Activity distribution of cytochrome oxidase in the rat retina. A quantitative histochemical study

Distribution and Activity of Mitochondrial Proteins in Vascular and Avascular Retinas: Implications for Retinal Metabolism

Purpose

Understanding the energetics of retinal neurons and glia is crucial for developing therapies for diseases that feature deficits in nutrient or oxygen availability. Herein, we performed a detailed characterization of the distribution and activity of mitochondrial proteins in the vascularized retinas of rat and marmoset, and the avascular retinas of rabbit and guinea pig. Further, we delineated expression of ubiquitous mitochondrial creatine kinase (uMtCK).

Methods

Expression of eight mitochondrial proteins was investigated using Western blotting, single- and double-labeling immunohistochemistry. Activities of cytochrome c oxidase, succinate dehydrgogenase, and isocitrate dehydrogenase were determined by enzyme histochemistry using unfixed tissue sections.

Results

In vascularized retinas, immunoreactivities were characterized by strong, punctate labeling in the plexiform layers, photoreceptor inner segments, somas of various cell types, notably retinal ganglion cells (RGCs), and the basolateral surface of the retinal pigment epithelium. In avascular retinas, immunoreactivities featured intense labeling of inner segments, together with weak, but unambiguous, staining of both plexiform layers. RGCs were relatively enriched. In Müller cells of avascular retinas, mitochondria were restricted to scleral-end processes. For each species, enzyme activity assays yielded similar results to the protein distributions. Labeling for uMtCK in vascular and avascular retinas was fundamentally similar, being restricted to neuronal populations, most notably inner segments and RGCs. Of all of the mitochondrial proteins, uMtCK displayed the strongest labeling in avascular retinas. uMtCK was not detectable in Müller cells in any species.

Conclusions

The current findings advance our understanding of the metabolic similarities and differences between vascular and avascular retinas.

Immunolocalisation pattern of complex I-V in ageing human retina: Correlation with mitochondrial ultrastructure

Earlier studies reported accumulation of mitochondrial DNA mutations in ageing and age-related macular degeneration. To know about the mitochondrial status with age, we examined immunoreactivity (IR) to markers of mitochondria (anti-mitochondrial antibody and voltage-dependent anion channel-1) and complex I-V (that mediate oxidative phosphorylation, OXPHOS) in donor human retinas (age: 19-94years; N=26; right eyes). In all samples, at all ages, IR to anti-mitochondrial antibody and voltage-dependent anion channel-1 was prominent in photoreceptor cells. Between second and seventh decade of life, strong IR to complex I-V was present in photoreceptors over macular to peripheral retina. With progressive ageing, the photoreceptors showed a decrease in complex I-IR (subunit NDUFB4) at eighth decade, and a weak or absence of IR in 10 retinas between ninth and tenth decade. Patchy IR to complex III and complex IV was detected at different ages. IR to ND1 (complex I) and complex II and V remained unaltered with ageing. Nitrosative stress (evaluated by IR to a nitro-tyrosine antibody) was found in photoreceptors. Superoxide dismutase-2 was found upregulated in photoreceptors with ageing. Mitochondrial ultrastructure was examined in two young retinas with intact complex IR and six aged retinas whose counterparts showed weak to absence of IR. Observations revealed irregular, photoreceptor inner segment mitochondria in aged maculae and mid-peripheral retina between eighth and ninth decade; many cones possessed autophagosomes with damaged mitochondria, indicating age-related alterations. A trend in age-dependent reduction of complex I-IR was evident in aged photoreceptors, whereas patchy complex IV-IR (subunits I and II) was age-independent, suggesting that the former is prone to damage with ageing perhaps due to oxidative stress. These changes in OXPHOS system may influence the energy budget of human photoreceptors, affecting their viability.

Oxygen consumption in the rat outer and inner retina: light- and pharmacologically-induced inhibition

Biochemical, physiological and histological data have established that 55-65% of retinal mitochondria are located in the photoreceptor inner segments and suggested that photoreceptors have at least a two-fold greater oxygen consumption (QO2) than the remaining inner retina. QO2 in isolated whole rat retina (QWR), outer retina (QOR) and inner retina (QIR) was measured during dark and rod-saturating light adaptation. The effects of function-specific chemical agents on QWR, QOR and QIR during dark and light adaptation were determined. In addition, the oxidation-reduction (redox) potential of cytochrome a3 of whole, outer and inner retina was measured during dark and light adaptation. During dark adaptation, the mean QWR was 1.62 mumol O2 (mg dry wt)-1 hr-1 and whole retinal level of reduced cytochrome a3 was 19%. They decreased by 24% and 37% during light adaptation, respectively. To determine QOR and QIR during dark and light adaptation, the outer retina was pharmacologically-isolated from inner retina using L-2-amino-4-phosphonobutyric acid plus kynurenic acid (APB/Kyn). Experiments in the presence or absence of APB/Kyn revealed that: (i) QOR, but not QIR, of the dark-adapted retina was decreased 37% during light adaptation, (ii) the outer and inner retina consumed 65% and 35% of the QWR during dark adaptation, respectively, and 54% and 46% of the QWR during light adaptation, respectively, (iii) the level of reduced retinal cytochrome a3 in the outer, but not inner, retina was decreased 34% during light adaptation, (iv) during light adaptation, the rate of QO2 was equal in the outer and inner retina, and (v) the effects of APB/Kyn were reversible. These results establish that the mean rate of QIR and retinal cytochrome a3 are unchanged during dark or light adaptation. In addition, they suggest that QOR:QIR in the rat may be modeled using a 65%:35% model during DA and a 55%:45% model during LA. All the function-specific agents--IBMX, lead, diltiazem, ouabain, CO2+ plus Mg2+ and verapamil--significantly decreased QWR during dark and light adaptation. A more detailed analysis revealed that IBMX and lead each selectively reduced (> or = 90%) QOR during dark adaptation whereas CO2+ plus Mg2+ and verapamil each selectively reduced (> or = 93%) QIR during dark and light adaptation. These results are consistent with the known pharmacological sites and mechanisms of these agents. Additional experiments determined that the IBMX- and lead-induced inhibition of QOR during dark adaptation resulted, either wholly or partially, from the influx of extracellular Ca2+. During dark adaptation in Ca(2+)-free medium: (i) QWR and QOR increased while QIR was unchanged, (ii) QOR was not decreased in the presence of IBMX and (iii) QOR was only partially decreased in the presence of lead.(ABSTRACT TRUNCATED AT 400 WORDS)

An optimized method for determining cytochrome oxidase activity in brain tissue homogenates

We have developed a method to accurately and reproducibly determine the total activity of cytochrome oxidase (CO) in rat brain tissue homogenates. Previously, accurate measurements have been difficult to obtain because detergents, which are needed to disrupt membranes and unmask CO, also inhibit the enzyme by solubilizing certain phospholipids required for rapid turnover. We compared various methods of sample preparation, and found that maximal CO activity in homogenates could be obtained using specific concentrations of detergents. The range of optimal detergent concentrations was relatively narrow, as CO activity fell sharply with small deviations from the optimum. Of 5 detergents tested, deoxycholate stimulated CO maximally over the widest range of concentrations. In deoxycholate-treated homogenate samples, the calculated CO turnover number was about 480 s-1, indicating that overall enzyme activity was maximal or near maximal, and therefore that the total content of CO was probably detected. This method was reproducible with large or small samples (e.g., < 1 mg tissue), and should be applicable to studies of neural tissue in general.

Inhibition of cytochrome oxidase and blue-light damage in rat retina

The activity of cytochrome oxidase, outer nuclear layer thickness, and edema were quantitatively evaluated in the blue-light exposed rat retina. Dark-adapted or cyclic-light reared rats were exposed to blue light with a retinal dose of 380 kJ/m2. Immediately, 1, 2, and 3 day(s) after exposure, the retinas of six rats from each adaptation group were examined. There was no difference between the dark-adapted and cyclic-light reared rats. Immediately after light exposure, cytochrome oxidase activity decreased. The activity in the inner segments remained low at day 1, while severe edema was observed in the inner and outer segments. The outer nuclear layer thickness decreased 1-3 days after exposure. The blue-light exposure inhibited cytochrome oxidase activity and caused retinal injury. Similarity of the injury process in the dark-adapted and cyclic-light reared retinas suggests that rhodopsin was not involved. The inhibition of cytochrome oxidase could be a cause of retinal damage.

Cytochrome oxidase activity in rat retina after exposure to 404 nm blue light

Cytochrome oxidase (CYO), a key enzyme in the respiratory chain, was observed as an indicator of retinal metabolism after an in vivo blue light exposure. Thirty Sprague-Dawley rats were exposed to optic radiation of 404 nm with a retinal dose of 110kJ/m2. Immediately after exposure, the CYO activity in the pigment epithelium, in the outer and inner segments of photoreceptors, and in the outer plexiform layer of the exposed retina, was reduced to one-third-to-half of the control level. However, there was an increase in CYO activity in the exposed retina one day after exposure. One week after exposure, the CYO activity in the inner segment and the outer plexiform layer was higher, while the activity in the other two layers was lower, than that at one day, although still higher than in the control. Two weeks after exposure, the CYO activity in the four retinal layers returned to the level of the control retina, as did the activity four weeks after. After exposure, no ophthalmoscopically visible retinal change and no light-microscopically evident morphological alterations were found. There was no retinal edema or loss of photoreceptor cells. The observed alteration in CYO activity after blue light exposure may represent an inhibition of retinal metabolism. The inhibition was reversible. If this compensation mechanism is overwhelmed, retinal damage may occur.