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Entire Organism (entire + organism)

Distribution by Scientific Domains
Medical Sciences75%

Selected Abstracts

ESCI award lecture: from a little mouse to rationale medicine for bone loss

EUROPEAN JOURNAL OF CLINICAL INVESTIGATION, Issue 10 2009
A. Leibbrandt
Abstract Completion of the human genome is one of the many significant milestones in the new era of systems biology. The current phase of genomic studies is focused upon parsing this new found genetic data with respect to scientific interest, and economic and health impact applications. As the sequences are now available and whole genome single nucleotide polymorphism maps for multiple human diseases will be available with the advent of modern genomics, the big challenge is to determine the function of these genes in the context of the entire organism. The emphasis is therefore on functional genomic analysis that represents the new front-line and limiting factor for realizing potential benefits of genome-based science. Defined gene targeting has been proven to be particularly useful as loss of expression mutants can reveal essential functions of molecules and the pathogenesis of disease. Using gene-targeted mice, my group has over the years identified genes that control heart and lung functions [1,5]; apoptosis [6,9]; lymphocyte activation [10,14]; cancer [15,17]; pain [18]; diabetes [19]; fertility [20] or wound healing [21]. In this study, I would like to review our work on RANKL in more detail. [source]

Fibrous Dysplasia as a Stem Cell Disease,

JOURNAL OF BONE AND MINERAL RESEARCH, Issue S2 2006
Mara Riminucci
Abstract At a time when significant attention is devoted worldwide to stem cells as a potential tool for curing incurable diseases, fibrous dysplasia of bone (FD) provides a paradigm for stem cell diseases. Consideration of the time and mechanism of the causative mutations and of nature of the pluripotent cells that mutate in early embryonic development indicates that, as a disease of the entire organism, FD can be seen as a disease of pluripotent embryonic cells. As a disease of bone as an organ, in turn, FD can be seen as a disease of postnatal skeletal stem cells, which give rise to dysfunctional osteoblasts. Recognizing FD as a stem cell disease provides a novel conceptual angle and a way to generate appropriate models of the disease, which will continue to provide further insight into its natural history and pathogenesis. In addition, skeletal stem cells may represent a tool for innovative treatments. These can be conceived as directed to alter the in vivo behavior of mutated stem cells, to replace mutated cells through local transplantation, or to correct the genetic defect in the stem cells themselves. In vitro and in vivo models are currently being generated that will permit exploration of these avenues in depth. [source]

Enrichment of peptides from plasma for peptidome analysis using multiwalled carbon nanotubes

JOURNAL OF SEPARATION SCIENCE, JSS, Issue 6 2007
Xin Li
Abstract Human plasma contains a complex matrix of proteolytically derived peptides (plasma peptidome) that may provide a correlate of biological events occurring in the entire organism. Analyzing these peptides from a small amount of serum/plasma is difficult due to the complexity of the sample and the low levels of these peptides. Here, we describe a novel peptidome analysis approach using multiwalled carbon nanotubes (MWCNTs) as an alternative adsorbent to capture endogenous peptides from human plasma. Harvested peptides were analyzed by using liquid chromatography-mass spectrometry as a means of detecting and assessing the adsorbed molecules. The improved sensitivity and resolution obtained by using liquid chromatography-mass spectrometry allowed detection of 2521 peptide features (m/z 300,1800 range) in about 50 ,L of plasma. 374 unique peptides were identified with high confidence by two-dimensional liquid chromatography system coupled to a nano-spray ionization linear ion trap-mass spectrometer. High recovery of BSA digest peptides enriched with MWCNTs, in both standard buffer and high abundance protein solution, was observed. Comparative studies showed that MWCNTs were superior to C18 and C8 for the capture of the smaller peptides. This approach could hold promise of routine plasma peptidome analysis. [source]

Fuel sensing and the central nervous system (CNS): implications for the regulation of energy balance and the treatment for obesity

OBESITY REVIEWS, Issue 3 2005
R. J. Seeley
Summary This review describes the product of the 3-day International Association for the Study of Obesity (IASO) Stock Conference held in March 2004 and sponsored by Abbott Laboratories. The conference was focused on how the mechanisms by which individual cells sense their own fuel status might influence the energy balance of the entire organism. Whether you are a single-celled organism or a sophisticated mammal with a large cerebral cortex, it is critical that cellular activity be matched to the available fuel necessary for that activity. Rapid progress has been made in the last decade in our understanding of the critical metabolic events that cells monitor to accomplish this critical task. More recent developments have begun to apply this understanding to how critical populations of neurones may monitor similar events to control both food intake and energy expenditure. The picture that emerges is that numerous peripheral fuel sensors communicate to the central nervous system (CNS) via neural and humoral routes. Moreover, it has been known for decades that specific populations of neurones sense changes in ambient glucose levels and adjust their firing rate in response and changes in neuronal glucose metabolism can influence energy balance. The CNS, however, does not just sense glucose but rather appears to be sensitive to a wide range of metabolic perturbations associated with fuel availability. This information is used to adjust both caloric intake and the disposition of fuels in the periphery. Increased understanding of these CNS fuel-sensing mechanisms may lead to novel therapeutic targets for obesity. [source]