Phosphatidylinositol stimulates phosphorylation of protein components I and II in rod outer segments of frog photoreceptors

Haploinsufficiency of RanBP2 is neuroprotective against light-elicited and age-dependent degeneration of photoreceptor neurons

Prolonged light exposure is a determinant factor in inducing neurodegeneration of photoreceptors by apoptosis. Yet, the molecular bases of the pathways and components triggering this cell death event are elusive. Here, we reveal a prominent age-dependent increase in the susceptibility of photoreceptor neurons to undergo apoptosis under light in a mouse model. This is accompanied by light-induced subcellular changes of photoreceptors, such as dilation of the disks at the tip of the outer segments, prominent vesiculation of nascent disks, and autophagy of mitochondria into large multilamellar bodies. Notably, haploinsufficiency of Ran-binding protein-2 (RanBP2) suppresses apoptosis and most facets of membrane dysgenesis observed with age upon light-elicited stress. RanBP2 haploinsufficiency promotes decreased levels of free fatty acids in the retina independent of light exposure and turns the mice refractory to weight gain on a high-fat diet, whereas light promotes an increase in hydrogen peroxide regardless of the genotype. These studies demonstrate the presence of age-dependent and RanBP2-mediated pathways modulating membrane biogenesis of the outer segments and light-elicited neurodegeneration of photoreceptors. Furthermore, the findings support a mechanism whereby the RanBP2-dependent production of free fatty acids, metabolites thereof or the modulation of a cofactor dependent on any of these, promote apoptosis of photoreceptors in concert with the light-stimulated production of reactive oxygen species.

Phosphorylation of rod outer segment proteins modulates phosphatidylethanolamine N-methyltransferase and phospholipase A2 activities in photoreceptor membranes

The activities of enzymes involved in lipid metabolism--phospholipase A2 (PLA2) and phosphatidylethanolamine N-methyltransferase (PE N-MTase)--were found to be differently affected by pre-incubation of rod outer segments (ROS) under protein phosphorylating or dephosphorylating conditions. Exposure to cAMP-dependent protein kinase (PKA), under dark or light conditions, produced a significant increase in PE N-MTase activity, whereas PLA2 activity decreased. Under standard protein kinase C (PKC) phosphorylating conditions in light, PE N-MTase activity was stimulated and PLA2 activity was not affected. When the assays were performed in the dark, both enzymatic activities were unaffected when compared to the corresponding controls. Incubation of ROS membranes in light in the presence of PKC activators phorbol 12,13-dibutyrate (PDBu) and dioctanoylglycerol (DOG) resulted in the same pattern of changes in enzyme activities as described for standard PKC phosphorylating condition. Pre-incubation of membranes with the PKC inhibitor H-7 reduced the stimulation of PDBu on PE N-MTase activity, and had no effect on PLA2 activity in ROS membranes incubated with the phorbol ester. Pre-treatment of isolated ROS with alkaline phosphatase resulted in decreased PE N-MTase activity and produced a significant stimulation of PLA2 activity under dark as well as under light conditions when compared to the corresponding controls. These findings suggest that ROS protein phosphorylation and dephosphorylation modulates PE N-MTase and PLA2 activities in isolated ROS, and that these activities are independently and specifically modulated by particular kinases. Furthermore, dephosphorylation of ROS proteins has the opposite effect to that produced by protein phosphorylation on the enzymes studied.

Can phosphorylation and dephosphorylation of rod outer segment membranes affect phosphatidate phosphohydrolase and diacylglycerol lipase activities?

Phosphatidate phosphohydrolase (PAPase) and diacylglycerol lipase (DGL) enzymatic activities were found to be differently affected by preincubation of rod outer segments (ROS) under protein phosphorylation or dephosphorylation conditions in darkness or in light. Under protein kinase C (PKC) phosphorylation conditions, PAPase and DGL were inhibited in darkness and in light. The inhibitory effect on PAPase and DGL activities by PKC phosphorylation in the presence of light was more pronounced when the activities were compared with the activities in control membranes determined in the presence of EGTA. The addition of PKC activators such as phorbol-12,13-dibutyrate and dioctanoylglycerol (DOG) instead of DG produced the same pattern of changes in enzymatic activities. Pretreatment of ROS membranes with cAMP-dependent protein kinase (PKA) produced a significant increase in both enzymatic activities in the presence of light. No changes were observed when ROS proteins were phosphorylated by PKA in the dark. Dephosphorylation of ROS membranes with alkaline phosphatase resulted in a decrease in PAPase activity that was more marked under light than under dark conditions. DGL activity was not modified under dephosphorylation conditions. These findings suggest that the metabolization of phosphatidic acid in isolated ROS is differently affected by protein phosphorylation and dephosphorylation reactions.

Protein kinase C activity and light sensitivity of single amphibian rods

Biochemical experiments by others have indicated that protein kinase C activity is present in the rod outer segment, with potential or demonstrated targets including rhodopsin, transducin, cGMP-phosphodiesterase (PDE), guanylate cyclase, and arrestin, all of which are components of the phototransduction cascade. In particular, PKC phosphorylations of rhodopsin and the inhibitory subunit of PDE (PDE ) have been studied in some detail, and suggested to have roles in downregulating the sensitivity of rod photoreceptors to light during illumination. We have examined this question under physiological conditions by recording from a single, dissociated salamander rod with a suction pipette while exposing its outer segment to the PKC activators phorbol-12-myristate,13-acetate (PMA) or phorbol-12,13-dibutyrate (PDBu), or to the PKC-inhibitor GF109203X. No significant effect of any of these agents on rod sensitivity was detected, whether in the absence or presence of a background light, or after a low bleach. These results suggest that PKC probably does not produce any acute downregulation of rod sensitivity as a mechanism of light adaptation, at least for isolated amphibian rods.

Phosphorylation of bovine rod photoreceptor cyclic GMP phosphodiesterase

The cyclic GMP phosphodiesterase (PDE) of retinal rods plays a key role in phototransduction and consists of two catalytic subunits (PDE alpha and PDE beta) and two identical inhibitory subunits (PDE gamma). Here we report that PDE alpha and PDE gamma are phosphorylated by protein kinase(s) C (PKC) from brain and rod outer segments (ROS). These same two types of PKC also phosphorylate PDE alpha in trypsin-activated PDE (without PDE gamma). In contrast, cyclic-AMP-dependent protein kinase catalytic subunit phosphorylates both PDE alpha and PDE beta, but not PDE gamma. This kinase does not phosphorylate trypsin-activated PDE. The synthetic peptides AKVISNLLGPREAAV (PDE alpha 30-44) and KQRQTRQFKSKPPKK (PDE gamma 31-45) inhibited phosphorylation of PDE by PKC from ROS. These data suggest that sites (at least one for each subunit) for phosphorylation of PDE by PKC are localized in these corresponding regions of PDE alpha and PDE gamma. Isoenzyme-specific PKC antibodies against peptides unique to the alpha, beta, gamma, delta, epsilon and zeta isoforms of protein kinase C were used to show that a major form of PKC in ROS is PKC alpha. However, other minor forms were also present.

Low molecular mass phosphoproteins from the frog rod outer segments form a complex with 48 kDa protein

Upon separation of cAMP-dependent low molecular mass phosphoproteins [Components I and II; Polans et al. (1979) J. gen. Physiol. 74, 595-613] from the frog rod outer segments by gel-chromatography, isoelectric focusing, non-denaturating electrophoresis and ion-exchange chromatography, they behave like subunits of the oligomeric complex. Apparent molecular mass of the complex determined by gel-chromatography is 52-57 kDa and by non-denaturating gradient electrophoresis is 62-66 kDa. The isoelectric point of the complex is 5.5. The elution profile of Components I and II upon gel-chromatography and ion-exchange chromatography coincides with that of major rod outer segment 48 kDa protein. The isoelectric point for them also coincides with the isoelectric point of 48 kDa protein. The amount of low molecular mass phosphoproteins is sealed rods is equal to one molecule per 60 rhodopsin molecules and coincides with that of a 48 kDa protein. It is suggested that in solution Components I and II form an oligomeric complex with 48 kDa protein.

The influence of arrestin (48K protein) and rhodopsin kinase on visual transduction

The shutoff of the phototransduction cascade in retinal rods requires the inactivation of light-activated rhodopsin. The underlying mechanisms were studied in functionally intact detached rod outer segments by testing the effect of either sangivamycin, an inhibitor of rhodopsin kinase, or phytic acid, an inhibitor of 48K protein binding to phosphorylated rhodopsin, on light responses recorded in whole-cell voltage clamp. The results suggest that isomerized rhodopsin is inactivated fully by multiple phosphorylation and that the binding of 48K protein accelerates recovery by quenching partially phosphorylated rhodopsin. Higher concentrations of sangivamycin cause changes in the light response that cannot be explained by selective inhibition of rhodopsin kinase and suggest that other protein kinases are needed for normal rod function.

Phosphatidylinositol-stimulated phosphorylation of an inhibitory subunit of cGMP phosphodiesterase in vertebrate rod photoreceptors

An inhibitory subunit (P gamma) of cGMP phosphodiesterase from vertebrate rod photoreceptors (frog, toad, and bovine) was phosphorylated by cytosolic protein kinase(s) derived from intact frog rod outer segments. The phosphorylation of frog P gamma was stimulated by phosphatidylinositol but not by cAMP or cGMP. One- and two-dimensional gel electrophoresis revealed that 70-80% of P gamma was phosphorylated with 1 mol of phosphate per frog P gamma under optimal conditions. A peptide that derived from an active domain of bovine P gamma was also phosphorylated. Phosphorylation of frog P gamma was inhibited by addition of the peptide to the reaction mixture. Phosphorylation of frog P gamma was also inhibited by addition of transducin subunits or active (P gamma-less) cGMP phosphodiesterase. Okadaic acid, on the other hand, enhanced P gamma phosphorylation, suggesting the presence of protein phosphatase(s) in the cytosolic fraction. These data suggest another mechanism for the regulation of cGMP phosphodiesterase in vertebrate rod photoreceptors.

Regulation by light of cyclic nucleotide-dependent protein kinases and their substrates in frog rod outer segments

Cyclic nucleotides (both cAMP and cGMP) stimulate the phosphorylation of several proteins of 65-70, 50-52, 21, 13, and 12 kD in rod outer segments (ROS) of the frog retina. Subcellular fractionation showed that phosphopeptides of 67, 21, 13, and 12 kD were soluble and phosphopeptides of 69, 67, 50-52, and 12 kD were membrane associated at physiological ionic strength. Components I and II, 13 and 12 kD, respectively, are the major cyclic nucleotide-dependent phosphoproteins of ROS and have been reported to be phosphorylated in the dark and dephosphorylated in the light. Under unstimulated conditions, phosphorylated Components I and II were found in the soluble fraction. Cyclic nucleotide stimulation of phosphorylation resulted in increased phospho-Components I and II in the soluble fraction, and phospho-Component II on the membrane. Light had no effect on the phosphorylation level of soluble Components I and II, but it caused a depletion within 1 s of the membrane-bound phospho-Component II. A half-maximal decrease in membrane-bound Component II was seen at 5 x 10(5) rhodopsins bleached per outer segment. The cyclic nucleotide-dependent protein kinase(s) were found primarily in the peripheral membrane fraction of ROS proteins. 8-bromo cyclic AMP was two orders of magnitude more effective than 8-bromo cyclic GMP at stimulating Component I and II phosphorylation. An active peptide of the Walsh inhibitor of cAMP-dependent protein kinase [PKI(5-22)amide] blocked the phosphorylation with an IC50 of 10 nM. Photoaffinity labeling studies with 8-N3-cAMP and 8-N3-cGMP revealed the presence of a 52-kD band specifically labeled with 8-N3-cAMP, but no specific 8-N3-cGMP labeling. These data suggest that cyclic nucleotide-dependent protein phosphorylation in ROS occurs via the activation of a cAMP-dependent protein kinase.

Modulation of inositol phospholipid metabolism by polyamines

At low concentrations of Mg2+, incorporation of 32P from [gamma-32P]ATP into phosphatidylinositol 4-phosphate (PIP) and phosphatidylinositol 4,5-bisphosphate (PIP2) in plasma membranes isolated from human polymorphonuclear leucocytes was enhanced 2-4-fold by the polyamines spermidine and spermine. Polyamines had no effects on inositol phospholipid phosphorylation at high concentrations of Mg2+. At 1 mM-Mg2+, [32P]PIP2 synthesis was maximally enhanced by 2 mM-spermine and 5 mM-spermidine, whereas putrescine only slightly enhanced synthesis. Spermine decreased the EC50 (concn. for half-maximal activity) for Mg2+ in [32P]PIP2 synthesis from 5 mM to 0.5 mM. Spermine did not modulate the Km for ATP for [32P]PIP or [32P]PIP2 synthesis. Spermine also decreased the EC50 for PI in [32P]PIP synthesis. In contrast, spermine elevated the apparent Vmax, without affecting the EC50 for PIP, for [32P]PIP2 synthesis. Spermine and spermidine also inhibited the hydrolysis of [32P]PIP2 by phosphomonoesterase activity. Therefore polyamines appear to activate inositol phospholipid kinases by eliminating the requirements for super-physiological concentrations of Mg2+. Polyamine-mediated inhibition of polyphosphoinositide hydrolysis would serve to potentiate further their abilities to promote the accumulation of polyphosphoinositides in biological systems.