A Method for Real-Time Assessment of Mitochondrial Respiration Using Murine Corneal Biopsy

Purpose

To develop and optimize a method to monitor real-time mitochondrial function by measuring the oxygen consumption rate (OCR) in murine corneal biopsy punches with a Seahorse extracellular flux analyzer.

Methods

Murine corneal biopsies were obtained using a biopsy punch immediately after euthanasia. The corneal metabolic profile was assessed using a Seahorse XFe96 pro analyzer, and mitochondrial respiration was analyzed with specific settings.

Results

Real-time adenosine triphosphate rate assay showed that mitochondrial oxidative phosphorylation is a major source of adenosine triphosphate production in ex vivo live murine corneal biopsies. Euthanasia methods (carbon dioxide asphyxiation vs. overdosing on anesthetic drugs) did not affect corneal OCR values. Mouse corneal biopsy punches in 1.5-mm diameter generated higher and more reproducible OCR values than those in 1.0-mm diameter. The biopsy punches from the central and off-central cornea did not show significant differences in OCR values. There was no difference in OCR reading by the tissue orientations (the epithelium side up vs. the endothelium side up). No significant differences were found in corneal OCR levels between sexes, strains (C57BL/6J vs. BALB/cJ), or ages (4, 8, and 32 weeks). Using this method, we showed that the wound healing process in the mouse cornea affected mitochondrial activity.

Conclusions

The present study validated a new strategy to measure real-time mitochondrial function in fresh mouse corneal tissues. This procedure should be helpful for studies of the ex vivo live corneal metabolism in response to genetic manipulations, disease conditions, or pharmacological treatments in mouse models.

PBN (Phenyl-N-Tert-Butylnitrone)-Derivatives Are Effective in Slowing the Visual Cycle and Rhodopsin Regeneration and in Protecting the Retina from Light-Induced Damage

A2E and related toxic molecules are part of lipofuscin found in the retinal pigment epithelial (RPE) cells in eyes affected by Stargardt's disease, age-related macular degeneration (AMD), and other retinal degenerations. A novel therapeutic approach for treating such degenerations involves slowing down the visual cycle, which could reduce the amount of A2E in the RPE. This can be accomplished by inhibiting RPE65, which produces 11-cis-retinol from all-trans-retinyl esters. We recently showed that phenyl-N-tert-butylnitrone (PBN) inhibits RPE65 enzyme activity in RPE cells. In this study we show that like PBN, certain PBN-derivatives (PBNDs) such as 4-F-PBN, 4-CF3-PBN, 3,4-di-F-PBN, and 4-CH3-PBN can inhibit RPE65 and synthesis of 11-cis-retinol in in vitro assays using bovine RPE microsomes. We further demonstrate that systemic (intraperitoneal, IP) administration of these PBNDs protect the rat retina from light damage. Electroretinography (ERG) and histological analysis showed that rats treated with PBNDs retained ~90% of their photoreceptor cells compared to a complete loss of function and 90% loss of photoreceptors in the central retina in rats treated with vehicle/control injections. Topically applied PBN and PBNDs also significantly slowed the rate of the visual cycle in mouse and baboon eyes. One hour dark adaptation resulted in 75-80% recovery of bleachable rhodopsin in control/vehicle treated mice. Eye drops of 5% 4-CH3-PBN were most effective, inhibiting the regeneration of bleachable rhodopsin significantly (60% compared to vehicle control). In addition, a 10% concentration of PBN and 5% concentration of 4-CH3-PBN in baboon eyes inhibited the visual cycle by 60% and by 30%, respectively. We have identified a group of PBN related nitrones that can reach the target tissue (RPE) by systemic and topical application and slow the rate of rhodopsin regeneration and therefore the visual cycle in mouse and baboon eyes. PBNDs can also protect the rat retina from light damage. There is potential in developing these compounds as preventative therapeutics for the treatment of human retinal degenerations in which the accumulation of lipofuscin may be pathogenic.

Leukemia inhibitory factor coordinates the down-regulation of the visual cycle in the retina and retinal-pigmented epithelium

Leukemia inhibitory factor (LIF), an interleukin-6 family neurocytokine, is up-regulated in response to different types of retinal stress and has neuroprotective activity through activation of the gp130 receptor/STAT3 pathway. We observed that LIF induces rapid, robust, and sustained activation of STAT3 in both the retina and retinal pigmented epithelium (RPE). Here, we tested whether LIF-induced STAT3 activation within the RPE can down-regulate RPE65, the central enzyme in the visual cycle that provides the 11-cis-retinal chromophore to photoreceptors in vivo. We generated conditional knock-out mice to specifically delete STAT3 or gp130 in RPE, retina, or both RPE and retina. After intravitreal injection of LIF, we analyzed the expression levels of visual cycle genes and proteins, isomerase activity of RPE65, levels of rhodopsin protein, and the rates of dark adaptation and rhodopsin regeneration. We found that RPE65 protein levels and isomerase activity were reduced and recovery of bleachable rhodopsin was delayed in LIF-injected eyes. In mice with functional gp130/STAT3 signaling in the retina, rhodopsin protein was also reduced by LIF. However, the LIF-induced down-regulation of RPE65 required a functional gp130/STAT3 cascade intrinsic to RPE. Our data demonstrate that a single cytokine, LIF, can simultaneously and independently affect both RPE and photoreceptors through the same signaling cascade to reduce the generation and utilization of 11-cis-retinal.

Alpha-phenyl-N-tert-butylnitrone (PBN) prevents light-induced degeneration of the retina by inhibiting RPE65 protein isomerohydrolase activity

α-Phenyl-N-tert-butylnitrone (PBN), a free radical spin trap, has been shown previously to protect retinas against light-induced neurodegeneration, but the mechanism of protection is not known. Here we report that PBN-mediated retinal protection probably occurs by slowing down the rate of rhodopsin regeneration by inhibiting RPE65 activity. PBN (50 mg/kg) protected albino Sprague-Dawley rat retinas when injected 0.5-12 h before exposure to damaging light at 2,700 lux intensity for 6 h but had no effect when administered after the exposure. PBN injection significantly inhibited in vivo recovery of rod photoresponses and the rate of recovery of functional rhodopsin photopigment. Assays for visual cycle enzyme activities indicated that PBN inhibited one of the key enzymes of the visual cycle, RPE65, with an IC(50) = 0.1 mm. The inhibition type for RPE65 was found to be uncompetitive with K(i) = 53 μm. PBN had no effect on the activity of other visual cycle enzymes, lecithin retinol acyltransferase and retinol dehydrogenases. Interestingly, a more soluble form of PBN, N-tert-butyl-α-(2-sulfophenyl) nitrone, which has similar free radical trapping activity, did not protect the retina or inhibit RPE65 activity, providing some insight into the mechanism of PBN specificity and action. Slowing down the visual cycle is considered a treatment strategy for retinal diseases, such as Stargardt disease and dry age-related macular degeneration, in which toxic byproducts of the visual cycle accumulate in retinal cells. Thus, PBN inhibition of RPE65 catalytic action may provide therapeutic benefit for such retinal diseases.

Factors that determine Ca2+ sensitivity of photoreceptor guanylyl cyclase. Kinetic analysis of the interaction between the Ca2+-bound and the Ca2+-free guanylyl cyclase activating proteins (GCAPs) and recombinant photoreceptor guanylyl cyclase 1 (RetGC-1)

We explored the possibility that, in the regulation of an effector enzyme by a Ca(2+)-sensor protein, the actual Ca(2+) sensitivity of the effector enzyme can be determined not only by the affinity of the Ca(2+)-sensor protein for Ca(2+) but also by the relative affinities of its Ca(2+)-bound versus Ca(2+)-free form for the effector enzyme. As a model, we used Ca(2+)-sensitive activation of photoreceptor guanylyl cyclase (RetGC-1) by guanylyl cyclase activating proteins (GCAPs). A substitution Arg(838)Ser in RetGC-1 found in human patients with cone-rod dystrophy is known to shift the Ca(2+) sensitivity of RetGC-1 regulation by GCAP-1 to a higher Ca(2+) range. We find that at physiological concentrations of Mg(2+) this mutation increases the free Ca(2+) concentration required for half-maximal inhibition of the cyclase from 0.27 to 0.61 microM. Similar to rod outer segment cyclase, Ca(2+) sensitivity of recombinant RetGC-1 is strongly affected by Mg(2+), but the shift in Ca(2+) sensitivity for the R838S mutant relative to the wild type is Mg(2+)-independent. We determined the apparent affinity of the wild-type and the mutant RetGC-1 for both Ca(2+)-bound and Ca(2+)-free GCAP-1 and found that the net shift in Ca(2+) sensitivity of the R838S RetGC-1 observed in vitro can arise predominantly from the change in the affinity of the mutant cyclase for the Ca(2+)-free versus Ca(2+)-loaded GCAP-1. Our findings confirm that the dynamic range for RetGC regulation by Ca(2+)/GCAP is determined by both the affinity of GCAP for Ca(2+) and relative affinities of the effector enzyme for the Ca(2+)-free versus Ca(2+)-loaded GCAP.

Kinetic and product distribution analysis of human eosinophil cationic protein indicates a subsite arrangement that favors exonuclease-type activity

With the use of a high yield prokaryotic expression system, large amounts of human eosinophil cationic protein (ECP) have been obtained. This has allowed a thorough kinetic study of the ribonuclease activity of this protein. The catalytic efficiencies for oligouridylic acids of the type (Up)nU>p, mononucleotides U>p and C>p, and dinucleoside monophosphates CpA, UpA, and UpG have been interpreted by the specific subsites distribution in ECP. The distribution of products derived from digestion of high molecular mass substrates, such as poly(U) and poly(C), by ECP was compared with that of RNase A. The characteristic cleavage pattern of polynucleotides by ECP suggests that an exonuclease-like mechanism is predominantly favored in comparison to the endonuclease catalytic mechanism of RNase A. Comparative molecular modeling with bovine pancreatic RNase A-substrate analog crystal complexes revealed important differences in the subsite structure, whereas the secondary phosphate-binding site (p2) is lacking, the secondary base subsite (B2) is severely impaired, and there are new interactions at the po, Bo, and p-1 sites, located upstream of the P-O-5' cleavable phosphodiester bond, that are not found in RNase A. The differences in the multisubsites structure could explain the reduced catalytic efficiency of ECP and the shift from an endonuclease to an exonuclease-type mechanism.

Single-strand-preferring RNases degrade double-stranded RNAs by destabilizing its secondary structure

To establish the mechanism of dsRNA degradation by mammalian single-stranded-preferring ribonucleases, and, in particular, the influence of their positively charged non-catalytic amino acid residues, we have studied the kinetic parameters of the depolimerization of single- and double-stranded polyribonucleotides such as poly(U), poly(U).poly(A), poly(C) and poly(C).poly(I) by the action of human seminal RNase, bovine seminal RNase and ox pancreas RNase A. While the activities of these RNases on poly(I).poly(C) were definitely lower than those on poly(C), the activities of human seminal and bovine seminal RNases on poly(U).poly(A) and poly(U) were of the same order of magnitude under physiological salt conditions. The ratio of the RNase A degrading activities towards poly(U) and poly(U).poly(A) at I = 0.16 M is ten times higher than the corresponding ratios determined with bovine seminal and human seminal ribonucleases. The high activities of these two RNases towards poly(U).poly(A) are discussed on the basis of their efficient estabilishing action on this double-helical nucleic acid due to their high affinity for poly(A). The destabilizing action of human seminal RNase and bovine seminal RNase on the poly (U).poly(A) duplex is higher than that measurable with bovine RNase A because of the higher number of positive charges present on those enzyme molecules. This may therefore explain why human seminal and bovine seminal ribonucleases are more efficient than RNase A in the depolymerization of poly(U).poly(A) at physiological ionic strength.

Primary structures of two ribonucleases from ginseng calluses. New members of the PR-10 family of intracellular pathogenesis-related plant proteins

The amino acid sequences of two ribonucleases from a callus cell culture of Panax ginseng were determined. The two sequences differ at 26% of the amino acid positions. Homology was found with a large family of intracellular pathogenesis-related proteins, food allergens and tree pollen allergens from both dicotyledonous and monocotyledonous plant species. There is about 30% sequence difference with proteins from species belonging to the same plant order (Apiales: parsley and celery), 60% with those from four other dicotyledonous plant orders and about 70% from that of the monocotyledonous asparagus. More thorough evolutionary analyses of sequences lead to the conclusion that the general biological function of members of this protein family may be closely related to the ability to cleave intracellular RNA and that they have an important role in cell metabolism. As the three-dimensional structure of one of the members of this protein family has been determined recently [Gajhede et al., Nature Struct Biol 3 (1996) 1040-1045], it may be possible to assign active-site residues in the enzyme molecule and make hypotheses about its mode of action. Structural features in addition to the cellular site of biosynthesis indicate that this family of ribonucleases is very different from previously investigated ones.

Determination of the nucleotide conformation in the productive enzyme-substrate complexes of RNA-depolymerases

The aim of this work is to determine the conformation of the nucleobase adjacent to the cleavable phosphodiester bond in the productive enzyme-substrate complex of RNA-depolymerizing enzymes. To this end the kinetic parameters of hydrolysis of UpA, 2'-C-Me- and 3'-C-Me-UpA were determined for RNase A, RNase Pb2, nuclease S1 and snake venom phosphodiesterase. In these derivatives the ranges of the allowed orientation of uridine residues are restricted due to the substitution of methyl groups for the ribose hydrogen atoms. The results described demonstrate that the proposed method is of general value for the estimation of the nucleotide glycoside angles in the productive enzyme-substrate complexes.

A novel guanyl-preferable ribonuclease of Bacillus polymyxa: isolation and characterization of the enzyme

Three forms of the extracellular alkaline ribonuclease of B. polymyxa (RNases Bpo I, Bpo II and Bpo III) were obtained in the homogeneous states. Relative molecular weights, N- and C-terminal amino acid sequences of the proteins were determined. The two higher-molecular weight forms of the enzyme (RNases Bpo I and Bpo III) were shown to be precursor molecules which differed from the mature B. polymyxa RNase (RNase Bpo II) by the presence of a extra twelve and six amino acid residues at the amino terminus, respectively. The study of catalytic properties of the enzyme elucidated that the extent of specificity of B. polymyxa RNase in respect to highpolymeric substrates is different from that of other natural Bacillus RNases. Amino acid composition of B. polymyxa RNase was established and structural similarity within family of Bacillus RNases is discussed. B. polymyxa RNase was shown to be inhibited by intracellular protein inhibitor of B. amyloliquefaciens RNase with the dissociation constant of 2.7 x 10(-12) M.

Dissociation constants and thermal stability of complexes of Bacillus intermedius RNase and the protein inhibitor of Bacillus amyloliquefaciens RNase

Binase, the extracellular ribonuclease of Bacillus intermedius, is inhibited by barstar, the natural protein inhibitor of the homologous RNase, barnase, of B. intermedius. The dissociation constants of the binase complexes with barstar and its double Cys40,82Ala mutant are about 10(-12) M, only 5 to 43 times higher than those of the barnase-barstar complex. As with barnase, the denaturation temperature of binase is raised dramatically in the complex. Calorimetric studies of the formation and stability of the binase-barstar complex show that the binase reaction with barstar is qualitatively similar to that of barnase but some significant quantitative differences are reported.

Mutational analysis of the active site of RNase of Bacillus intermedius (BINASE)

To elucidate the functional role of some residues in the active site of binase, the extracellular ribonuclease of Bacillus intermedius, we used site-directed mutagenesis. On cleavage of various substrates the catalytic activity of binase mutant His101 Glu is 2.0-2.7% of that for the native enzyme. The decrease in activity is determined mainly by the decrease in molecular rate constant kcat, with almost unchanged affinity of the enzyme for the substrate, characterized by KM. This is the expected result if His101 acts as an general acid, donating a proton to the leaving group on cleavage of a phosphodiester bond. The replacement of Lys26 by Ala causes a reduction in the enzyme activity to 13-33%, depending on the substrate. The activity decreases are due to changes in both kcat and KM for poly(A) and poly(A) but in kcat alone for GpA. In the latter case the effect is far less than that seen in the homologous mutation in the closely related enzyme, barnase.

High sequence similarity between a ribonuclease from ginseng calluses and fungus-elicited proteins from parsley indicates that intracellular pathogenesis-related proteins are ribonucleases

A ribonuclease from a callus cell culture of Panax ginseng C.A. Mey strain R1 was isolated. A pure protein with an apparent molecular mass of 18 kDa was obtained. The N-terminal sequences of the protein and of the C-terminal CNBr peptide were determined. No homology with other ribonucleases was found, but there was 60-70% sequence identity with two intracellular pathogenesis-related (IPR) proteins from parsley, indicating that not only these two proteins, but also homologous IPR proteins identified in other plant species are ribonucleases.

Primary structure and catalytic properties of extracellular ribonuclease of Bacillus circulans

A complete amino acid sequence of extracellular Bacillus circulans RNase was established and compared with a structure of B. amyloliquefaciens RNase. Gln15, Gly65 and Gln104 in B. amyloliquefaciens RNase were found to be replaced by Leu, Ala and Lys, respectively, in B. circulans RNase. Catalytic properties of B. circulans RNase were studied.

NMR studies of a complex of RNAse from Penicillium brevicompactum with dinucleoside phosphonate and the implications for the mechanism of enzyme action

The chemical-shift dependences of the proton signals of the guanosine and uridine moieties were measured as a function of the relative amount of GpcU complexed with RNase Pb1 (EC 3.1.27.3). The equal values of the chemical-shift changes of the guanosine C8-protons on complex formation between GpcU and RNase Pb1 and that of the 3'-GMP and RNase Pb1 allow to conclude that the guanosine base is bound in the same manner in these protein-ligand complexes. The guanosine moiety of GpcU is also most probably bound in the syn-conformation. The absence of changes in both the linewidths and the chemical shifts of the C1', C5 and C6-proton signals of the uridine on complex formation indicates that the uridine moiety of the dinucleoside phosphonate is not immobilized in the complex. The pH dependences of the chemical shifts of the C2-protons of the histidine-imidazole ring of RNase Pb1 and that of the 31P of GpcU in the RNase complex were studied. The results suggest that there is a direct interaction between the phosphonate group of the ligand and the protonated imidazole ring of His-90. The side groups of His-38 and Glu-56 are hydrogen bonded to each other at neutral pH and they are located in the vicinity of the phosphonate group of GpcU. When the carboxyl group of Glu-56 is protonated the His-38 imidazole ring forms a new hydrogen bond with one of the phosphoryl oxygens of the phosphonate group. On the basis of these results we propose the mechanism of action of RNase Pb1 which is probably also true for RNase T1.

Increase of specificity of RNase from Bacillus amyloliquefaciens (barnase) by substitution of Glu for Ser57 using site-directed mutagenesis

Bacterial ribonucleases from Bacillus amyloliquefaciens and Bacillus intermedius show the specificity towards the nature of a nucleoside at the O3' end of the phosphodiester bond to be split in the preference order G > A >> U > C in the cleavage reactions of polynucleotides. It follows from the X-ray data that the substrate guanosine base is bound at the active site of these RNases in the same manner as for high-specificity guanylic RNases. We supposed that the difference in specificity for the two types of RNases is due to the additional hydrogen bond between the protein and a purine base in the case of bacterial guanyl-preferring RNases in contrast to the high-specificity guanylic RNases. To examine this hypothesis we prepared the Ser57 --> Glu mutant of B. amyloliquefaciens, in which this hydrogen bond is eliminated. Kinetic studies demonstrate that the specificity of this mutant towards guanylic substrates is 35-times greater than that of the wild-type RNases from B. amyloliquefaciens and close to that of RNases T1.

A comparative study on the catalytic properties of guanyl-specific ribonucleases

The kinetic parameters of reactions catalyzed by four guanyl-specific RNases T1, Pb1, Th1 and Sa were studied comparatively using three types of substrates; guanosine-2',3'-cyclophosphates, GpN dinucleoside phosphates and synthetic polyribonucleotides. The kinetic parameters were shown to be similar in spite of considerable differences in primary structures of these RNases, including amino acid residues of the active sites. Therefore, primary structures of guanyl RNases allow for a considerable number of substitutions (both in the 'recognising' and catalytical parts of the active site) without changes in the catalytical parameters.

Specificity of guanylic RNases to polynucleotide substrates

Kinetic parameters kcat and KM were measured for cleavage of poly I, poly A, poly U, poly C and poly I poly C by guanyl-specific RNases Sa, Pb1 and T1 and compared with that of guanyl-preferential RNase Bi. Catalytic efficiencies of the investigated enzymes to polynucleotide substrates vary considerably. The structural basis for specificity of these RNases is discussed. A hypothesis is suggested that Ser-56 plays an important role in recognition of poly A by RNase Bi.

A route to 2',5'-oligoadenylates with increased stability towards phosphodiesterases

The rates of enzymatic hydrolysis of 2',5'-oligoadenylates and their synthetic analogs have been measured. These compounds were treated with either NIH 3T3 cell lysates, mouse liver homogenates or snake venom phosphodiesterase. All analogs with 3'-terminal acyclic nucleoside residues demonstrated greater stability compared with the natural compound adenylyl(2'-5')adenylyl(2'-5')adenosine.

Stereoelectronic effects in RNase-catalysed reactions of dinucleoside phosphate cleavage

The rate at which dinucleoside phosphates are cleaved by RNases is supposed to be determined by the mole fraction of enzyme-substrate complexes in which the phosphodiester moiety of a dinucleoside phosphate has a highly reactive conformation. The mole fraction of such complexes for a particular RNase depends on the nature of a nucleoside at the O5'-end of the phosphodiester bond. Experimental data are presented to support this hypothesis.

Correlative variations of the free energies for enzyme-substrate complex formation and the transition-state stabilization for RNases

It was found for RNases of different specificities that changes in the free energy for substrate-enzyme binding induced by variations in the nucleotide base structure are accompanied by proportional changes in kcat/Km. This was considered to be a consequence of the strain in the enzyme-substrate complex.