Deletional Analysis of the rod Photoreceptor Cell Peripherin/RDS Carboxy-Terminal Region

The C-terminal region of peripherin/rds contains three predicted α-helical domains. One of these domains, corresponding to amino acids 311-322, form an amphiphilic α-helix previously shown to promote membrane fusion. The present studies were conducted to determine how the additional α-helical regions of the peripherin/rds C-terminus affect complex formation with rom-1, glycosylation, intracellular localization and membrane fusion properties. Bovine peripherin/rds and rom-1 were epitope tagged with an amino-terminal FLAG-tag or amino-terminal hemagglutinin (HA)-tag, respectively, and cloned into the pCI-neo expression vector for transient transfection into COS cells. Similarly, four C-terminal peripherin/rds truncation mutants (Δ1, Δ2, Δ3 and Δ4), corresponding to deletions of -19, -29, -39 and -59 amino acids were designed to disrupt the α-helical domains. Immunofluorescence microscopy and enzymatic digestions demonstrated that full-length peripherin/rds and the four C-terminal deletion mutants were localized to intracellular membranes and were all Endo-H sensitive. Western blotting and immunoprecipitation studies showed that the FLAG-tagged bovine peripherin/rds (full-length) was expressed as a 76 kDa dimer, which associates with HA-tagged rom-1 to form a higher order complex. The deletion mutants were also able to associate with rom-1. However, when analyzed using non-denaturing tricine electrophoresis, full-length peripherin/rds and the Δ1, Δ2 and Δ3 mutants formed homo-oligomeric complexes, while the Δ4 mutant appeared to form only homodimers suggesting a region upstream of amino acid 300 may be involved in C-terminal interactions. Membrane fusion was then evaluated using fluorescence resonance energy transfer (RET) techniques. Intracellular COS cell membranes containing full-length peripherin/rds fused with rod outer segment plasma membrane vesicles. This fusion was inhibited with the addition of a synthetic peptide (PP-5) corresponding to the fusion domain of peripherin/rds. In contrast, fusion was negligible with any of the C-terminal truncation mutants. Collectively, these results suggest that in addition to the fusion domain, other regions of the peripherin/rds C-terminus are required for fusion. Most interesting is the observation that the last 19 amino acids, a region downstream of the fusion peptide that is deleted in the Δ1 mutant, appear to be necessary for fusion. This region corresponds to the epitope for anti-peripherin/rds monoclonal antibody 2B6, which is shown to partially inhibit peripherin/rds mediated membrane fusion. © 2002 Elsevier Science Ltd

Deletional Analysis of the Rod Photoreceptor Cell Peripherin/RDS Carboxy-Terminal Region

The C-terminal region of peripherin/rds contains three predicted α-helical domains. One of these domains, corresponding to amino acids 311–322, form an amphiphilic α-helix previously shown to promote membrane fusion. The present studies were conducted to determine how the additional α-helical regions of the peripherin/rds C-terminus affect complex formation with rom-1, glycosylation, intracellular localization and membrane fusion properties. Bovine peripherin/rds and rom-1 were epitope tagged with an amino-terminal FLAG-tag or amino-terminal hemagglutinin (HA)-tag, respectively, and cloned into the pCI-neo expression vector for transient transfection into COS cells. Similarly, four C-terminal peripherin/rds truncation mutants (Δ1, Δ2, Δ3 and Δ4), corresponding to deletions of −19, −29, −39 and −59 amino acids were designed to disrupt the α-helical domains. Immunofluorescence microscopy and enzymatic digestions demonstrated that full-length peripherin/rds and the four C-terminal deletion mutants were localized to intracellular membranes and were all Endo-H sensitive. Western blotting and immunoprecipitation studies showed that the FLAG-tagged bovine peripherin/rds (full-length) was expressed as a 76 kDa dimer, which associates with HA-tagged rom-1 to form a higher order complex. The deletion mutants were also able to associate with rom-1. However, when analyzed using non-denaturing tricine electrophoresis, full-length peripherin/rds and the Δ1, Δ2 and Δ3 mutants formed homo-oligomeric complexes, while the Δ4 mutant appeared to form only homodimers suggesting a region upstream of amino acid 300 may be involved in C-terminal interactions. Membrane fusion was then evaluated using fluorescence resonance energy transfer (RET) techniques. Intracellular COS cell membranes containing full-length peripherin/rds fused with rod outer segment plasma membrane vesicles. This fusion was inhibited with the addition of a synthetic peptide (PP-5) corresponding to the fusion domain of peripherin/rds. In contrast, fusion was negligible with any of the C-terminal truncation mutants. Collectively, these results suggest that in addition to the fusion domain, other regions of the peripherin/rds C-terminus are required for fusion. Most interesting is the observation that the last 19 amino acids, a region downstream of the fusion peptide that is deleted in the Δ1 mutant, appear to be necessary for fusion. This region corresponds to the epitope for anti-peripherin/ rds monoclonal antibody 2B6, which is shown to partially inhibit peripherin/rds mediated membrane fusion

ROM-1 Potentiates Photoreceptor Specific Membrane Fusion Processes

Photoreceptor outer segment (OS) renewal requires a series of tightly regulated membrane fusion events which are mediated by a fusion complex containing protein and lipid components. The best characterized of these components, is a unique photoreceptor specific tetraspanin, peripherin/rds (P/rds, a.k.a., peripherin-2, Rds and Prph). In these studies we investigated the role of peripherin\u27s non-glycosylated homolog, ROM-1, in OS fusion using a COS cell heterologous expression system and a well characterized cell free fusion assay system. Membranes isolated from COS-7 cells transfected with either FLAG-tagged P/rds or HA-tagged ROM-1 or both proteins were assayed for their ability to merge with fluorescently labeled OS plasma membrane (PM). Such membrane merger is one measure of membrane fusogenicity. The highest percent fusion was observed when the proteins were co-expressed. Furthermore detailed analysis of the fusion kinetics between fluorescently labeled PM and proteo-liposomes containing either, pure P/rds, pure ROM-1 or the ROM-1-P/rds complex clearly demonstrated that optimal fusion requires an ROM-1/P/rds complex. Proteo-liposomes composed of ROM-1 alone were not fusogenic. Peptide competition studies suggest that optimization of fusion may be due to the formation of a fusion competent peripherin/rds C-terminus in the presence of ROM-1. These studies provide further support for the hypothesis that a P/rds dependent membrane fusion complex is involved in photoreceptor renewal processes. © 2006 Elsevier Ltd. All rights reserved

ROM-1 Potentiates Photoreceptor Specific Membrane Fusion Processes

Photoreceptor outer segment (OS) renewal requires a series of tightly regulated membrane fusion events which are mediated by a fusion complex containing protein and lipid components. The best characterized of these components, is a unique photoreceptor specific tetraspanin, peripherin/rds (P/rds, a.k.a., peripherin-2, Rds and Prph). In these studies we investigated the role of peripherin’s non-glycosylated homolog, ROM-1, in OS fusion using a COS cell heterologous expression system and a well characterized cell free fusion assay system. Membranes isolated from COS-7 cells transfected with either FLAG-tagged P/rds or HA-tagged ROM-1 or both proteins were assayed for their ability to merge with fluorescently labeled OS plasma membrane (PM). Such membrane merger is one measure of membrane fusogenicity. The highest percent fusion was observed when the proteins were co-expressed. Furthermore detailed analysis of the fusion kinetics between fluorescently labeled PM and proteo-liposomes containing either, pure P/rds, pure ROM-1 or the ROM-1-P/rds complex clearly demonstrated that optimal fusion requires an ROM-P/rds1 complex. Proteo-liposomes composed of ROM-1 alone were not fusogenic. Peptide competition studies suggest that optimization of fusion may be due to the formation of a fusion competent peripherin/rds C-terminus in the presence of ROM-1. These studies provide further support for the hypothesis that a P/rds dependent membrane fusion complex is involved in photoreceptor renewal processes

Healing, Livelihood, Frozen Lakes, Direction, Mutability: Water in Poetry

Water in Poetry: Five Poets Explore Water Images and References in their Work. Each of the five poets will read and discuss the role of water in specific poems they have written. Dr. Mary E. Martin will focus on the healing associations of water in her poems, the inherent calming of being near and in water as well as the uncertain journeys to discover bodies of water. She also writes about the disaster of a flood from the perspective of the water, written shortly after Hurricane Katrina. For almost twenty years, Dr. Jane Smith has been writing a series of poems from the perspective of a Nantucket woman whose husband is the captain of a whaling ship; the poems, often in response to excerpts from his letters, see the ocean as potential as livelihood, but also as a barrier and ongoing threat. Susan Ludvigson’s poems reflect her having grown up in Wisconsin with lakes and rivers that attracted her. She recounts the transforming experience of her first visit to see the lilies of Landsford Canal. Her home town, Rice Lake—named for the wild rice that used to grow in the lake—has many associations for her that are captured in her poems. The lake itself is large with many islands that hole many adventures, such as driving cars out over the frozen lake in the winter, swimming in the summers, including the dangerous swimming on horseback during the warm weather. Evelyne Weeks also grew up around water. Her poems carve a large exploration of water as noted in her quote, “The river gives direction to the road…and the world.” Her poems about water invoke meditation and memory as well as the real effects of erosion. As a lover of the sounds of words, Alex Muller looks for new music as much in the water as anywhere else. His motet poems, in particular, evoke the structure of the ripple; with movable lines, these poems construct an intricate polyphony of concentric voices, which slip into each other and echo simultaneously, moving toward the mutability and fluidity of language