Motion compensation for in vivo subcellular optical microscopy.

In this review, we focus on the impact of tissue motion on attempting to conduct subcellular resolution optical microscopy, in vivo. Our position is that tissue motion is one of the major barriers in conducting these studies along with light induced damage, optical probe loading as well as absorbing and scattering effects on the excitation point spread function and collection of emitted light. Recent developments in the speed of image acquisition have reached the limit, in most cases, where the signal from a subcellular voxel limits the speed and not the scanning rate of the microscope. Different schemes for compensating for tissue displacements due to rigid body and deformation are presented from tissue restriction, gating, adaptive gating and active tissue tracking. We argue that methods that minimally impact the natural physiological motion of the tissue are desirable because the major reason to perform in vivo studies is to evaluate normal physiological functions. Towards this goal, active tracking using the optical imaging data itself to monitor tissue displacement and either prospectively or retrospectively correct for the motion without affecting physiological processes is desirable. Critical for this development was the implementation of near real time image processing in conjunction with the control of the microscope imaging parameters. Clearly, the continuing development of methods of motion compensation as well as significant technological solutions to the other barriers to tissue subcellular optical imaging in vivo, including optical aberrations and overall signal-to-noise ratio, will make major contributions to the understanding of cell biology within the body.

Use of independent component analysis to improve signal-to-noise ratio in multi-probe fluorescence microscopy.

In conventional multi-probe fluorescence microscopy, narrow bandwidth filters on detectors are used to avoid bleed-through artefacts between probes. The limited bandwidth reduces the signal-to-noise ratio of the detection, often severely compromising one or more channels. Herein, we describe a process of using independent component analysis to discriminate the position of different probes using only a dichroic mirror to differentiate the signals directed to the detectors. Independent component analysis was particularly effective in samples where the spatial overlap between the probes is minimal, a very common case in cellular microscopy. This imaging scheme collects nearly all of the emitted light, significantly improving the image signal-to-noise ratio. In this study, we focused on the detection of two fluorescence probes used in vivo, NAD(P)H and ANEPPS. The optimal dichroic mirror cutoff frequency was determined with simulations using the probes spectral emissions. A quality factor, defined as the cross-channel contrast-to-noise ratio, was optimized to maximize signals while maintaining spatial discrimination between the probes after independent component analysis post-processing. Simulations indicate that a ∼3 fold increase in signal-to-noise ratio using the independent component analysis approach can be achieved over the conventional narrow-band filtering approach without loss of spatial discrimination. We confirmed this predicted performance from experimental imaging of NAD(P)H and ANEPPS in mouse skeletal muscle, in vivo. For many multi-probe studies, the increased sensitivity of this 'full bandwidth' approach will lead to improved image quality and/or reduced excitation power requirements.

Rapid overlapping-volume acquisition and reconstruction (ROVAR): automated 3D tiling for high-resolution, large field-of-view optical microscopy.

Micrometer-scale three-dimensional data from fluorescence microscopes offer unique insight into cellular morphology and function by resolving subcellular locations of fluorescent dyes and proteins. To increase field-of-view size while using a high-resolution multiphoton microscope, we have created an automated system of rapidly acquiring overlapping image stacks from multiple fields-of-view along a nonplanar tissue surface. Each image stack is acquired only between the surface and the maximal penetrating depth, as determined by the image signal-to-background ratio. This results in the acquisition of the volume containing visible tissue along the tissue surface, excluding the empty volume above the tissue and the volume beyond the maximum imaging depth within the tissue. The automated collection of overlapping volumes is followed by reconstruction that can efficiently generate a single three-dimensional volume of the tissue surface. This approach yields data spanning multiple millimetres at micrometre resolution that is faster while requiring less work from the microscope operator. The advantages of the system are demonstrated by acquisition of data from intact, unfixed organs without a coverglass both in vivo and in situ.

Optimizing multiphoton fluorescence microscopy light collection from living tissue by noncontact total emission detection (epiTED).

A benefit of multiphoton fluorescence microscopy is the inherent optical sectioning that occurs during excitation at the diffraction-limited spot. The scanned collection of fluorescence emission is incoherent; that is, no real image needs to be formed on the detector plane. The nearly isotropic emission of fluorescence excited at the focal spot allows for new detection schemes that efficiently funnel all attainable photons to detector(s). We previously showed [Combs, C.A., et al. (2007) Optimization of multiphoton excitation microscopy by total emission detection using a parabolic light reflector. J. Microsc. 228, 330-337] that parabolic mirrors and condensers could be combined to collect the totality of solid angle around the excitation spot for tissue blocks, leading to ∼8-fold signal gain. Using a similar approach, we have developed an in vivo total emission detection (epiTED) instrument modified to make noncontact images from outside of living tissue. Simulations suggest that a ∼4-fold enhancement may be possible (much larger with lower NA objectives than the 0.95 NA used here) with this approach, depending on objective characteristics, imaging depth and the characteristics of the sample being imaged. In our initial prototype, 2-fold improvements were demonstrated in the mouse brain and skeletal muscle as well as the rat kidney, using a variety of fluorophores and no compromise of spatial resolution. These results show this epiTED prototype effectively doubles emission signal in vivo; thus, it will maintain the image signal-to-noise ratio at two times the scan rate or enable full scan rate at approximately 30% reduced laser power (to minimize photo-damage).

Oxygen consumption and cellular ion transport: evidence for adenosine triphosphate to O2 ratio near 6 in intact cell.

Oxygen (O2) consumption and net K+ uptake were measured simultaneously upon reintroduction of K+ into a K+-depleted suspension of renal tubules. The K+/O2 stoichiometries of 11.8 +/- 0.2 and 8.4 +/- 0.6 were obtained for reduced nicotinamide adenine dinucleotide- and flavoprotein-linked substrates, respectively. These values complement classical K+ to adenosine triphosphate (ATP) and ATP/O2 stoichiometries, thereby demonstrating a remarkably efficient coupling between the processes of Na+- and K+-dependent adenosinetriphosphatase-mediated ion transport and oxidative phosphorylation within the intact cell.

Relation between work and phosphate metabolite in the in vivo paced mammalian heart.

Nuclear magnetic resonance (NMR) spectroscopy was used to monitor, on a beat-to-beat basis, the concentration of creatine phosphate and adenosine triphosphate during alterations in the work output of canine hearts in vivo. Over a wide range of rate-pressure products (5,000 to 25,000 mmHg/min), the relative amounts of creatine phosphate and adenosine triphosphate within the heart remained constant. The relative concentration of free adenosine diphosphate was calculated under the reasonable assumption that the creatine kinase-catalyzed reaction is near equilibrium in this tissue. The free concentration of adenosine diphosphate also did not change over this range of rate-pressure products. The data demonstrate that the concentration of these compounds is highly regulated in vivo and suggest that factors other than their concentration may be involved in the modulation of steady-state myocardial work output with oxygen consumption.

Phosphorus-31 nuclear magnetic resonance analysis of transient changes of canine myocardial metabolism in vivo.

The time course of the relative myocardial phosphocreatine and adenosine triphosphate contents (PCr/ATP) during step changes in heart rate in vivo was studied in 14 dogs using 31P nuclear magnetic resonance (NMR) to determine if transient changes in the high energy phosphates occur with changes in cardiac work. Coronary sinus blood flow (CF), oxygen consumption (MVO2), and NMR data were simultaneously measured during brief (approximately 3 min), paced increases in heart rate in these open chest animals. 31P spectra were collected with a time resolution of 15-16 s (PCr signal to noise 22-41:1). Paced tachycardia associated with increased CF and MVO2 had no significant transient or sustained effect on PCr/ATP. Higher heart rates, associated with decreased CF and blood pressure, caused rapid decreases of PCr/ATP that were reversible upon return to control rates. These data indicate that there are no transient changes in 31P metabolites (on a 15-16-s time base) during step changes in cardiac work associated with increased CF. This lack of change demonstrates that ATP hydrolysis and production are closely matched and that the feedback mechanism linking these processes occurs rapidly with no detectable transient change in the phosphate metabolites. In contrast, when the CF response to tachycardia is insufficient PCr is quickly depleted. This latter result suggests that the PCr/ATP ratio may be a sensitive, rapidly responding indicator of coronary supply/demand mismatching in vivo.

Developmental changes in the relation between phosphate metabolites and oxygen consumption in the sheep heart in vivo.

This study examines the role of phosphate metabolites in the regulation of mitochondrial oxygen consumption of the heart in vivo as a function of development. We used an open chest lamb/sheep preparation in which myocardial oxygen consumption (MVO2) was monitored via an extracorporeal shunt from the coronary sinus. Phosphate metabolites were monitored simultaneously using 31P nuclear magnetic resonance with a surface coil overlying the left ventricle. Graded infusions of epinephrine were used to increase MVO2 in both neonatal lambs (age 5-12 d, n = 8), and mature sheep (26-86 d, n = 6). The maximal increase in MVO2 achieved was 220 +/- 38% in the newborns and 350 +/- 66% in the mature animals. Associated with these increases in MVO2 in the newborn lambs are significant (P less than 0.001) decreases in PCr/ATP, and increases in calculated ADP and intracellular Pi. This was in contrast to the mature sheep, in which there were no significant changes in PCr/ATP, ADP, or Pi. In conclusion, we find that (a) there are changes in PCr/ATP, Pi, and ADP in newborn animals with moderate increases in work that are not apparent in mature animals of the same species and (b) that these changes suggest that cytosolic ATP hydrolysis products may be more important in regulation of myocardial energy metabolism in the newborn than in the adult.

Spontaneous luminal disequilibrium pH in S3 proximal tubules. Role in ammonia and bicarbonate transport.

We determined whether a spontaneous luminal disequilibrium pH, pHdq (pH measured - pH equilibrium), was present in isolated perfused rabbit S2 and S3 proximal tubules. Luminal pH was measured by perfusing with the fluorescent pH probe 1,4-DHPN, and the equilibrium pH was calculated from the measured collected total CO2 and dissolved CO2 concentrations. S2 tubules failed to generate a spontaneous pHdq. S3 tubules generated a spontaneous acidic pHdq of -0.46 +/- 0.15 (P less than 0.05), which was obliterated following the addition of carbonic anhydrase (0.1 mg/ml) to the perfusate. In S3 tubules perfused and bathed in 4 mM total ammonia, luminal total ammonia rose from 4.08 +/- 0.05 mM (perfusate) to 4.95 +/- 0.20 mM (collected fluid) (P less than 0.02). Carbonic anhydrase added to the perfusate prevented the rise in the collected total ammonia concentration. We conclude that the rabbit S3 proximal tubule lacks functional luminal carbonic anhydrase. The acidic pHdq in the S3 segment enhances the diffusion of NH3 into the lumen. In contrast, the S2 segment has functional luminal carbonic anhydrase.

Inhibition of Renal Metabolism. Relative effects of arsenate on sodium, phosphate, and glucose transport by the rabbit proximal tubule.

These studies examine the inhibitory effects of arsenate on the transport of sodium, phosphate, glucose, and para-aminohippurate (PAH) as well as oxidative metabolism by proximal convoluted tubules from the rabbit kidney. Transport rates were measured with radioisotopes in isolated and perfused segments. Metabolic activity was monitored through oxygen-consumption rates and HADH fluorescence in parallel studies in suspensions of cortical tubules. The addition of 1mM arsenate to the perfusate reduced fluid absorption rates from 1.24 +/- 0.17 to 0.66 +/- 0.19 nl/nm.min (P < 0.01) and lumen-to-bath phosphate transport from 9.93 +/- 3.47 to 4.25 +/- 1.08 pmol/mm.min (P < 0.01). Similar concentrations of arsenate reduced glucose transport only slightly from 66.1 +/- 6.0 to 56.8 +/-4 4.6 pmol/mm.min (P < 0.05) and had no effect of PAH secretion. Removing phosphate from the perfusate did not affect the net transport of sodium or glucose. In suspensions of tubules, arsenate increased oxygen consumption rates by 20.5 +/- 2.9% and decreased NADH fluorescence by 10.8 +/- 1.5%. These effects on metabolism were concentration dependent and magnified in the presence of ouabain. The data indicate that arsenate's main effect is to uncouple oxidative phosphorylation, and that graded uncoupling of oxidative metabolism causes graded reductions in the net transport of both sodium and phosphate. Glucose transport is inhibited only slightly and PAH secretion is not affected. Thus, partial as opposed to complete inhibition of metabolism reveals that different relationships exist between net sodium transport and the transport of phosphate, glucose, and PAH by the proximal renal tubule.

Comparison of energy metabolism in human normal and neoplastic (Burkitt's lymphoma) lymphoid cells.

In order to detect possible differences in the energy metabolism between normal and neoplastic lymphoid cells, we studied purified normal human lymphocytes (FL) and transformed lymphoblastoid cell lines derived from umbilical cord blood (CL) and compared them to cell lines derived from American Burkitt's lymphoma (BL). The total adenosine triphosphate production rate by these cells was estimated by measuring O2 consumption and lactic acid production rates. O2 consumption (nmol/min/mg protein) was 4.9 +/- 0.3 (S.D.) in CL, 4.4 +/- 0.3 in FL, and 4.9 +/- 0.3 in BL. Lactic acid production (nmol/min/mg protein) was 30.9 +/- 3.0 in CL, 29.9 +/- 3.0 in FL, and 23.4 +/- 4.0 in BL. Using these values of O2 consumption and lactic acid production, the average adenosine triphosphate production rates (nmol/min/mg protein) were calculated to be 60 in CL, 56 in FL, and 53 in BL. We conclude that the BL do not have more aerobic glycolysis than do normal lymphoid cells, suggesting that the lactic acidosis seen in American Burkitt's lymphoma is not due to a preferential glycolytic metabolism of the tumor. More likely, the lactic acidosis is simply due to the large total mass of these neoplastic cells and not due to a modification of their energy metabolism.

The efficiency of (Na+ + K+)-ATPase in tumorigenic cells.

The efficiency of (Na+ + K+)-ATPase (i.e. the amount of K+ pumped per ATP hydrolyzed) in intact tumorigenic cells was estimated in this study. This was accomplished by simultaneously measuring the rate of ouabain-sensitive K+ uptake and oxygen consumption in tumorigenic cell suspensions during the reintroduction of K+ to K+-depleted cells. The ATP turnover was then estimated by assuming 5.6-6 ATP/O2 as the stoichiometry of NADH-linked respiration in these cells. In the three cell lines tested (hamster and chick embryo cells transformed with Rous sarcoma virus and Ehrlich ascites cells), the K+/ATP ratio was approximately 2, the same value as that found in normal tissues. Furthermore, only 20% of the total ATP production of these cells was used by (Na+ + K+)-ATPase.

Comparison of the effects of increased intracellular calcium and antidiuretic hormone on active sodium transport in frog skin. A study with the calcium ionophore A23187.

The addition of the Ca2+ ionophore A23187 (1 microM) to the inside solution of the frog skin resulted in an approx. 40% transient increase in the active influx of Na+ and ionic conductance, which decayed to an approx. 13% steady-state stimulation after 1--2 h. A23187 had no effect from the outside solution. A23187's stimulatory action is most likely the result of the ionophore's ability to increase intracellular Ca2+. This contention is supported by the following experimental results: (1) reintroduction of Ca2+ into a Ca2+-free inner solution stimulated Na+ transport only in the presence of A23187: (2) Mg2+ would not mimic these effects, and (3) EGTA in the inner solution would inhibit the A23187 response. The stimulation of active transport and ionic conductances elicited by A23187 were found to be very similar to those caused by antidiuretic hormone. Several lines of evidence suggest that A23187 may by-pass steps in the normal antidiuretic hormone stimulatory process: (1) A23187 and antidiuretic hormone are apparently non-additive; (2) A23187 acts three times faster than antidiuretic hormone; (3) A23187 stimulates antidiuretic hormone-insensitive frog skins, and (4) results from other laboratories indicate that A23187 does not increase cyclic AMP concentrations. It is speculated that an increase in free intracellular Ca2+ may be a step in the normal antidiuretic hormone stimulatory process. This increase in intracellular Ca2+ may in turn stimulate active sodium transport by increasing the Na+ permeability of the outer 'rate-limiting' membrane.

Changes in pyridine nucleotide levels alter oxygen consumption and extra-mitochondrial phosphates in isolated mitochondria: a 31P-NMR and NAD(P)H fluorescence study.

Isolated rat-liver mitochondria were used to study the relation between mitochondrial NADH levels, oxygen consumption (QO2), and extra-mitochondrial phosphates. Alterations in NADH and QO2 were accomplished by incubating mitochondria with different substrates or varying amounts of exogenous ATPase while monitoring QO2 and NAD(P)H fluorescence. Two sets of conditions were studied: (1) in the presence of excess ADP and inorganic phosphate, an increase in NAD(P)H fluorescence was associated with a linear increase in QO2; (2) when QO2 was driven by the steady-state hydrolysis of ATP by exogenous ATPase, increases in QO2 were associated with proportional decreases in NAD(P)H fluorescence. For all substrates tested this relation was linear; however, the slope was substrate dependent. Different substrates were able to maintain different NAD(P)H levels at the same QO2. To investigate this further, effects of changing substrates at constant QO2 on NAD(P)H and extra-mitochondrial phosphates were determined. Addition of glutamate + malate to mitochondria respiring on citrate caused a 50% increase in NAD(P)H fluorescence, a 41% decrease in ADP, and a 30% decrease in inorganic phosphate. Similar changes for the substrate jump, pyruvate + malate to glutamate + malate were found. Finally, it was determined that a linear relation holds between increases in NAD(P)H fluorescence and increases in QO2 when substrates were varied at constant, physiologic levels of extra-mitochondrial ADP. These results indicate that QO2 depends on NAD(P)H levels as well as on extra-mitochondrial phosphates over a wide range of respiratory rates.

Studies on the relationship between glycolysis and (Na+ + K+)-ATPase in cultured cells.

In several tissues a coupling between glycolysis and (Na+ + K+)-ATPase has been observed. We report here studies on the coupling of glycolysis and (Na+ + K+)-ATPase in Rous-transformed hamster cells and Ehrlich ascites tumor cells. The rate of (Na+ + K+)-ATPase was estimated by the initial rate of ouabain-sensitive K+ influx after K+ reintroduction to K+-depleted cells. Experiments were performed with cells producing ATP via oxidative phosphorylation alone (i.e., lactate sole substrate), glycolysis alone (i.e., glucose as substrate in the absence of oxygen or with antimycin A), or glycolysis and oxidative phosphorylation (i.e., glucose as substrate in the presence of oxygen). The cells produced ATP at approximately the same rate under all of these conditions, but the initial rate of K+-influx was approx. 2-fold higher when AtP was produced from glycolysis. Changes in cell Na+ due to other transport processes related to glycolysis, such as Na+-H+ exchange, Na+-glucose cotransport, and K+-H+ exchange were ruled out as mediators of this effect on (Na+ + K+)-ATPase. These data suggest that glycolysis is more effective than oxidative phosphorylation in providing ATP to (Na+ + K+)-ATPase to these cultured cells.

Muscle adenylate kinase catalyzes adenosine 5'-tetraphosphate synthesis from ATP and ADP.

Muscle adenylate kinases from rabbit and porcine sources were found by NMR to catalyze the formation of adenosine tetraphosphate (5'AdoP4) from adenosine triphosphate (ATP) and adenosine diphosphate (ADP). The reaction was completely reversible, with an equilibrium constant of approx. 0.1 at 30 degrees C. The synthesis of 5'AdoP4 from ATP and ADP occurred very slowly, taking over 12 h to reach equilibrium under the conditions used in this study. The sources of micromolar concentrations of 5'AdoP4 found in biological tissues is unknown: potentially, the slow adenylate-kinase-catalyzed breakdown and synthesis of 5'AdoP4 may serve as an important regulator of the steady-state concentration of 5'AdoP4 in muscle tissue.

Combination of 31P-NMR magnetization transfer and radioisotope exchange methods for assessment of an enzyme reaction mechanism: rate-determining steps of the creatine kinase reaction.

The theoretical analysis of a reversible enzyme reaction performed in this work shows that the 31P-NMR magnetization (saturation) transfer technique combined with a radioisotope exchange method may potentially provide information on the position of rate-determining step(s). It depends on chemical shifts of NMR signals of nuclei of interest in free and enzyme-bound forms of substrate(s) and product(s) of the reaction. The creatine kinase reaction (MgATP + creatine----MgADP + P-creatine) has been used as a model. Chemical shifts of 31P in binary, ternary and transitional state substrate-enzyme complexes have been estimated by the variable frequency saturation transfer (VFST) method. This method is based on selective irradiation of numerous points in the spectrum and observation of changes in the intensity of visible line(s) which occur due to chemical exchange between it and lines which are not visible in the routine spectrum. Also, dissociation rate constants of MgADP-containing complexes were determined. Magnetization exchange rates, P-creatine----[gamma-P]MgATP and [beta-P]MgADP----[beta-P]MgATP, were compared with radioisotope exchange rates, [gamma-32P-MgATP----P-creatine and [3H]MgADP----MgATP at different [P-creatine]/[creatine] ratios and at different temperatures. All these exchange rates were close to each other at 30-37 degrees C and [PCr]/[Cr] ratios lower than 2. It is concluded that phosphoryl group transfer is the rate-determining step of the overall creatine kinase reaction under these conditions. However, at lower temperatures (below 25 degrees C) or at high [PCr]/[Cr] ratios ([ADP] less than 20 microM) the rate-determining step seems to be shifted toward dissociation of nucleotide substrates from enzyme-substrate complexes, since exchange rates became significantly different. This approach is useful for analysis of mechanism of enzymatic reactions and also can be applied to non-enzymatic reactions and evaluation of small rapidly exchangeable metabolite pools.

Kinetics of creatine phosphokinase and adenylate kinase. A two-dimensional NMR analysis.

The kinetics of creatine phosphokinase and adenylate kinase catalyzed reactions were studied at equilibrium by two-dimensional Fourier transform phosphorus-31 nuclear magnetic resonance. For the creatine phosphokinase reaction, a pseudo-first-order rate constant of 0.29 s-1 was determined for the transfer of a phosphate group from adenosine triphosphate to creatine phosphate. For the adenylate kinase reaction two slow rate processes were required to describe the experimental results. The conversion of adenosine diphosphate to adenosine monophosphate was found to have a pseudo-first-order rate constant of 1.2 s-1, whereas that for the release of adenosine triphosphate from its enzyme complex occurred at a rate of 14 s-1.

On the mechanism of the amiloride-sodium entry site interaction in anuran skin epithelia.

The steady-state transport kinetics of the interaction between external sodium and the diuretic drug, amiloride, was studied in isolated anuran skin epithelia. We also investigated the effect of calcium on the amiloride-induced inhibition of short-circuit current (Isc) in these epithelial preparations. The major conclusions of this study are: (a) amiloride is a noncompetitive inhibitor of Na entry in bullfrog and grassfrog skin, but displays mixed inhibition in R. temporaria and the toad. A hypothesis which states that the interaction sites for amiloride and Na on the putative entry protein are spatially distinct in all of these species is proposed. (b) The stoichiometry of interaction between amiloride and the Na entry mechanism is not necessarily one-to-one. (c) The external Ca requirement for the inhibitory effect of amiloride is not absolute. Amiloride, at all concentrations, is equally effective in inhibiting Isc of bullfrog skin independently from the presence or absence of external Ca.