The aim of this study was to characterize the response to exercise training in several mouse strains and estimate the genetic contribution to phenotypic variation in the responses to exercise training. Male mice from three inbred strains [C57Bl/6J (BL6), FVB/NJ (FVB), and Balb/cJ (Balb/c)] and three hybrid F(1) strains [CB6F1/J (CB6 = female Balb/c x male BL6), B6F F(1) (female BL6 x male FVB), and FB6 F(1) (female FVB x male BL6)] completed an exercise performance test before and after a 4-wk treadmill running program. Distance was used as the primary estimate of endurance exercise performance. FVB mice showed the greatest response to training, with five- to sevenfold greater increases in distance run compared with BL6 and Balb/c strains. Specifically, BL6, FVB, and Balb/c strains increased distance by 33, 172, and 23%, respectively. A similar pattern of changes across strains was observed for run time (17, 87, and 11%) and work (99, 287, and 57%). As a group, F(1) hybrid mice derived from BL6 and FVB strains showed an intermediate response to training (61%). However, further analysis indicated that training responses in FB6 F(1) mice (80%) were approximately 2.5-fold greater than responses in B6F F(1) mice (33%, P = 0.08). A similar pattern of changes between FB6 and B6F F(1) mice was observed for run time (44.5 and 17%) and work (141 and 59%). These data demonstrate that there are large strain-dependent differences in training responses among inbred mouse strains, suggesting that genetic background contributes significantly to adaptation to exercise. Furthermore, the contrasting responses in B6F and FB6 F(1) strains show that a maternal component strongly influences strain-dependent differences in training responses.
The ability of dual-energy x-ray absorptiometry (DEXA) to detect small changes in body composition was studied in 17 men and women during a dehydration-rehydration protocol. Scale weight (BW) and total mass (TM) from DEXA were highly related (r > 0.99) as were estimates of fat-free mass (r = 0.99) and percent fat (r = 0.97) from DEXA and densitometry. Changes in BW of approximately 1.5 kg due to fluid loss and gain were highly correlated (r = 0.90) with both changes in TM and soft-tissue mass (STM) by DEXA but less so (r = 0.67) with changes in lean-tissue mass (LTM). Mean changes in TM, STM, and LTM were not different (P > 0.05) from changes in BW. Estimates of bone mass and fat were unaffected by changes in hydration. We conclude that DEXA is able to detect small individual changes in TM and STM and is also useful for detecting group changes in LTM.
Peroxisome proliferator-activated receptors (PPAR) decrease the production of cytokine and inducible nitric-oxide synthase (iNOS) expression, which are associated with aging-related inflammation and insulin resistance. Recently, the involvement of the induction of heme oxygenase-1 (HO-1) in regulating inflammation has been suggested, but the exact mechanisms for reducing inflammation by HO-1 remains unclear. We found that overexpression of HO-1 and [Ru(CO) 3 Cl 2 ] 2 , a carbon monoxide (CO)-releasing compound, increased not only ERK5 kinase activity, but also its transcriptional activity measured by luciferase assay with the transfection of the Gal4-ERK5 reporter gene. This transcriptional activity is required for coactivation of PPAR␦ by ERK5 in C2C12 cells. [Ru(CO) 3 Cl 2 ] 2 activated PPAR␦ transcriptional activity via the MEK5/ERK5 signaling pathway. The inhibition of NF-B activity by ERK5 activation was reversed by a dominant negative form of PPAR␦ suggesting that ERK5/PPAR␦ activation is required for the anti-inflammatory effects of CO and HO-1. Based on these data, we propose a new mechanism by which CO and HO-1 mediate anti-inflammatory effects via activating ERK5/PPAR␦, and ERK5 mediates CO and HO-1-induced PPAR␦ activation via its interaction with PPAR␦.Muscle wasting is a major feature of the cachexia associated with diverse pathologies such as cancer, sepsis, diabetes, and aging (1). Several cytokines have been implicated in the pathogenesis of muscle wasting, most notably TNF-␣, 2 a pro-inflammatory cytokine that was originally called "cachectin" (1). In addition, aging-related chronic low grade inflammation by TNF-␣ plays an important role in insulin resistance (2). It has been proposed that chronic inflammation by TNF-␣-mediated NF-B activation and subsequent inducible nitric-oxide synthase (iNOS) induction relates to muscle wasting and insulin resistance as we will explain below. Cai et al. (3) have shown that activation of NF-B, through muscle-specific transgenic expression of activated IB kinase  (MIKK), causes profound muscle wasting that resembles clinical cachexia. In contrast, no overt phenotype was seen upon muscle-specific inhibition of NF-B through expression of IB suppressor (MISR), and denervation and tumor-induced muscle loss were substantially reduced and survival rates improved by NF-B inhibition in MISR mice, which is consistent with a critical role for NF-B in the pathology of muscle wasting, especially in diabetes and during the process of aging (3). Recent studies suggest the involvement of iNOS in the pathogenesis of insulin resistance (4, 5). First, most inducers of insulin resistance, including obesity (6), free fatty acids (7), hyperglycemia (8, 9), TNF-␣, oxidative stress, and endotoxin, increase iNOS expression. Second, iNOS mediates the impaired insulin-stimulated glucose uptake by treatment with TNF-␣ and lipopolysaccharide in cultured muscle cells (10). iNOS expression is elevated in skeletal muscle of patients with type 2 diabetes (11, 12), and high fat diet-induced...
Background The G-protein-coupled receptor (GPCR)-kinase interacting protein-1 (GIT1) is a multi-domain scaffold protein that participates in many cellular functions including receptor internalization, focal adhesion remodeling, and signaling by both GPCRs and tyrosine kinase receptors. However, there have been no in vivo studies of GIT1 function to date. Methods and Results To determine essential functions of GIT1 in vivo, we generated a traditional GIT1 knockout (KO) mouse. GIT1 KO mice exhibited ∼60% perinatal mortality. Pathologic examination showed that the major abnormality in GIT1-KO mice was impaired lung development characterized by markedly reduced numbers of pulmonary blood vessels and increased alveolar spaces. Since vascular endothelial growth factor (VEGF) is essential for pulmonary vascular development, we investigated the role of GIT1 in VEGF signaling in the lung and cultured endothelial cells (EC). Because activation of phospholipase-Cγ (PLCγ and ERK1/2 by angiotensin II requires GIT1, we hypothesized that GIT1 mediates VEGF-dependent pulmonary angiogenesis by modulating PLCγ and ERK1/2 activity in EC. In cultured EC, knockdown of GIT1 decreased VEGF-mediated phosphorylation of PLCγ and ERK1/2. PLCγ and ERK1/2 activity in lungs from GIT1 KO mice was reduced postnatally. Conclusions Our data support a critical role for GIT1 in pulmonary vascular development by regulating VEGF-induced PLCγ and ERK1/2 activation.
Changes in cardiorespiratory fitness in response to a standardized exercise training protocol differ substantially between individuals. Results from cross-sectional, twin, and family studies indicate genetics contribute to individual differences in both baseline exercise capacity and the response to training. Exercise capacity and responses to training also vary between inbred strains of mice. However, such studies have utilized a limited number of inbred strains. Therefore, the aim of this study was to characterize exercise-training responses in a larger number of genetically diverse strains of inbred mice and estimate the contribution of genetic background to exercise training responses. Eight-week old male mice from 24 inbred strains (n = 4–10/strain) performed a graded exercise test before and after 4 weeks of exercise training. Before training, exercise capacity was significantly different between strains when expressed as time (range = 21–42 min) and work performed (range = 0.42–3.89 kg·m). The responses to training also were significantly different between strains, ranging from a decrease of 2.2 min in NON/ShiLtJ mice to an increase of 8.7 min in SWR/J mice. Changes in work also varied considerably between the lowest (−0.24 kg·m in NON/ShiLtJ) and highest (+2.30 kg·m in FVB/NJ) performing strains. Heart and skeletal muscle masses also varied significantly between strains. Two broad sense heritability estimates were calculated for each measure of exercise capacity and for responses to training. For change in run time, the intraclass correlation between mice within the same inbred strain (rI) was 0.58 and the coefficient of genetic determination (g2) was 0.41. Heritability estimates were similar for the change in work: rI = 0.54 and g2 = 0.37. In conclusion, these results indicate genetic background significantly influences responses to exercise training.
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