Rojas, Reyna Lara-Martínez, Edgar Leyva-García, Mateo Larralde-Laborde, Guadalupe Domíguez, Chiharu Murata, Yolanda Margarita-Vazquez, Rafael Payro, Manuel Barbosa, Alejandro Valderrama, Hortencia Montesinos, Alejandra Domínguez-Camacho, Víctor H García-Olmos, Regina Ferrer, Patricia G Medina-Bravo, Fernanda Santoscoy, Cristina Revilla-Monsalve, Luis Felipe Jiménez-García, Julio Morán, Jalil Villalobos-Alva, Mario Javier Villalobos, Raúl Calzada-León, Perla Altamirano, and Myriam M Altamirano-Bustamante

Subjects

Medicine, Science

Abstract

Background and aimsThis is the first time that obesity and diabetes mellitus (DM) as protein conformational diseases (PCD) are reported in children and they are typically diagnosed too late, when β-cell damage is evident. Here we wanted to investigate the level of naturally-ocurring or real (not synthetic) oligomeric aggregates of the human islet amyloid polypeptide (hIAPP) that we called RIAO in sera of pediatric patients with obesity and diabetes. We aimed to reduce the gap between basic biomedical research, clinical practice-health decision making and to explore whether RIAO work as a potential biomarker of early β-cell damage.Materials and methodsWe performed a multicentric collaborative, cross-sectional, analytical, ambispective and blinded study; the RIAO from pretreated samples (PTS) of sera of 146 pediatric patients with obesity or DM and 16 healthy children, were isolated, measured by sound indirect ELISA with novel anti-hIAPP cytotoxic oligomers polyclonal antibody (MEX1). We carried out morphological and functional studied and cluster-clinical data driven analysis.ResultsWe demonstrated by western blot, Transmission Electron Microscopy and cell viability experiments that RIAO circulate in the blood and can be measured by ELISA; are elevated in serum of childhood obesity and diabetes; are neurotoxics and works as biomarkers of early β-cell failure. We explored the range of evidence-based medicine clusters that included the RIAO level, which allowed us to classify and stratify the obesity patients with high cardiometabolic risk.ConclusionsRIAO level increases as the number of complications rises; RIAOs > 3.35 μg/ml is a predictor of changes in the current indicators of β-cell damage. We proposed a novel physio-pathological pathway and shows that PCD affect not only elderly patients but also children. Here we reduced the gap between basic biomedical research, clinical practice and health decision making.

Published

2020

2. Diabetes Drug Discovery: hIAPP1–37 Polymorphic Amyloid Structures as Novel Therapeutic Targets

Author

Isaac Fernández-Gómez, Marquiza Sablón-Carrazana, Alberto Bencomo-Martínez, Guadalupe Domínguez, Reyna Lara-Martínez, Nelly F. Altamirano-Bustamante, Luis Felipe Jiménez-García, Karina Pasten-Hidalgo, Rosa Angélica Castillo-Rodríguez, Perla Altamirano, Suchitil Rivera Marrero, Cristina Revilla-Monsalve, Peter Valdés-Sosa, Fabio Salamanca-Gómez, Eulalia Garrido-Magaña, Chryslaine Rodríguez-Tanty, and Myriam M. Altamirano-Bustamante

Subjects

IAPP, diabetes mellitus, pharmacological chaperones, amyloid structures, conformational diseases, drug discovery, Organic chemistry, QD241-441

Abstract

Human islet amyloid peptide (hIAPP1–37) aggregation is an early step in Diabetes Mellitus. We aimed to evaluate a family of pharmaco-chaperones to act as modulators that provide dynamic interventions and the multi-target capacity (native state, cytotoxic oligomers, protofilaments and fibrils of hIAPP1–37) required to meet the treatment challenges of diabetes. We used a cross-functional approach that combines in silico and in vitro biochemical and biophysical methods to study the hIAPP1–37 aggregation-oligomerization process as to reveal novel potential anti-diabetic drugs. The family of pharmaco-chaperones are modulators of the oligomerization and fibre formation of hIAPP1–37. When they interact with the amino acid in the amyloid-like steric zipper zone, they inhibit and/or delay the aggregation-oligomerization pathway by binding and stabilizing several amyloid structures of hIAPP1–37. Moreover, they can protect cerebellar granule cells (CGC) from the cytotoxicity produced by the hIAPP1–37 oligomers. The modulation of proteostasis by the family of pharmaco-chaperones A–F is a promising potential approach to limit the onset and progression of diabetes and its comorbidities.

Published

2018

3. Drug Development in Conformational Diseases: A Novel Family of Chemical Chaperones that Bind and Stabilise Several Polymorphic Amyloid Structures.

Author

Marquiza Sablón-Carrazana, Isaac Fernández, Alberto Bencomo, Reyna Lara-Martínez, Suchitil Rivera-Marrero, Guadalupe Domínguez, Rafaela Pérez-Perera, Luis Felipe Jiménez-García, Nelly F Altamirano-Bustamante, Massiel Diaz-Delgado, Fernand Vedrenne, Lina Rivillas-Acevedo, Karina Pasten-Hidalgo, María de Lourdes Segura-Valdez, Sergio Islas-Andrade, Eulalia Garrido-Magaña, Alejandro Perera-Pintado, Anaís Prats-Capote, Chryslaine Rodríguez-Tanty, and Myriam M Altamirano-Bustamante

Subjects

Medicine, Science

Abstract

The increasing prevalence of conformational diseases, including Alzheimer's disease, type 2 Diabetes Mellitus and Cancer, poses a global challenge at many different levels. It has devastating effects on the sufferers as well as a tremendous economic impact on families and the health system. In this work, we apply a cross-functional approach that combines ideas, concepts and technologies from several disciplines in order to study, in silico and in vitro, the role of a novel chemical chaperones family (NCHCHF) in processes of protein aggregation in conformational diseases. Given that Serum Albumin (SA) is the most abundant protein in the blood of mammals, and Bovine Serum Albumin (BSA) is an off-the-shelf protein available in most labs around the world, we compared the ligandability of BSA:NCHCHF with the interaction sites in the Human Islet Amyloid Polypeptide (hIAPP):NCHCHF, and in the amyloid pharmacophore fragments (Aβ17-42 and Aβ16-21):NCHCHF. We posit that the merging of this interaction sites is a meta-structure of pharmacophore which allows the development of chaperones that can prevent protein aggregation at various states from: stabilizing the native state to destabilizing oligomeric state and protofilament. Furthermore to stabilize fibrillar structures, thus decreasing the amount of toxic oligomers in solution, as is the case with the NCHCHF. The paper demonstrates how a set of NCHCHF can be used for studying and potentially treating the various physiopathological stages of a conformational disease. For instance, when dealing with an acute phase of cytotoxicity, what is needed is the recruitment of cytotoxic oligomers, thus chaperone F, which accelerates fiber formation, would be very useful; whereas in a chronic stage it is better to have chaperones A, B, C, and D, which stabilize the native and fibril structures halting self-catalysis and the creation of cytotoxic oligomers as a consequence of fiber formation. Furthermore, all the chaperones are able to protect and recondition the cerebellar granule cells (CGC) from the cytotoxicity produced by the hIAPP20-29 fragment or by a low potassium medium, regardless of their capacity for accelerating or inhibiting in vitro formation of fibers. In vivo animal experiments are required to study the impact of chemical chaperones in cognitive and metabolic syndromes.

Published

2015