The effect of adenosinetriphosphate upon actomyosin solutions,studied with a recording dual beam light-scattering photometer

A recording dual beam light-scattering photometer is described which permits kinetic studies involving changes in turbidity, and which is not, as are single photocell instruments, affected by the errors due to the attenuation of the scattered light within the turbid medium. With this method, a renewed study has been made of the physical changes occuring in actomyosin under the influence of ATP.     

Differential Light Scattering from Spherical Mammalian Cells

The differential scattered light intensity patterns of spherical mammalian cells were measured with a new photometer which uses high-speed film as the light detector. The scattering objects, interphase and mitotic Chinese hamster ovary cells and HeLa cells, were modeled as (a) a coated sphere, accounting for nucleus and cytoplasm, and (b) a homogeneous sphere when no cellular nucleus was present. The refractive indices and size distribution of the cells were measured for an accurate comparison of the theoretical model with the light-scattering measurements. The light scattered beyond the forward direction is found to contain information about internal cellular morphology, provided the size distribution of the cells is not too broad.     

Effect of change in concentration upon lens turbidity as predicted by the random fluctuation theory.

Theoretical calculations were performed to predict how the light scattering intensity would change with changes in concentration in the gel state. The theory of light scattering was applied to a random distribution of hard spheres. The spherical particles with constant diameter were embedded in a medium having a different refractive index. The light-scattering intensities obtained as a function of concentration showed that in dilute solutions the scattered light intensity increases with concentration. However, in concentrated solution greater than 0.1 or 0.2 volume fraction, the light-scattering intensity decreases with increase in concentration.     

Fluorescence and light-scattering measurements on hog cholera-infected PK-15 cells

Differences in fluorescence distributions and light-scattering patterns have been observed from hog cholera-infected and noninfected PK-15 cells. The fluorescence measurements were made with the Los Alamos flow microfluorometer (FMF) using fluorescent antibody staining procedures on fixed cells. The FMF technique has several advantages over traditional microspectrophotometry; it permits rapid, individual measurements on large numbers of cells using a flow system. The light scattered from 2–30 ° by suspensions of live infected and noninfected cells was measured with a new photometer which uses high-speed film as the detector.     

NADH-synergism of NADPH-dependent o-dealkylation of type II compounds, p-anisidine and p-phenetidine, in rat liver microsomes.

When fresh citrated platelet-rich plasma was stirred at 900 rpm, stopping the stirrer increased the extinction, E (optical density, absorbance), of the plasma by 25%. After the platelets from humans or rabbits had changed shape on the addition of ADP, stopping the stirrer increased E by only about 2%. Assuming the shape of a platelet to approximate an ellipsoid of revolution which is originally flat and becomes more or less spherical after ADP, the effects of stirring on extinction are accounted for with conventional light-scattering theory. The change in extinction caused by stirring is the basis of a proposed nondestructive and remote assay of platelet shape. Extinction changes induced by chlorpromazine, which causes disk-sphere transformation only, are found to agree with theoretical predictions based on the shape change. The effects of ADP, which also produces pseudopods, are systematically smaller. The optical effects of shape and pseudopods can be separated: those of shape are sensitive to stirring, while those of pseudopods are not. ADP evidently produces a 37% increase in extinction of stirred platelets due to disk-sphere transformation plus a 9% decrease due to pseudopod formation (net increase, 28%). With simplified models of pseudopods, light-scattering theory is found to confirm that pseudopod formation should cause a decrease in extinction and total light scattering.     

Low-angle light-scattering instrument for DNA solutions

A light-scattering instrument capable of measurements on native DNA at angles as low as 10° is described. The major features of the instrument, which make it capable of low-angle measurements, are the use of an intense light source in which the incident beam is monitored directly and the use of a long, rectangular sample cell in which the scattered light can be measured at low angles with no interference from the incident beam. Methods for calibrating the instrument and for determining scattering correction factors are described. Procedures for the preparation and use of various calibration standards are given.     

A light-scattering pressure-jump kinetics apparatus.

We have developed an optical sample cell made of stainless steel and fitted with three quartz ultracentrifuge windows in standard holders, to follow the kinetics of macromolecular reactions by the pressure-jump technique. Photomultiplier response to transmitted white light is continuously subtracted from photomultiplier response to white light scattered at 90°C, the difference being displayed by an oscilloscope. The pressure is simultaneously monitored by a quartz pressure sensor in mechanical contact with the sample. Pressurization is accomplished by leading in gas from a commercial cylinder, as originally described by Ljunggren and Lamm, but the pressurization time has been reduced by a factor of 25, to 2 millisec, by valving off a fixed volume of helium and introducing it into the sample cell through a high-speed solenoid valve. Determinations may be repeated at will on a single sample, of total volume under 2 ml. This light-scattering pressure-jump apparatus has been used to observe the kinetics of a number of macromolecular interactions and to determine rate constants for the ribosome-subunit interaction of Escherichia coli.     

The differential scattering of circularly polarized light by chloroplasts and evaluation of their true circular dichroism

Chloroplasts isolated from pea leaves display an intense circular dichroism in the range 600 to 720nm. Circularly polarized light is also differentially scattered by chloroplasts, and this effect can be confused with circular dichroism. By using an instrumental modification it was possible to distinguish, and record separately, the ellipticities of the transmitted light (circular dichroism) and of the scattered light in the same c.d. instrument. By means of a light-scattering apparatus, the intensity of unpolarized light scattered by chloroplasts was measured as a function of wavelength and of angle. This measurement allowed the aforementioned ellipticities to be corrected for mutual interference. At a concentration of 4mug of chlorophyll/ml (the optimum practical concentration of chloroplasts at which there was no significant interaction of scattering and absorption effects) spectra of true circular dichroism (circular differential absorption) and circular differential scattering were obtained. The former showed maxima, positive at 688nm and negative at 676nm, with an intensity Deltatheta=8.3m degrees .litre.(mg of chlorophyll)(-1).cm(-1). The latter had a maximum at 683nm with an intensity of +47m degrees with respect to the solvent baseline; this value is independent of the concentration of chloroplasts in dilute suspensions. It is suggested that the intense circular dichroism of chloroplasts reflects specific chlorophyll-chlorophyll interactions in the light-harvesting pigment. The advantages of this method for determining the c.d. of scattering suspensions over those of other investigators are discussed.     

Effect of sonication on nucleotide-dependent light scattering changes in retinal rod outer segment suspensions.

Near-infrared light scattering from suspensions of rod outer segment fragments is a useful probe of visible-light-activated changes in peripheral membrane proteins in photoreceptor cells. Limited sonication of suspensions has been shown to increase the amplitude of light induced turbidity changes in the presence of guanosine triphosphate by a factor of 2. Further sonication led to a decrease in the signal amplitude by an order of magnitude. This reduction has been puzzling, since the activity of the GTP-binding protein (as measured by GTP hydrolysis turnover number) was unaffected by the range of sonication used. This effect of sonication is investigated here using a novel, Reticon-based apparatus that measures the angular distribution of scattered light from samples as small as 1 microliter. The results show that even at high rhodopsin concentrations (125 microM) with millimeter path lengths, significant amounts of unscattered light are transmitted by the samples. A simple phenomenological theory that assumes a constant fractional change in scattering power (15%), independent of amount of sonication, explains the effect of sonication on the angle dependence data as well as the original turbidity data. The results have general relevance for optimization of light-scattering studies of membrane systems.     

Bacteriorhodopsin induces a light-scattering change in Halobacterium halobium

When suspensions of Halobacterium halobium are exposed to bright light, the light-scattering properties of the bacteria change. This light-scattering response can produce a transmission decrease of about 1% throughout the red and near-infrared region. The action spectrum for the light-scattering response appropriately matches the absorption spectrum of bacteriorhodopsin. The response is eliminated by cyanide p-trifluoro-methoxyphenylhydrazone, a proton ionophore, and by triphenylmethylphosphonium, a membrane permanent cation. A mild hypertonic shock induces a similar light-scattering change, suggesting that bright light causes the bacteria to shrink about 1% in volume, thereby producing the light-scattering response.     

Periodic cell aggregation in suspensions of Dictyostelium discoideum

Abstract. Periodic activities of Dictyostelium discoideum can be observed in cell suspension as two types of oscillations in the light-scattering properties, spike-shaped and sinusoidal. Responses of suspended cells to applied chemoattractants are also reflected by transient changes in light scattering. Alterations in the light-scattering properties are due to structural changes such as changes in cell shape and/or changes in the size of cell aggregates. Therefore, changes in the aggregation state during autonomous oscillations and during attractant-induced responses were investigated. In order to be able to withdraw multiple samples and larger sample volumes from optically monitored cell suspensions, a photometer comprising glass fiber optics immersable in a cell suspension was constructed. Samples were fixed with formaldehyde and photographed. The aggregation state of the samples was quantified by counting the number of particles (cells and cell aggregates) per volume. Folic acid elicited in suspensions of undifferentiated cells a transient decrease in the number of particles per volume as did cAMP in suspensions of preaggregation cells. Periodic changes in the number of particles per volume occurred synchronously with spike-shaped and sinusoidal oscillations. The relative amplitude of the oscillations in particle number was larger during sinusoids than during spikes. Photographs showed periodic changes in the aggregate size during sinusoidal oscillations. In each cycle, the cell-aggregation phase was followed by a phase of partial disaggregation. The recurring loosening of cell-cell contacts may be relevant for sorting out the different cell types. The potential role of contact site as synchronizer and as constituent of an oscillator is discussed.     

Automated scanning of bone marrow cell colonies growing in agar-containing glass capillaries

An optical scanning system was developed to determine the growth of clusters and colonies of granulocytes and macrophages from mouse bone marrow cells in agar capillary tubes. The system consists of a commercially available photometer with a densitometer attachment, a two-mirror set to receive the light scattered by the cell colonies, a multiple capillary holder and an automatic sample changer. Parameters affecting scanning were examined and optimized: background scatter, instrument adjustments (e.g. signal damping) and threshold settings for clusters and colonies. Combined with the advantageous agar capillary technique, the complete scanning system provides an easy, accurate and sensitive method for rapid quantitation of hemopoietic cell colony formation in vitro.     

Spherical scatters in the lens of Acrossocheilus hexagonolepis as revealed by scanning electron microscopy and UV-visible spectroscopy

Scanning electron microscopy revealed the presence of spherical granules 0.25-0.75 micron in diameter in the lens fibres of the hill stream fish Acrossocheilus hexagonolepis. The density of the granules was approximately 8,500 per mm2. The size of the particles and their distribution pattern suggested they functioned in spherical scattering of the light. The absorbance and transmittance of light at different wavelengths obtained from the spectroscopic analysis of the lens indicated that a small percentage of light was neither absorbed nor transmitted. Since reflection usually does not take place from the ocular refractive structure, it may be that this proportion of the light was scattered from the lens.     

Optical coherence microscopy. A technology for rapid, in vivo, non-destructive visualization of plants and plant cells

We describe the development and utilization of a new imaging technology for plant biology, optical coherence microscopy (OCM), which allows true in vivo visualization of plants and plant cells. This novel technology allows the direct, in situ (e.g. plants in soil), three-dimensional visualization of cells and events in shoot tissues without causing damage. With OCM we can image cells or groups of cells that are up to 1 mm deep in living tissues, resolving structures less than 5 microm in size, with a typical collection time of 5 to 6 min. OCM measures the inherent light-scattering properties of biological tissues and cells. These optical properties vary and provide endogenous developmental markers. Singly scattered photons from small (e.g. 5 x 5 x 10 microm) volume elements (voxels) are collected, assembled, and quantitatively false-colored to form a three-dimensional image. These images can be cropped or sliced in any plane. Adjusting the colors and opacities assigned to voxels allows us to enhance different features within the tissues and cells. We show that light-scattering properties are the greatest in regions of the Arabidopsis shoot undergoing developmental processes. In large cells, high light scattering is produced from nuclei, intermediate light scatter is produced from cytoplasm, and little if any light scattering originates from the vacuole and cell wall. OCM allows the rapid, repetitive, non-destructive collection of quantitative data about inherent properties of cells, so it provides a means of continuously monitoring plants and plant cells during development and in response to exogenous stimuli.     

A diffused-optics flash kinetic spectrophotometer (DOFS) for measurements of absorbance changes in intact plants in the steady-state

Measurements of steady-state light-induced absorbance changes in intact plants are often hindered by interference from large changes in the light-scattering properties of the chloroplasts. In this work we present a new instrument, the diffused-optics flash spectrophotometer (DOFS), which reduces the magnitude of light scattering interference to manageable levels. In this spectrophotometer, the conventional light path is replaced with a set of light-scrambling chambers formed from a highly light-scattering plastic. The main scrambling chamber acts both to homogeneously diffuse as well as to split the measuring beam into sample and reference channels. Since the measuring beam has no defined incident angle, it is essentially 'pre-scattered', and further scattering changes that occur in the sample have minimal effect on the apparent absorbance changes. The combination of a pulsed probe light and differential optics and electronics provides a high signal-to-noise ratio, stable baseline and high time resolution. We also introduce a technique to account for residual scattering changes. Sets of measurements are made with the instrument in optical configurations that are differentially sensitive to light-scattering changes but yield nearly identical absorbance changes. The difference in apparent absorbance spectra taken with the two configurations reveals the spectral shape of the scattering changes without interference from absorbance signals. Spectra of the scattering contributions are then used to eliminate residual scattering interference from kinetic traces. We suggest that DOFS is ideally suited for study of steady-state electron transfer reactions in intact plants.     

Twin-beam laser velocimeter for the investigation of spermatozoon motility

Previous laser light-scattering studies of spermatozoon motility have been hampered by the large, asymmetric shape of spermatozoa, which causes difficulties in the interpretation of intensity fluctuations in the light scattered from a single laser beam. This paper describes an experimental arrangement for measuring the distribution of transit times for swimming spermatozoa using two slightly separated, focused laser beams. The theory of operation of the instrument is developed to enable the analysis of the experimentally obtained cross-correlation functions. The effects of the pronounced spermatozoon asymmetry and associated intensity modulation in the scattered light are also investigated and shown to be negligible for the twin beam experimental arrangement, provided that the swimming speed distribution has a coefficient of variation (sigma/upsilon greater than 0.1. Results obtained using this apparatus are presented for the velocity distribution of spermatozoa from a variety of bulls.     

An artifact in measurements of in vivo light-induced absorbance changes

The effects of scattered actinic radiation on photomultipliers (Hamamatsu R-562) were investigated. Using cotton-wool to model dense biological preparations, it was found that the scattered actinic radiation received by the photomultiplier gives rise to phytochrome-like signals. This demonstrated the necessity to shield the photomultiplier from scattered actinic light for sensitive measurements with light-scattering preparations.     

A method for measuring sedimentation and diffusion of macromolecules in capillary tubes by total intensity and quasi-elastic light-scattering techniques.

Light scattered from a macromolecular solution in a capillary tube is used to determine both the sedimentation and translational diffusion coefficients. The capillary tube is spun in a preparative centrifuge, removed, and placed in a light-scattering photometer equipped with a scanning mechanism. The intensity distribution of scattered light along the tube represents the concentration profile in the tube and provides the measure of boundary migration. The sedimentation coefficient is determined from this measure and the applied centrifugal field. The diffusion coefficient is obtained from a time-autocorrelation analysis of fluctuations in intensity of light scattered from any fixed point of the profile. These coefficients were obtained for two monodisperse systems, R17 bacteriophage and 28s ribosomal rat liver RNA. The molecular weights obtained from ratios of these coefficients are in good agreement with literature values. In the sedimentation analysis, deviations from linearity between boundary displacement and applied field were found to be less than 1%. This precision confirms that the boundary is stable for the capillary geometry even in the absence of a preformed density gradient. The sedimentation coefficients of identical samples were also measured with the Spinco Model E analytical ultracentrifuge; results of the two methods agree to within 4%. As a consequence of the capillary tube geometry and light-scattering detection, sedimentation coefficients can be obtained from sample volumes of less than 100 μl. This detection techniques is thus far demonstrated to be at least an order of magnitude more sensitive than Schlieren optics, thereby useful when uv absorption is not applicable. For diffusion measurements there are also several inherent advantages. The diffusion coefficient is obtained from the identical sample, and scanning provides the capability to measure D from various parts of the sedimentation profiles and thereby directly explore concentration dependence, homogeneity, and integrity of the sample. The capillary tube with a layer of silicone oil over the sample and centrifugation provides an effective method to cleanse the solution and trap all dust.     

Discrimination of eukaryotic phytoplankton cell types from light scatter and autofluorescence properties measured by flow cytometry

Flow cytometric methods for recognizing several groups of eukaryotic marine phytoplankton were tested using 26 laboratory cultures. Each culture was divided into three aliquots, and these samples were analyzed for 1) Coulter volume; 2) light scatter (magnitude and polarization properties of forward scattered light and magnitude of right-angle scattered light) and autofluorescence emission (phycoerythrin and chlorophyll); and 3) autofluorescence excitation (by 488 nm and 515 nm light). Three kinds of cells could be easily distinguished from others in the culture collection: 1) The two cryptophytes and the rhodophyte had high phycoerythrin/chlorophyll ratios; 2) the two coccolithophores depolarized forward scattered light; and 3) the two pennate diatoms scattered only a relatively small amount of light in the forward direction compared with that at right angles. Mean chlorophyll fluorescence excited by blue light relative to that excited by green light was highest in the four chlorophytes, but there was overlap between some of these and some other kinds of cells. Unresolved cell types included centric diatoms, dinoflagellates, and naked coccolithophores. Forward light scatter and Coulter volume were closely related (except for the pennate diatoms) over a range of about 0.01 to 30 pL (equivalent spherical diameter about 3 to 40 microns), according to a logarithmic function.