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Micro-Volume Couette Flow Sample Orientation for Absorbance and Fluorescence Linear Dichroism

Rachel Marrington ^*, Timothy R. Dafforn , David J. Halsall  and Alison Rodger ^*

^* Department of Chemistry, University of Warwick, Coventry, CV4 7AL, United Kingdom; Biosciences, University of Birmingham, Edgbaston, Birmingham, B15 2TT, United Kingdom; and Department of Clinical Biochemistry, Addenbrooke's Hospital, Cambridge, CB2 2QQ, United Kingdom

Correspondence: Address reprint requests to Alison Rodger, E-mail: a.rodger{at}warwick.ac.uk.

	ABSTRACT

TOP ABSTRACT INTRODUCTION MATERIALS AND METHODS RESULTS CONCLUSIONS APPENDIX ACKNOWLEDGEMENTS REFERENCES

 
Linear dichroism (LD) can be used to study the alignment of absorbing chromophores within long molecules. In particular, Couette flow LD has been used to good effect in probing ligand binding to DNA and to fibrous proteins. This technique has been previously limited by large sample requirements. Here we report the design and application of a new micro-volume Couette flow cell that significantly enhances the potential applications of flow LD spectroscopy by reducing the sample requirements for flow linear dichroism to 25 µL (with concentrations such that the absorbance maximum of the sample in a 1-cm pathlength cuvette is 1). The micro-volume Couette cell has also enabled the measurement of fluorescence-detected Couette flow linear dichroism. This new technique enables the orientation of fluorescent ligands to be probed even when their electronic transitions overlap with those of the macromolecule and conversely. The potential of flow-oriented fluorescence dichroism and application of the micro-volume Couette LD cell are illustrated by the collection of data for DNA with minor groove and intercalating ligands: DAPI, Hoechst, and ethidium bromide. As with conventional fluorescence, improved sensitivity compared with absorbance LD is to be expected after instrumentation optimization.

	INTRODUCTION

TOP ABSTRACT INTRODUCTION MATERIALS AND METHODS RESULTS CONCLUSIONS APPENDIX ACKNOWLEDGEMENTS REFERENCES

 
Linear dichroism (LD) is a phenomenon caused by the differential absorption of light polarized parallel and perpendicular to an orientation axis. It has a long history and a wide range of applications, all requiring a means of orienting the sample. For biological molecules, where the sample has to be hydrated, the most versatile sample orientation method has proved to be solution phase Couette flow orientation (Bloemendal and Vangrondelle, 1993; Hofricheter and Eaton, 1976; Nordén et al., 1992; Rodger, 1993). The main applications of such flow LD to date have been to DNA and DNA drug systems (Nordén et al., 1992; Wada, 1964; Wada and Kozawa, 1964). Recent applications of LD for structural characterization of biomacromolecular systems include both membrane-bound and fibrous proteins, which can be difficult to study using other methods (Dafforn et al., 2004; Johansson and Davidsson, 1985; Rodger, 1993; Rodger et al., 2002). However, despite recent sample reduction (Rodger et al., 2002), the sample requirements of flow LD experiments to date (200 µL of a sample whose absorbance is 1 in a 1-cm cuvette) has precluded its use in systems where limited material is available.

Couette cells are derived from the work of Couette (1890) and were first developed into an instrument for flow dichroism by Wada and Kozawa (1964). Sample orientation is effected by viscous drag generated by a flow gradient imposed on solution flowing in a narrow gap between the walls of a rotating cylindrical cell (Fig. 1). Previous studies have used either a rotating inner and fixed outer cylinder (Wada and Kozawa, 1964), or a rotating outer and fixed inner cylinder (Lee and Davidson, 1968; Oriel and Schellman, 1966). The former design offers more flow stability and has been the most popular. The light path through the cell is made of ultraviolet (UV) transparent materials, usually quartz, that allow optimal transmission of light. If the center rotates then it needs to be made of optically transparent material and the stationary outer cylinder requires at least two transparent windows, and vice versa. The incident light beam can be either perpendicular (Wada and Kozawa, 1964) or parallel (Lee and Davidson, 1968) to the axis of rotation. We adopt the perpendicular orientation in all of our applications.

View larger version (15K): [in this window] [in a new window]   FIGURE 1  Schematic diagram of LD flow Couette cell.

View larger version (21K): [in this window] [in a new window]   FIGURE 2  Schematic diagram showing the capillary and rod assembly in the micro-volume Couette cell.

View larger version (78K): [in this window] [in a new window]   FIGURE 3  (a) Photograph of micro-volume Couette flow cell and (b) schematic diagram of micro-volume Couette flow cell.

The LD for a given transition depends on the orientation of the sample (as summarized by the orientation parameter S) and the angle between the macroscopic orientation axis and the transition moment according to Eq. 1:

(1)

where LD^r is the reduced linear dichroism and A is the absorbance by the sample (in practice, we measure this independently and scale to adjust for pathlength differences between the LD and absorbance experiment).

	MATERIALS AND METHODS

TOP ABSTRACT INTRODUCTION MATERIALS AND METHODS RESULTS CONCLUSIONS APPENDIX ACKNOWLEDGEMENTS REFERENCES

 
Design of micro-volume Couette flow LD cell
A cross section of the micro-volume Couette flow LD cell is shown in Fig. 4. This was designed and built by Crystal Precision Optics, Rugby, UK. The major innovation in our design is the use of quartz capillaries and rods to hold and orient the sample (Glass Precision Engineering, Leighton Buzzard, UK and Enterprise-Q, Manchester, UK). The capillary units are demountable for removal during cleaning and sample loading. This also provides the possibility for use as a disposable sample holder, an attractive idea in the case of some samples. In this work, the capillaries are sealed at the base with Araldite Rapid (Bostik Findley, Stafford, UK) and held in position in the metal base unit by an "O"-ring. A quartz rod is held suspended rigidly from the lid and is inserted into the capillary before operation (Fig. 2).

View larger version (40K): [in this window] [in a new window]   FIGURE 4  General arrangement drawing showing detail of quartz micro-volume Couette flow LD cell.

View larger version (10K): [in this window] [in a new window]   FIGURE 5  A chart to show the relationship between voltage and rpm of the capillary.

Due to the size of the surface area of the capillary and the need to have light incident only on the middle front and back of the solution (otherwise an averaging over samples oriented perpendicular and parallel to the propagation direction would occur) a 2.54-cm diameter x 10-cm focal length lens (Edmund Optics, York, UK) was placed 10 cm in front of the center of the rod. The beam diverges after the capillary unit (in part due to the first lens and in part due to the capillary/rod), so a second lens (2.54-cm diameter x 6-cm focal length) was placed after the sample to focus the light onto the PMT, thereby improving the signal/ noise ratio by maximizing the number of photons reaching the PMT. The focal length of this lens can be varied somewhat without compromising the quality of the data.

The micro-volume 180° Couette flow LD cell was adapted to detect light emitted at 90° by drilling an extra exit hole in the capillary housing at 90° from the path of the incident beam and putting a long focal length lens (2.54-cm diameter x 15-cm focal length) close to this hole to capture and focus maximum light onto the PMT (which is located further from the cell in this configuration).

The minimum volume of sample required depends on the amount of Araldite Rapid used to seal the bottom end of the capillaries because the height of the light beam and the O-ring are fixed. In our standard system a depth of 4 mm Araldite Rapid was used to seal the capillaries, the rod was lowered to 1 mm above this when fully assembled, and the total pathlength of the system was 500 µm. Volumes of at least 25 µL gave the same LD signal, however, higher volumes (e.g., 40 µL) are easier to load without introducing bubbles.

Construction of micro-volume Couette flow LD cell
A major consideration when constructing the micro-volume Couette LD cell was to ensure the rotating quartz capillary and the stationary quartz rod remained parallel. The main body of the micro-volume Couette LD cell is manufactured from laboratory and food industry specification stainless steel (Fig. 4). The bearings and drive spindle were also stainless steel and designed to be dust and water resistant. The drive spindle has a precision-located rubber insert to maintain parallelism and friction drive. The baseplate has been designed specifically for a Jasco CD spectropolarimeter (Tokyo, Japan) with a large sample compartment, but can readily be modified for other CD spectropolarimeters. The base incorporates positioning dowels. These are sufficient to ensure that the cell body is automatically located to line up with the center of the light beam.

The stationary suspended quartz rod is held firmly in position by a cell cap. This has been designed to enable different diameter rods to be installed, allowing the option of changing the annular gap between the inside of the capillary and the outside of the rod without losing the axial parallelism between the capillary and the rod. The base unit of the LD cell has three slots to hold the lenses machined to an accuracy of 10 µm in the linear path and 0.001° in the 90° plane to ensure concentricity in all paths relative to the center line of the rotating capillary. The lens holders were fabricated to ensure that the center of the lens was concentric with the center of the capillary and vertically with the light beam. The optical pathlength of the beam could be adjusted by the linear movement of the lenses along the precision-machined slide ways.

DNA and ligand preparation
Calf thymus DNA, highly lypholized, and the well-characterized DNA groove binders 4',6-diamidino-2-phenylindole (DAPI) and bisbenzimide H33258 (Hoechst), and ethidium bromide were all supplied by Sigma (Poole, UK). Stock solutions were prepared in water (18.2 M). DNA solutions were prepared by hydration of ct-DNA overnight in deionized water. Concentrations of ct-DNA were determined spectrophotometrically using the molar absorption coefficient per base of ₂₅₉ = 6600 M^–1 cm^–1 (Wells et al., 1970). High-purity groove binders/intercalators were used and their concentrations determined by mass using a Sartorius supermicro seven-figure balance (Goettingen, Germany).

Control and validation experiments
The effect of using capillaries as a sample holder for LD and FDFLD was investigated by comparing to reference data collected for LD, CD, and fluorescence. For LD, comparisons against a large-volume Couette flow LD cell (1800 µL) with an inner quartz cylinder that rotates within a steel housing unit with two quartz windows (pathlength 1 mm) was undertaken using ct-DNA solutions at a range of concentrations from 0 to 1000 µM in sodium cacodylate buffer (10 mM, pH 7, Sigma) and NaCl (10 mM, Sigma) (Rodger, 1993). Buffer baseline subtracted LD data were collected from 400 to 190 nm at a data pitch of 0.5 nm, scanning speed of 500 nm min^–1, a response of 0.25 s, bandwidth of 2 nm, and averaging over four scans. CD analysis using ammonium camphor sulphonate (0.02% w/v, Jasco) was carried out with the capillary stationary within the baseplate setup and the spectra compared with a 5-mm pathlength quartz cuvette in the normal position for CD analysis. Water baseline corrected CD data were collected between 350 and 185 nm every 0.5 nm, scanning at 200 nm min ^–1, a response of 0.5 s, bandwidth of 2 nm, and averaging eight scans. Both of these measurements were collected using the Jasco J-715 spectropolarimer in appropriate modes. Fluorescence data were collected using a Perkin Elmer LS50B fluorimeter (Buckinghamshire, UK) not adapted for the use of capillaries, comparing a masked (mimicking the location of the rod) capillary and a 5-mm pathlength quartz cuvette with four polished sides. Aqueous solutions of ct-DNA (317 µM, Sigma), ethidium bromide (30 µM, Sigma) in sodium cacodylate buffer (10 mM, pH 7, Sigma), and NaCl (10 mM, Sigma) were used. Buffer baseline corrected data were collected in excitation mode with the emission wavelength set at 0 nm. Fluorescence data were collected from 600 to 200 nm at a scanning speed of 200 nm min^–1, excitation slit widths of 5 nm, and emission slit widths of 2.5 nm. Data were averaged over four scans.

The design of the micro-volume Couette LD cell at present is such that all samples need to be preprepared and loaded into a clean capillary, as it is not possible to remove and replace the rod unit and accurately titrate into the capillary. Validation of the micro-volume Couette LD cell was carried out using ct-DNA (200 µM) comparing repeat analyses in the same capillary and different capillaries. Data were collected using the parameters detailed above under LD control experiments. Analysis of the negative signal at 259 nm yielded information about the errors associated with sample reloading and cell reassembly.

DNA-ethidium bromide binding validation experiments
An application of the micro-volume Couette LD cell is in the analysis of DNA-ligand binding. An example of the binding of ethidium bromide, a classical intercalator, and DNA is shown in this article. The concentration of ct-DNA was held constant at 200 µM and the concentration of ethidium bromide was varied from 5 to 50 µM in 5-µM increments. All solutions were buffered at pH 7.0 using sodium cacodylate buffer (10 mM, Sigma) and contained NaCl (10 mM, Sigma).

LD and fluorescence linear dichroism experiments of DNA-ligand complexes
Applications involving LD and FDFLD of ligands binding to DNA are also reported here. The fluorescent ligands chosen include ethidium bromide, a DNA intercalator with 90°, and two DNA minor groove binders, Hoechst and 4',6-diamidino-2-phenylindole (DAPI) with 45° for long-axis polarized transitions and 90° for short-axis polarized transition. These ligands were expected to provide both positive and negative LD and/or FDFLD signals at a range of different wavelengths. LD and FDFLD experiments of DNA-ligand complexes were performed using calf thymus DNA and groove binder/intercalator solutions of concentration 1000 µM and 50 µM, respectively, thus giving a mixing ratio of 20:1. The solutions were buffered at pH 7 using sodium cacodylate (10 mM, Sigma).

LD and FDFLD data were collected using a Jasco J-715 circular dichroism spectropolarimeter with a large sample compartment that was adapted for LD measurements by turning the PEM into an oscillating half-wave plate. CD artifacts are less likely with this configuration than when a quarter-wave plate is added to an unadapted CD machine. There is no evidence in any spectra of such artifacts. All spectra were taken at room temperature (23°C) using the same quartz capillary and rod with the following parameters: 600–200 nm, data pitch 0.5 nm, scan speed 500 nm min^–1, response 0.25 s, bandwidth 2 nm, and averaged over four separate scans. The corrected spectra were calculated by subtracting a baseline from the stationary capillary, when no LD signal would be present.

UV-visible absorbance spectra and fluorescence spectra were recorded using a Jasco V-550 UV-visible spectrophotometer and a Perkin Elmer LS50B fluorimeter, respectively. A 1-mm pathlength quartz cuvette was used to collect UV spectra of ct-DNA and ligands, and a 1-cm pathlength cuvette used for the concentration determination of ct-DNA. Fluorescence excitation spectra were collected in a 5-mm pathlength cuvette with the emission wavelength set to 0 nm, which means all wavelengths emitted and scattered light are collected. This was done to reflect fluorescence data collected in the micro-volume Couette LD system, because the J-715 spectropolarimeter does not have a second monochromator. For fluorescence measurements of the groove binders (DAPI and Hoechst) an excitation slit width of 4 nm and emission slit width of 2.5 nm were used, whereas for ethidium bromide an excitation slit width of 10 nm and emission slit width of 5 nm was used. Data were averaged over four scans at 200 nm min^–1 scanning speed.

Fluorescence LD control experiments were also carried out using both ct-DNA (1000 µM) and each respective drug (50 µM) at pH 7.0 to ensure that the signal being detected is not due to background scatter or intrinsic properties of the components of the DNA-ligand mixtures.

	RESULTS

TOP ABSTRACT INTRODUCTION MATERIALS AND METHODS RESULTS CONCLUSIONS APPENDIX ACKNOWLEDGEMENTS REFERENCES

 
Verification that capillaries as sample holders do not distort spectra
Control linear dichroism (capillary system versus large-volume Couette flow LD cell with a pathlength of 1 mm), circular dichroism (3-mm inner diameter (i.d.) capillary versus 5-mm pathlength rectangular cuvette) and fluorescence (3-mm i.d. capillary versus 5-mm square fluorescence cuvette) experiments using the capillaries were carried out to show that there are no intrinsic problems with undertaking spectroscopic experiments in the extruded quartz capillaries.

LD spectra of ct-DNA in the range 0–1000 µM measured with the micro-volume Couette LD cell were able to be rescaled so that there was good agreement with data collected in the standard Couette cell across the whole wavelength range down to 200 nm (data not shown). All spectra were consistent with those in the literature (Hofricheter and Eaton, 1976; Houssier et al., 1974; Lee and Davidson, 1968; Nordén et al., 1992; Nordén and Kurucsev, 1994; Simonson and Kubista, 1993; Wada, 1964; Wilson and Schellman, 1978).

CD measurements were undertaken using ammonium camphor sulfonate (0.02% w/v), a standard routinely used for the calibration of CD spectropolarimeters. It yields two signals, a negative signal at 192.5 nm and the other a positive signal at 290.5 nm, with the ratio of the two being 2 (Lowry, 1935; Miles et al., 2003; Takakuwa et al., 1985). The i.d. of the capillaries used is three-fifths that of the reference quartz cuvette. The 3-mm i.d. capillary when rescaled by the appropriate pathlength gave a very good agreement with the reference cuvette data down to 190 nm (data not shown). This shows that the capillary is giving accurate data down to these wavelengths.

Both the LD and CD validation experiments were done with the capillary in the Jasco J-715 CD spectropolarimeters with holders that have been designed for that instrument's baseplate and light beam. With regard to the fluorescence experiments, the controls were undertaken in an LS50B fluorimeter for which we were not able to design a holder that focused the light beam appropriately, therefore the data were of much poorer quality. However, when using ct-DNA (317 µM) and ethidium bromide (30 µM) a masked capillary yielded fluorescence spectra that overlaid with the controls from the same instrument, albeit with less intensity and more noise (data not shown).

Validation of micro-volume Couette flow LD cell
Measurement of a number of individual capillaries established that their pathlength differs by <1% when capillaries are cut from the same local region of the extruded quartz source material. Multiple LD analyses of the same sample were undertaken, by comparing the signal intensity at 259 nm of a sample of ct-DNA (200 µM) over 15 separate loadings of the capillary. The relative standard deviation (RSD) was 1.1%. An analogous experiment on the same sample without reloading gave an RSD of 0.8%. Thus the errors from realignment and small pathlength variations from sample reloading and cell reassembling contribute an acceptably small amount to overall variation.

Fig. 5 shows the relationship between voltage and rpm using a ct-DNA (200 µM) sample. It can be seen that a minimum voltage of 3 V is required to ensure sufficient rotation of this cell. This value will depend on the motor being used. As the voltage and rpm increases, the intensity of the LD signal also increases. A linear relationship was observed at voltages above 3 V (which fortuitously corresponds to 3000 rpm).

The LD of DNA in the micro-volume Couette LD cell (Fig. 6 a) shows a typical DNA LD spectrum: a negative maximum at 259 nm due to -^* transitions of the DNA bases. Fig. 6 b shows a plot of LD₂₅₉ versus DNA concentration at constant rotation speed. These follow the Beer-Lambert law and show the orientation of DNA is not dependent on concentration over this range. The extent of DNA orientation was found to be 10–15% by substituting values for the LD and absorbance and using an average DNA base orientation of 86° (Chou and Johnson, 1993).

View larger version (14K): [in this window] [in a new window]   FIGURE 6  (a) LD spectrum of ct-DNA (550 µM) in sodium cacodylate buffer (10 mM, pH 7) and NaCl (10 mM); (b) LD259 versus DNA concentration in a capillary cell at voltage 4 V.

View larger version (29K): [in this window] [in a new window]   FIGURE 7  LD spectra of DNA (200 µM) and different concentrations of ethidium bromide (0–50 µM) using a sodium cacodylate buffer (10 mM, pH 7) and NaCl (10 mM).

(2)

where is the intensity of light emitted in the direction of the PMT (which is along the direction of orientation) after absorbance from a perpendicularly polarized light beam and similarly for other terms. By way of contrast, in LD₁₈₀ (the usual configuration) what is detected are the photons that are not absorbed and that proceed straight through the sample:

(3)

assuming the ideal situation where both polarizations of light beams have the same incident intensity. Thus in general qualitative terms the LD₉₀ signals are expected to be opposite in sign from those measured in LD₁₈₀. The more detailed dependence on the angle the transition moment makes with the orientation direction and the fraction of aligned DNA of the LD₉₀ measured on a spinning sample (4 V) and completely unoriented (0 V) is (see Appendix):

(4)

It should be noted that the final line of this equation is based on the assumptions that: i), the sample can be represented as some fully aligned and some unaligned molecules, ii), is small, and iii), the DNA does not rotate significantly between excitation and emission. LD₉₀ is thus expected to be negative for 0 < < 60° and positive for 60° < < 90°. By way of contrast, the change-over point is 54.7° for LD₁₈₀.

DNA is not expected to have an LD₉₀ signal because it is not fluorescent, as is in fact the case. However, upon adding DAPI, Hoechst, and ethidium bromide, the spectra of Figs. 8–10 were observed. Absorbance, LD₁₈₀ and standard excitation fluorescence spectra (with wide open emission slit as described above) are also shown.

View larger version (12K): [in this window] [in a new window]   FIGURE 8  Spectra of DNA (1000 µM) and DAPI (50 µM). (a) Absorption spectra of DAPI (dashed line) and DAPI-ct-DNA (solid line), (b) fluorescence excitation spectrum of DAPI-ct-DNA with all emitted photons detected, (c) LD spectra of ct-DNA (dashed line) and DAPI-ct-DNA (solid line), and (d) FDFLD spectrum of DAPI-ct-DNA. All solutions prepared using a sodium cacodylate buffer (10 mM, pH 7).

View larger version (13K): [in this window] [in a new window]   FIGURE 9  Spectra of DNA (1000 µM) and Hoechst (50 µM). (a) Absorption spectra of Hoechst (dashed line) and Hoechst-ct-DNA (solid line), (b) fluorescence excitation spectrum of Hoechst-ct-DNA with all emitted photons detected, (c) LD spectra of ct-DNA (dashed line) and Hoechst-ct-DNA, and (d) FDFLD spectrum of Hoechst-ct-DNA. All solutions prepared using a sodium cacodylate buffer (10 mM, pH 7).

View larger version (14K): [in this window] [in a new window]   FIGURE 10  DNA (1000 µM) and ethidium bromide (50 µM). (a) Absorption spectra of ethidium bromide (dashed line) and ethidium bromide-ct-DNA (solid line). (Inset) Enlarged region of ethidium bromide band. (b) Fluorescence excitation spectra with all emitted photons detected, (c) LD spectra of ct-DNA (dashed line) and ethidium bromide-ct-DNA (solid line), and (d) FDFLD spectra. All solutions prepared using a sodium cacodylate buffer (10 mM, pH 7).

The FDFLD spectrum of DAPI bound to ct-DNA is given in Fig. 8 d. There is a large negative peak at 350 nm corresponding to the positive LD₁₈₀ band in Fig. 8 c. There is also a smaller negative peak at 265 nm. This feature corresponds to the 262-nm peak in the DAPI absorbance spectrum that is approximately half the intensity of the one at 347 nm. Thus LD₉₀ is able to probe ligand transitions usually masked by the DNA absorbance. It should be noted that the FDFLD intensity will be dependent on the quantum yields of different binding modes and/or different sequences. In addition there is also the possibility of enhanced intensity due to energy transfer from the DNA bases. Given the magnitude of this peak such an effect is not obvious in this spectrum.

DNA-Hoechst interactions
The absorption spectra of free and ct-DNA-bound Hoechst is shown in Fig. 9 a. It can be seen that there is red shift of absorbance maximum of 20 nm upon the binding of Hoechst to ct-DNA. There is also a hypochromism of 60%. Fig. 9 b shows the fluorescence excitation of Hoechst bound to ct-DNA with all emitted photons collected. A peak maximum is seen at 367 nm with a shoulder at 338nm. The LD spectra of ct-DNA and ct-DNA in the presence of Hoechst are given in Fig. 9 c. The ct-DNA shows a characteristic negative peak at 259 nm. When Hoechst is present there is a decrease in LD signal intensity compared to ct-DNA alone that could be a Hoechst contribution or a reduction in DNA alignment. It has previously been concluded from studies by Moon et al. (1996) that Hoechst binds in the minor groove of AT-rich regions (though the consensus of opinion is that Hoechst binds in the major groove of GC-rich DNA probably in some kind of partially intercalated binding mode; Colson et al., 1995; Moon et al., 1996), and the positive peak 360 nm is due to the Hoechst bound to ct-DNA along the minor groove.

Fig. 9 d shows the FDFLD spectrum of Hoechst bound to ct-DNA. There is a broad negative peak in the 290–440 nm region. This corresponds well with the fluorescence excitation data collected and with the broad positive peak at 360 nm in the LD spectrum. The positive FDFLD peak at 273 nm is the red-shifted signal of the 260-nm free Hoechst absorbance, consistent with this being a long-axis polarization transition whose LD signal is usually buried under that of the DNA. The superficial similarity of the DAPI and Hoechst FDFLD in the DNA region is misleading as one should note that the baselines slope so the 260-nm region is an FDFLD maximum for DAPI, whereas for Hoechst the same region is an absorbance minimum so not a signal. Similarly the 270-nm positive peak is in fact zero for DAPI and an FDFLD signal for Hoechst.

DNA-ethidium bromide interactions
Fig. 10 a shows the absorption spectra of free and ct-DNA-bound ethidium bromide. The absorption maximum at 525 nm shows a red shift of 40 nm upon the binding to ct-DNA. There is also a hypochromism of 25%. The fluorescence excitation spectrum of ethidium bromide bound to ct-DNA with all emitted photons collected is shown in Fig. 10 b. A peak maximum at 300 nm with a shoulder at 330 nm is observed. A more intense peak is also present at 530 nm. The LD spectra of ct-DNA and ct-DNA in the presence of ethidium bromide are given in Fig. 10 c. The ct-DNA shows a characteristic negative peak at 259 nm. When ethidium bromide is present there is an increase in LD signal intensity compared to ct-DNA alone. Ethidium bromide is a well-known and well-characterized intercalator. This means that the aromatic rings of ethidium bromide are able to insert between basepairs on the DNA making the DNA more rigid therefore increasing alignment (Nordén and Tjerneld, 1976). There are two negative signals due to the ethidium bromide, one at 520 nm and one showing as a shoulder and wavelength shift on the DNA signal at 300 nm.

Fig. 10 d shows the FDFLD spectrum of ethidium bromide bound to ct-DNA. There is a broad positive peak with a maximum at 525 nm, corresponding to the negative LD band at that wavelength. There is also a broad positive peak from 250 to 350 nm corresponding to the absorbance peaks in this region. These signals are consistent with an intercalated ethidium bromide and show that it is possible to use absorbance signals that are usually complicated by being masked by DNA spectroscopy. Enhanced signals due to energy transfer from the DNA bases are more likely for an intercalator than for a groove binder. Once again although this possibility cannot be ruled out at this stage, the ethidium FDFLD does not resemble the DNA absorbance shape, so we conclude at least that this is not a dominant effect.

	CONCLUSIONS

TOP ABSTRACT INTRODUCTION MATERIALS AND METHODS RESULTS CONCLUSIONS APPENDIX ACKNOWLEDGEMENTS REFERENCES

 
A micro-volume Couette flow cell has been designed and developed for linear dichroism spectroscopy for applications where sample availability is restricted. This is particularly a relevant issue for biological samples. Flow orientation is achieved by the alignment of linear molecules between a fixed quartz rod and rotating quartz capillary. The capillaries used are optically uniform and have advantages of being cheap and removable, which means that they have the potential of being disposable as well as being significantly easier to clean than other LD cells. Focusing lenses are used to focus the light beam onto the capillary, therefore, maximizing the photon count interacting with the sample. The capillaries do not distort LD, CD, or fluorescence spectra as shown by comparison with data collected using standard sample cells. Method validation using calf thymus DNA and groove binding and intercalating DNA binding ligands has shown sample volumes of 25 µL are sufficient to obtain reproducible stable LD spectra, although slightly larger volumes reduce the risk of introducing air bubbles into the capillary upon loading. The ct-DNA has been oriented with an orientation parameter of S = 10–15% assuming an angle of 86° between the macroscopic orientation axis and the DNA base transition moment.

The capillary design of the micro-volume Couette flow LD cell has also enabled a new technique of fluorescence-detected flow linear dichroism to be undertaken. Exit holes from the cell at both 90° and 180° to the incident light enable measurement of fluorescence LD and normal LD, respectively. In both cases lenses have been placed close to the exit hole to capture the maximum amount of the emitted light and focus this toward the PMT. For measurements of fluorescence LD it was also necessary to move the PMT to be at right angles to the incident light beam.

The FDFLD showed the intrinsic contribution to the LD of the bound ligands whose bands lie under the DNA bands thus showing the potential of FDFLD for probing fluorophores in LD independently from other chromophores. The data are of sufficient quality that it has been possible to probe clearly transitions that are usually hidden by overlapping DNA absorbances. The quality of the fluorescence LD data are less good than the standard LD signal, however, due to the configuration of the spectrometer rather than the cell design. The use of filters or a second monochromator would improve the signal/noise in these experiments. Work is in progress to design a new spectrometer with smaller light beams and both fluorescence and linear dichroism capabilities to significantly improve the quality of the FDFLD data. It will be advantageous for this experiment to record actual differences in intensities of emitted light rather than logarithms of ratios.

	APPENDIX

TOP ABSTRACT INTRODUCTION MATERIALS AND METHODS RESULTS CONCLUSIONS APPENDIX ACKNOWLEDGEMENTS REFERENCES

 
Fluorescence detected flow linear dichroism equations
The shear force of the Couette flow gives a preferential orientation direction to the sample. For simplicity in this preliminary analysis let us assume that a fraction, of the DNA is perfectly oriented and a fraction, 1 – is randomly oriented. Due to this experiment design, which uses a Jasco J-715 spectropolarimeter, our data output is the logarithm of the ratio of the signals from the horizontal and vertical polarizations of linearly polarized light. Thus, following a thought process analogous to that derived by Canet et al. (2001) (for fluorescence polarization anisotropy with a photoelastic modulator and a single monochromator with no filters) our LD₉₀, the signal measured when the J-715 instrument is in LD mode and the photomultiplier tube is at 90°, is:

(A1)

where I^zy denotes light that is polarized along z with propagation direction along x and that is subsequently detected with polarization along the y direction with propagation direction along z, etc. We may thus write,

(A2)

where k depends on light intensity, pathlength, sample concentration, etc. and is the y component of the electric dipole transition moment when it emits radiation; similarly ex is for excitation.

If we assume that the molecule does not rotate significantly while it is in the excited state (DNA is large so molecules bound to it rotate slowly), then we can drop the ex and em labels and write

(A3)

where is the angle between µ and the z axis and ß is the angle between the projection of µ onto xy plane and x axis then, e.g.,

(A4)

A rotational average with respect to ß leads to:

(A5)

(A6)

For a randomly oriented sample (0 V on the motor in practice) where we also average over

(A7)

(A8)

Thus we can write the FDFLD on a sample of which a small fraction << 1 is oriented as:

(A9)

So for transitions polarized along the orientation axis:

(A10)

which after subtraction of the unoriented baseline is zero to first order in .

For transitions polarized perpendicular to the orientation axis

(A11)

which after subtraction of the unoriented baseline is positive to first order in . The sign behavior of the variable term in Eq. A9 that is not removed on baseline subtraction is summarized in Fig. 11.

View larger version (11K): [in this window] [in a new window]   FIGURE 11  Plot of from 0° to 180°, although the plot has symmetry 90°.

The zero points in the polarization dependent term of LD₉₀ are at 0°, 60°, 120°, 180°. Thus one expects the data, as presented in this work with the zero rotation spectrum subtracted, to have a negative signal if the transition moment lies between 0° and 60° from the DNA long axis, and a positive sign if it lies from 60° to 90°. This contrasts with standard configuration LD spectra where the change-over point is the magic angle of 54.7° and the sign dependence is the opposite way around. So intercalators are expected to have a positive LD₉₀ signal and long-axis polarized transitions of groove binders to have a negative signal.

	ACKNOWLEDGEMENTS

TOP ABSTRACT INTRODUCTION MATERIALS AND METHODS RESULTS CONCLUSIONS APPENDIX ACKNOWLEDGEMENTS REFERENCES

 
The authors gratefully acknowledge the help of the referees as well as discussions with Y. Dupont and S. Windsor in leading to an understanding of the underlying basis of what had been measured. The technical skill and enthusiasm of Rhoderick Mortimore of Crystal Precision Optics in constructing the LD cells is gratefully acknowledged.

Financial support from the Engineering and Physical Sciences Research Council, UK (GR/M91105) and Syngenta, UK was also essential to the progress of this work.

Submitted on September 19, 2003; accepted for publication June 14, 2004.

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