Light-induced decreases in cGMP concentration precede changes in membrane permeability in frog rod photoreceptors

This study examines whether changes in cGMP concentration initiated by illumination of frog rod photoreceptors occur rapidly enough to implicate cGMP as an intermediate between rhodopsin activation in the disc membrane and permeability changes in the plasma membrane. Previous studies using whole retinas or isolated outer segments have provided conflicting evidence on the role of cGMP in the initial events of phototransduction. The rod photoreceptor preparation employed in this work consists of purified suspensions of outer segments still attached to the mitochondria-rich ellipsoid portion of the inner segment. These photoreceptors are known to retain normal electrophysiological responses to illumination and have cGMP levels comparable to those measured in the intact retina. When examined under several different conditions, changes in cGMP concentrations were found to occur as rapidly or more rapidly than the suppression of the membrane dark current. Subsecond changes in cGMP concentration were analyzed with a rapid quench apparatus and confirmed by comparison with a rapid freezing technique. In a 1 mM Ca2+ Ringer's solution, cGMP levels decrease to 65% of their final extent within 200 ms after bright illumination; changes in membrane dark current follow a similar time course. When the light intensity is decreased to 8000 rhodopsins bleached per rod per s, the light-induced cGMP decrease is completed within 50 ms, with 7 X 10(5) cGMP molecules hydrolyzed per rhodopsin bleached. During this time the dark current has not yet begun to change. Thus, under physiological conditions it is clear that changes in cGMP concentration precede permeability changes at the plasma membrane. The correlation of rapid changes in cGMP levels with changes in membrane current leave open the possibility that changes in cGMP concentration may be an obligatory step in the reaction sequence linking rhodopsin activation by light and the resultant decrease in sodium permeability of the plasma membrane.     

Light-induced changes of sensitivity in Limulus ventral photoreceptors

The responses of Limulus ventral photoreceptors to brief test flashes and to longer adapting lights were measured under voltage clamp conditions. When the cell was dark adapted, there was a range of energy of the test flashes over which the peak amplitude of the responses (light-induced currents) was directly proportional to the flash energy. This was also true when test flashes were superposed on adapting stimuli but the proportionality constant (termed peak currently/photon) was reduced. The peak current/photon was attenuated more by brighter adapting stimuli than by less bright adapting stimuli. The peak current/photon is a measure of the sensitivity of the conductance-increase mechanism underlying the light response of the photo-receptor. The response elicited by an adapting stimulus had a large initial transient which declined to a smaller plateau. The peak current/photon decreased sharply during the declining phase of the transient and was relatively stable during the plateau. This indicates that the onset of light adaptation is delayed with respect to the onset of the response to the adapting stimulus. If the adaptational state just before the onset of each of a series of adapting stimuli was constant, the amplitude of the transient was a nearly linear function of intensity. When the total intensity was rapidly doubled (or halved) during a plateau response, the total current approximately doubled (or halved). We argue that the transition from transient to plateau, light-elicited changes of threshold, and the nonlinear function relating the plateau response to stimulus intensity all reflect changes of the responsiveness of the conductance-increase mechanism.     

Light-induced Mn2+ influx in Limulus ventral photoreceptors

In contrast to insect species, light-activated influx of divalent ions into Limulus ventral photoreceptors has proven difficult to demonstrate. We used the quench of the fluorescent indicator dye, fura-2, to measure Mn²⁺ influx. Limulus ventral photoreceptors were injected with fura-2 and excited at 360 nm. When the photoreceptors were bathed in 1 mmol · l⁻¹ Mn²⁺, an approximately 1% per 10 s decline in the fura-2 fluorescence during intervals between 50-ms flashes was taken as a measure of Mn²⁺ entry in darkness. Fluorescence decline during 10-s flashes was used to monitor Mn²⁺ entry during the photoresponse. During the 10-s flashes we observed a small rapid decline of the fura-2 fluorescence even in the absence of Mn²⁺. This reflected a contamination of the fluorescence signal arising from light-induced release of intracellular calcium stores. A subsequent slower decline in fluorescence during the 10-s flash, amounting to approximately 9% per 10 s, was only observed in the presence of extracellular Mn²⁺ and was attributed to Mn²⁺ influx. This light-activated influx was not through voltage-gated calcium channels since it persisted under voltage clamp, was not stimulated by depolarizing current injections, nor blocked by NiCl₂. Depletion of internal calcium stores by cyclopiazonic acid treatment did not accelerate Mn²⁺ influx. Accepted: 30 January 1998     

Light-induced transient ion flux responses from maize leaves and their association with leaf growth and photosynthesis

Net fluxes of H+, K+ and Ca2+ ions from maize (Zea mays L.) isolated leaf segments were measured non-invasively using ion-selective vibrating microelectrodes (the MIFE technique). Leaf segments were isolated from the blade base, containing actively elongating cells (basal segments), and from non-growing tip regions (tip segments). Ion fluxes were measured in response to bright white light (2600 micromoles m-2 s-1) from either the leaf segments or the underlying mesophyll (after stripping the epidermis). Fluxes measured from the mesophyll showed no significant difference between basal and tip regions. In leaf segments (epidermis attached), light-induced flux kinetics of all ions measured (H+, Ca2+ and K+) were strikingly different between the two regions. It appears that epidermal K+ fluxes are required to drive leaf expansion growth, whereas in the mesophyll light-induced K+ flux changes are likely to play a charge balancing role. Light-stimulated Ca2+ influx was not directly attributable either to leaf photosynthetic performance or to leaf expansion growth. It is concluded that light-induced ion flux changes are associated with both leaf growth and photosynthesis.     

Platelet-conditioned medium increases endothelial electrical resistance independently of cAMP/PKA and cGMP/PKG

Platelets release a soluble factor into blood and conditioned medium (PCM) that decreases vascular endothelial permeability. The objective of this study was to determine the signal-transduction pathway that elicits this decrease in permeability. Permeability-decreasing activity of PCM was assessed by the real-time measurement of electrical resistance across cell monolayers derived from bovine pulmonary arteries and microvessels. Using a desensitization protocol with cAMP/protein kinase A (PKA)-enhancing agents and pharmacological inhibitors, we determined that the activity of PCM is independent of PKA and PKG. Genistein, an inhibitor of tyrosine kinases, prevented the increase in endothelial electrical resistance. Because lysophosphatidic acid (LPA) has been proposed to be responsible for this activity of PCM and is known to activate the G(i) protein, inhibitors of the G protein pertussis toxin and of the associated phosphatidylinositol 3-kinase (PI3K) wortmannin were used. Pertussis toxin and wortmannin caused a 10- to 15-min delay in the characteristic rise in electrical resistance induced by PCM. Inhibition of phosphorylation of extracellular signal-regulated kinase with the mitogen-activated kinase kinase inhibitors PD-98059 and U-0126 did not prevent the activity of PCM. Similar findings with regard to the cAMP protocols and inhibition of G(i) and PI3K were obtained for 1-oleoyl-LPA. These results demonstrate that PCM increases endothelial electrical resistance in vitro via a novel, signal transduction pathway independent of cAMP/PKA and cGMP/PKG. Furthermore, PCM rapidly activates a signaling pathway involving tyrosine phosphorylation, the G(i) protein, and PI3K.     

Magnitude of increase in retinal cGMP metabolic flux determined by 18O incorporation into nucleotide alpha-phosphoryls corresponds with intensity of photic stimulation

The property of cyclic nucleotide phosphodiesterases to catalyze 3'-P--O bond cleavage and the insertion of a single nonexchangeable atom of 18O from [18O]water into the phosphoryl of the 5'-nucleotide product has been utilized as a means for measuring the hydrolytic flux of cGMP and cAMP in isolated dark-adapted intact rabbit retinas. Without illumination 18O labeling of guanine nucleotide (GTP and GDP) alpha-phosphoryls proceeds linearly for at least 80 s at a rate of 3.3 nmol of 18O/s.g of retina (wet weight). This rate is estimated to be approximately 8 times greater in the rod outer segment layer where over 90% of retinal cGMP metabolic components reside. Photic stimulation during a 20-s incubation was provided by intermittent flashes of light representing 800 ms of total illumination. Light stimuli over a range of intensities of greater than 3 log units commencing with a minimally detectable intensity produce graded increments in the rate of 18O incorporation into guanine nucleotide alpha-phosphoryls to a maximum increase of 5-fold. On the basis of only the 800-ms period of illumination this maximum increase is 125-fold. Steady state levels of retinal cGMP are not altered appreciably over this greater than 3 log range of light intensities but a light stimulus exceeding this intensity range causes an approximate 50% decrease in retinal cGMP concentration and a relative decline in the maximal rate of 18O labeling of guanine nucleotide alpha-phosphoryls. No light-related increases were detected in 18O incorporation into adenine nucleotide alpha-phosphoryls nor the gamma-phosphoryls of GTP or ATP or Pi. These observations indicate that light stimuli over greater than 3 log of light intensity produce incremental increases in cGMP metabolic flux that result from comparable increases in the rates of both cGMP generation and cGMP hydrolysis. It is postulated that increases in cGMP metabolic flux rather than changes in cGMP steady state levels are integral to phototransduction by a mechanism that involves the coupling of cGMP synthesis and/or hydrolysis to either the release of calcium from disc membranes or the inhibition of Na+ conductance by the photoreceptor membrane. This is suggested to occur by an energy-linked process and/or the generation of protons.     

Light-induced electrical potential changes and motility in desmids

Motility of the desmid Cosmarium cucumis depends on light: switching the light on induces a large fraction of previously immotile cells to start moving, and switching it off causes many motile cells to stop. Turning light on or off causes light-induced electrical potential changes which can be measured with internal microelectrodes. The electrical gradient within the cell is not correlated with the light gradient. Consequently, the cell cannot obtain information concerning the spatial distribution of the incident light, e.g. for phototactic orientation. However, light-induced potential changes could serve as signals for photokinesis, since switching the light on causes a transient increase and switching the light off a transient decrease in the electrical potential of the front half as compared to the rear half or the extracellular space.     

Sublinear summation of responses in locust photoreceptors

Summary The response of a locust, Locusta migratoria, photoreceptor to a simultaneous pair of dim flashes is smaller than the sum of the responses to the individual component flashes, even when the photon absorption sites are separated by a distance of 120 m, which should prevent them from interacting biochemically. A similar depression is observed when a flash is paired with a depolarizing current instead of a second flash, irrespecive of whether the flash response precedes or follows the current response. These results indicate that the sublinear summation is caused by the activation of a voltage-activated shunting conductance. This conductance is not blocked by low intracellular concentrations of tetraethylammonium chloride, and is therefore different from the conductance which causes the decrease of the receptor's step response from transient to steady-state.     

Caffeine ingestion and metabolic responses of tetraplegic humans during electrical cycling

Normally, caffeineingestion results in a wide spectrum of neural and hormonal responses,making it difficult to evaluate which are critical regulatory factors.We examined the responses to caffeine (6 mg/kg) ingestion in a group ofspinal cord-injured subjects [7 tetraplegic(C_5-7) and 2 paraplegic(T₄) subjects] at rest andduring functional electrical stimulation of their paralyzed limbs tothe point of fatigue. Plasma insulin did not change, caffeine had noeffect on plasma epinephrine, and there was a slight increase(P < 0.05) in norepinephrine after15 min of exercise. Nevertheless, serum free fatty acids were increased (P < 0.05) after caffeine ingestionafter 60 min of rest and throughout the first 15 min of exercise, butthe respiratory exchange ratio was not affected. The exercise time wasincreased (P < 0.05) by 6% or 1.26 ± 0.57 min. These data suggest that caffeine had direct effects onboth the adipose tissue and the active muscle. It is proposed that theergogenic action of caffeine is occurring, at least in part, by adirect action of the drug on muscle.

     

Membrane current responses of skate photoreceptors

Light-evoked membrane currents were recorded with suction electrodes from the outer segments of individual photoreceptors enzymatically dissociated from the skate retina. The intensity-response relation of dark-adapted cells closely followed a Michaelis function for which a half-saturating response was elicited by a flash intensity that produced about 36 photoisomerizations. Dim-light responses, as well as the early rising phase of the responses to a wide range of flash intensities, could be described by a reaction scheme that involved a series of four first-order delay stages. The number of delay stages required to model the rising phase of the photocurrents did not change in light adaptation. However, background illumination that reduced sensitivity by 1.5 log units, or a bleaching exposure that resulted in a nearly equivalent desensitization, shortened significantly the time scale of the responses. In both instances there were two- to threefold increases in the rate constants of the transitional delays, and almost complete suppression of the tail current that characterized the response of the dark-adapted cell. These findings suggest that although light adaptation alters the gain and kinetics of the transduction mechanism, the nature of the intervening processes is the same in dark- and light-adapted photoreceptors. Moreover, the results show clearly that there is no need to postulate the existence of a second class of cone-like rods to account for the remarkable ability of skate photoreceptors to respond to incremental stimuli presented on "saturating" background fields or after exposure to an intense bleaching light.     

Light-induced behavioral responses (`phototaxis') in prokaryotes

Light-induced sensory responses are among the oldest scientific observations on bacterial behavior. Various types of response have been characterized physiologically in detail. However, the molecular basis of this type of response is only slowly emerging. In many of these systems photosynthetic pigments absorb the light. This then generates a signal via electron transport, feeding into a canonical chemotaxis signal transduction pathway. Nevertheless, several examples have been identified in which dedicated photoreceptor proteins do play a role. The intrinsic complexity of some of these signal transduction systems is overwhelming, in part because of the significant apparent redundancy. The genomics information that is now available for several model organisms (in particular Rhodobacter sphaeroides and Synechocystis sp. PCC6803) facilitates obtaining an increasingly detailed view of the molecular basis of the partial reactions that jointly form the basis of this type of elementary behavioral response. This revised version was published online in August 2006 with corrections to the Cover Date.     

Involvement of cGMP in cellular melatonin responses.

Melatonin can enhance and suppress constitutive protein secretion from murine melanoma M2R cells in vitro in a cholera-toxin (CTX) sensitive process. In a number of tissues melatonin has been shown to modulate cGMP levels. The involvement of cGMP in melatonin responses in the melanoma cells was investigated. The effects of melatonin on melanoma cells cGMP and cGMP-phosphodiesterase activity and the effects of cGMP analogs on the melatonin-mediated modulation of protein secretion were studied. Melatonin reduced cGMP levels in the melanoma cells. CTX treatment had a similar and non-additive effect. The effects of melatonin on protein secretion were abrogated by activation of cGMP-dependent protein kinases. In addition, melatonin inhibited cGMP phosphodiesterase activity in these cells. The data presented indicate that inhibition of cGMP via a CTX sensitive G protein may be a major signal transduction pathway used by melatonin in melanoma cells.