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Homeostatic Pathways (homeostatic + pathway)

Distribution by Scientific Domains
Life Sciences75%

Selected Abstracts

Ontogeny of energy homeostatic pathways via neuroendocrine signaling in Atlantic salmon

DEVELOPMENTAL NEUROBIOLOGY, Issue 9 2010
Anne-Grethe Gamst Moen
Abstract Leptin and ghrelin are known to regulate energy homeostasis via hypothalamic neuropeptide signaling in mammals. Recent studies have discovered that these hormones exist in teleosts, however, very little is known concerning their role during teleost ontogeny. Here, we have examined the steady state levels of leptins, ghrelins, their target neuropetides and several growth factors during Atlantic salmon development. Initial experiments revealed differential expression of leptin genes and ghrelin isoforms during embryogenesis. In larvae, equal upregulation of ghrl1 and ghrl2 was observed just prior to exogenous feeding while a surge of lepa1 occurred one week after first-feeding. Subsequent dissection of the embryos and larvae showed that lepa1, cart, pomca1, and agrp are supplied as maternal transcripts. The earliest zygotic expression was observed for lepa1 and cart at 320 day degrees. By 400 day degrees, this expression was localized to the head and coincided with upregulation of ghrl2 and npy. Over the hatching period growth factor signaling predominated. The ghrelin surge prior to first-feeding was exclusively localized in the internal organs and coincided with upregulation of npy and agrp in the head and agrp in the trunk. One week after exogenous feeding was established major peaks were detected in the head for lepa1 and pomca1 with increasing levels of cart, while lepa1 was also significantly expressed in the trunk. By integrating theses data into an ontogenetic model, we suggest that the mediation of Atlantic salmon energy homeostatic pathways via endocrine and neuropeptide signaling retains putative features of the mammalian system. © 2010 Wiley Periodicals, Inc. Develop Neurobiol 70: 649,658, 2010 [source]

Regulation of Human Myometrial Contractility During Pregnancy and Labour: Are Calcium Homeostatic Pathways Important?

EXPERIMENTAL PHYSIOLOGY, Issue 2 2001
Rachel M. Tribe
If we are to develop new strategies for the treatment and management of preterm and dysfunctional term labour, it is imperative that we improve current understanding of the control of human uterine activity. Despite many studies of animal pregnancy, there is a paucity of knowledge relating to the complex control of human myometrium during pregnancy. It is hypothesized that human myometrium is relatively quiescent during the majority of pregnancy and that as term approaches there is cascade of molecular events that prepare the uterus for labour. This review will consider the cellular mechanisms involved in the regulation of human myometrial activity and the modulation of these by hormonal and mechanical signals. In particular, the contribution of calcium homeostatic pathways to the control of human myometrial contractility during gestation will be discussed. [source]

Autoantigens in systemic autoimmunity: critical partner in pathogenesis

JOURNAL OF INTERNAL MEDICINE, Issue 6 2009
A. Rosen
Abstract. Understanding the mechanisms of human autoimmune rheumatic diseases presents a major challenge, due to marked complexity involving multiple domains, including genetics, environment and kinetics. In spite of this, the immune response in each of these diseases is largely specific, with distinct autoantibodies associated with different disease phenotypes. Defining the basis of such specificity will provide important insights into disease mechanism. Accumulating data suggest an interesting paradigm for antigen selection in autoimmunity, in which target tissue and immune effector pathways form a mutually reinforcing partnership. In this model, distinct autoantibody patterns in autoimmunity may be viewed as the integrated, amplified output of several interacting systems, including: (i) the specific target tissue, (ii) the immune effector pathways that modify antigen structure and cause tissue damage and dysfunction, and (iii) the homeostatic pathways activated in response to damage (e.g. regeneration/differentiation/cytokine effects). As unique antigen expression and structure may occur exclusively under these amplifying circumstances, it is useful to view the molecules targeted as ,neo-antigens', that is, antigens expressed under specific conditions, rather than ubiquitously. This model adds an important new dynamic element to selection of antigen targets in autoimmunity, and suggests that the amplifying loop will only be identified by studying the diseased target tissue in vivo. [source]