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JEM, Volume 200, Number 12, 1539-1545
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Loss of Synchronized Retinal Phagocytosis and Age-related Blindness in Mice Lacking {alpha}vß5 Integrin

Emeline F. Nandrot1, Yoonhee Kim1, Scott E. Brodie1,3, Xiaozhu Huang4, Dean Sheppard4, and Silvia C. Finnemann1,2

1 Margaret M. Dyson Vision Research Institute, Department of Ophthalmology
2 Department of Cell and Developmental Biology, Weill Medical College of Cornell University, New York, NY 10021
3 Department of Ophthalmology, Mount Sinai School of Medicine, New York, NY 10029
4 Lung Biology Center, Department of Medicine, University of California, San Francisco, San Francisco, CA 94143

Address correspondence to Silvia C. Finnemann, Dyson Vision Research Institute, LC305, Box 233, Weill Medical College of Cornell University, 1300 York Ave., New York, NY 10021. Phone: (212) 746-2278; Fax: (212) 746-8444; email: sfinne{at}med.cornell.edu


   Abstract
 Top
 Abstract
 Introduction
 Materials and Methods
 Results
 Discussion
 References
 
Daily phagocytosis by the retinal pigment epithelium (RPE) of spent photoreceptor outer segment fragments is critical for vision. In the retina, early morning circadian photoreceptor rod shedding precedes synchronized uptake of shed photoreceptor particles by RPE cells. In vitro, RPE cells use the integrin receptor {alpha}vß5 for particle binding. Here, we tested RPE phagocytosis and retinal function in ß5 integrin–deficient mice, which specifically lack {alpha}vß5 receptors. Retinal photoresponses severely declined with age in ß5–/– mice, whose RPE accumulated autofluorescent storage bodies that are hallmarks of human retinal aging and disease. ß5–/– RPE in culture failed to take up isolated photoreceptor particles. ß5–/– RPE in vivo retained basal uptake levels but lacked the burst of phagocytic activity that followed circadian photoreceptor shedding in wild-type RPE. Rhythmic activation of focal adhesion and Mer tyrosine kinases that mediate wild-type retinal phagocytosis was also completely absent in ß5–/– retina. These results demonstrate an essential role for {alpha}vß5 integrin receptors and their downstream signaling pathways in synchronizing retinal phagocytosis. Furthermore, they identify the ß5–/– integrin mouse strain as a new animal model of age-related retinal dysfunction.

Key Words: circadian rhythm • knockout • photoreceptors • retinal pigment • epithelium • vision


Abbreviations used in this paper: ERG, electroretinogram; FAK, focal adhesion kinase; MerTK, Mer tyrosine kinase, POS, photoreceptor outer segment fragments; RPE, retinal pigment epithelium.


   Introduction
 Top
 Abstract
 Introduction
 Materials and Methods
 Results
 Discussion
 References
 
Daily clearance phagocytosis by the retinal pigment epithelium (RPE) is essential for function and longevity of photoreceptor neurons. In the retina, photoreceptor rods and cones continuously renew their light-sensitive outer segments (1, 2). Circadian rhythms regulate photoreceptor outer segment turnover such that rods shed their most aged tips each morning with the onset of light, whereas cones shed their tips with the onset of night (3, 4). Early morning rod shedding precedes a synchronized burst of RPE phagocytosis, which rapidly clears shed photoreceptor outer segment fragments (POS) from the retina (5). Molecular mechanisms that RPE cells may use to coordinate their phagocytic response to shed POS are thus far unknown.

In the mammalian eye, RPE cells do not normally divide and each RPE cell underlies ~30 photoreceptor cells. Therefore, each individual RPE cell phagocytoses more material over a lifetime than any other cell type in the body. Even minor delays or inefficiencies in POS clearance by RPE cells will gradually cause accumulation of undigested photoreceptor components. Indeed, decline in RPE phagolysosomal processing is associated with the accumulation of storage bodies containing fluorescent lipofuscin, which is a complex mix of molecules rich in lipids that is characteristic for RPE aging in the human eye (6, 7). Excessive levels of lipofuscin are associated with retinal disease including the development of age-related macular degeneration, which is the leading cause of blindness among the elderly (8, 9).

The machinery used by RPE cells to phagocytose shed POS belongs to a family of related clearance mechanisms used by other cell types such as macrophages and dendritic cells to phagocytose apoptotic cells (10). These mechanisms use common phagocyte surface receptors such as the Mer tyrosine kinase (MerTK; references 1113), the scavenger receptor CD36 (1417), and the integrin adhesive receptors {alpha}vß3 and {alpha}vß5 (16, 1820). MerTK deficiency abolishes RPE's ability to internalize POS, which causes early onset retinal degeneration in the Royal College of Surgeons rat strain and in transgenic mice (1113, 2123). To our knowledge, phagocytosis by RPE lacking other phagocytic receptors has not been characterized to date.

Here, we explore ß5 integrin–deficient mice to identify the effects of a permanent lack of {alpha}vß5 integrin receptors on retinal and RPE function. Our results show that {alpha}vß5 integrin deficiency is sufficient to cause age-related vision loss in ß5–/– mice accompanied by accumulation of RPE lipofuscin, a cardinal feature of RPE aging and disease. Quantification of POS clearance demonstrates that lack of {alpha}vß5 integrin primarily affects the phagocytic function of the RPE: ß5–/– RPE in vitro fails to phagocytose POS and ß5–/– RPE in vivo completely lacks the characteristic burst of phagocytosis in response to early morning rod shedding. Furthermore, our experiments identify a strict temporal regulation of focal adhesion kinase (FAK) and MerTK activities in the retina that correlates with circadian photoreceptor shedding. Strikingly, these synchronized signaling events are completely abolished in {alpha}vß5-deficient retina. Together, these data provide the first direct evidence that {alpha}vß5 integrin–dependent signaling is essential for retinal function by controlling RPE phagocytosis.


   Materials and Methods
 Top
 Abstract
 Introduction
 Materials and Methods
 Results
 Discussion
 References
 
Animals.
Previous characterization of ß5–/– mice showed that these mice are viable and fertile, and they show no obvious morphologic abnormalities (2426). ß5–/– and wild-type mice of the same genetic background (129T2/SvEmsJ; The Jackson Laboratory) were housed under cyclic 12-h light/12-h dark light conditions (light onset at 6.00 h) and fed ad libitum. All procedures involving animals were approved by the Weill Medical College Institutional Animal Care and Use Committee.

For experiments, mice were killed by CO2 asphyxiation. Lens and cornea were removed from enucleated eyeballs. Fresh eyecups were processed for microscopy or Western blotting as described below.

Electroretinography.
Electroretinograms (ERGs) of five ß5–/– and seven wild-type mice that were exactly age matched were recorded monthly between the ages of 4 and 12 mo. Mice were dark adapted overnight before anesthesia by i.p. injection of 100 mg/kg ketamine and 10 mg/kg xylazine. After topical eye anesthesia (0.5% proparacaine hydrochloride) and pupil dilation (10% phenylephrine hydrochloride and 1% tropicamide), full-field scotopic ERGs were recorded using a custom-made gold wire corneal contact lens electrode scaled to the mouse eye (provided by T. Mittag, Mount Sinai School of Medicine, New York, NY) and subdermal reference (forehead) and ground (back) electrodes as described previously (27). A photostimulator mounted in a reflective dome (Ganzfeld) was used to deliver 10-µs white flashes with full intensity flash stimuli of 1.5 cd-s/m2 (UTAS-2000; LKC Technologies). Neutral density filters, ranging from –2.4 to 0 log neutral density filter (log ND) in 0.4 log unit steps were used to decrease light stimuli. Stimuli were presented in order of increasing intensity. At least three separate responses were generated and presented as means ± SD for each of the seven intensities tested. A-wave amplitudes were measured from the baseline to the trough of the a-wave. B-wave amplitudes were measured from the trough of the a-wave to the peak of the b-wave.

Immunofluorescence and Light Microscopy.
10-µm-thick frozen sections from paraformaldehyde-fixed eyecups were prepared and stained with antibodies exactly according to established procedures (18, 28). For methyl green staining, 8-µm sections were cut from eyecups fixed in formaldehyde/ethanol/acetic acid and embedded in paraffin. RGB light microscopy images were acquired using IP lab on a microscope (Axiovert 35; Carl Zeiss MicroImaging, Inc.) with a CCD camera (SenSys) and recompiled in Photoshop 7.0 (Adobe).

Cultured cells were fixed in ice-cold methanol and processed as described previously (29). Antibodies used were ß5 integrin monoclonal antibody, polyclonal antibodies to ß5 integrin (provided by L.F. Reichardt, University of California, San Francisco, San Francisco, CA) and to ZO-1 (Zymed). Secondary antibodies were purchased from Molecular Probes. Wide-field fluorescence images were acquired using MetaMorph (Universal Imaging) on an epifluorescence microscope (model C600; Nikon) with a cooled CCD camera (Princeton) or on a confocal microscopy system (model TSP2; Leica) and recompiled in Photoshop 7.0.

Electron Microscopy.
Eyecups were fixed in 2.5% glutaraldehyde and 0.2% picric acid in 0.1 M cacodylate buffer, pH 7.3. Samples were post-fixed in 1% osmium tetroxide for 1 h, dehydrated in acetone, and embedded in Epon. Ultrathin sections were stained with uranyl acetate and lead citrate. Specimens were examined at 80 kV with an electron microscope (model 100 CXII; JEOL). Phagosomes were counted in electron micrographs of 0.5-µm retinal cross sections. For each time point and strain, three continuous stretches of RPE/photoreceptors of at least 1 mm in length, each prepared from different eyes, were examined. Structures were counted as phagosomes only if they (a) resided in the RPE cytoplasm and (b) contained lamellar membranes of the same appearance as those of intact photoreceptor outer segment tips in the same field.

Primary RPE Cell Culture.
To isolate RPE from 12-d-old mice for primary culture, we adapted an experimental procedure previously used to harvest rat RPE (28). In brief, enucleated eyecups were treated with 1 mg/ml bovine hyaluronidase (Sigma-Aldrich) in Ca2+-Mg2+–free Hepes-buffered Hanks' saline (Cellgro) for 45 min to allow peeling off the neural retina and expose the RPE. After incubation was performed in 2 mg/ml trypsin (Difco) in Hepes-buffered Hanks' saline for 45 min, patches of RPE were peeled off manually from Bruch's membrane. Patches of purified RPE cells were seeded on serum-coated glass coverslips and grown in DMEM and 10% FBS at 37°C for 5–7 d before experiments.

POS Phagocytosis Assays.
POS were isolated according to established protocols from bovine eyes obtained fresh from the slaughterhouse (18). Integrin inhibiting peptide GRGDSP and inactive control peptide GRADSP were purchased from Calbiochem. To determine POS binding or internalization, cells received POS covalently labeled with FITC dye (Molecular Probes; reference 18). Confluent RPE cells were challenged with ~10 POS per cell in DMEM with 4% FCS for the duration of the experiment, chilled, washed three times with PBS containing 1 mM MgCl2 and 0.2 mM CaCl2 to remove excess POS, and lysed or fixed in ice-cold methanol. Nuclei were labeled with DAPI. Phagocytosed FITC-POS were quantified by fluorescence microscopy using a wide-field setup (model E600; Nikon) with filters for FITC and DAPI. For each sample, phagocytosed (bound or internalized) POS in four separate fields of at least 20 cells each were counted. Duplicate samples were processed in each experiment. Three similar experiments were performed.

Cell Lysis and Immunoblotting.
Cells were solubilized in 50 mM Hepes, pH 7.4, 150 mM NaCl, 10% glycerol, 1.5 mM MgCl2, and 1% Triton X-100 that was freshly supplemented with 1% each of protease and phosphatase inhibitor cocktails (Sigma-Aldrich). Whole cell lysates representing 10,000 RPE cells or 10% of one mouse eyecup were immunoblotted using primary antibodies to FAK protein (C20; Santa Cruz Biotechnology, Inc.), FAK-P-Tyr-397 (Biosource), MerTK protein (RD systems), phospho-MerTK (Fabgennix) and RPE65 (provided by T.M. Redmond, National Eye Institute, Bethesda, MD), and to appropriate horseradish peroxidase–conjugated secondary antibodies; this was followed by ECL detection (PerkinElmer). X-ray films were scanned and signals quantified using NIH Image 1.61.


   Results
 Top
 Abstract
 Introduction
 Materials and Methods
 Results
 Discussion
 References
 
Age-related Loss of Photoreceptor Function in ß5 Integrin–deficient Mice.
We used scotopic ERG recordings to compare photoreceptor function of ß5–/– mice with that of strain-matched wild-type controls between 4 and 12 mo old. Retinal photoresponses significantly and progressively declined with age in ß5–/– mice. Individual ERG recordings showed that single light flashes of different intensities elicited reduced a- and b-waves in ß5–/– mice compared with wild-type mice at 12 mo (Fig. 1, a and b). Reduction of a-wave amplitudes in 12-mo-old ß5–/– mice by up to 74% indicated a primary defect in rod photoreceptor function. To determine onset and progression of visual impairment of ß5–/– mice, we performed ERG recordings of age-matched groups of wild-type and ß5–/– mice from 4 to 12 mo old. All 4-mo-old ß5–/– mice had normal vision (Fig. 1, c and d). Scotopic responses declined in all ß5–/– mice after 4 mo old (Fig. 1 c). At 6 mo old, some ß5–/– mice showed reduced photoresponses, whereas others were still normal. With advancing age, ß5–/– mice became more similar to each other and more different from control mice (Fig. 1 c). In general, both a- and b-wave amplitudes significantly decreased with age in ß5–/– mice, whereas those of wild-type controls remained mostly constant (Fig. 1 d). These results demonstrated that a lack of {alpha}vß5 integrin caused late onset retinal dysfunction in mice.



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Figure 1. ß5 integrin–deficient mice lose vision with age. We recorded scotopic ERG responses obtained after a light flash stimulus attenuated with 0.4 log ND (a, c, and d) or attenuated as indicated (b). We compared a-wave (left) and b-wave (right) amplitudes of control (open circles) and ß5–/– (closed diamonds) mice. A-wave amplitudes are given as absolute values. (a) Representative ERG responses are diminished in 12-mo-old ß5–/– mice (right) compared with wild-type mice (left). Both a- and b-wave peaks (arrows) are affected. (b) Mean scotopic responses to flashes of different intensities are decreased in 12-mo-old ß5–/– mice. Asterisks indicate significant differences between wild-type and ß5–/– amplitudes at the same flash intensity (n = 5–7, Student's t test, *, P < 0.05; **, P < 0.01). (c) Responses of individual animals (c) and of averages (d) illustrate decline of retinal function in ß5–/– mice with age. Asterisks indicate significant differences between wild-type and ß5–/– amplitudes at the same age (n = 5–7, Student's t test, *, P < 0.05; **, P < 0.01).

 
Age Pigment Deposits in ß5 Integrin–deficient Mice.
Next, we compared retinal morphologies of ß5–/– and wild-type mice. We confirmed that ß5 integrin localized to the apical surface of the RPE in wild-type but not in ß5–/– eyes (Fig. 2, a–d). Gross retinal morphology was similar in 1- and 12-mo-old mice of both strains (Fig. 2, compare a and b with e and f). However, at 12 mo old, ß5–/–, but not wild-type, RPE contained high numbers of vesicular autofluorescent storage bodies (Fig. 2, g and h). At the electron microscopic level, we observed more abundant inclusion bodies in RPE of ß5–/– mice compared with wild-type mice (Fig. 2, i and j). Similar inclusion bodies are associated with incomplete turnover of POS-derived material and accumulate in aged and diseased retina. Excessive accumulation of autofluorescent storage bodies therefore suggested impaired POS turnover or phagocytosis by the RPE in ß5 integrin–deficient mice.



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Figure 2. ß5 integrin–deficient RPE accumulates autofluorescent lipofuscin with age. (a–d) Cryosections of 1-mo-old eyecups of wild-type (a and c) and ß5–/– (b and d) mice were labeled with ß5 antibody (green). Nuclei are shown in red. (a) In the wild-type mouse, whole retina sections with the neural retina present and ß5 integrin was present in the photoreceptor outer segment layer, which also contains apical microvillar processes of RPE ensheathing photoreceptor outer segments (reference 28). (b) As expected, ß5 integrin was absent from ß5–/– retina. (c and d) To determine whether ß5 integrin resided on photoreceptor outer segments or on RPE apical extensions, we prepared sections from eyecups from which the neural retina was peeled off before fixation. Prominent ß5 integrin labeling at the apical surface of wild-type but not ß5–/– RPE indicated that mouse RPE in vivo expresses apical {alpha}vß5 integrin. (e–f) Methyl green–stained paraffin sections of eyecups from 12-mo-old wild-type (e) and ß5–/– (f) mice were examined by light microscopy. Wild-type and ß5–/– retina did not differ in appearance of photoreceptor nuclei (cyan at the top of the field), inner and outer segments (clear areas), and RPE (brown pigment and cyan nuclei). (g–h) Cryosections of eyecups from 12-mo-old wild-type (g) and ß5–/– (h) mice were examined by wide-field fluorescence microscopy to detect DAPI-stained nuclei (cyan) and autofluorescence (detected in the rhodamine channel, red). ß5–/–, but not wild-type, RPE contained numerous autofluorescent inclusion bodies resembling the characteristic age pigment lipofuscin in human RPE (32). (i–j) Ultrathin sections of eyecups from 12-mo-old wild-type (i) and ß5–/– (j) mice were examined by transmission electron microscopy. Increased presence of electron dense inclusion bodies in ß5–/– RPE compared with wild-type RPE confirmed the results obtained by fluorescence microscopy. Bars: (a–h) 10 µm; (i and j) 1 µm.

 
Impaired POS Phagocytosis by ß5 Integrin–deficient RPE.
To directly test the phagocytic activity of ß5–/– RPE, we performed in vitro phagocytosis assays. These allowed us to distinguish direct effects of ß5 integrin knockout on phagocytic activity of RPE from secondary effects caused by altered photoreceptor shedding or photoreceptor–RPE interactions. ß5–/– RPE cells in primary culture retained overall similar morphology and pigmentation as wild-type RPE (Fig. 3, a and d). Labeling with ß5 antibody confirmed that wild-type, but not ß5–/–, RPE in culture continued to express abundant {alpha}vß5 (Fig. 3, b and e). However, RPE from ß5–/– mice phagocytosed fewer isolated POS than RPE from wild-type mice during 1 h of POS challenge (Fig. 3, c and f). Quantification of particle uptake revealed that loss of {alpha}vß5 drastically reduced RPE phagocytosis of POS by ~75% at all time points rather than delaying phagocytosis kinetics (Fig. 3 g). RGD peptides compete for ligand binding by many integrins including {alpha}vß5. Sensitivity of wild-type, but not ß5–/–, RPE phagocytosis to RGD peptides therefore confirmed that wild-type, but not ß5–/–, RPE phagocytosis used {alpha}vß5, which is the sole integrin at the apical phagocytic surface of RPE (Fig. 3 h; reference 18).



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Figure 3. Lack of {alpha}vß5 integrin impairs RPE phagocytosis of POS. We examined primary RPE in culture from wild-type (a–c) and ß5–/– (d–f) mice. Confocal x-y scans of transmitted light (a and d) and of apical {alpha}vß5 integrin (green) and nuclei (red) in the same fields (b and e) were used to compare general cell morphology and to illustrate apical {alpha}vß5 receptors in wild-type, but not in ß5–/–, RPE. (c and f) Junction marker ZO-1 (blue) and nuclei (red) appeared similar by wide-field fluorescence microscopy. However, ß5–/– RPE in primary culture phagocytosed fewer FITC-POS (green) than wild-type RPE during a 1-h phagocytic challenge. (g) Quantification of in vitro phagocytosis assays showed reduced POS uptake by ß5–/– RPE compared with wild-type RPE at all time points. Results represent means ± SD, n = 3, Student's t test, P < 0.01 at 1–3 h. (h) RGD peptides inhibited POS uptake by wild-type but not by ß5–/– RPE in a concentration-dependent manner. Bars show 1-h FITC-POS uptake by wild-type and ß5–/– RPE in the presence of 2 mM RAD-inactive control peptide, 1 or 2 mM integrin inhibiting RGD peptide as indicated. Since RGD peptides affected cell–substrate adhesion of both wild-type and ß5–/– RPE at concentrations above 2 mM, these concentrations were not used for phagocytosis assays. Thus, the 63% inhibition we observed in the presence of 2 mM RGD peptide may not represent maximal possible inhibition of POS uptake by RGD peptides. Results represent means ± SD, n = 3, Student's t test, P < 0.01 for wild-type RPE, RGD versus RAD peptide at 2 mM. (i) Phagosome quantification in electron micrographs of retinal cross sections revealed that ß5–/– retina lacked the characteristic burst of phagocytosis that followed the light onset (at 6.00 h) in wild-type retina. Mean (numbers of phagosomes) ± SD is shown. Sections from three eyecups per time point harvested in three separate experiments were examined.

 
To determine the phagocytic activity of RPE cells in vivo, we counted the numbers of RPE phagosomes containing shed POS in electron microscopy images of cross sections of eyecups derived from wild-type and ß5–/– mice at 3–4 wk old. As characteristic for normal retina, phagosome abundance increased promptly in wild-type RPE after the 6.00 h light onset, but was very low at all other times of day (Fig. 3 i, black bars). In stark contrast to normal RPE, ß5–/– RPE completely lacked the phagocytic burst in response to circadian outer segment shedding, but it contained similar numbers of POS phagosomes at all times of day (Fig. 3 i, gray bars). Together, this quantification of POS phagocytosis by ß5–/– RPE in vitro and in vivo demonstrated that a lack of {alpha}vß5 integrin directly altered the phagocytic activity of RPE cells. Importantly, POS uptake was impaired in ß5 integrin–deficient mice at a young age when vision was still normal (Fig. 1).

ß5 Integrin–deficient RPE Cells in Culture Fail to Activate FAK and MerTK upon POS Challenge.
Our previous studies attributed an essential signaling response to POS challenge involving FAK and MerTK in rat RPE to signaling downstream of {alpha}vß5 integrin (29). Therefore, we determined levels of tyrosine phosphorylation of FAK and MerTK that usually imply activation of these kinases. 1 h phagocytic challenge with isolated POS but not with assay medium alone increased phosphorylation at FAK's autophosphorylation site tyrosine 397 (Y397) in wild-type mouse RPE in culture 3.1-fold (Fig. 4 a). Similarly, POS specifically increased MerTK tyrosine phosphorylation 4.4-fold (Fig. 4 b). In contrast, ß5–/– RPE cells did not respond to POS challenge with phosphorylation of either FAK or MerTK (Fig. 4, a and b). Absence of FAK and MerTK phosphorylation was not caused by lower levels of expression of these kinases as immunoblotting showed similar steady-state amounts of these proteins in wild-type and ß5–/– RPE.



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Figure 4. ß5 integrin–deficient RPE in culture fails to activate phagocytic signaling. (a) Primary wild-type and ß5–/– RPE in culture were untreated (lanes /) or received assay medium (lanes m) or POS in assay medium (lanes POS) for 1.5 h. Lysates normalized for RPE protein content were analyzed by immunoblotting with antibodies specific for FAK-P-Y397 and FAK protein. Specific activity of FAK is given as a ratio of FAK-P-Y397 to total FAK and given as fold change compared with untreated wild-type RPE. (n = 3). (b) The same experiment was performed to determine changes in MerTK activity. Specific activity of MerTK is given as a ratio of PY-MerTK to total MerTK and given as fold change compared with untreated wild-type RPE. (a and b) Results are presented as means ± SD. Asterisks indicate significant differences in ratios between wild-type and ß5–/– samples of the same treatment (Student's t test, P < 0.001).

 
ß5 Integrin–deficient Mice Lack In Vivo Phagocytic Signaling.
Finally, we set out to test whether retinal phagocytosis in vivo also involved signaling pathways using FAK and MerTK. We harvested eyecups from age-matched, 3-wk-old wild-type and ß5–/– mice in 1.5-h intervals from 1 h before light onset (5.00 h) until 11.00 h and at 18.00 h. Fig. 5 shows that FAK and MerTK tyrosine phosphorylation levels in wild-type eyecups promptly increased after light onset and peaked at 6.30 h and 8.00 h, respectively, the period of the daily phagocytic burst of RPE (Fig. 3 i). In contrast, ß5–/– eyecups retained basal levels of FAK and MerTK tyrosine phosphorylation at all times (Fig. 5, a–c). Protein expression levels remained constant and were the same in both wild-type and ß5–/– eyecups. Equal levels of the RPE-specific protein RPE65 confirmed that all eyecup samples represented the same number of RPE cells (Fig. 5 a).



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Figure 5. ß5 integrin–deficient retina lacks synchronized activation of FAK and MerTK. (a) Eyecup detergent lysates were prepared from 3-wk-old wild-type and ß5–/– mice at different times of the day, as indicated. Expression and phosphorylation profiles of proteins were compared by immunoblotting with primary antibodies as indicated in the panels. (b and c) Specific activities of FAK and MerTK were determined as in Fig. 4. Promptly after light onset, levels of active, phosphorylated FAK and MerTK increased in wild-type eyecups. This increase was absent in ß5–/– eyecups. Similar results were obtained comparing expression and activity profiles of FAK and MerTK in wild-type and ß5–/– mice at 7 and 12 mo (unpublished data). Note that the rise in FAK phosphorylation preceded the increase of MerTK phosphorylation. This agreed well with our earlier data from in vitro phagocytosis assays showing that MerTK activation upon POS challenge requires FAK activation (reference 29). Ratios of active, phosphorylated protein/total protein are given as fold change compared with ratios in wild-type eyes at 5.00 h, which were set at 1.0 arbitrarily. Results are presented as means ± SD. Asterisks indicate significant differences in ratios (n = 3, Student's t test, P < 0.05) between wild-type and ß5–/– samples at the same time points.

 
Thus, FAK and MerTK activation during POS phagocytosis by RPE in vitro completely correlated with rhythmic activation of these kinases during retinal phagocytosis in vivo. Together, these results strongly suggested that MerTK and FAK activation in whole eyecups at the peak of daily phagocytic activity reflected rhythmic phagocytic signaling by RPE cells in the retina. Furthermore, a lack of these signaling pathways in ß5-deficient RPE indicated that they required {alpha}vß5 integrin.


   Discussion
 Top
 Abstract
 Introduction
 Materials and Methods
 Results
 Discussion
 References
 
This study provides the first demonstration that a lack of {alpha}vß5 integrin impairs a form of noninflammatory clearance phagocytosis in vivo. Our results suggest that peak activity of the RPE's engulfment machinery requires {alpha}vß5 integrin–dependent signaling pathways via FAK and MerTK. This signaling mechanism is essential for long-term function of photoreceptors.

Our data show that RPE cells use {alpha}vß5 integrin–dependent signaling to synchronize their unique rhythmic phagocytic activity with the circadian rhythm of photoreceptor shedding in the retina. In vitro evidence has long suggested that macrophages and dendritic cells, like RPE cells, use {alpha}vß3 or {alpha}vß5 integrin receptors to phagocytose spent cells undergoing apoptosis (10, 16, 20). Furthermore, a lack of functional MerTK impairs both engulfment of spent cells by macrophages and engulfment of spent POS by RPE (13, 23). Together, these results suggest that integrin downstream signaling pathways may also serve to acutely increase engulfment capacity of other phagocytic cells such as macrophages to ensure rapid and efficient clearance of apoptotic cells.

In vivo and in vitro POS–RPE interactions differ significantly from each other, as POS are always in contact with RPE cells in the retina, but de novo binding by POS must precede engulfment in in vitro assays. However, our results show that RPE in vivo and in vitro activate identical signaling pathways to POS phagocytic challenge. This implies a primary role for {alpha}vß5 integrin in RPE function as an important signaling protein that initiates and controls the in vivo rhythm of POS phagocytosis by the RPE.

Our results identify a defect in RPE phagocytosis that causes age-related blindness in mice lacking {alpha}vß5 integrin. ß5–/– mice lacked synchronized POS phagocytosis even at a young age immediately after retinal maturation. In contrast, photoreceptor function in these mice decreased only when they were >4 mo old. Similarly, only RPE of old ß5–/– mice revealed accumulation of autofluorescent age lipids. This suggests that the altered time course of POS uptake by RPE is the primary effect of ß5 integrin deficiency in the retina. It further demonstrates that basal levels of POS phagocytosis in ß5–/– mice suffice to clear shed POS from the retina within 24 h, thus preventing buildup of shed POS, which causes rapid damage to retinal photoreceptors (21, 22, 30). However, accumulation of autofluorescent storage lipids we detected in ß5–/– mice of age indicates that engulfed POS are likely processed incompletely by ß5–/– RPE cells. We suggest that such differences in phagolysosomal digestion of POS material may account for secondary effects on photoreceptor function causing the age-dependent vision loss in ß5–/– mice. Fluorescent lipofuscin accumulation is a common characteristic of aging and of many forms of disease in the human retina (9). Our data support earlier evidence that suggested a direct link of altered photoreceptor POS turnover and lipofuscin accumulation by the RPE (31). They further validate the ß5–/– mouse strain as a valuable animal model for studies of retinal aging. Future studies will explore how environmental or additional genetic factors may contribute to onset, progression, and severity of retinal defects in mice that lack {alpha}vß5 integrin.


   Acknowledgments
 
We thank T. Mittag for providing the ERG corneal electrode and E. Kavalarakis and N. Peachey for help with ERG recordings. We thank L.F. Reichardt and T.M. Redmond for providing antibodies. We thank M. Sircar for excellent technical support and L. Cohen-Gould for assistance with electron microscopy.

This work was supported by National Institutes of Health grants EY13295 and EY14184 (to S.C. Finnemann), and grants HL53949 and HL64353 (to D. Sheppard). S.C. Finnemann is the recipient of a Kirchgessner Research grant. S.E. Brodie was supported in part by an unrestricted grant from Research To Prevent Blindness to the Department of Ophthalmology, Mount Sinai School of Medicine.

The authors have no conflicting financial interests.

Submitted: 19 July 2004
Accepted: 4 November 2004


   References
 Top
 Abstract
 Introduction
 Materials and Methods
 Results
 Discussion
 References
 

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