Advances in geroscience: impact on healthspan and chronic disease.

Population aging is unprecedented, without parallel in human history, and the 21st century will witness even more rapid aging than did the century just past. Improvements in public health and medicine are having a profound effect on population demographics worldwide. By 2017, there will be more people over the age of 65 than under age 5, and by 2050, two billion of the estimated nine billion people on Earth will be older than 60 (http://unfpa.org/ageingreport/). Although we can reasonably expect to live longer today than past generations did, the age-related disease burden we will have to confront has not changed. With the proportion of older people among the global population being now higher than at any time in history and still expanding, maintaining health into old age (or healthspan) has become a new and urgent frontier for modern medicine. Geroscience is a cross-disciplinary field focused on understanding the relationships between the processes of aging and age-related chronic diseases. On October 30-31, 2013, the trans-National Institutes of Health GeroScience Interest Group hosted a Summit to promote collaborations between the aging and chronic disease research communities with the goal of developing innovative strategies to improve healthspan and reduce the burden of chronic disease.

Regulation of heart valve morphogenesis by Eph receptor ligand, ephrin-A1.

Disease or malformation of heart valves is one of the leading causes of morbidity and mortality in both children and adults. These congenital anomalies can remain undetected until cardiac function is compromised, making it important to understand the underlying nature of these disorders. Here we show that ephrin-A1, a ligand for class A Eph receptor tyrosine kinases, regulates cardiac valve formation. Exogenous ephrin-A1-Fc or overexpression of ephrin-A1 in the heart inhibits epithelial-to-mesenchymal transformation (EMT) in chick atrioventricular cushion explants. In contrast, overexpression of wild-type EphA3 receptor promotes EMT via a kinase-dependent mechanism. To analyze ephrin-A1 in vivo, we generated an ephrin-A1 knockout mouse through gene targeting. Ephrin-A1 null animals are viable but exhibit impaired cardiac function. Loss of ephrin-A1 results in thickened aortic and mitral valves in newborn and adult animals. Analysis of early embryonic hearts revealed increased cellularity in outflow tract endocardial cushions and elevated mesenchymal marker expression, suggesting that excessive numbers of cells undergo EMT. Taken together, these data indicate that ephrin-A1 regulates cardiac valve development, making ephrin-A1-deficient mice a novel model for congenital heart defects.

Molecular classification of nemaline myopathies: "nontyping" specimens exhibit unique patterns of gene expression.

Nemaline myopathy (NM) is a slowly progressive or nonprogressive neuromuscular disorder caused by mutations in genes encoding skeletal muscle sarcomeric thin filament proteins. It is characterized by great heterogeneity at the clinical, histopathological, and genetic level. Although multiple molecular pathways are commonly affected in all NM patients, little is known about the molecular characteristics of muscles from patients in different NM subgroups. We have analyzed a group of global gene expression data sets for transcriptional patterns characteristic of particular nemaline myopathy classes. Differential expression between disease subgroups was primarily seen in mitochondrial-, structural-, and transcription-related genes. Multiple lines of evidence support the hypothesis that muscles from cases with "nontyping" NM, although clinically classified as typical NM, share a unique pathophysiological state and are characterized by distinct patterns of gene expression. Determination of the specific molecular differences in NM subgroups may eventually lead to improved prognostic determinations and treatment of these patients.