* School of Optometry and Department of Biology, University of Waterloo, Waterloo, Ontario, N2L 3G1 Canada;
Bausch and Lomb, Rochester, New York 14603-0450; and
Faculty of Medicine and Dentistry, Department of Biochemistry, University of Western Ontario, London, Ontario, N6A 5C1 Canada
Received December 4, 2002; accepted February 8, 2003
ABSTRACT
Previous work using the in vitro bovine lens as a model has shown a correlation between toxicity and lens optical function and showed much higher sensitivity in detecting irritancy of several surfactants at much lower concentrations than the Draize score. In the current study, cultured bovine lenses were used to study the effects of the surfactant sodium dodecyl sulfate (SDS) on lens optical properties and mitochondrial integrity. Bovine lenses were exposed to SDS (0.1 to 0.00625%) for 30 min and cultured for 24 h. Compared to controls (n = 17), loss of sharp focus was evident immediately following exposure to 0.1% SDS (n = 14, p < 0.0001). At 24 h loss of sharp focus became evident in all groups. Loss of lens transparency, significant increase in lens wet weight, and axial length were seen 24 h postexposure in lenses treated with 0.1 to 0.025% SDS. Confocal analysis 24 h postexposure showed SDS concentration-dependent decrease in number and length of the mitochondria in lens epithelial and superficial cortical fiber cells. The results of this study show a correlation between lens optical properties and metabolic function and together provide a sensitive in vitro model of ocular chemical toxicity. Results of confocal analysis suggest that the mitochondrial integrity of the superficial cortical fiber cells is most sensitive to damage caused by SDS. The results further suggest that recovery of lens metabolic function is necessary for the recovery of lens optical properties.
Key Words: mitochondria; bovine lens optical properties; in vitro toxicology; ocular toxicity; mild irritation and recovery; sodium dodecyl sulfate.
Damage of cultured intact lenses has been quantitatively evaluated by measuring changes in focal quality (focal length variability) using an automated scanning laser system (Herbert et al., 1998; Sivak and Herbert, 1997
; Sivak et al., 1992
, 1994
, 1995
). The effects of known ocular irritants are important to consider regarding the specific mechanisms of the damage they cause. The negatively charged anionic surfactant sodium dodecyl sulfate (SDS) was chosen as a model chemical in this study because rabbit eyes exposed to SDS during Draize testing not only show increased corneal swelling but also show delayed recovery (Kennah et al., 1989
). In a previous study using the automated scanning lens system and cultured bovine lenses, it was shown that SDS induced a significant decrease in lens optical function (Sivak and Herbert, 1997
).
The mammalian lens can be divided into an elongating compartment in the posterior lens and a proliferation compartment in the epithelium of the anterior lens. Cell division in the lens is restricted to the proliferating compartment of the epithelial cells. This proliferation compartment in the lens epithelium can be further divided in to three subcompartments, related to the anatomy of the anterior lens and a rate of cell division. Lens epithelial cells found in the proximity of the ciliary body (equator) show the fastest mitotic rate and are referred to as the equatorial zone. Epithelial cells located in the proximity of the iris show slower mitotic rates and are referred to as the intermediate zone. Finally, epithelial cells overlying the anterior suture regions of the lens undergo little or no mitosis and are referred to as the central zone. At the lens equator, epithelial cells of the equatorial zone differentiate into fiber cells, producing an elongating compartment (McAvoy, 1978).
A gradual increase in number of the mitochondria in the lens epithelium, from central to the equatorial zones, is seen (Wanko and Gavin, 1958). In bovine lenses, at least 33% of energy used in the form of ATP is derived from mitochondrial respiration (Trayhurn and van Heyningen, 1972
). Recently it has been shown that mitochondrial distribution in vertebrate lenses is restricted to a thin zone consisting of the single layer of epithelium and the superficial cortical fiber cells. While distribution of the mitochondria in lens epithelial cells remains relatively unchanged over time, the depth at which mitochondria appear in the superficial cortical fiber cells decreases as a function of age (Bantseev et al., 1999
).
The objectives of this investigation were to evaluate changes in lens optical properties and spatial distribution and morphology of mitochondria after 30 min of treatment with different concentrations of SDS to understand mechanisms of toxicity and possible recovery from this model chemical. The analysis of sharpness of focus over time using an automated scanning laser monitor was used to assess lens optical properties. Confocal microscopy and a mitochondria-specific fluorescent dye, Rhodamine 123, were used to assess lens mitochondrial distribution and morphology.
MATERIALS AND METHODS
Chemicals and reagents.
Culture medium (M199), sodium bicarbonate, agarose, L-glutamine, NaCl, SDS, and NaOH were purchased from Sigma Chemical Co. (St. Louis, MO). HEPES, penicillin, streptomycin, and dialyzed fetal bovine serum were obtained from Gibco-BRL (Burlington, ON, Canada). Rhodamine 123 was obtained from Molecular Probes (Eugene, OR).
Eye dissection.
Bovine eyes obtained from a local abattoir were opened under sterile conditions and the lenses were removed. To minimize physical handling of lenses (i.e., transfer from the culture plate and then to the chamber for scanning) they were immediately placed into a three-part chamber (see Analysis of the Lens Optical Properties below) containing 25 ml of culture medium (M199) supplemented with 21 mM HEPES, 26 mM sodium bicarbonate, 0.7 mM L-glutamine, 7 mM of NaOH, 100,000 units penicillin and 100 mg streptomycin, and 3% dialyzed fetal bovine serum and incubated at 37°C with 45% CO2. After 24 h lenses exhibiting mechanical damage during dissection, as evaluated by the visible opacities, were discarded.
Lens treatment.
Lenses were exposed to SDS (0.1 to 0.00625%) for 30 min, rinsed with saline (0.9% NaCl), placed in fresh M199 and incubated at 37°C and 45% CO2. A minimum of 11 lenses (total n = 84) were used for each treatment group.
Analysis of the lens optical properties.
Lens optical quality (the average back vertex distance, BVD) and sharpness of focus (BVD variability) were assessed using the ScantoxTM In Vitro Lens Assay System (Harvard Apparatus, Holliston, MA) before exposure, immediately, 4, 8, and 24 h after the treatment. The ScantoxTM In Vitro Lens Assay System consists of a collimated laser source that projects a laser beam onto a plain mirror mounted at 45° on a carriage assembly. This mirror reflects the laser beam directly up through the scanner table surface and through the lens under examination. The mirror carriage is connected via a drive screw to a positioning motor. This positioning motor turns the drive screw and thereby moves the laser in user-defined steps across the lens in an automated fashion. A digital camera captures the actual position and slope of the laser beam at each step. When all steps have been taken, the captured data for each step position is used to calculate the BVD for each position and the difference in that measurement between beams. Lenses were placed in 25 ml of M199 into specially designed three-part chamber made of 70 mm tall glass, silicone rubber insert, and a metal base (modified from Weerheim and Sivak, 1992) and suspended within the chamber on a 14-mm inner diameter beveled washer designed to support the lens at the equatorial rim. A series of 22 laser beams were passed at specified increments of 0.5 mm for a total range of 11 mm. Thus, the results for this part of the study involved 9240 objective optical measurements (84 lenses, 5 scan points, 22 beams).
Confocal analysis of mitochondrial integrity.
For confocal analysis lenses were transferred into 10 ml serum-free M199 in Wheaton-33 sample glass vials (VWR, Mississauga, ON, Canada). A minimum of nine lenses for each treatment group were used for confocal analysis (total n = 60). These lenses were stained for mitochondria using 20 µM Rhodamine 123 for 45 min at 37°C. Rhodamine 123 is a lipophilic cell-permeable, cationic nontoxic fluorescent dye that is readily sequestered specifically by active mitochondria (Johnson et al., 1980). Lenses were immobilized on cover glasses (no. 1, 18 mm2, Corning Labware & Equipment, Corning, NY), attached over 10 mm holes drilled in the bottom of each well of a six well plate using 1% agarose, previously melted in M199 and cooled to 35°C.
A Zeiss confocal laser scanning microscope (CLSM) 410 system attached to an Axiovert 100 microscope with a 40x water-immersion C-Apochromat objective (numeric aperture 1.2) was used. The combination of an argon/krypton laser with a 488 nm excitation laser line, and a 590 nm long pass emission filter, were used to visualize Rhodamine 123 fluorescence. To minimize laser bleaching of Rhodamine 123, a T = 0.01 neutral density filter for laser attenuation was applied to a 488 nm excitation laser line.
Anterior, equatorial, and posterior regions of whole lenses were optically sectioned, capturing both epithelial and the superficial cortical fiber cells (in case of anterior and equatorial regions) or superficial cortical fiber cells only (in case of the posterior region of the lens that does not have epithelial layer), at 510 µm steps from the surface to a depth below which Rhodamine 123 fluorescence disappeared or to 220 µm (maximum working distance of the objective). Since the mitochondria-free zone (MFZ) of the rat lens starts at 177 µm beneath the lens surface in one-week-old rat lenses and decreases to 30 µm in 22-month-old rat lenses (Bantseev et al., 1999), it was felt that a 220 µm working distance may also be sufficient for a bovine lens study. The analysis of the depth below which mitochondria disappears and MFZ starts was based on at least 10 images per lens using software supplied with the confocal microscope (Carl Zeiss LSM, version 3.96).
Measurements of the relative intensity fluorescence of Rhodamine 123, indicating electron transport chain potential were made in lens epithelial cells immediately below the lens capsule (surface). In superficial cortical fiber cells that measure was made 20 µm below the surface to ensure that none of the epithelial cells were present (in the case of anterior and equatorial regions). The analysis was based on at least five images per lens. Oblique confocal micrographs of lens were generated, often containing both epithelial and superficial cortical fiber cells. Therefore, four standardized representative 21 µm x 21 µm sections of the lens epithelium containing the nucleus and the surrounding mitochondria were selected from each image for analysis of Rhodamine 123 fluorescence. To analyze the fluorescence of Rhodamine 123 in the superficial cortical fiber cells, whole images (91 µm x 91 µm) were used. The total number of images analyzed for this part of the study was based on all 60 lenses, with at least five measurements per lens plus three regions of epithelial cells where each was based on the average of four images (measured in 45 out of 60 lenses), and amounted to the total of 975 images.
Following laser scan measurements or at the end of confocal analysis, the axial, equatorial lengths were measured using digital calipers and the lens wet weight was measured using a digital scale. A minimum of nine lenses were used from each treatment group (total n = 62).
Statistical analysis.
Statistical calculations were completed using a two-way repeated measures ANOVA or one-way ANOVA. A probability value of less than or equal to 0.05 was considered significant.
RESULTS
Lens Anatomy and Optical Properties after in Vitro SDS treatments
The untreated control lenses remained transparent at the end of the experiment, as evaluated visually under the dissection microscope for the presence of opacities (Fig. 1, control). The severity of opacities 24 h postexposure were SDS concentration-dependent. While exposure to concentrations of SDS at 0.0125 and 0.00625% caused moderate opacities, concentrations of SDS at 0.0250.1% caused severe opacities (Fig. 1
). These concentrations caused opacities around the equator and an overall cloudiness of anterior and posterior lens surfaces. Lens axial swelling also took place as a function of SDS concentration (Fig. 1
). While the 0.0250.1% SDS treated lenses showed general cloudiness of the anterior and posterior surfaces, opacities localized at the posterior suture of the 0.0125 and 0.00625% SDS treated lenses were seen (Fig. 1
, 0.0125 and 0.00625% SDS, posterior).
|
|
Figure 2 shows representative scan plots obtained using an automated ScantoxTM In Vitro Lens Assay System. These show little change in back vertex distance variability (BVD variability) in controls (Fig. 2A
) and a significant increase in the BVD variability associated with SDS treatment (Fig. 2B
, showing an example for 0.1% SDS). A 2.5-fold increase in BVD variability (an indication of loss of sharp focus) was evident in the 0.1% SDS group lenses as early as the 0 h scan point (0.85 ± 0.16 mm, p < 0.0001) as compared to controls (0.34 ± 0.04 mm, Table 2
). By the 4 h scan point significant increases in BVD variability were seen in the 0.0125% (0.61 ± 0.05 mm, p = 0.004) and 0.05% SDS treated group lenses (0.51 ± 0.05mm, p = 0.05; Table 2
). While at the 4 h scan no difference in BVD variability was seen in the 0.00625% SDS group lenses, a borderline increase in BVD variability was seen in the 0.025% SDS group lenses (0.48 ± 0.05 mm, p = 0.086). At the 8 h scan point a significant increase in BVD variability was seen in the 0.0125% (0.53 ± 0.05 mm, p = 0.0283), 0.0125% (0.60 ± 0.05 mm, p = 0.0012), and the 0.1% (0.95 ± 0.13 mm, p < 0.0001) SDS group lenses as compared to controls (0.33 ± 0.02 mm, Table 2
). At the 24 h scan point, significant increases in BVD variability was seen in the 0.00625% SDS group lenses (0.66 ± 0.06 mm, p = 0.001) as compared to controls (0.34 ± 0.02 mm, Table 2
).
|
|
|
|
|
Lens superficial cortical fiber cells.
Overall, the mitochondria in the superficial cortical fiber cells of control lenses were not as dense as those in the epithelium and were evenly distributed throughout the cytoplasm (Figs. 3D3F). However much higher numbers and significantly longer average length (41.16 ± 2.24 µm, p < 0.0001) of mitochondria was seen in the superficial cortical fiber cells at the equator (Fig. 3E
), in comparison to the mitochondria in the anterior zone (18.37 ± 1.22, Table 4
and Fig. 3D
) and posterior zone (17.22 ± 1.22 µm, Table 4
and Fig. 3F
) of the superficial cortical fiber cells in controls (Table 4
).
|
|
The mitochondrial distribution from the surface of the lens to the depth at which the MFZ starts was measured in the anterior, equatorial, and posterior superficial cortical fiber cells and compared with the same relative regions in controls (Table 4). Due to the absence of the mitochondria in lenses treated with 0.0250.1% SDS, the MFZ could not be measured. Similarly the MFZ could not be measured in the posterior superficial cortical fiber cells in the 0.0125 and 0.00625% SDS- treated lenses or the anterior superficial cortical fiber cells of the 0.0125% SDS-treated lenses. The MFZ measured at the equator in the superficial cortical fiber cells started at a significantly reduced depth in the 0.0125% SDS-treated lenses (71.35 ± 2.95 µm, p < 0.0001) as compared with controls (205.20 ± 11.10 µm, Table 4
). While the MFZ in the equatorial superficial cortical fiber cells in lenses treated with the 0.00625% SDS started significantly deeper (183.10 ± 34.90, p < 0.0001) than that in the 0.0125% SDS-treated lenses, this measure was similar the same region of controls (Table 4
). Similarly the MFZ in the anterior superficial cortical fiber cells in lenses treated with 0.00625% SDS started at a depth (142.50 ± 5.70 µm, Table 4
) similar to same relative region in controls (153.90 ± 17.10 µm, Table 4
).
DISCUSSION
Widely used in many household and cosmetic products (Bruner, 1992; Grant and Acosta, 1996
), the surfactant SDS bears a negative anionic polar head group and a hydrophobic portion. In an aqueous environment the SDS molecules organize themselves in such way that the hydrophobic portion is sequestered from the highly polar aqueous medium by a surrounding, approximately spherical shell formed by the anionic head groups (Schreier et al., 2000
). Thus when biological tissues, such as the lens of the eye, are exposed to SDS, a series of events including lysis, extraction of proteins, and, ultimately, cell membrane disruption, takes place (Helenius and Simons, 1975
). Once the cell membrane is disrupted, the SDS will accumulate inside the cell, continuing to dissolve intracellular proteins even after the chemical is rinsed off. Together these events lead to the observed ocular toxicity and delayed recovery after exposure to SDS at higher concentrations (Schreier et al., 2000
).
Previous work using the cultured bovine ocular lens model has shown a correlation between toxicity and lens optical function (Sivak et al., 1990, 1995
). In another example this in vitro model showed its effectiveness in measuring the ocular irritancy potential of several surfactants (Sivak et al., 1994
). While the irritancy ranking of tested surfactants were similar to that of Draize scores, the bovine lens in vitro model showed much higher sensitivity in detecting irritancy at much lower concentrations than the Draize score (Sivak et al., 1994
). The results of the current study showed an SDS concentration dependent change in both lens optical properties and a decrease in number and length of the mitochondria in epithelial and superficial cortical fiber cells. Exposure to higher concentrations of SDS (0.025 to 0.1%) for 30 min leads to loss of lens optical function over time that was sustained 24 h after treatment. Likewise, 24 h following treatment with higher concentrations of SDS, no mitochondria were seen in lens epithelial and superficial cortical fiber cells. Overall, loss of lens transparency, erosion of the epithelium, vacuoles in the superficial cortical fiber cells, increases in lens wet weight, and axial swelling seen 24 h after exposure indicate that the lenses sustained damage after exposure to SDS at these concentrations.
The morphology and distribution of mitochondria in lens epithelial cells seen 24 h after exposure of lenses treated with 0.0125 and 0.00625% SDS was similar to that of control lenses. However, mitochondrial morphology and distribution in lens superficial cortical fiber cells looked much different. In anterior and superficial cortical fiber cells at equator fewer and shorter mitochondria were seen. However, the absence of mitochondria in the posterior superficial cortical fiber cells and the presence of vacuoles indicate that the mitochondria of the superficial cortical fiber cells are most sensitive to SDS induced changes, even at concentrations as low as 0.00625%. Therefore, loss of mitochondria and presumably reduced metabolic function in the posterior superficial cortical fiber cells may be responsible for the opacities around the posterior sutures and also the loss of sharp focus seen at the 24 h scan point in lenses treated with the 0.00625% SDS.
In lenses treated with SDS the significant morphological changes in the mitochondria of lens epithelial and superficial cortical fiber cells studied by confocal microscopy are similar to the changes in the morphology of the mitochondria of Hep-2 neoplastic cells treated with staphylococcal -toxin (Paradisi et al., 1976
). Besides some nuclear modification seen in those cells associated with treatment, the most significant biphase morphological change over time was observed in the mitochondrial structure studied by electron microscopy. A decrease in length of the mitochondria (from elongated to shorter) was outlined as an early structural change in cells treated for 30 min whereas swelling and change from shorter to round morphology of the mitochondria in cells treated for 3 and 6 h was outlined as a later phase of the cytotoxicity response. However, the confocal analysis of mitochondrial morphology was done using a mitochondria-specific fluorescent dye, Rhodamine 123, that emits fluorescence from metabolically active mitochondria. Therefore, a third stage was noted in lenses treated with higher concentrations of SDS where Rhodamine 123 fluorescence was not seen, indicating the absence of metabolically active mitochondria in both lens epithelial and superficial cortical fiber cells.
The Draize test (Draize et al., 1944), adopted widely for the assessment of ocular irritancy and toxicity, is currently used to evaluate the safety of chemical substances that are foreign to biological systems (xenobiotics). The Draize test is based mainly on scoring of observed macroscopic changes to the rabbit cornea, conjunctiva, and iris after exposure to a test compound. The test has been criticized because of its subjectivity, the high doses used (Chambers et al., 1993
; Freeberg et al., 1986
; Griffith et al., 1980
; Lambert et al., 1993
; Williams, 1985
), their intra- and interlaboratory variability (McDonald et al., 1977
; Weil and Scala, 1971
), and most important, the harmful effect to living animals (Rowan, 1984
; Zbinden, 1985
). The test has also been criticized because of its inability to distinguish between the irritating effects of chemicals at low concentrations. The in vitro approach used here showed sufficient sensitivity to assess the toxicity caused by low SDS concentrations.
The transparent cornea and the lens of the vertebrate eye are responsible for focusing light on the retina. During embryonic development, the surface ectoderm gives rise to the epithelial cells of the cornea and the lens, making them similar not only functionally but in their gene expression as well (Piatigorsky, 1998). Therefore changes in the lens in response to potentially toxic chemicals can provide a relevant measure of corneal (i.e., ocular) irritancy (Edwards et al., 1970
).
The ability to measure changes associated with low concentrations of SDS seen in this study is an important toxicity parameter that has been difficult to measure using other in vitro methods (McCulley and Stephens, 1993). The automated scanning laser monitor provides objective measurements of changes in lens optical function over time. Confocal microscopy analysis of the morphology and distribution of the mitochondria in lens epithelial and superficial cortical fiber cells showed a significant morphological change in the mitochondria. Confocal microscopy permits optical sectioning through a living intact tissue, the lens, with resolution and contrast superior to conventional light microscopy, and without the artifacts induced by the preparation of specimens for electron microscopy (Wilson, 1989
; Wright et al., 1993
).
ACKNOWLEDGMENTS
This work was supported by a grant from the Natural Science and Engineering Research Council of Canada and by Bausch & Lomb, Rochester, NY (J.G.S.). The support of an Ontario Graduate Scholarship to V.B. is acknowledged.
NOTES
1 To whom correspondence should be addressed at School of Optometry, University of Waterloo, Waterloo, Ontario, N2L 3G1 Canada. Fax: (519) 725-0784. E-mail: jsivak{at}uwaterloo.ca.
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