Hormones and the levels of humoral regulation]

The problems on the place of hormones secreted by "classical" endocrine glands, on their relationship with other compounds that possess physiological activity, criteria that determine the definition "hormone" are considered in this article. The conception about the levels of the humoral regulatory systems that are organized and formed during phylogenesis and ontogenesis and provide a consecutive increase in their complexity and mobility of adaptation to changes of environment and internal conditions are substantiated on the basis of numerous data. The metabolites that are products of nonspecific activity of any cell of the multicellular organism form the first and simplest level of humoral regulatory organization. The next (second) level of humoral organization is also formed by chemically simple substances. However, these substances are specialized products of the secretory activity of cells and exert potent influence on the physiological processes. Neuroamines and regulatory peptides are applied to these agents, in the first place. They arise simultaneously and jointly at the first stage of ontogenesis. The distinctive characters of the third level of the humoral regulation are increased and complication of the regulatory activity conditioned by cooperative influences of humoral agents produced by single secretory elements situated outside the classical endocrine glands. The chemically and originally different substances causing predominantly local effects are attributed to these physiologically active substances. Their participation in general adaptive reactions as well as inclusion of classical hormones into hierarchy of humoral regulation signify the formation of the forth regulatory level that provides realization of general homeostatic reactions peculiar to the whole organism.(ABSTRACT TRUNCATED AT 250 WORDS)     

Is there anything "autonomous" in the nervous system?

The terms "autonomous" or "vegetative" are currently used to identify one part of the nervous system composed of sympathetic, parasympathetic, and gastrointestinal divisions. However, the concepts that are under the literal meaning of these words can lead to misconceptions about the actual nervous organization. Some clear-cut examples indicate that no element shows "autonomy" in an integrated body. Nor are they solely "passive" or generated "without mental elaboration." In addition, to be "not consciously controlled" is not a unique attribute of these components. Another term that could be proposed is "homeostatic nervous system" for providing conditions to the execution of behaviors and maintenance of the internal milieu within normal ranges. But, not all homeostatic conditions are under the direct influence of these groups of neurons, and some situations clearly impose different ranges for some variables that are adaptative (or hazardous) in the tentative of successfully coping with challenging situations. Finally, the name "nervous system for visceral control" emerges as another possibility. Unfortunately, it is not only "viscera" that represent end targets for this specific innervation. Therefore, it is commented that no quite adequate term for the sympathetic, parasympathetic, and gastrointestinal divisions has already been coined. The basic condition for a new term is that it should clearly imply the whole integrated and collaborative functions that the components have in an indivisible organism, including the neuroendocrine, immunological, and respiratory systems. Until that, we can call these parts simply by their own names and avoid terms that are more "convenient" than appropriate.     

Cross-regulation in development of neuroendocrine and immune systems

Cross-regulatory effects of immune and neuroendocrine systems on their appearance and functioning occur during a whole life period. At different stages of ontogenesis, the functions of these systems are diverse. In perinatal ontogenesis hormones, neuropeptides and neurotransmitters control the processes of growth and differentiation of various embryo tissues, particularly lymphoid. In the postnatal period, their functions are mostly in homeostasis maintaining of the immune system in response to changes of the environment. Conversely, transmitters of the immune system, such as cytokines, whose synthesis is increased in inflammation, and thymic peptides, program the development of the neuroendocrine system of the embryo. The perinatal period is crucial for final appearance of these systems. Changes in one of the interacting systems, caused by negative environmental factors at this stage, usually provoke changes in other developing systems for a long period. Plasticity of physiological systems in perinatal development allows the organism to adapt to changed conditions. However, these changes can limit physiological functions in interacting systems and induce the appearance of various pathologies in postnatal life.     

The Na+-K+-ATPase as self-adhesion molecule and hormone receptor

Thanks to the homeostasis of the internal milieu, metazoan cells can enormously simplify their housekeeping efforts and engage instead in differentiation and multiple forms of organization (tissues, organs, systems) that enable them to produce an astonishing diversity of mammals. The stability of the internal milieu despite drastic variations of the external environment (air, fresh or seawater, gastrointestinal fluids, glomerular filtrate, bile) is due to transporting epithelia that can adjust their specific permeability to H(2)O, H(+), Na(+), K(+), Ca(2+), and Cl(-) over several orders of magnitude and exchange substances with the outer milieu with exquisite precision. This exchange is due to the polarized expression of membrane proteins, among them Na(+)-K(+)-ATPase, an oligomeric enzyme that uses chemical energy from ATP molecules to translocate ions across the plasma membrane of epithelial cells. Na(+)-K(+)-ATPase presents two types of asymmetries: the arrangement of its subunits, and its expression in one pole of the epithelial cell ("polarity"). In most epithelia, polarity consists of the expression of Na(+)-K(+)-ATPase towards the intercellular space and arises in part from the interaction of the extracellular segment of the β-subunit with another β-subunit present in a Na(+)-K(+)-ATPase molecule expressed by a neighboring cell. In addition to enabling the Na(+)-K(+)-ATPase to transport ions and water vectorially, this position exposes its receptors to ouabain and analogous cardiotonic steroids, which are present in the internal milieu because these were secreted by endocrine cells.     

The effects of gravity on the circadian timing system

The physiological system responsible for the temporal coordination of an organism is the circadian timing system (CTS). This system provides two forms of temporal coordination. First, the CTS provides for synchronization of the organism with the 24 hour period of the external environment. This synchronization of the organism with the environment is termed entrainment. Second, this system also provides for internal coordination of the various physiological, behavioral, and biochemical events within the organism. When either of these two temporal relationships are disturbed, various dysfunctions can be manifest within the organism. Homeostatic capacity of other physiological systems may be reduced. Performance is decreased and sleep disorders, mental health impairment (e.g., depression), jet lag syndrome, and shift work maladaptation frequently occur. Over the last several years, several studies have evaluated the potential influence of gravity on this physiological control system by examining changes in rhythmic characteristics of organisms exposed to altered gravitational environments. The altered gravitational environments have included the microgravity of spaceflight as well as hyperdynamic fields produced via centrifugation.     

Epithelial polarity and tubulogenesis in vitro

The most fundamental type of organization of cells in metazoa is that of epithelia, which comprise sheets of adherent cells that divide the organism into topologically and physiologically distinct spaces. Some epithelial cells cover the outside of the organism; these often form multiple layers, such as in skin. Other epithelial cells form monolayers that line internal organs, and yet others form tubes that infiltrate the whole organism, carrying liquids and gases containing nutrients, waste and other materials. These tubes can form elaborate networks in the lung, kidney, reproductive passages and vasculature tree, as well as the many glands branching from the digestive system such as the liver, pancreas and salivary glands. In vitro systems can be used to study tube formation and might help to define common principles underlying the formation of diverse types of tubular organ.     

Role of the neuroendocrine system in aging

The study involves 3 aspects of neuroendocrine control over the organism functions in aging: the decline in reproductive functions, the reduction of growth hormone secretion and the decrease in thymic functional activity and the altered relationship between neuroendocrine and immune systems. The role that an age-related decrease in dopamine and noradrenaline production by hypothalamic neurones plays in the above age changes in neuroendocrine control has been traced. The age-related decrease in functions of hypothalamic catecholaminergic neurones is apparently caused by the damaging effect of hormones (prolactin, glucocorticoids and, especially, estrogen), free radicals and toxins, both of the endogenous and exogenous origin. The restrained nutrition increases lifespan of the experimental animal owing to reduced "wear out" of the neuroendocrine system and organs and tissues that are controlled by this system.     

Circadian Rhythms and Masking: An Overview

Masking, as is well known, enables an organism to act immediately and in an appropriate way to changes of the environment, integrating with internally produced rhythmicity. It now appears that masking can be used to cover a far wider range of problems than was originally intended. To separate masking effects from the effects due to an internal oscillator, several techniques have been used. Such protocols, however, like the constant routine protocol, often replace one form of masking by another. The situation becomes even more complex when one realizes that the output of an internal oscillator modifies the input. The question might be asked whether it is possible to study the properties of the internal oscillator in vivo at all. This article attempts to produce a framework for future discussions.     

Circadian Rhythms and Masking: An Overview

Masking, as is well known, enables an organism to act immediately and in an appropriate way to changes of the environment, integrating with internally produced rhythmicity. It now appears that masking can be used to cover a far wider range of problems than was originally intended. To separate masking effects from the effects due to an internal oscillator, several techniques have been used. Such protocols, however, like the constant routine protocol, often replace one form of masking by another. The situation becomes even more complex when one realizes that the output of an internal oscillator modifies the input. The question might be asked whether it is possible to study the properties of the internal oscillator in vivo at all. This article attempts to produce a framework for future discussions.     

Biocultural Interaction and the Mechanism of Mosaic Evolution in the Emergence of "Modern" Morphology

"Modern" human form results from reduction in both craniofacial and postcranial Middle Pleistocene levels of robustness. In a classic manifestation of mosaic evolution, these reductions began at different times and proceeded at different rates in different places. They were produced by mutations acting alone when particular cultural developments eased the forces of selection. The separate regional appearances of obligatory cooking and projectile use late in the Middle Pleistocene produced separate and predictable manifestations of morphological reduction. There is no common "modern" configuration, and no single geographic locale was responsible for the various aspects of reduction that contribute to "modern" morphology.     

Effects of stimulated physical activity on the circadian pacemaker of vertebrates

A dogma in the field of circadian rhythms is that in order to keep accurate time, pacemakers that generate such rhythms must be relatively independent of changes in the external and internal environment. While it is true that the period of circadian oscillators is conserved within a narrow range, regardless of alterations in the external and internal environment, numerous perturbations have now been found that can change the period and/or induce a phase shift in circadian pacemakers. Many of these perturbations also alter the overall level of activity and/or metabolic state of the organism. In 1960, Aschoff suggested that alterations in the "level of excitement" may induce changes in circadian clocks. Although little attention has been given to this hypothesis over the past three decades, recent findings support its validity and open new avenues for studying the function and organization of circadian clock systems.     

Behavioral neuroendocrinology in nontraditional species of mammals: things the 'knockout' mouse CAN'T tell us

The exploration of many of the fundamental features of mammalian behavioral neuroendocrinology has benefited greatly throughout the short history of the discipline from the study of highly inbred, genetically characterized rodents and several other "traditional" exemplars. More recently, the impact of genomic variation in the determination of complex neuroendocrine and behavioral systems has advanced through the use of single and multiple gene knockouts or knockins. In our essay, we argue that the study of nontraditional mammals is an essential approach that complements these methodologies by taking advantage of allelic variation produced by natural selection. Current and future research will continue to exploit these systems to great advantage and will bring new techniques developed in more traditional laboratory animals to bear on problems that can only be addressed with nontraditional species. We highlight our points by discussing advances in our understanding of neuroendocrine and behavioral systems in phenomena of widely differing time scales. These examples include neuroendocrine variation in the regulation of reproduction across seasons in Peromyscus, variation in parental care by biparental male rodents and primates within a single infant rearing attempt, and circadian variation in the regulation of the substrates underlying mating in diurnal vs. nocturnal rodents. Our essay reveals both important divergences in neuroendocrine systems in our nontraditional model species, and important commonalities in these systems.     

Evolution of invertebrate homeostasis: Osmotic and ionic regulation

• 1.1. Homeostasis, or the maintenance of a constant internal environment, in invertebrate organisms decreases the dependence of these organisms on the vagaries of the external environment.
• 2.2. The evolution of physiological processes influencing homeostatic conditions begins with the organism being totally dependent upon the external environment, passing through a series of intermediate stages during which fluctuation in a given internal parameter occur, proceeding finally to a condition where the internal environment is constant and independent of the external environment.
• 3.3. A hypothetical scheme for the possible evolutionary pathway of osmotic and ionic regulation in aquatic invertebrates was developed in an attempt to follow the process of homeostasis in these organisms.
• 4.4. Primitive marine cells developed mechanisms to regulate the ionic composition of the cytoplasm probably in association with the need for volume regulation.
• 5.5. The development of a body wall separated an internal body fluid from the external sea-water and the ionic composition of the body fluids was initially maintained slightly different from that of the sea-water by essentially passive means.
• 6.6. The addition of excretory organs, which arose initially through an inpushing of the body wall, brought about the ability for osmoregulation.
• 7.7. Homeostatic mechanisms must be in place before an organism can move from one environment to another.

     

Role of epithelial cells in initiation and propagation of intestinal inflammation. Eliminating the static: tight junction dynamics exposed

Like all mucosal surfaces, the intestine forms a barrier that separates the external environment, i.e., the gut lumen, from the protected internal milieu. The intestinal barrier is formed by the epithelial cells that line the luminal surface. Plasma membranes of these cells prevent free passage of hydrophilic molecules across this barrier but do not seal the space between cells. This function is provided by the tight junction. Each cell is encircled at the apicolateral boundary by the tight junction, which seals the paracellular space. The tight junction does not form a completely impermeant seal, however, because that would prevent paracellular absorption of essential nutrients and ions; intestinal tight junctions are "leaky" and allow solutes to be transported paracellularly according to size and charge. Abundant data are available to demonstrate that barrier properties of tight junctions can be modulated in response to physiological, pharmacological, and pathophysiological stimuli, but the structural modifications responsible for these responses are poorly defined. Recent advances in understanding the role of tight junction dynamics in response to such stimuli are the focus of this review.     

Interaction of preparation "ATP-LONG" with distearoylphosphatidylcholine monolayer

Interaction of ATP and its derivative "ATP-LONG", the preparations raising general resistanse of an organism to physical stress, with the model phospholipid monolayer membrane of distearoylphosphatidylcholine has been investigated. It is shown, that these substances interact with a monolayer under partial embedding of a purine base between the phospholipid molecules. However their regulatory influence cannot be explained only by the effect of plasmatic membrane lipid components on physical parameters.     

Organization of the Rosy Locus in DROSOPHILA MELANOGASTER: Further Evidence in Support of a CIS-Acting Control Element Adjacent to the Xanthine Dehydrogenase Structural Element

The present report summarizes our recent progress in the genetic dissection of an elementary genetic unit in a higher organism, the rosy locus (ry:3--52.0) in Drosophila melanogaster. Pursuing the hypothesis that the rosy locus includes a noncoding control region, as well as a structural element coding for the xanthine dehydrogenase (XDH) peptide, experiments are described that characterize and map a rosy locus variant associated with much lower than normal levels of XDH activity. Experiments are described that fail to relate this phenotype to alteration in the structure of the XDH peptide, but clearly associate this character with variation in number of molecules of XDH per fly. Large-scale fine-structure recombination experiments locate the genetic basis for this variation in the number of molecules of XDH per fly to a site immediately to the left of the XDH structural element within a region previously designated as the XDH control element. Moreover, experiments clearly separate this "underproducer" variant site from a previously described "overproducer" site within the control region. Examination of enzyme activity in electrophoretic gels of appropriate heterozygous genotypes demonstrates the cis-acting nature of this variation in the number of molecules of XDH. A revision of the map of the rosy locus, structural and control elements is presented in the light of the additional mapping data now available.     

Bacterial virulence as a target for antimicrobial chemotherapy

As bacterial resistance to currently used antibiotics increases, so too must efforts to identify novel agents and strategies for the prevention and treatment of bacterial infection. In the past, antimicrobial drug discovery efforts have focused on eradicating infection by either cidal or static agents, resulting in clearance of the bacterium from the infected host. To this end, drug discovery targets have been those proteins or processes essential for bacterial cell viability. However, inhibition of the interaction between the bacterium and its host may also be a target. During establishment of an infection, pathogenic bacteria use carefully regulated pathways of conditional gene expression to transition from a free-living form to one that must adapt to the host milieu. This transition requires the regulated production of both extracellular and cell-surface molecules, often termed virulence factors. As the biological imperatives of the invading organism change during the course of an infection, the expression of these factors is altered in response to environmental cues. These may be changes in the host environment, for example, pH, metabolites, metal ions, osmolarity, and temperature. Alternatively, effector molecules produced by the bacterium to sense changing cell density can also lead to changes in virulence gene expression. Although the mechanisms of pathogenesis among different bacteria vary, the principles of virulence are generally conserved. Bacterial virulence may therefore offer unique opportunities to inhibit the establishment of infection or alter its course as a method of antimicrobial chemotherapy.