Synaptic deficits in layer 5 neurons precede overt structural decay in 5xFAD mice.

Synaptic decay and neurodegeneration are hallmarks of Alzheimer's disease that are thought to precede dementia. Recently, we have reported that the first signs of neuritic dystrophy in a new transgenic mouse model of familial Alzheimer's disease (FAD) called the "5xFAD" are axonal dystrophy followed by loss of spines on basal dendrites. The 5xFAD mouse has profound loss of layer 5 neurons by 12months, and these initial structural insults appear between 4 and 6months of age. Here, we test, for the first time, if synaptic failure of layer 5 neurons in the 5xFAD mouse precedes these structural changes. We used longitudinal, in vivo two-photon fluorescence imaging of bigenic 5xFAD/YFP mice to assess the overall structural stability of layer 5 neurons in young mice (age less than 14weeks). We found these neurons to be structurally and morphologically sound. In parallel, we used in vitro, whole-cell patch clamp electrophysiology of layer 5 pyramidal neurons, from mice aged 8-12weeks, to reveal significant pre- and postsynaptic defects in these cells. Thus our data suggest that layer 5 neurons in the 5xFAD mouse model have synaptic deficits at an early time point, before any overt structural dystrophy, and that such synaptic failure, with co-temporal biochemical changes, may be an early step in neuronal loss.

Application of two-photon flash photolysis to reveal intercellular communication and intracellular Ca2+ movements.

Two-photon excitation makes it possible to excite molecules in volumes of much less than 1 fl. In two-photon flash photolysis (TPFP) this property is used to release effector molecules from caged precursors with high three-dimensional resolution. We describe and examine the benefits of using TPFP in model solutions and in a number of cell systems to study their spatial and temporal properties. Using TPFP of caged fluorescein, we determined the free diffusion coefficient of fluorescein (D=4 x 0(-6) cm(2)/s at 20 degrees C, which is in close agreement with published values). TPFP of caged fluorescein in lens tissue in situ revealed spatial nonuniformities in intercellular fiber cell coupling by gap junctions. At the lens periphery, intercellular transport was predominantly directed along rows of cells, but was nearly isotropic further from the periphery. To test an algorithm aiming to reconstruct the Ca(2+) release flux underlying physiological Ca(2+) signals in heart muscle cells, TPFP of DM-Nitrophen was utilized to generate artificial microscopic Ca(2+) signals with known underlying Ca(2+) release flux. In an experiment with mouse oocytes, the recently developed Ca(2+) cage dimethoxynitrophenyl-ethyleneglycol-bis-(beta-aminoethylether)-N,N,N('),N(') tetraacetic acid-4 (DMNPE-4) was released in the oocyte cytosol and inside a nucleolus. Analysis of the resulting fluorescence changes suggested that the effective diffusion coefficient within the nucleolus was half of that in the cytosol. These experiments demonstrate the utility of TPFP as a novel tool for the optical study of biomedical systems.

Dendritic spine geometry is critical for AMPA receptor expression in hippocampal CA1 pyramidal neurons.

Dendritic spines serve as preferential sites of excitatory synaptic connections and are pleomorphic. To address the structure-function relationship of the dendritic spines, we used two-photon uncaging of glutamate to allow mapping of functional glutamate receptors at the level of the single synapse. Our analyses of the spines of CA1 pyramidal neurons reveal that AMPA (alpha-amino-3-hydroxy-5-methyl-4-isoxazolepropionic acid)-type glutamate receptors are abundant (up to 150/spine) in mushroom spines but sparsely distributed in thin spines and filopodia. The latter may be serving as the structural substrates of the silent synapses that have been proposed to play roles in development and plasticity of synaptic transmission. Our data indicate that distribution of functional AMPA receptors is tightly correlated with spine geometry and that receptor activity is independently regulated at the level of single spines.

Ion selectivities of the Ca(2+) sensors for exocytosis in rat phaeochromocytoma cells.

1. The ion selectivities of the Ca(2+) sensors for the two components of exocytosis in rat phaeochromocytoma (PC12) cells were examined by measurement of membrane capacitance and amperometry. The cytosolic concentrations of metal ions were increased by photolysis of caged-Ca(2+) compounds and measured with low-affinity indicators benzothiazole coumarin (BTC) or 5-nitrobenzothiazole coumarin (BTC-5N). 2. The Ca(2+)-induced increases in membrane capacitance comprised two phases with time constants of 30--100 ms and 5 s. Amperometric events reflecting the exocytosis of large dense-core vesicles occurred selectively in the slow phase, even with increases in the cytosolic Ca(2+) concentration of > 0.1 mM. 3. The slow component of exocytosis was activated by all metal ions investigated, including Cd(2+) (median effective concentration, 18 pM), Mn(2+) (500 nM), Co(2+) (900 nM), Ca(2+) (8 microM), Sr(2+) (180 microM), Ba(2+) (280 microM) and Mg(2+) (> 5 mM). In contrast, the fast component of exocytosis was activated by Cd(2+) (26 pM), Mn(2+) (620 nM), Ca(2+) (24 microM) and Sr(2+) (320 microM), but was only slightly increased by Ba(2+) (> 2 mM) and Co(2+) and not at all by Mg(2+). 4. The fast component, but not the slow component, was competitively blocked by Na(+) (median effective concentration, 44 mM) but not by Li(+), K(+) or Cs(+). Thus, the Ca(2+) sensor for the fast component of exocytosis is more selective than is that for the slow component; moreover, this selectivity appears to be based on ionic radius, with cations with radii of 0.84 to 1.13 A (1 A = 0.1 nm) being effective. 5. These data support a role for synaptotagmin--phospholipid as the Ca(2+) sensor for the exocytosis of large dense-core vesicles and they suggest that an additional Ca(2+)-sensing mechanism operates in the synchronous exocytosis of synaptic-like vesicles.

Two-photon and UV-laser flash photolysis of the Ca2+ cage, dimethoxynitrophenyl-EGTA-4.

We report efficient two-photon and UV-laser flash photolysis of dimethoxynitrophenyl-EGTA-4 (DMNPE-4), a newly-developed photolabile Ca(2+)-specific chelator. This compound exhibits good two-photon absorption at 705 nm, has a low Mg2+ affinity (approximately 7 mM), a Kd for Ca2+ of 19 nM, a quantum yield of 0.20 and changes its Ca2+ affinity by 21,000-fold upon photolysis. Two-photon excitation photolysis (TPP) experiments were performed with a Ti:Sapphire laser in solutions containing DMNPE-4 with either 0 or 10 mM Mg2+ and compared to that of the widely used Ca2+ cage, DM-nitrophen (Kd for Ca2+ 5 nM, Kd for Mg2+ 2.5 microM, quantum yield 0.18, affinity change 600,000-fold). The resulting Ca2+ signals were recorded with the fluorescent Ca2+ indicator fluo-3 and a laser-scanning confocal microscope in the line-scan mode. In vitro, photolysis of DMNPE-4:Ca2+ produced Ca(2+)-release signals that had comparable amplitudes and time courses in the presence and absence of Mg2+. However, photorelease of Ca2+ from DM-nitrophen was obviated by the presence of Mg2+. In patch-clamped isolated cardiac myocytes, equivalent TPP results were obtained in analogous experiments. Single-photon excitation of DMNPE-4 by Nd:YAG laser flashes produced Na-Ca exchange currents of comparable amplitude in the absence and presence of Mg2+. However, only very small currents were observed in DM-nitrophen solution containing 10 mM Mg2+. In conclusion, both DMNPE-4 and DM-nitrophen undergo TPP, however, only DMNPE-4 exhibits efficient release of Ca2+ in the presence of Mg2+.

Post-priming actions of ATP on Ca2+-dependent exocytosis in pancreatic beta cells.

The role of cytosolic ATP in exocytosis was investigated by using amperometric measurement of insulin exocytosis in pancreatic beta cells, which were stimulated with photolysis of caged Ca2+ compounds. Insulin exocytosis occurred with two rates. We found that ATP hastened and augmented the exocytosis via selective enhancement of the exocytosis with the faster rate. A nonhydrolysable analog of ATP, adenosine 5'-O-(3-thiotriphosphate), which blocks ATPase, was even more effective than ATP, indicating that the phosphorylation event occurred downstream of ATP-dependent vesicle transportation and priming. The action of ATP was eliminated by a competitive antagonist of cAMP, and by an inhibitor of adenylate cyclase. These data characterize an ATP sensing mechanism for the Ca2+-dependent exocytosis involving adenylate-cyclase, cAMP-dependent protein kinase, and, possibly, the fusion machinery itself. Thus, the fast exocytotic machinery requires both phosphorylation and Ca2+ for the final triggering and likely constitutes a distal ATP sensor for insulin exocytosis that acts in concert with ATP-sensitive K+ channels.

Supralinear Ca2+ signaling by cooperative and mobile Ca2+ buffering in Purkinje neurons.

Endogenous high-affinity Ca2+ buffering and its roles were investigated in mouse cerebellar Purkinje cells with the use of a low-affinity Ca2+ indicator and a high-affinity caged Ca2+ compound. Increases in the cytosolic Ca2+ concentration ([Ca2+]i) were markedly facilitated during repetitive depolarization, resulting in the generation of steep micromolar Ca2+ gradients along dendrites. Such supralinear Ca2+ responses were attributed to the saturation of a large concentration (0.36 mM) of a mobile, high-affinity (dissociation constant, 0.37 microM) Ca2+ buffer with cooperative Ca2+ binding sites, resembling calbindin-D28K, and to an immobile, low-affinity Ca2+ buffer. These data suggest that the high-affinity Ca2+ buffer operates as the neuronal computational element that enables efficient coincidence detection of the Ca2+ signal and that facilitates spatiotemporal integration of the Ca2+ signal at submicromolar [Ca2+]i.

Photolabile amiloride derivatives as cation site probes of the Na,K-ATPase.

Treatment of purified canine renal Na,K-ATPase with a range of photoactivatable amiloride derivatives results in inhibition of ATPase activity prior to illumination. Inhibition by amiloride derivatives substituted on a guanidium N could not be prevented by the presence of either K or Na; however, these cations could protect the enzyme against inhibition by derivatives substituted on the 5-position of the pyrazine ring. In the case of 5-(N-ethyl-[2'-methoxy-4'-nitrobenzyl])amiloride (NENMBA), the presence of monovalent cations (Na, K, and Rb) protected the enzyme effectively against inhibition, with concentrations in the millimolar range. ATP did not prevent inhibition; furthermore, native and NENMBA-treated enzyme exhibited normal levels of high affinity [3H]ADP (and hence ATP) binding. The rate of inhibition increased with increasing concentrations of NENMBA. Extensive washing of NENMBA-inhibited enzyme did not restore ATPase activity, showing that NENMBA has an extremely slow off-rate for dissociation from its inhibitory site. Partially inhibited enzyme could be rapidly pelleted and resuspended in NENMBA-free buffer and inhibition was observed to continue, albeit at a somewhat diminished rate, suggesting that NENMBA gains access to its inhibitory site after partitioning into the lipid phase rather than directly from the aqueous solution. Photolysis of NENMBA-inhibited enzyme resulted in covalent incorporation of the reagent into the alpha-subunit of the Na,K-ATPase, as observed by separation of labeled protein on a Laemmli gel and Western analysis using a polyclonal amiloride antibody. Almost all of the covalent labeling could be prevented by the presence of Rb in the incubation and labeling medium. These results suggest that NENMBA inhibits the Na, K-ATPase by disruption of the cation transport domain rather than the catalytic domain of the enzyme and that it promises to be a useful tool for cation site localization.

Millisecond studies of calcium-dependent exocytosis in pituitary melanotrophs: comparison of the photolabile calcium chelators nitrophenyl-EGTA and DM-nitrophen.

DM-nitrophen (DMN) is a photolabile calcium chelator that has been used extensively to study calcium-triggered exocytosis. Nitrophenyl-EGTA (NPE) is a recently synthesized photolabile calcium chelator that, unlike DMN, selectively binds calcium over magnesium. Here, we compare NPE and DMN for their effectiveness in raising cytosolic calcium ([Ca]i) to trigger exocytosis. The whole cell patch clamp technique was used to monitor membrane capacitance (Cm) and to load both calcium indicator dye and photolabile chelators into rat pituitary melanotrophs prior to flash photolysis. In cells dialysed with DMN, a transient increase in [Ca]i was observed immediately after continuity between the patch pipette and the cell cytosol was achieved. This 'loading transient' reflects the release of calcium from DMN during the binding of intracellular magnesium. No such transient was seen with NPE, consistent with the negligible binding of magnesium to this chelator. Following flash photolysis of DMN or NPE, [Ca]i increased, triggering both a rapid exocytic burst and slower sustained phases of exocytosis. When flashes of the same intensity were compared, the photolysis of NPE resulted in smaller increases in [Ca]i and slower exocytic bursts than that of DMN. These findings are in accordance with the properties of the two compounds [Ellis-Davies G.C.R., Kaplan J.H. Nitrophenyl-EGTA, a photolabile chelator that selectively binds Ca2+ with high affinity and releases it rapidly upon photolysis. Proc Natl Acad Sci USA 1994; 91: 187-191] and the calcium dependency of the exocytic burst [Thomas P., Wong J.G., Lee A.K., Almers W. A low affinity Ca2+ receptor controls the final steps in peptide secretion from pituitary melanotrophs. Neuron 1993; 11: 93-104]. Although NPE is somewhat less effective than DMN in raising [Ca]i, this chelator promises to be a useful and interesting tool for the time-resolved study of calcium-dependent exocytosis in the presence of physiological concentrations of magnesium.

Laser photolysis of caged calcium: rates of calcium release by nitrophenyl-EGTA and DM-nitrophen.

Nitrophenyl-EGTA and DM-nitrophen are Ca2+ cages that release Ca2+ when cleaved upon illumination with near-ultraviolet light. Laser photolysis of nitrophenyl-EGTA produced transient intermediates that decayed biexponentially with rates of 500,000 s-1 and 100,000 s-1 in the presence of saturating Ca2+ and 290,000 s-1 and 68,000 s-1 in the absence of Ca2+ at pH 7.2 and 25 degrees C. Laser photolysis of nitrophenyl-EGTA in the presence of Ca2+ and the Ca2+ indicator Ca-orange-5N produced a monotonic increase in the indicator fluorescence, which had a rate of 68,000 s-1 at pH 7.2 and 25 degrees C. Irradiation of DM-nitrophen produced similar results with somewhat slower kinetics. The transient intermediates decayed with rates of 80,000 s-1 and 11,000 s-1 in the presence of Ca2+ and 59,000 s-1 and 3,600 s-1 in the absence of Ca2+ at pH 7.2 and 25 degrees C. The rate of increase in Ca(2+)-indicator fluorescence produced upon photolysis of the DM-nitrophen: Ca2+ complex was 38,000 s-1 at pH 7.2 and 25 degrees C. In contrast, pulses in Ca2+ concentration were generated when the chelator concentrations were more than the total Ca2+ concentration. Photoreleased Ca2+ concentration stabilized under these circumstances to a steady state within 1-2 ms.

Kinetics of prephosphorylation reactions and myosin light chain phosphorylation in smooth muscle. Flash photolysis studies with caged calcium and caged ATP.

The pre-myosin light chain (MLC20) phosphorylation components of the lag phase (td) of contractile activation were determined in permeabilized smooth muscles activated by photolytic release of ATP from caged ATP and/or Ca2+ from 4-(2-nitrophenyl)-EGTA (NP-EGTA). Calmodulin (CaM) shortened the td (470 ms at 0 added CaM) that followed Ca2+ release, but its effect (td = approximately 200 ms) saturated at 40 microM. Photolysis of caged ATP following preequilibration with identical [Ca4CaM] shortened td to 41 ms. The rate of phosphorylation was very fast (3.5 s-1 at 22 degrees C in the presence of 5 microM exogenous CaM) following photolysis of caged ATP, and, following Ca2+ release, phosphorylation was accelerated by CaM. Simultaneous photolysis of caged ATP and NP-EGTA was followed by a td of 194 ms at 5 microM CaM and a rate of MLC20 phosphorylation intermediate between these parameters following photolysis of, respectively, NP-EGTA and caged ATP. In the presence of the normal, total endogenous CaM content (37 +/- 4 microM) of protal vein smooth muscles td was 565 ms. Steady state maximum force at pCa 5.5 was increased by much lower (100 nM) exogenous [CaM] than was required (> 2.5 microM) to shorten the td. We estimate the endogenous CaM available under steady state conditions in vivo to be approximately 0.25 microM and probably less during a rapid Ca2+ transient. We conclude that the [CaM] dependence of the kinetics of MLC20 phosphorylation and force development (t1/2 and td) initiated by Ca2+ reflects the recruitment of a slowly diffusible component of total CaM. The relatively long duration of td (197 ms) at saturating [CaM] suggests the contribution to td of an additional component, possibly a prephosphorylation activation/isomerization of the Ca4CaM myosin light chain kinase complex (Török, K., and Trentham, D. R. (1994) Biochemistry 33, 12807-12820). The relatively short delay (108 ms in the presence of 40 microM CaM) following simultaneous photolysis of NP-EGTA and caged ATP suggests that preincubation with ATP (prior to photolysis of NP-EGTA) may inhibit the formation of a preactive Ca2CaM myosin light chain kinase complex.

Electrical currents generated by a partially purified Na/Ca exchanger from lobster muscle reconstituted into liposomes and adsorbed on black lipid membranes: activation by photolysis of Ca2+.

The Na/Ca exchanger from lobster muscle crossreacts specifically with antibodies raised against the dog heart Na/Ca exchanger. Immunoblots of the lobster muscle and mammalian heart exchangers, following SDS-PAGE, indicate that the invertebrate and mammalian exchangers have similar molecular weights: about 120 kDa. The exchanger from lobster muscle was partially purified and functionally reconstituted into asolectin vesicles which were loaded with 160 mM NaCl. 45Ca uptake by these proteoliposomes was promoted by replacing 160 mM NaCl in the external medium with 160 mM KCl to produce an outwardly-directed Na+ concentration gradient. When the proteoliposomes were adsorbed onto black lipid membranes (BLM), and DM-Nitrophen-Ca2+ ("caged Ca2+") was added to the KCl medium, photolytically-evoked Ca2+ concentration jumps elicited transient electric currents. These currents corresponded to positive charge exiting from the proteoliposomes, and were consistent with the Na/Ca exchanger-mediated exit of 3 Na+ in exchange for 1 entering Ca2+. The current was dependent upon the Ca2+ concentration jump, the protein integrity, and the outwardly directed Na+ gradient. KCl-loaded proteoliposomes did not produce any current. Low external Na+ concentrations augmented the current, whereas Na+ concentrations > 25 mM reduced the current. The dependence of the current on free Ca2+ was Michaelis-Menten-like, with half-maximal activation (KM(Ca)) at < 10 microM Ca2+. Caged Sr2+ and Ba2+, but not Mg2+, also supported photolysis-evoked outward current, as did Ni2+, but not Mn2+. However, Mg2+ and Mn2+ augmented the Ca-dependent current, perhaps by facilitating the adsorption of proteoliposomes to the BLM. The Ca-dependent current was irreversibly blocked by La3+ (added as 200 microM DMN-La3+). The results indicate that the properties of the Na/Ca exchanger can be studied with these electro-physiological methods.

Rapid adaptation of cardiac ryanodine receptors: modulation by Mg2+ and phosphorylation.

Channel adaptation is a fundamental feature of sarcoplasmic reticulum calcium release channels (called ryanodine receptors, RyRs). It permits successive increases in the intracellular concentration of calcium (Ca2+) to repeatedly but transiently activate channels. Adaptation of RyRs in the absence of magnesium (Mg2+) and adenosine triphosphate is an extremely slow process (taking seconds). Photorelease of Ca2+ from nitrophenyl-EGTA, a photolabile Ca2+ chelator, demonstrated that RyR adaptation is rapid (milliseconds) in canine heart muscle when physiological Mg2+ concentrations are present. Phosphorylation of the RyR by protein kinase A increased the responsiveness of the channel to Ca2+ and accelerated the kinetics of adaptation. These properties of the RyR from heart may also be relevant to other cells in which multiple agonist-dependent triggering events regulate cellular functions.

Nitrophenyl-EGTA, a photolabile chelator that selectively binds Ca2+ with high affinity and releases it rapidly upon photolysis.

The synthesis and properties of a caged calcium are described. The compound is an ortho-nitrophenyl derivative of EGTA. It is synthesized in 10 steps and with 24% overall yield. The photosensitive chelator, nitrophenyl-EGTA, has a Kd value for Ca2+ of 80 nM and for Mg2+ of 9 mM. Upon exposure to UV radiation (approximately 350 nm), the chelator is cleaved, yielding iminodiacetic acid photoproducts with low Ca affinity (Kd = 1 mM). The quantum yield of photolysis of nitrophenyl-EGTA in the presence of Ca2+ is 0.23 and in the absence of Ca2+ is 0.20. In experiments with chemically skinned skeletal muscle fibers, a fully relaxed fiber equilibrated with nitrophenyl-EGTA-Ca2+ complex, in the presence of 1 mM free Mg2+, maximally contracted after a single flash from a frequency-doubled ruby laser (347 nm). Half-maximal tension was achieved in 18 ms at 15 degrees C. Nitrophenyl-EGTA provides a tool for the investigation of the mechanism of Ca(2+)-dependent physiological processes, since under conditions of normal intracellular Ca2+ and Mg2+ concentrations, only Ca2+ is bound by the photolabile chelator and on illumination released rapidly and in high photochemical yield.

Modification of lysine 501 in Na,K-ATPase reveals coupling between cation occupancy and changes in the ATP binding domain.

Treatment of the canine renal Na,K-ATPase with N-(2-nitro-4-isothiocyanophenyl)-imidazole (NIPI) results in irreversible loss of enzymatic activity. The reactivity of the protein toward the probe is about 10-fold greater in the E1.Na or sodium-bound form than when it is in the E2.K or potassium-bound form. Fully inactivated enzyme does not bind ATP but binds sodium and potassium and undergoes the major enzyme conformational transitions (Ellis-Davies, G. C. R., and Kaplan, J. H. (1990) J. Biol. Chem. 265, 20570-20576). Labeling of the sodium pump protein with [3H]NIPI in either the E1.Na or E2.K conformations results in the covalent incorporation of one molecule of probe per alpha-subunit of ATPase. Trypsin treatment of purified alpha-subunit, and separation of the digest using reverse-phase high performance liquid chromatography, yields five major radioactive fragments in each case. Amino acid sequencing indicates that only one residue, lysine 501, is labeled by NIPI. This suggests that the integrity of the domain containing Lys501 is essential for both high and low affinity binding of ATP by the Na,K-ATPase. Furthermore, the spatial organization of the protein close to lysine 501 is changed in the E1.Na and E2.K form of the enzyme. This change is reflected in the greater reactivity of lysine 501 in the E1.Na conformation and indicates that the binding of either sodium or potassium ions to their sites on the sodium pump has differential effects on the nucleotide binding domain containing lysine 501.

Mechanics and structure of cross-bridges during contractions initiated by photolysis of caged Ca2+.

Cross-bridge structure and mechanics were studied during development of skinned frog muscle fiber contractions initiated by photolysis of DM-nitrophen (a caged Ca2+). Stiffness rises earlier than tension following photo-release of Ca2+. A similar lead of stiffness in electrically stimulated fibers and the early rise of the I11/I10 ratio of equatorial X-ray reflections are thought to signal attachment of cross-bridges into states with lower force than in steady-state contraction. We investigated the structure of the early attachments by electron microscopy of fibers activated by photolysis of DM-nitrophen and then ultra-rapidly frozen and freeze substituted with tannic acid and OsO4. Sections from relaxed fibers show helical tracks of myosin heads on the thick filaments surface. Optical diffraction patterns show strong meridional intensities and layer lines up to the 6th order of 1/43 nm, indicating preservation and resolution of periodic structures smaller than 10 nm. Following photo-release of Ca2+, the 1/43 nm myosin layer line becomes less intense, and higher orders disappear. A approximately 1/36 nm layer line appears early (12-15 ms) and becomes stronger at later times. The 1/14.3 nm meridional spot weakens initially and recovers at a later time, while it broadens laterally. The 1/43 nm meridional spot is present during contraction, but the 2nd order meridional spot (1/21.5 nm) is weak or absent. These results are consistent with time resolved X-ray diffraction data on the periodic structures within the fiber. In sections along the 1,1 plane of activated fibers, the individual cross-bridges have a wide range of shapes and angles, perpendicular to the fiber axis or pointing toward or away from the Z-line. Fibers frozen at 13 ms, 33 ms, and 220 ms after photolysis all show surprisingly similar cross-bridges. Thus, a highly variable distribution of cross-bridge shapes and angles is established early in contraction.

Rate of release of Ca2+ following laser photolysis of the DM-nitrophen-Ca2+ complex.

The determination of the rate of release of Ca2+ by pulsed photolysis of the photolabile chelator DM-nitrophen is important for its use in time-resolved physiological studies: the rate of substrate or effector release should be faster than the processes they initiate. Flash photolysis of DM-nitrophen using a 50-ns pulse from a frequency-doubled ruby laser (with emission at 347 nm having energy of ca. 10-20 mJ) yields short-lived photochromic or aci-nitro intermediates. At pH 6.9, double-exponential decay of a photochromic intermediate was observed for DM-nitrophen itself and its Ca2+ complex (tau 1/2 values of 24 and 570 microseconds, and 32 and 220 microseconds respectively), while only monoexponential decay of the DM-nitrophen-Mg2+ complex was detected (tau 1/2 = 31 microseconds). Only the photochemistry of DM-nitrophen-Ca2+ was found to be pH sensitive (monoexponential decay, tau 1/2 approximately 115 microseconds at pH 7.9 and 8.9). Use of the Ca(2+)-sensitive metallochromic dye antipyrylazo III in conjunction with pulsed photolysis of DM-nitrophen-Ca2+ enabled an upper limit of the half-time of release of Ca2+ to be established of ca. 180 microseconds (the rate of association of Ca2+ with the dye was probably rate determining). The rate of Ca2+ photorelease may, however, be faster than this. Thus, the DM-nitrophen-Ca2+ complex releases Ca2+ on photolysis sufficiently rapidly for the study of many Ca(2+)-dependent physiological processes with improved kinetic resolution over conventional mixing methods.

Binding of Na+ ions to the Na,K-ATPase increases the reactivity of an essential residue in the ATP binding domain.

Treatment of the canine renal Na,K-ATPase with N-(2-nitro-4-isothiocyanophenyl)-imidazole (NIPI), a new imidazole-based probe, results in irreversible loss of enzymatic activity. Inactivation of 95% of the Na,K-ATPase activity is achieved by the covalent binding of 1 molecule of [3H]NIPI to a single site on the alpha-subunit of the Na,K-ATPase. The reactivity of this site toward NIPI is about 10-fold greater when the enzyme is in the E1Na or sodium-bound form than when it is in the E2K or potassium-bound form. K+ ions prevent the enhanced reactivity associated with Na+ binding. Labeling and inactivation of the enzyme is prevented by the simultaneous presence of ATP or ADP (but not by AMP). The apparent affinity with which ATP prevents the inactivation by NIPI at pH 8.5 is increased from 30 to 3 microM by the presence of Na+ ions. This suggests that the affinity with which native enzyme binds ATP (or ADP) at this pH is enhanced by Na+ binding to the enzyme. Modification of the single sodium-responsive residue on the alpha-subunit of the Na,K-ATPase results in loss of high affinity ATP binding, without affecting phosphorylation from Pi. Modification with NIPI probably alters the adenosine binding region without affecting the region close to the phosphorylated carboxyl residue aspartate 369. Tightly bound (or occluded) Rb+ ions are not displaced by ATP (4 mM) in the inactivated enzyme. Thus modification of a single residue simultaneously blocks ATP acting with either high or low affinity on the Na,K-ATPase. These observations suggest that there is a single residue on the alpha-subunit (probably a lysine) which drastically alters its reactivity as Na+ binds to the enzyme. This lysine residue is essential for catalytic activity and is prevented from reacting with NIPI when ATP binds to the enzyme. Thus, the essential lysine residue involved may be part of the ATP binding domain of the Na,K-ATPase.

Modulation of Ca2+ channel selectivity and cardiac contraction by photorelease of Ca2+.

The effect of rapid increases of extracellular Ca2+ concentration on tension development and Ca2+ channel selectivity has been investigated in frog (Rana pipiens) ventricular myocardium using a novel light-sensitive Ca2+ chelator, dimethoxy-nitrophen. Dimethoxy-nitrophen is a photolabile tetracarboxylate Ca2+ chelator that on photolysis to dicarboxylate fragments alters its affinity (Kd) for Ca2+ from 5 X 10(-9) to 2 X 10(-3) M. A single 160-microseconds ultraviolet light pulse induced the release of approximately 80-100 microM Ca2+ with a half-time of 200 microseconds. In low extracellular Ca2+ concentration, Na+ current through the Ca2+ channel was blocked by photorelease of extracellular Ca2+ in less than 500 microseconds; nevertheless, 60-80 ms were required to activate or enhance tension. Enhancement of tension was more effective when Ca2+ was released during the activation of the Ca2+ channel than during its inactivation. The voltage dependence of enhanced tension, caused by photorelease of Ca2+, was bell shaped and was similar to that of Ca2+ current. These findings suggest that Ca2+ transport through the Ca2+ channel is the primary mechanism for the transport of Ca2+ to activate tension in the frog heart. The use of dimethoxy-nitrophen makes it possible to examine the rapid kinetics of the Ca-dependent processes involved in regulation of channel function and contraction.

Caged-Ca2+: a new agent allowing liberation of free Ca2+ in biological systems by photolysis.

The alkaline earth cation complexes of DM-nitrophen [1-(2-nitro-4,5-dimethoxyphenyl)-N,N,N',N'-tetrakis-[(oxycarbonyl) methyl]- 1,2-ethanediamine)] release the bound cation in the millisecond time range upon irradiation by a short UV-light pulse. This technique allows to generate cation (eg. Ca2+) concentration jumps or pulses in solution or in cellular systems. The physico-chemical properties of DM-nitrophen and its Mg2+, Ca2+ and Ba2+ complexes are investigated by employing spectrophotometric and potentiometric techniques. In case of Ca2+ a stability constant of the complex up to nearly 10(11) M-1 is found. The magnitude of representative Mg2+ and Ca2+ concentration jumps which can be generated under realistic experimental conditions are calculated on the basis of the thermodynamic parameters reported here.