1.
Proteomics: a tool to develop novel diagnostic methods and unravel molecular mechanisms of pediatric diseases.
Torres-Arroyo, A, Ruiz-Lara, A, Castillo-Villanueva, A, Méndez-Cruz, ST, Espinosa-Padilla, SE, Espinosa-Rosales, FJ, Zarate-Mondragón, F, Cervantes-Bustamante, R, Bosch-Canto, V, Vizzuett-López, I, et al
Boletin medico del Hospital Infantil de Mexico. 2017;(3):233-240
Abstract
Proteomics is the study of the expression of changes and post-translational modifications (PTM) of proteins along a metabolic condition either normal or pathological. In the field of health, proteomics allows obtaining valuable data for treatment, diagnosis or pathophysiological mechanisms of different illnesses. To illustrate the aforementioned, we describe two projects currently being performed at the Instituto Nacional de Pediatría: The immuno-proteomic study of cow milk allergy and the Proteomic study of childhood cataract. Cow's milk proteins (CMP) are the first antigens to which infants are exposed and generate allergy in some of them. In Mexico, the incidence of CMP allergy has been estimated at 5-7%. Clinical manifestations include both gastrointestinal and extra-gastrointestinal symptoms, making its diagnosis extremely difficult. An inappropriate diagnosis affects the development and growth of children. The goals of the study are to identify the main immune-reactive CMP in Mexican pediatric population and to design more accurate diagnostic tools for this disease. Childhood cataract is a major ocular disease representing one of the main causes of blindness in infants; in developing countries, this disease promotes up to 27% of cases related to visual loss. From this group, it has been estimated that close to 60% of children do not survive beyond two years after vision lost. PTM have been pointed out as the main cause of protein precipitation at the crystalline and, consequently, clouding of this tissue. The study of childhood cataract represents an outstanding opportunity to identify the PTM associated to the cataract-genesis process.
2.
Platelet clinical proteomics: Facts, challenges, and future perspectives.
García, Á
Proteomics. Clinical applications. 2016;(8):767-73
Abstract
In recent years, proteomics has been applied to platelet clinical research. Platelets are small enucleated cells that play a fundamental role in hemostasis. In a pathological context, unwanted platelet activation is related to various diseases, primarily thrombosis, but also cancer metastasis, inflammation, immunity, and neurodegenerative diseases. The absence of a nucleus is one of the reasons why proteomics can be considered an ideal analytical tool for platelet research. Indeed, platelet proteomics has allowed the identification of many novel signaling proteins and receptors, several of which are being pursued as potential therapeutic targets. Encouraged by this success, several research groups have recently initiated clinical proteomics studies covering diseases where platelets are involved in some way, such as coronary artery disease, storage pool diseases, uremia, cystic fibrosis, and Alzheimer disease. The goal was to identify platelet biomarkers and drug targets that can help to improve the treatment/diagnosis of the disease and provide further mechanistic evidences of the role platelets play in the pathology. The present article will comment on the recent progress of clinical proteomics in the context of platelet research, challenges, and perspectives for the future ahead.
3.
Understanding high-density lipoprotein function in disease: recent advances in proteomics unravel the complexity of its composition and biology.
Birner-Gruenberger, R, Schittmayer, M, Holzer, M, Marsche, G
Progress in lipid research. 2014;:36-46
Abstract
Although the epidemiology of high-density lipoprotein (HDL) cholesterol and cardiovascular risk has been consistent, pharmacologic interventions to increase HDL-cholesterol by delaying HDL catabolism did not translate into reduction in cardiovascular risk. HDL particles are small, protein-rich when compared to other plasma lipoprotein classes. Latest progresses in proteomics technology have dramatically increased our understanding of proteins carried by HDL. In addition to proteins with well-established functions in lipid transport, iron transport proteins, members of the complement pathway, and proteins involved in immune function and acute phase response were repeatedly identified on HDL particles. With the unraveling of the complexity of the HDL proteome, different laboratories have started to monitor its changes in various disease states. In addition, dynamic aspects of HDL subgroups are being discovered. These recent studies clearly illustrate the promise of HDL proteomics for deriving new biomarkers for disease diagnosis and to measure the effectiveness of current and future treatment regimens. This review summarizes recent advances in proteomics and lipidomics helping to understand HDL function in health and disease.
4.
Molecular mechanisms of probiotic action: a proteomic perspective.
Siciliano, RA, Mazzeo, MF
Current opinion in microbiology. 2012;(3):390-6
Abstract
Probiotics are living microorganisms that confer beneficial effects to human health when supplied in adequate amounts, by promoting digestion and uptake of dietary nutrients, strengthening intestinal barrier function, modulating immune response and enhancing antagonism towards pathogens. The purpose of the present article is to focus on microbial proteomics, pointing out its usefulness in the investigation of molecular mechanisms underlying probiotic effects. It deals, in particular, with molecular strategies responsible for adaptation to the harsh physical-chemical environment of the gastro-intestinal tract, bacterial adhesion to host epithelial cells and intestinal mucosa and probiotic immunomodulatory properties, as analyzed by proteomics in the past few years.