[Eph family receptors as therapeutic targets].

Anti-angiogenic therapy is currently a commonly accepted and rapidly developing approach in oncology and other pathologies linked to aberrant neovascularization. Discovery and validation of additional molecular targets in angiogenesis is needed due to the limitations of the existing clinical therapeutics inhibiting activity of vascular endothelial growth factor (VEGF) and its receptors. A brief review of normal and pathological biological functions of the Eph family of receptor tyrosine kinases and their ephrin ligands is presented, and the approaches to developing therapeutics with anti- and pro-angiogenic and anti-tumor activity based on selective molecular modulation of Eph-ephrin signaling pairs are discussed. Functional roles of Eph-kinases and ephrins in such mechanisms of cancerogenesis as cell proliferation and invasion are also addressed.

[Classification of self-organizing peptides].

Amino acid sequences of known natural and synthetic self-assembling peptides were searched and analyzed for their characteristic patterns. The attempted formal numerical description of the repeating motifs, which have been revealed, resulted in building of general classification system embracing core-sequences of the peptides capable of nanostructure formation. Advantages and potency of the proposed rational classification were demonstrated via its comparison with the output from the earlier system described by the others.

Myosin VIIa participates in opsin transport through the photoreceptor cilium.

Two types of Usher syndrome, a blindness-deafness disorder, result from mutations in the myosin VIIa gene. As for most other unconventional myosins, little is known about the function or functions of myosin VIIa. Here, we studied the photoreceptor cells of mice with mutant myosin VIIa by electron immunomicroscopy and microscopic autoradiography. We found evidence that myosin VIIa functions in the connecting cilium of each photoreceptor cell and participates in the transport of opsin through this structure. These findings provide the first direct evidence that opsin travels along the connecting cilium en route to the outer segment. They demonstrate that a myosin may function in a cilium and suggest that abnormal opsin transport might contribute to blindness in Usher syndrome.

Myosin VIIa as a common component of cilia and microvilli.

The distribution of myosin VIIa, which is defective or absent in Usher syndrome 1B, was studied in a variety of tissues by immunomicroscopy. The primary aim was to determine whether this putative actin-based mechanoenzyme is a common component of cilia. Previously, it has been proposed that defective ciliary function might be the basis of some forms of Usher syndrome. Myosin VIIa was detected in cilia from cochlear hair cells, olfactory neurons, kidney distal tubules, and lung bronchi. It was also found to cofractionate with the axonemal fraction of retinal photoreceptor cells. Immunolabeling appeared most concentrated in the periphery of the transition zone of the cilia. This general presence of a myosin in cilia is surprising, given that cilia are dominated by microtubules, and not actin filaments. In addition to cilia, myosin VIIa was also found in actin-rich microvilli of different types of cell. We conclude that myosin VIIa is a common component of cilia and microvilli.

Regulation of the phosphorylation state of rhodopsin by dopamine.

G protein-coupled receptors (GPCRs) are regulated by kinases and phosphatases that control their phosphorylation state. Here, the possibility that the state of GPCR phosphorylation could be affected by paracrine input was explored. We show that dopamine increased the rate of dephosphorylation of rhodopsin, the light receptor, in intact frog retinas. Further, we found that rod outer segments from dopamine-treated retinas contained increased rhodopsin phosphatase activity, indicating that this effect of dopamine on rhodopsin was mediated by stimulation of rhodopsin phosphatase. Dopamine is a ubiquitous neuromodulator and, in the retina, is released from the inner cell layers. Thus, our results identify a pathway for feedback regulation of rhodopsin from the inner retina and illustrate the involvement of dopamine in paracrine regulation of the sensitivity of a GPCR.

Contribution of protein kinase C to the phosphorylation of rhodopsin in intact retinas.

Similar to other G protein-coupled receptors, the visual receptor, rhodopsin, is phosphorylated by both a substrate-regulated kinase, rhodopsin kinase, and a second messenger-regulated kinase, protein kinase C. In the present study, the extent of involvement of protein kinase C in the light-dependent phosphorylation of rhodopsin in intact retinas was assessed using a specific activator (phorbol ester) and specific inhibitor (calphostin C) of protein kinase C. Kinetic analysis of rhodopsin phosphorylation following different illumination conditions revealed that hyperactivation of protein kinase C with phorbol ester resulted in a relative increase in rhodopsin phosphorylation that peaked 10-15 min after the onset of illumination. Following this period, the rate of rhodopsin dephosphorylation was increased in the phorbol ester-treated retinas, so that by about 30 min the amount of phosphorylation was similar to that in control retinas. Treatment of retinas with calphostin C, a potent regulatory domain-directed inhibitor of protein kinase C, resulted in an approximately 50% reduction in the light-dependent phosphorylation of rhodopsin. This inhibitor had no effect on the activity of rhodopsin kinase in vitro. Last, we show that frog rhodopsin is phosphorylated in vitro by protein kinase C from frog rod outer segments, indicating that this kinase could directly modulate rhodopsin in vivo. In conclusion, the present results reveal that the kinetics of rhodopsin phosphorylation/dephosphorylation differ markedly, depending on whether protein kinase C or rhodopsin kinase activity dominates, and that, under the conditions studied, protein kinase C contributes to approximately half of the phosphorylation of rhodopsin in intact frog retinas.

Myosin VIIa, the product of the Usher 1B syndrome gene, is concentrated in the connecting cilia of photoreceptor cells.

Usher syndrome is the most common form of combined deafness and blindness. The gene that is defective in Usher syndrome 1B (USH1B) encodes for an unconventional myosin, myosin VIIa. To understand the cellular function of myosin VIIa and why defects in it lead to USH1B, it is essential to determine the precise cellular and subcellular localization of the protein. We investigated the distribution of myosin VIIa in human and rodent photoreceptor cells and retinal pigment epithelium (RPE), primarily by immunoelectron microscopy, using antibodies generated against two different domains of the protein. In both human and rodent retinae, myosin VIIa was detected in the apical processes of the RPE and in the cilium of rod and cone photoreceptor cells. Immunogold label was most concentrated in the connecting cilium. Here, myosin VIIa appeared to be distributed outside the ring of doublet microtubules near the ciliary plasma membrane. These observations indicate that a major role of myosin VIIa in the retina is in the photoreceptor cilium, perhaps in such a function as trafficking newly synthesized phototransductive membrane or maintaining the diffusion barrier between the inner and outer segments. Our results support the notion that defective ciliary function is the underlying cellular abnormality that leads to cellular degeneration in Usher syndrome.

Protein kinase C in rod outer segments: effects of phosphorylation of the phosphodiesterase inhibitory subunit.

The inhibitory subunit (PDE gamma) of the cGMP phosphodiesterase (PDE alpha beta gamma 2) in rod outer segments (ROS) realizes its regulatory role in phototransduction by inhibition of PDE alpha beta catalytic activity. The photoreceptor G-protein, transducin, serves as a transducer from the receptor (rhodopsin) to the effector (PDE) and eliminates the inhibitory effect of PDE gamma by direct interaction with PDE gamma. Our previous study [Udovichenko, Cunnick, Gonzalez and Takemoto (1994) J: Biol. Chem. 269, 9850-9856] has shown that PDE gamma is a substrate for protein kinase C (PKC) from ROS and that phosphorylation by PKC increases the ability of PDE gamma to inhibit PDE alpha beta catalytic activity. Here we report that transducin is less effective in activation of PDE alpha beta (gamma p)2 (a complex of PDE alpha beta with phosphorylated PDE gamma, PDE gamma p) than PDE alpha beta gamma 2. PDE gamma p also increases the rate constant of GTP hydrolysis of transducin (from 0.16 S-1 for non-phosphorylated PDE gamma to 0.21 s-1 for PDE gamma p). These data suggest that phosphorylation of the inhibitory subunit of PDE by PKC may regulate the visual transduction cascade by decreasing the photoresponse.

Acridine orange differential staining of total DNA and RNA in normal and galactosemic lens epithelial cells in culture using flow cytometry.

The lens epithelial cells are a primary site of involvement in galactosemia. Changes in their size, shape and proliferative capacity have been observed upon exposure to high galactose. In this report, changes in the cell cycle pattern of normal and galactosemic lens epithelial cells were examined by use of flow cytometry. Both changes in DNA and RNA were observed using the fluorochrome, acridine orange. Under the appropriate conditions acridine orange can be used to differentiate double-stranded DNA from single-stranded RNA. Using this approach, the DNA and RNA of normal and galactosemic (1, 4, or 7 days) lens epithelial cells can be compared. The results indicate that lens epithelial cells, when exposed to 40 mM galactose media or 30 mM glucose for 7 days, are induced to enter mitosis. Mannitol did not mimic these results. Changes in the cell cycle pattern were not observed when the cells were treated for 1 or 4 days. Although higher numbers of cells in mitosis were observed after 7 days exposure to 40 mM galactose, a correlation between proliferation, as measured by 3H-thymidine uptake, and mitosis was not possible. Apoptosis was evaluated as a possible explanation for these results. The changes in the DNA staining pattern could be use to monitor lens epithelial cells during galactosemia.

Functional effect of phosphorylation of the photoreceptor phosphodiesterase inhibitory subunit by protein kinase C.

In rod outer segments the light activation of cGMP phosphodiesterase (PDE alpha beta gamma 2) is accomplished by removal of the gamma inhibitory subunit (PDE gamma) from the PDE alpha beta catalytic subunits. A light activation of the inositol signaling pathway also occurs, but there is little information linking these two signal transduction pathways. Here we report that protein kinase C (PKC) purified from bovine rod outer segment phosphorylates the bovine PDE gamma with incorporation of 0.9 +/- 0.1 mol of phosphate/mol of PDE gamma. Phosphorylation of PDE gamma increases its ability to inhibit PDE alpha beta catalytic activity (trypsin-activated PDE, tPDE) with an IC50 for phosphorylated PDE gamma of 26 +/- 4 pM and an IC50 of 60 +/- 5 pM for unphosphorylated PDE gamma. Inhibition of tPDE by PDE gamma is characterized by two values of Kd, Kd1 = 34 pM and Kd2 = 760 pM. Phosphorylation of PDE gamma by PKC eliminates the functional heterogeneity of the PDE gamma population resulting in a single value of Kd = 23 pM. Free PDE gamma (without PDE alpha beta catalytic subunits) is a better substrate for PKC than PDE gamma in a complex with PDE alpha beta. Phosphorylation of free PDE gamma by PKC is characterized by a value of Vmax = 1,550 +/- 148 units/mg (Km = 21.0 +/- 1.9 microM). In contrast, phosphorylation of PDE gamma in PDE alpha beta gamma 2 complex has two values of Vmax, Vmax1 = 0.3 +/- 0.1 units/mg of PDE gamma (Km1 = 0.4 +/- 0.2 microM) and Vmax2 = 0.7 +/- 0.2 units/mg of PDE gamma (Km2 = 4.6 +/- 0.9 microM). ROS PKC phosphorylates Thr35 in PDE gamma. We have previously reported (Morrison, D. F., Rider, M. A., and Takemoto, D. J. (1987) FEBS Lett. 222, 266-270; Lipkin, V. M., Udovichenko, I. P., Bodarenko, V. A., Yurovskaya, A. A., Telnykh, E. V., and Skiba, N. P. (1990) Biomed. Sci. (Lond.) 1, 305-308) that the central fragment of PDE gamma (24-45) is responsible for binding to PDE catalytic subunits. The new data suggests that this region of PDE gamma also includes the site for phosphorylation by PKC and that phosphorylation increases the ability of PDE gamma to inhibit PDE catalytic activity. This altered regulation of visual transduction may play a role in desensitization or light adaptation.

[Localization of segments in the Gs protein interacting with adenylate cyclase using a Gs/G0-chimera]. / Lokalizatsiia v belke uchastkov vzaimodeistviia s adenilattsiklazoi s pomoshch'iu konstruirovaniia Gs/G0-khimernykh form.

cDNAs coding for three types of alpha-subunits of GTP-binding proteins Gs and G0 (a short form of alpha s with Asp-Ser in positions 71 and 72, a long form of alpha s with the insertion of 16 amino acid residues instead of Asp-Ser (71-72)--both from bovine brain, and alpha 0 from bovine cerebellum as well as some chimeric alpha s/alpha 0 genes were cloned into a modified pGEM-2 plasmid vector under the control of the SP6 promoter. All the genes were in vitro transcribed and translated, and some functional properties of the resulting proteins were determined, such as adenylyl cyclase activation, ADP-ribosylation with pertussis toxin, limited nucleotide-dependent trypsin proteolysis. Parts of the alpha s polypeptide chain necessary for the activation of adenylyl cyclase were mapped. The alpha s domain interacting with adenylyl cyclase is formed by the alpha s polypeptide chain fragments 235-294 and 337-356 (numbering as of the alpha s long form).

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.

Site-directed mutagenesis of the inhibitory subunit of retinal rod cyclic GMP phosphodiesterase.

In order to study the role of individual amino acids in the function of the inhibitory subunit, gamma, of retinal rod phosphodiesterase (PDE), the following substitutions were made: Arg-24----Gly, Lys-29----Thr, Arg-33----Gly, Lys-39----Thr, Lys-41----Thr, Lys-44----Thr, Lys-45----Thr, Glu-77----Gly, and Tyr-84----Ala. Deletion of seven C-terminal amino acids (delta 81-87) was also investigated, and the activity of all the mutant PDE gamma forms determined. Expression of the mutant PDE gamma genes was achieved by sequential in vitro transcription and translation. The results suggest that PDE gamma fragment 24-33, which is rich in basic amino acids, and in particular Arg-24, is essential for PDE gamma binding both to the catalytic subunits (alpha and beta) of phosphodiesterase (PDE alpha beta) and to the alpha-subunit of transducin (T alpha), the GTP-binding protein found in retinal rods that activates cyclic GMP PDE. In contrast, the C-terminal fragment of PDE gamma participates in phosphodiesterase inhibition and in binding to T alpha, but not in binding to PDE alpha beta.

[Isolation of a homogeneous functionally active beta-adrenergic receptor from bovine cerebellum using lauroyl sucrose. Effect of trypsin on receptor activity]. / Vydelenie gomogennogo funktional'no aktivnogo beta- adrenoretseptora iz mozzhechka byka s ispol'zovaniem lauroilsakharozy. Vliianie tripsina na aktivnost'' retseptora.

The synthesis of lauroyl sucrose capable of solubilizing 100% of beta-adrenergic receptors from bovine cerebellum membranes has been carried out. The preparative procedure for isolation of homogeneous beta-adrenergic receptors including affinity chromatography on the novel support, oxprenolol-Sepharose, is described. According to SDS-PAAG electrophoresis data, the Mr value for the beta-adrenergic receptor is 61 kD. The purified beta-adrenergic receptor can interact with the purified GTP-binding regulatory protein of adenylate cyclase (Gs) after their reconstitution into liposomes. Trypsin treatment of the purified receptor does not interfere with its functional properties, nor does it change the hydrodynamic parameters under non-denaturing conditions despite the fact that the polypeptide chain of the receptor is cleaved by trypsin.