Interrelated mechanisms in reward and learning

This brief review is focused on recent work in our laboratory, in which we assayed nicotine-induced neurotransmitter changes, comparing it to changes induced by other compounds and examined the receptor systems and their interactions that mediate the changes. The primary aim of our studies is to examine the role of neurotransmitter changes in reward and learning processes. We find that these processes are interlinked and interact in that reward-addiction mechanisms include processes of learning and learning-memory mechanisms include processes of reward. In spite being interlinked, the two processes have different functions and distinct properties and our long-term aim is to identify factors that control these processes and the differences among the processes. Here, we discuss reward processes, which we define as changes examined after administration of nicotine, cocaine or food, each of which induces changes in neurotransmitter levels and functions in cognitive areas as well as in reward areas. The changes are regionally heterogeneous and are drug or stimulus specific. They include changes in the transmitters assayed (catecholamines, amino acids, and acetylcholine) and also in their metabolites, hence, in addition to release, uptake and metabolism are involved. Many receptors modulate the response with direct and indirect effects. The involvement of many transmitters, receptors and their interactions and the stimulus specificity of the response indicated that each function, reward and learning represents the involvement of different pattern of changes with a different stimulus, therefore, many different learning and many different reward processes are active, which allow stimulus specific responses. The complex pattern of reward-induced changes in neurotransmitters is only a part of the multiple changes observed, but one which has a crucial and controlling function.     

Kidney atrophy vs hypertrophy in diabetes: which cells are involved?

One of the first structural changes in diabetic nephropathy (DN) is the renal enlargement. These changes resulted in renal hypertrophy in both glomerular and tubular cells. Shrink in the kidney size, which described as kidney atrophy resulted from the loss of nephrons or abnormal nephron function and lead to loss of the kidney function. On the other hand, increase in kidney size, which described as hypertrophy resulted from increase in proximal tubular epithelial and glomerular cells size. However overtime, tubular atrophy and tubulointerstitial fibrosis occurs as subsequent changes in tubular cell hypertrophy, which is associated with the infiltration of fibroblast cells into the tubulointerstitial space. The rate of deterioration of kidney function shows a strong correlation with the degree of tubulointerstitial fibrosis. A consequence of long-standing diabetes/hyperglycemia may lead to major changes in renal structure that occur but not specific only to nephropathy. Identifying type of cells that involves in renal atrophy and hypertrophy may help to find a therapeutic target to treat diabetic nephropathy. In summary, the early changes in diabetic kidney are mainly includes the increase in tubular basement membrane thickening which lead to renal hypertrophy. On the other hand, only renal tubule is subjected to apoptosis, which is one of the characteristic morphologic changes in diabetic kidney to form tubular atrophy at the late stage of diabetes.     

Transport changes associated with growth control and malignant transformation.

We can distinguish two classes of membrane transport changes in cultured cells: (a) growth-rate contingent changes are those which occur in coordination with the onset of density-dependent inhibition of growth; (b) transformation-specific changes are those which occur when cells become transformed, and which can be detected even when normal and transformed cells are growing at the same rate. Growth-rate contingent changes include the density-dependent changes in phosphate, nucleoside, glucose, amino acid, and potassium transport. Only one transformation-specific transport change has been found in Rous-transformed chicken embryo fibroblasts: an increased rate of hexose transport. The variation in potassium transport are associated with variations in the number of ouabain binding sites in the membrane. The molecular basis for changes in the rate of hexose transport is unknown, although gross changes in membrane bilayer composition and "fluidity" seem not to be involved. In analyzing the regulation of hexose transport activity, we find that decreased cAMP may play a role in the transformation-specific increase in hexose transport, but that fibrinolytic activity is not necessary.     

Components involved in virally mediated membrane fusion and permeability changes.

1. Intact F glycoprotein is required to induce permeability changes in Lettrée cells or in erythrocytes. Some HN glycoproteins may also be required. Permeability changes thus offer a simple, accurate and rapid means of assaying the integrity of F glycoprotein in certain viral preparations. 2. The '1-day' virus (which contains intact F glycoprotein but which differs morphologically from '3 day' virus) does not cause permeability changes; it can be rendered active by various physical treatments. It is concluded that the environment in which F glycoprotein is embedded is a determining factor for permeability changes. 3. The entry of fluorescently labelled peptides into cells made permeable by virus has been measured. Peptides having a molecular weight in excess of 1000 enter poorly, suggesting a 'pore' size of approx. 1 nm in diameter. 4. Two novel assay methods concerned with virus--cell fusion are described. The first measures the fluorescence enhancement that occurs when anthroylstearate is transferred from anthroylstearate-labelled virus to cells. The second measures the giant-cell formation that occurs when partially fused erythrocytes are exposed to hypo-osmotic treatment. The '1-day' virus is active in these assays. In contrast with permeability changes, virus--cell fusion is insensitive to changes in external Ca2+-concentration. 5. The results are compatible with a model [Knutton & Pasternak (1979) Trends Biochem. Sci. 4, 220--223; Impraim, Foster, Micklem & Pasternak (1980) Biochem. J. 186, 847--860] in which virus--cell fusion is a prerequisite for permeability changes, and in which permeability changes are the cause of haemolysis and giant-cell (polykaryon) formation.     

Activity-dependent regulation of HCN pacemaker channels by cyclic AMP: signaling through dynamic allosteric coupling

Signal transduction in neurons is a dynamic process, generally thought to be driven by transient changes in the concentration of second messengers. Here we describe a novel regulatory mechanism in which the dynamics of signaling through cyclic AMP are mediated by activity-dependent changes in the affinity of the hyperpolarization-activated, cation nonselective (HCN) channels for cAMP, rather than by changes in cAMP concentration. Due to the allosteric coupling of channel opening and ligand binding, changes in cellular electrical activity that alter the opening of the HCN channels modify the binding of static, basal levels of cAMP. These changes in ligand binding produce long-lasting changes in channel function which can contribute to the regulation of rhythmic firing patterns.     

Oscillations of calcium ion concentrations in Physarum polycephalum

Aequorin is a photoprotein which emits light in response to changes in free calcium concentration. When aequorin was microinjected into plasmodia of Physarum polycephalum, light emission varied in synchrony with the motile oscillations of the organisms. Therefore, movement is correlated which changes in the concentration of free calcium.     

The Influence of Aging on Skin and Oral Mucosa1

Although the skin of the elderly shows many clinically obvious changes such as wrinking, dryness and patchy pigmentation it is difficult to determine to what extent extrinsic factors are responsible. On the other hand the mucosa lining the mouth which is exposed to a different environment has been claimed to show many similar clinical changes. The literature describing age-associated cellular changes is replete with conflicting reports. This is compounded by confusion of what constitutes “old”. There is no consensus on age-associated changes of fundamental attributes such as epithelial thickness, rates of tissue turnover or metabolic activity. Studies being carried out by the author suggest that there are few structural changes which occur in all surface epithelia with age but glycolytic activity is significantly increased. Ultrastructurally, significant quantities of fine fibrillar material have been observed to be associated with the basement membrane of oral epithelium, blood vessels and nerve bundles in the cheek. It is concluded that structural and functional changes that occur in skin and mucosa with age have not yet been defined adequately and further research is necessary in this area.     

Can macaroni penguins keep up with climate- and fishing-induced changes in krill?

Macaroni penguins have evolved to cope with the highly variable conditions of the Southern Ocean. However, changes in prey supply and patchiness potentially associated with changes in climate and krill fishing activity may be occurring too rapidly for the penguins to adapt. We use a stochastic dynamic programming model to examine how changes in both the mean and patchiness of krill supply may affect the foraging decisions, and therefore breeding success, of female macaroni penguins at South Georgia. We predict that rapid changes in the mean supply of prey will have more of an effect on the condition of the female and chick than changes in prey patchiness, and that changes in foraging behavior compensate for changes in prey up to a threshold point, beyond which breeding success is likely impacted. In particular, we predict that the location of the threshold is affected by whether or not the penguins are adapted to the prey environment in which they are foraging, with the female and chick receiving on average 20% less of their daily energetic requirement if the female is not foraging optimally.     

Constitutive activation of angiotensin II type 1 receptor alters the orientation of transmembrane Helix-2

A key step in transmembrane (TM) signal transduction by G-protein-coupled receptors (GPCRs) is the ligand-induced conformational change of the receptor, which triggers the activation of a guanine nucleotide-binding protein. GPCRs contain a seven-TM helical structure essential for signal transduction in response to a large variety of sensory and hormonal signals. Primary structure comparison of GPCRs has shown that the second TM helix contains a highly conserved Asp residue, which is critical for agonist activation in these receptors. How conformational changes in TM2 relate to signal transduction by a GPCR is not known, because activation-induced conformational changes in TM2 helix have not been measured. Here we use modification of reporter cysteines to measure water accessibility at specific residues in TM2 of the type 1 receptor for the octapeptide hormone angiotensin II. Activation-dependent changes in the accessibility of Cys76 on TM2 were measured in constitutively activated mutants. These changes were directly correlated with measurement of function, establishing the link between physical changes in TM2 and function. Accessibility changes were measured at several consecutive residues on TM2, which suggest that TM2 undergoes a transmembrane movement in response to activation. This is the first report of in situ measurement of TM2 movement in a GPCR.     

Pressure-induced changes in the solution structure of the GB1 domain of protein G

The solution structure of the GB1 domain of protein G at a pressure of 2 kbar is presented. The structure was calculated as a change from an energy-minimised low-pressure structure using (1)H chemical shifts. Two separate changes can be characterised: a compression/distortion, which is linear with pressure; and a stabilisation of an alternative folded state. On application of pressure, linear chemical shift changes reveal that the backbone structure changes by about 0.2 A root mean square, and is compressed by about 1% overall. The alpha-helix compresses, particularly at the C-terminal end, and moves toward the beta-sheet, while the beta-sheet is twisted, with the corners closest to the alpha-helix curling up towards it. The largest changes in structure are along the second beta-strand, which becomes more twisted. This strand is where the protein binds to IgG. Curved chemical shift changes with pressure indicate that high pressure also populates an alternative structure with a distortion towards the C-terminal end of the helix, which is likely to be caused by insertion of a water molecule.     

Physical characteristics in the new model of the cerebrospinal fluid system

It is unknown which factors determine the changes in cerebrospinal fluid (CSF) pressure inside the craniospinal system during the changes of the body position. To test this, we have developed a new model of the CSF system, which by its biophysical characteristics and dimensions imitates the CSF system in cats. The results obtained on a model were compared to those in animals observed during changes of body position. A new model was constructed from two parts with different physical characteristics. The "cranial" part is developed from a plastic tube with unchangeable volume, while the "spinal" part is made of a rubber baloon, with modulus of elasticity similar to that of animal spinal dura. In upright position, in the "cranial" part of the model the negative pressure appears without any measurable changes in the fluid volume, while in "spinal" part the fluid pressure is positive. All of the observed changes are in accordance to the law of the fluid mechanics. Alterations of the CSF pressure in cats during the changes of the body position are not significantly different compared to those observed on our new model. This suggests that the CSF pressure changes are related to the fluid mechanics, and do not depend on CSF secretion and circulation. It seems that in all body positions the cranial volume of blood and CSF remains constant, which enables a good blood brain perfusion.     

Rac recruits high-affinity integrin alphavbeta3 to lamellipodia in endothelial cell migration

Integrin alphavbeta3 has an important role in the proliferation, survival, invasion and migration of vascular endothelial cells. Like other integrins, alphavbeta3 can exist in different functional states with respect to ligand binding. These changes involve both affinity modulation, by which conformational changes in the integrin heterodimer govern affinity for individual extracellular matrix proteins, and avidity modulation, by which changes in lateral mobility and integrin clustering affect the binding of cells to multivalent matrices. Here we have used an engineered monoclonal antibody Fab (antigen-binding fragment) named WOW-1, which binds to activated integrins alphavbeta3 and alphavbeta5 from several species, to investigate the role of alphavbeta3 activation in endothelial cell behaviour. Because WOW-1 is monovalent, it is insensitive to changes in integrin clustering and therefore reports only changes in affinity. WOW-1 contains an RGD tract in its variable region and binds only to unoccupied, high-affinity integrins. By using WOW-1, we have identified the selective recruitment of high-affinity integrins as a mechanism by which lamellipodia promote formation of new adhesions at the leading edge in cell migration.     

Micro-evolution and emergence of pathogens

Changes in the epidemiology of infectious diseases are the direct result of ecological and evolutionary changes in hosts and parasites. Precisely what the causal processes are is rarely known in any particular case, and this hinders the design of appropriate control strategies. This is particularly so for emerging infections, as opportunity is rapidly lost to study the ecological parameters which might have affected initial emergence. However, molecular evolutionary studies of the pathogens can yield data which discriminate between possible causes. The current distribution of DNA sequence variation is important information which may reveal past and current changes in pathogen population structures, and can also identify adaptive changes in pathogen genes which have affected their evolution. Such studies have been quite intensively performed on particular viral and bacterial pathogens, and some of the successes of these are noted here. Approaches to understanding the recent evolution of eukaryotic pathogens are outlined, with particular reference to current problems of emerging zoonoses, and changes in virulence and drug resistance.     

Changes in platelet membrane glycoproteins during blood bank storage.

The literature on membrane glycoprotein changes occurring during platelet storage is reviewed. Technical problems which may have biased reports are clarified, and the consensus of current studies is established. The membrane alterations that occur during blood bank storage are reminiscent of the surface changes which result from platelet secretion: an increased surface concentration of GP IIb-IIIa and GMP-140, and the appearance of platelet membrane microparticles in the supernatant plasma. The clinical importance of these changes is unknown. Future directions for research on the structure and function of stored platelets are discussed.     

Relationships between embolism,stem water tension,and diameter changes

A model for embolism in the sapflow process was developed, in which embolism is described as a physical process linked to real physical properties of the conduits and the thermodynamic state of water. Different mechanisms leading to embolism and their effect on water relations and especially diurnal diameter changes in a tree were examined. The mechanisms of heterogeneous nucleation, air-seeding, and bubble growth have been considered. The significance of embolism has been revealed here by examining diameter changes, which is an easily measurable quantity under field conditions. The most fundamental effects of embolism on sapflow are decrease in permeability and release of water from embolizing conduits to the transpiration stream. These can be indirectly detected by observing diameter changes. If possible changes in elasticity are not accounted for, embolism generally tends to enhance the amplitude of the diurnal diameter changes due to reduced permeability and increased tensions. In the case of reduced elasticity, embolism gives rise to smaller amplitudes of diameter changes.     

Loss of sensory input causes rapid structural changes of inhibitory neurons in adult mouse visual cortex

A fundamental property of neuronal circuits is the ability to adapt to altered sensory inputs. It is well established that the functional synaptic changes underlying this adaptation are reflected by structural modifications in excitatory neurons. In contrast, the degree to which structural plasticity in inhibitory neurons accompanies functional changes is less clear. Here, we use two-photon imaging to monitor the fine structure of inhibitory neurons in mouse visual cortex after deprivation induced by retinal lesions. We find that a subset of inhibitory neurons carry dendritic spines, which form glutamatergic synapses. Removal of visual input correlates with a rapid and lasting reduction in the number of inhibitory cell spines. Similar to the effects seen for dendritic spines, the number of inhibitory neuron boutons dropped sharply after retinal lesions. Together, these data suggest that structural changes in inhibitory neurons may precede structural changes in excitatory circuitry, which ultimately result in functional adaptation following sensory deprivation.     

Consideration of the importance of measuring thermal discomfort in biomedical research

Core temperature stability is the result of a dynamically regulated balance of heat loss and gain, which is not reflected by a simple thermometer reading. One way in which these changes manifest is in perceived thermal comfort, ‘feeling too cold’ or ‘feeling too hot’, which can activate stress pathways. Unfortunately, there is surprisingly little preclinical research that tracks changes in perceived thermal comfort in response to either disease progression or various treatments. Without measuring this endpoint, there may be missed opportunities to evaluate disease and therapy outcomes in murine models of human disease. Here, we discuss the possibility that changes in thermal comfort in mice could be a useful and physiologically relevant measure of energy trade-offs required under various physiological or pathological conditions.     

Biochemical differences in the reactions of visual cortex neurons to deprivation]

Early visual deprivation was interferometrically shown to entail changes in the concentration and contents of the protein substance with simultaneous changes of the neurons size. The changes are statistically significant in the lamina V and not in the laminasIII and IV. The changes in each lamina are associated with definite group of the neurons the development of which is, probably, determined by visual stimuli.     

The role of Ca2+-dependent biochemical changes in the ageing process in normal red cells and in the development of irreversibly sickled cells

During the ageing process of normal red cells and in the formation of irreversibly sickled cells (ISCs) there is a progressive increase in the intracellular concentration of Ca2+. This is parallelled by the development of a variety of morphological and biochemical changes in older fractions of normal cells and in ISCs which are similar to those seen in normal cells exposed to Ca2+ ionophore. These changes include cell shrinkage, loss of membrane lipid and degradation of cytoskeletal proteins and polyphosphoinositides. In this paper we consider the ways in which the Ca2+-dependent biochemical changes may be related to the morphological alterations which are characteristic of ageing and irreversible sickling.