Your search keyword '"Netti A"' showing total 2 results

1. Dehydration affects cardiovascular nitric oxide synthases and caveolins in growing rats.

Author

Netti, Vanina, Iovane, Agustina, Vatrella, Mariana, Magnani, Natalia, Evelson, Pablo, Zotta, Elsa, Fellet, Andrea, and Balaszczuk, Ana

Subjects

*HEART metabolism, *ANIMAL experimentation, *AORTA, *BLOOD pressure, *BODY weight, *CARDIOVASCULAR system physiology, *CARRIER proteins, *DEHYDRATION, *HEART ventricles, *HEART atrium, *HEART rate monitoring, *HEMATOCRIT, *HISTOLOGICAL techniques, *LIPID peroxidation (Biology), *NITRIC oxide, *OXIDOREDUCTASES, *PROBABILITY theory, *RATS, *RESEARCH funding, *STATISTICS, *DATA analysis, *DATA analysis software, *DESCRIPTIVE statistics, *ONE-way analysis of variance, *IN vivo studies

Abstract

Purpose: During the postnatal stage, cardiovascular nitric oxide (NO) system and caveolins (cav) may be regulated differentially in response to hypovolemic state induced by water restriction. Our aim was to examine the effects of water restriction on NO synthases (NOS) and cav in the atria, ventricle and aorta of growing rats. Methods: Male Sprague-Dawley rats aged 25 and 50 days were divided into ( n = 15): WR: water restriction 3 days; WAL: water ad libitum 3 days. Systolic blood pressure, NOS activity and NOS/cav protein levels were measured. Results: Dehydration induced a larger increase in SBP in WR25 group. Ventricular NOS activity, endothelial NOS (eNOS) and neuronal isoform (nNOS) of WR25 pups were increased, and both cav were decreased. In the WR50 group, NOS activity remained unchanged. In the atria, NOS activity, eNOS and nNOS decreased in WR25 associated with increased cav-1; in the WR50 group, NOS activity was increased without changes in NOS isoforms. In the aorta of WR25, NOS activity and inducible NOS (iNOS) were decreased; NOS activity was unchanged in WR50, despite the decreased levels of eNOS and increased iNOS, cav-1 and cav-3. Conclusions: NO system adjustments in cardiovascular system under osmotic stress in vivo depend on postnatal age, being eNOS and nNOS, the isoforms that determine NOS activity in cardiac tissue in 25-day-old pups. Changes in cav abundance during hypovolemic state may contribute to age-related NO production. [ABSTRACT FROM AUTHOR]

Published

2016

2. Comparison of cardiovascular aquaporin-1 changes during water restriction between 25- and 50-day-old rats.

Author

Netti, Vanina, Vatrella, Mariana, Chamorro, Melina, Rosón, María, Zotta, Elsa, Fellet, Andrea, and Balaszczuk, Ana

Subjects

*HEART physiology, *PROTEIN metabolism, *HEART analysis, *ANALYSIS of variance, *ANIMAL experimentation, *BIOPHYSICS, *BODY weight, *COMPARATIVE studies, *DEHYDRATION, *FLUID therapy, *HISTOLOGICAL techniques, *HUMAN growth, *IMMUNOHISTOCHEMISTRY, *INFANT development, *RESEARCH methodology, *RATS, *RESEARCH funding, *STATISTICS, *WESTERN immunoblotting, *DATA analysis, *DATA analysis software, *DESCRIPTIVE statistics, *MEMBRANE transport proteins, *CHILDREN

Abstract

Purpose: Aquaporin-1 (AQP1) is the predominant water channel in the heart, linked to cardiovascular homeostasis. Our aim was to study cardiovascular AQP1 distribution and protein levels during osmotic stress and subsequent hydration during postnatal growth. Methods: Rats aged 25 and 50 days were divided in: 3d-WR: water restriction 3 days; 3d-WAL: water ad libitum 3 days; 6d-WR+ORS: water restriction 3 days + oral rehydration solution (ORS) 3 days; and 6d-WAL: water ad libitum 6 days. AQP1 was evaluated by immunohistochemistry and western blot in left ventricle, right atrium and thoracic aorta. Results: Water restriction induced a hypohydration state in both age groups (40 and 25 % loss of body weight in 25- and 50-day-old rats, respectively), reversible with ORS therapy. Cardiac AQP1 was localized in the endocardium and endothelium in both age groups, being evident in cardiomyocytes membrane only in 50-day-old 3d-WR group, which presented increased protein levels of AQP1; no changes were observed in the ventricle of pups. In vascular tissue, AQP1 was present in the smooth muscle of pups; in the oldest group, it was found in the endothelium, increasing after rehydration in smooth muscle. No differences were observed between control groups 3d-WAL and 6d-WAL of both ages. Conclusion: Our findings suggest that cardiovascular AQP1 can be differentially regulated in response to hydration status in vivo, being this response dependent on postnatal growth. The lack of adaptive mechanisms of mature animals in young pups may indicate an important role of this water channel in maintaining fluid balance during hypovolemic state. [ABSTRACT FROM AUTHOR]

Published

2014