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Renal blood flow in the conscious, unrestrained ratGrady, Heather January 1989 (has links)
The aim of this project is to test the hypothesis that the rate of renal blood flow remains constant under normal physiological conditions. Methods were developed for long term studies of renal blood flow (using the Doppler flow probe) and blood pressure in the conscious unrestrained rat. Special care was taken to maintain and observe the rats under normal, physiological conditions. Since the Doppler flow probe measures blood velocity rather than flow, changes in renal arterial diameter will alter the output of the flow meter, even if flow is constant. In order to measure flow more accurately, chanqes in vessel diameter were prevented by a short length of silastic tubing inserted into the renal, ortery under the probe. Blood flow was expressed as a percentage of the maximal flow measured when the animal was completely relaxed. Using this preparation, renal blood flow was measured continuously under normal conditions in both the light and dark cycles. Studies were performed to assess the effects on renal blood flow of anaesthesia, surgery and stress, and to assess the effect on renal blood flow of blockade of the renal nerves. Renal blood flow was depressed approximately 50% by anaesthesia, due to the effects of the anaesthetic agent rather than the accompanying surgery. Renal blood flow did not fully recover for 3-4 days after anaesthesia with, or without surgery. Renal blood flow was depressed by stress, even though blood pressure was unchanged. A mild sudden auditory disturbance caused a transient 23% fall in renal blood flow. A continuous auditory disturbance, depressed renal blood flow by 16% for several minutes. Handling the rat resulted in a 33% fall in renal blood flow which lasted for over 30 minutes. When measured continuously, renal blood flow was found to vary considerably. When the rat was completely relaxed renal blood flow was highest (defined as 100%). Renal blood flow remained high when eating and drinking (79%), but fell when the rat became alert but completely still (74%). During general movement renal blood flow was low (73%) with flow lowest while grooming (64%). Flow was apparently related to the degree of alertness and to activity. The extent of variation of flow is such that the calculated mean daily value of renal blood flow was only 80% of the maximum flow observed during complete relaxation. The depression of renal blood flow seen during activity and disturbance was largely prevented during reversible blockade of the ipsilateral renal nerve, induced by slow infusion of xylocaine around the renal artery. It was completely abolished by bilateral renal nerve blockade with Xylocaine. The depressive effects of activity and disturbance on renal blood flow were restored an hour after the Xylocaine infusion ceased. These studies clearly show that renal nerve is involved in control of renal blood flow under physiological conditions. It is clear that renal blood flow varies markedly under normal physiological conditions and in response to the external environment. A constant renal blood flow is not a necessity for normal renal function.
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Sympathetic neural control of renal blood flowLeonard, Bridget Louise January 2001 (has links)
Renal sympathetic nerve activity (RSNA) plays an important role in the control of renal hemodynamics and function. It achieves this control by changing the mean levels of activity and/or changing the power of the distinct frequencies that comprise this mean activity. My studies, presented in four parts, investigate how total renal blood flow (RBF) and intrarenal blood flow are controlled by these changes in RSNA. While RSNA and RBF both show oscillations at various frequencies, the functional significance and regulation of these oscillations is not well understood. To establish whether the strength of these oscillations is under differential control I measured the frequency spectrum of RSNA and RBF following volume expansion in conscious rabbits. At least 6 days prior to experiments animals underwent surgery to implant an electrode for recording renal nerve activity and a flow probe for recording RBF. Volume expansion resulted in a 25 ± 5% decrease in mean RSNA, paralleled by an increase in RBF. Renal denervated rabbits did not show an increase in RBF with volume expansion. Spectral analysis of the different frequencies in RSNA showed oscillations in RSNA between 0.2 to 0.4 Hz were selectively decreased following volume expansion (14 ± 3 to 6±1% of total power in RSNA at < 3Hz). A corresponding decrease in the strength of oscillations in RBF at this frequency was also seen (20 ± 6 to 8 ± 2%). In contrast the strength of respiratory (0.8 to 2.0 Hz) and cardiac (3 to 6 Hz) related rhythms did not change with volume expansion. These results show that selective changes in the different frequency components of RSNA can occur. While RSNA plays a significant role in the regulation of RBF, little is known about the role renal nerves may play in the control of regional kidney blood flows i.e. cortical and medullary blood flow (CBF and MBF respectively). This is an important question as the control of blood flow to the renal medulla has been shown to be critical in the long-term control of arterial pressure, chiefly through its influence on tubular reabsorption of salt and water. If renal nerves are involved in the control of medullary blood flow then they may also have a role in long-term arterial pressure regulation. My aim was to investigate the role RSNA may have in the regulation of both CBF and MBF. In a series of experiments, using pentobarbitone anaesthetized rabbits, I electrically stimulated the renal nerves whilst simultaneously recording RBF, CBF, and MBF. Three sequences of stimulation were applied, 1) varying the amplitude of stimulation, 2) varying the frequency of stimulation and 3) stimulation with a modulated sinusoidal pattern which allows determination of the frequency response characteristics of each flow. Increasing amplitude or frequency of stimulation progressively decreased all flow variables. RBF and CBF responded similarly, but MBF responded less. For example, 0.5 V stimulation decreased CBF by 20 ± 9% but MBF fell by only 4 ± 6%. The amplitude of oscillations in all flow variables was progressively reduced as the frequency of sinusoidal stimulation was increased. An increased amplitude of oscillation was observed at 0.12 and 0.32 Hz in MBF, and to a lesser extent RBF, but not CBF. MBF therefore appears to be less sensitive than CBF to the magnitude of RSNA, but more able to respond to these higher frequencies of neural stimulation. These results show that regional renal blood flows may be differentially regulated by RSNA and indicate a role for RSNA in the control of MBF. To further investigate the effects of RSNA on intrarenal blood flow I performed another series of experiments in which I reflexly increased RSNA while simultaneously recording CBF and MBF. I exposed pentobarbitone anesthetized, artificially ventilated rabbits to graded reductions in inspired 02 content. A separate group of animals with denervated kidneys underwent the same protocol. Graded hypoxia (16, 14, 12 and 10% inspired 02) progressively reduced arterial 02 partial pressure and increased RSNA (by 8 ± 3, 44 ± 25, 62 ± 21 and 76 ± 37% respectively compared with air) without affecting MAP. This was accompanied by progressive reductions in CBF (by 2 ± 1, 5 ± 2, 11 ± 3 and 14 ± 2% respectively) in intact but not denervated rabbits. MBF was unaffected by hypoxia in either group. Thus, reflex increases in RSNA cause renal cortical vasoconstriction, but not at vascular sites regulating MBF. Taken together results from both these studies provide strong evidence that MBF is less sensitive to the vasoconstrictor influence of RSNA than is CBF. However, larger, chronic increases in RSNA, such as occur in heart failure, could be associated with decreases in MBF. This may implicate RSNA in the long-term control of arterial pressure. The 0.3 Hz oscillation in RSNA, and thus MAP, is intermittent in its presence. In a final series of experiments I studied the underlying reasons for the presence or absence of the 0.3 Hz oscillation. Using conscious animals I studied the oscillation under a range of sympathetic stimulants. I was unable to induce an oscillation in MAP at 0.3 Hz and propose reasons for this. To allow further analysis, I performed a second set of experiments in which I induced the oscillation in RBF by electrical stimulation of the aortic depressor nerve. I found that large amplitude oscillations in baroreceptor stimulation were required to induce oscillations in RBF and MAP. I speculate on what this may tell us about the nature of the slow oscillation.
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Characterisation of ryanodine receptor expression in the rat cochleaMorton-Jones, Rachel January 2007 (has links)
Increases in intracellular Ca2+ play a central role in cochlear function. The ryanodine receptor (RyR) intracellular Ca2+ release channel, a ubiquitous element of Ca2+ signalling, has been implicated in the regulation of sound transduction and auditory neurotransmission. Despite this, the molecular basis underlying RyR-mediated Ca2+ signalling in the cochlea has been limited. This thesis investigates the molecular and functional characterisation of RyR expression in the cochlea. RT-PCR analysis showed expression of RyR1, RyR2 and RyR3 isoform mRNA transcripts in the rat cochlea and also in the spiral ganglion. Localisation of RyR protein revealed differential expression of these isoforms in the cochlea. Strong RyR immunolabelling for RyR1, RyR2 and RyR3 were detected in the spiral ganglion neuron (SGN) cell bodies. RyR3 labelling extended to the synaptic terminals innervating the inner and outer hair cells. RyR2 expression also occurred in the inner hair cells and supporting cells of the organ of Corti. Cells associated with ion homeostasis in the cochlea were also labelled, including RyR1 in spiral limbus interdental cells, and RyR2 and RyR3 in spiral prominence epithelial cells and stria vascularis basal cells. In the SGN cell bodies, confocal imaging of Ca2+ store release confirmed the presence of a functional RyR-gated Ca2+ store. Superfusion of glutamate and α-amino-3-hydroxy-5-methyl-4-isoxazole propionic acid (AMPA) evoked large Ca2+ responses in the SGN cell bodies that were dependent upon Ca2+ entry. However, subsequent depletion of SGN RyR-gated Ca2+ stores substantially reduced the glutamate- and AMPA-induced Ca2+ responses, demonstrating that the majority of the Ca2+ signal derived from RyR-gated Ca2+ stores via Ca2+ -induced Ca2+ release. Involvement of the AMPA/Kainate-type glutamate receptor was confirmed by elimination of glutamate- and AMPA-induced Ca2+ responses with an AMPA/Kainate receptor antagonist. These findings support a role for RyR in the regulation of auditory neurotransmission, sound transduction and cochlear electrochemical homeostasis. These data also demonstrate coupling between somatic AMPA-type glutamate receptors and RyR-gated Ca2+ stores, which is likely to influence auditory neurotransmission. / Whole document restricted, but available by request, use the feedback form to request access.
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Gap junctions in the lens: is location everything?Sisley, Aran Mathew George January 2007 (has links)
The primary function of the ocular lens is as a light-focusing structure. To this end the lens is avascular, with a highly ordered arrangement of cells that acts to reduce light scattering. However, the avascular nature of the lens presents the problem of supplying cells deep within the lens with nutrients and removing waste products of cellular metabolism, i.e. maintaining cellular homeostasis, To solve this problem the lens possesses intercellular channels, called gap junctions, that facilitate cell-to-cell communication and are regulated by changes in the subcellular distribution and age dependent processing of the gap junction protein subunits, called connexins. The lens expresses three types of connexins (Cx): Cx43 in the anterior surface epithelial cells and connexins 46 and 50 in the fibre cells. Therefore, to fully examine the role of GJs in lens homeostasis, regional differences in GJ structure and function need to be quantified. In this thesis I present the results of experiments designed to map the differentiation dependent changes to subcellular distribution and posttranslational processing of Cx46 and Cx50 in mouse and rat lenses. My results quantitatively show for the first time that Cx50 undergoes two discrete cleavage events in a similar manner to that previously shown for Cx46, and that qualitatively Cx46 does the same in the mouse lens' Such posttranslational processing has important effects on the proposed lens circulation model (Mathias et al., 1997) that accounts for lens homeostasis. In addition, I have examined the functional contribution of gap junctions to localized intercellular communication in different regions of wildtype and Cx46-KO mouse lenses, using highly localised uncaging of fluorescein with Two-Photon Excited Flash Photolysis (TPEFP) in half lenses, The results of these experiments have provided the first supporting evidence for a macromolecule-permeable pathway, previously suggested by Shestoplaov and Bassnett (2000, 2003), that acts in conjunction with gap junctions to facilitate intercellular communication in the lens core. My results show that this pathway acts at a localised level to confer cell-to-cell communication that is as effective as that mediated by gap junctions, and therefore a re-evaluation of current models of lens homeostasis is now required. / Whole document restricted, but available by request, use the feedback form to request access.
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Myocardial force and intracellular Ca2+ in an animal model of hypertensive heart failureWard, Marie-Louise January 2003 (has links)
Hypertensive heart failure has long been associated with diminished cardiac contractile function, yet the underlying cellular mechanisms are not well understood. The aim of this Thesis was to investigate the relationship between intracellular calcium ([Ca2+]i) and isometric force during the relatively narrow time frame in which long-standing compensated hypertrophy progresses to decompensated end-stage heart failure in an animal model of human essential hypertension. In order to carry out this aim, left ventricular trabeculae were utilized from failing hearts of spontaneously hypertensive rats (SHR) and their normotensive Wistar-Kyoto (WKY) controls. At a physiological stimulation frequency (5 Hz), and temperature (37 °C), the peak stress of SHR trabeculae was significantly reduced compared to WKY, although no differences in the time-course of the twitch were detected. Measurements using fura-2/AM as an index of intracellular [Ca2+] showed that, for SHR, both the peak of the Ca2+ transient and the resting [Ca2+]i were increased and the decay of the Ca2+ transient was prolonged compared to WKY. This unexpected result, i.e. depression of twitch force despite an increased Ca2+ transient, was investigated further by utilizing experimental protocols known to affect [Ca2+]i and force. Varying extracellular calcium ([Ca2+]o) between 0.5 and 5 mM showed that the reduction of force development by SHR trabeculae was not associated with reduced myofilament Ca2+ sensitivity, since, although peak [Ca2+]i continued to increase with increasing [Ca2+]o, peak stress reached a plateau. Investigation of the force-frequency response between 0.2 and 10 Hz showed that the mismatch in peak Ca2+ and peak force was apparent across all frequencies for SHR. A consistent finding of studies that have made measurement of [Ca2+]i in failing myocardium is that the decay of intracellular Ca2+ following SR release is prolonged. Additionally, expression levels of the SR Ca2+ -ATPase have been reported as reduced, in conjunction with increased expression of the sarcolemmal Na+/Ca2+ exchanger. Although the decay of fluorescence was slower for SHR in this study, no experimental evidence was found to suggest that sarcolemmal Ca2+ extrusion was increased in SHR in comparison to WKY. The re-circulation fraction of activator Ca2+ during recovery from potentiation was not different between rat strains, indicating that SL Ca2+ extrusion was not increased in SHR. Additionally, the decay of fluorescence remained slower for SHR even when the SR Ca2+ -ATPase contribution was functionally removed. Inhibition of the SL Ca2+ -ATPase, together with the functional removal of the SR, removed the differences in the decay of fluorescence between rat strains. A decrease in the sarcolemmal extrusion of [Ca2+]i by the Ca2+ -.ATPase might therefore explain the observed differences in the resting [Ca2+]i and in the amplitude of the Ca2+ transient between rat strains. In summary, this study has provided the first measurements of [Ca2+]i and isometric force carried out at physiological temperature and stimulation frequency in LV trabeculae from failing SHR hearts and their age-matched, normotensive, WKY controls. Most importantly, for this animal model the contractile dysfunction typical of heart failure is not associated with reduced availabilty of [Ca2+]i. Instead it is suggested that contractile function is compromised in these LV trabeculae by the increased collagen, and its three-dimensional organisation.
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Thermoreception, thermoregulation and the early thermal environmentYoung, Andrew January 1985 (has links)
Previous investigations1,2 have shown that the capacity of rats and rabbits reared at an elevated environmental temperature to thermoregulate in the cold is impaired. This impairment appears permanent and is associated with other thermoregulatory dysfunction (altered febrile response and altered response to intrahypothalamic noradrenaline injection). The present study investigated the role of the thermal environment in the development of thermoregulatory function by studying the performance of the intact thermoregulatory system and components thereof at different levels of processing of thermal information (thermoreceptive, early integrative and effector levels). The present study confirmed the impaired capacity of heat-reared rats to maintain colonic temperature in the cold and future indicated that this was likely to be attributable to active rather than passive components of the thermoregulatory system. Exposure to an environmental temperature of 20°C for 20 days was able to prevent thermoregulatory dysfunction (as assessed by intrahypothalamic noradrenaline injection) if it occurred after about 14 days of age. Exposure to 20°C was progressively less effective in averting thermoregulatory dysfunction after about 60-80 days of age. The experimental design identified these effects as being of environmental rather than genetic origin. Thermal information processing at the level of the caudal trigeminal nucleus resembled that described at thermoreceptors. The static and dynamic responses of thermoreceptive neurones at this level were quantified and found not to differ between 20°C – and 30°C-reared rats. The distribution of facial thermal receptive fields and the projections of these at the caudal trigeminal nucleus were mapped and also found not to differ. Thermal information originating from truncal skin was intercepted at a midline midbrain level. Data presented here suggested that the sites at which this thermal information could be intercepted included but probably were not restricted to the raphe nuclci. Both warm- and cold-responsive units were present at the midbrain. The abundance of thermoresponsive units was the same in 20°C- and 30°C-reared rat as was the ratio of warm:cold-responsive units. The stimulus configurations by which responses of midbrain thermoresponsive units could be characterised were more complex than at the caudal trigeminal nuclcus. Thermal responses were principally static with little response to temperature change. The pooled static responses of warm- and cold-responsive units over the 5-45°C range were the same in 20°C- and 30°C-reared rats. The cutaneous receptive fields at the midbrain level were diffuse, covering most of the truncal surface. There was an almost universal and consistent interaction with noxious input at midbrain thermoresponsive units. Warm-responsive units were inhibited by simultaneous noxious stimulation at almost any body site while the activity of cold-responsive units was augmented by such stimulation. At the thermoeffector level, noradrenaline-induced thermogenesis was equal in 20°C- and 30°C- reared rats. Heat-rearing was not observed to produce identifiable effects on the peripheral processing of thermal information, either at the afferent or efferent limbs of the thermoregulatory system. Heat-rearing does however produce changes in thermophysiological responses that are primarily mediated via a central mechanism (responses to intrahypothalamic noradrenaline, febrile response). It is therefore surmised that alterations in thermoregulatory function following heat-rearing are attributable to changes in central rather than peripheral processing of thermal information. 1 Cooper et al., (1980) J Physiol [ Lond ] 303: 165-172 2 Ferguson et al., (1981) Can J Physiol Pharmacol 59: 91-95
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Respiratory sensation in asthmatic subjects and matched controlsGaeta, Helen January 1994 (has links)
Asthmatics most "at risk of death" from their asthma are those that have severe asthma with a history of severe life threatening attacks (SLTAs). Some asthmatics are poor perceivers of the severity of their asthma. It is not known whether these two groups form a homogeneous population. The aim of this thesis was to establish whether this was the case by comparing the sensitivity of asthmatics classified as severe with a history of severe life threatening attacks, asthmatics without a history of SLTAs, mild and moderate asthmatics, and matched controls to externally added resistive loads during inspiration. It also aimed to establish whether poor sensitivity to externally added resistive loads during inspiration was associated with diminished amplitude or increased latency of scalp potentials evoked by inspiratory occlusion. Two studies were conducted to meet the first aim. The first study tested the applicability of the equal variance normal-normal model of signal detection theory as a descriptor of subjects' performance when discriminating between different levels of externally added resistive loads during inspiration. Twelve subjects rated their capacity to distinguish between pairs of resistive loads ranging from 2-33cmH2O/L/s presented during a single inspiration. Data were collected for 100, 200 and 300 single breath trials. The results showed that the model fitted the data well; that 200 trials provided performance indices that were sufficiently precise to distinguish between relatively low, average and high levels of sensitivity; and that, for the modality tested, respiratory sensation complied with Weber’s Law. The second study applied the validated procedure to test the ability of 25 asthmatics classified either as severe, or mild or moderate, and 25 matched controls to distinguish between pairs of external resistive loads ranging from 2-33cmH2O/L/s presented during a single inspiration. Analysis of the data (ANOVA) showed that there were no significant differences in the ability of subjects to distinguish between resistive loads regardless of whether they were severe asthmatics with or without a history of SLTAs, mild or moderate asthmatics, or matched controls. It was concluded that asthmatics with poor sensitivity to the respiratory sensation tested and asthmatics most "at risk of death" from their asthma were not a homogeneous group, but poor sensitivity coupled with severe asthma, and a history of SLTAs most likely increased the risk of death to that patient. Four studies were conducted to meet the second aim. The first three studies were concerned with determining the reproducibilty of the scalp potential evoked by inspiratory occlusion (designated respiratory event related evoked potentials, RREP) and establishing a reliable recording protocol for the RREP that was relatively free of artefact. The results showed that the RREP was relatively stable over time and the best recording sites were cephalic electrode pairs C3-Cz and C4-Cz (10-20 International System). The fourth study examined the relationship between the ability of 25 asthmatic subjects and their matched controls to distinguish between levels of resistive loads added to inspiration and the latencies and amplitudes of the first positive and first negative components of the RREP. Correlation analysis showed that there was no relationship between sensitivity to added resistive loads during inspiration and RREP component parameters. It was concluded that diminution or absence of the early components of the RREP was not indicative of impaired perception of respiratory sensation though some issues regarding the appropriateness of the analysis still require resolution. / Whole document restricted, but available by request, use the feedback form to request access.
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Collagen fibres, force and intracellular calcium in rat cardiac trabeculaeHanley, Peter John January 1999 (has links)
A thin cardiac muscle preparation of rat (ventricular trabeculae) was used in the two studies described in this Thesis. First, I investigated the mechanisms by which volatile anaesthetics decrease cardiac contractility using trabeculae loaded with a fluorescent Ca2+ indicator. Second, I employed confocal laser scanning microscopy to determine the three-dimensional microstructure of perimysial collagen fibres over the range of sarcomere lengths (1.9 - 2.3 µm) in which passive force increases steeply. The volatile anaesthetics halothane (0.23 – 3 %) and isoflurane (0.48 - 4%) produced dose-dependent decreases in the amplitudes of the intracellular Ca2+ transients and twitch force. They also produced changes in cellular autofluorescence, consistent with an increase in the concentration of the reduced forms of nicotinamide adenine nucleotides and flavoproteins. When the fluorescent Ca2+ indicator signals were corrected for changes in cellular autofluorescence, the volatile anaesthetics did not significantly change diastolic [Ca2+]. In the presence of halothane or isoflurane, restoration of Ca2+ transients to control levels, achieved by elevation of external [Ca2+], did not restore peak force. Moreover, maximal Ca2+-activated force, elicited using ryanodine tetani, was reduced by halothane and isoflurane. Thus, the negative inotropic actions of halothane and isoflurane in cardiac muscle reflect both reduced availability of Ca2+ and decreased responsiveness of the contractile system to Ca2+. Reconstructed three-dimensional images showed that perimysial collagen fibres are wavy (as distinct from coiled) cords which straighten considerably as sarcomere length is increased from ~1.85 µm (near-resting length) to ~2.3 µm. These observations are consistent with the notion that the straightening of these fibres is responsible for limiting cardiac sarcomere length to ~2.3 µm.
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Dynamic expression patterns of major lens membrane proteinsGrey, Angus Cheverton January 2006 (has links)
Whole document restricted, see Access Instructions file below for details of how to access the print copy. / Differentiation-dependent expression of membrane proteins is emerging as a common theme in a variety of protein expression studies conducted in the lens. Often however, the physiological relevance of, and cellular signalling mechanisms responsible for these expression patterns is not well understood. The lens microcirculation system, proposed to maintain lens homeostasis, is generated by spatial differences in lens membrane transport and structural proteins. To investigate the roles of major membrane transport and structural proteins in lens homeostasis, high resolution microscopy of lens tissue over large distances is required. This thesis presents the expression patterns of the two most abundant lens membrane proteins, Aquaporin-0 and MP20, which were both shown to change with lens fibre cell differentiation. While changes in the expression pattern of both membrane proteins has been shown previously, the application of a new lens sectioning and imaging protocol has enabled, for the first time, the changing expression patterns of both proteins to be placed in the context of the intrinsic differentiation and age gradient in the lens. Additionally, correlations between protein expression pattern and lens function have been made through immunolabelling of lens sections containing extracellular space markers. Finally, novel techniques have been developed to investigate the post-translational modifications responsible for the changing expression patterns. MP20 was initially found in a cytoplasmic pool which inserted into the lens fibre cell membrane upon degradation of cell nuclei. This membrane insertion event correlated to the formation of a barrier to extracellular diffusion. To investigate the cellular signals involved in MP20 membrane insertion, a biochemical protocol was developed to isolate a pool of MP20 derived from cytoplasmic vesicles, which was compared to membrane-bound MP20 using mass spectrometry. While MP20 was detected in both samples, differential post-translational modifications indicative of a membrane insertion signal were not observed. Initially localised to peripheral lens fibre cell membranes, Aquaporin-0 was found to aggregate predominantly on the broad sides of fibre cells, often in dome-like structures deeper into the lens. As cell nuclei degraded, the signal from an Aquaporin-0 C-terminal antibody was lost briefly, before returning in non-nucleated cells to be strong and membranous. In the lens core, signal was lost, which was shown by Western blotting and mass spectrometry to be due to cleavage of the Aquaporin-0 C-terminus. Conventional dissection techniques were unable to separate the fine zones of Aquaporin-0 labelling, necessitating the development of a novel laser microdissection/mass spectrometry approach to correlate Aquaporin-0 labelling to post-translational modifications. Additionally, MALDI tissue profiling has also been developed to investigate regional differences in the post-translational modification state of Aquaporin-0. Results from these experiments confirmed that loss of Aquaporin-0 C-terminal labelling was due to cleavage. These exciting techniques will be useful tools in the continuing investigation of changes in post-translational modifications of major lens membrane proteins. Knowledge of the high resolution expression patterns of the two most abundant lens membrane proteins has enhanced our understanding of their roles in lens homeostasis. The development of tools to investigate the cellular signals involved in the generation of lens membrane protein expression patterns is crucial if we are to advance our understanding of lens development and function.
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Renal blood flow in the conscious, unrestrained ratGrady, Heather January 1989 (has links)
The aim of this project is to test the hypothesis that the rate of renal blood flow remains constant under normal physiological conditions. Methods were developed for long term studies of renal blood flow (using the Doppler flow probe) and blood pressure in the conscious unrestrained rat. Special care was taken to maintain and observe the rats under normal, physiological conditions. Since the Doppler flow probe measures blood velocity rather than flow, changes in renal arterial diameter will alter the output of the flow meter, even if flow is constant. In order to measure flow more accurately, chanqes in vessel diameter were prevented by a short length of silastic tubing inserted into the renal, ortery under the probe. Blood flow was expressed as a percentage of the maximal flow measured when the animal was completely relaxed. Using this preparation, renal blood flow was measured continuously under normal conditions in both the light and dark cycles. Studies were performed to assess the effects on renal blood flow of anaesthesia, surgery and stress, and to assess the effect on renal blood flow of blockade of the renal nerves. Renal blood flow was depressed approximately 50% by anaesthesia, due to the effects of the anaesthetic agent rather than the accompanying surgery. Renal blood flow did not fully recover for 3-4 days after anaesthesia with, or without surgery. Renal blood flow was depressed by stress, even though blood pressure was unchanged. A mild sudden auditory disturbance caused a transient 23% fall in renal blood flow. A continuous auditory disturbance, depressed renal blood flow by 16% for several minutes. Handling the rat resulted in a 33% fall in renal blood flow which lasted for over 30 minutes. When measured continuously, renal blood flow was found to vary considerably. When the rat was completely relaxed renal blood flow was highest (defined as 100%). Renal blood flow remained high when eating and drinking (79%), but fell when the rat became alert but completely still (74%). During general movement renal blood flow was low (73%) with flow lowest while grooming (64%). Flow was apparently related to the degree of alertness and to activity. The extent of variation of flow is such that the calculated mean daily value of renal blood flow was only 80% of the maximum flow observed during complete relaxation. The depression of renal blood flow seen during activity and disturbance was largely prevented during reversible blockade of the ipsilateral renal nerve, induced by slow infusion of xylocaine around the renal artery. It was completely abolished by bilateral renal nerve blockade with Xylocaine. The depressive effects of activity and disturbance on renal blood flow were restored an hour after the Xylocaine infusion ceased. These studies clearly show that renal nerve is involved in control of renal blood flow under physiological conditions. It is clear that renal blood flow varies markedly under normal physiological conditions and in response to the external environment. A constant renal blood flow is not a necessity for normal renal function.
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