Irina Surgucheva

Guanylyl cyclase activating protein: A calcium-sensitive regulator of phototransduction

Guanylyl cyclase activating protein (GCAP1) has been proposed to act as a calcium-dependent regulator of retinal photoreceptor guanylyl cyclase (GC) activity. Using immunocytochemical and biochemical methods, we show here that GCAP1 is present in rod and cone photoreceptor outer segments where phototransduction occurs. Recombinant and native GCAP1 activate recombinant human retGC (outer segment-specific GC) and endogenous GC(s) in rod outer segment (ROS) membranes at low calcium. In addition, we isolate and clone a retinal homolog, termed GCAP2, that shows 50% identity with GCAP1. Like GCAP1, GCAP2 activates photoreceptor GC in a calcium-dependent manner. Both GCAP1 and GCAP2 presumably act on GCs by a similar mechanism; however, GCAP1 specifically localizes to photoreceptor outer segments, while in these experiments GCAP2 was isolated from extracts of retina but not ROS. These results demonstrate that GCAP1 is an activator of ROS GC, while the finding of a second activator, GCAP2, suggests that a similar mechanism of GC regulation may be present in outer segments, other subcellular compartments of the photoreceptor, or other cell types.

GCAP1(Y99C) mutant is constitutively active in autosomal dominant cone dystrophy

GCAP1 stimulates photoreceptor guanylate cyclase (GC) in bleached vertebrate photoreceptors when [Ca2+]free decreases but is inactivated when cytoplasmic [Ca2+]free increase after dark adaptation. A Y99C mutation in GCAP1 has recently been found to be associated with autosomal dominant cone dystrophy. We show that the GCAP1(Y99C) mutant and native GCAP1 are highly effective in stimulation of photoreceptor GC1. The Ca2+ sensitivity of the mutant GCAP1, however, is markedly altered, causing reduced but persistent stimulation of GC1 under physiological dark conditions. These results are consistent with a model in which enhanced GC activity in dark-adapted cones leads to elevated levels of cytoplasmic cGMP. Alterations in physiological cGMP levels are also associated with other retinal degenerations, including Lebers congenital amaurosis.

Synoretin--A new protein belonging to the synuclein family.

Aoffa-Synuclein, a presynaptic nerve terminal protein, may be an important component of Lewy bodies in Parkinsons disease, dementia with Lewy bodies, and other neurodegenerative diseases. Additionally, recent genetic studies based on linkage analysis and cosegregation of A53T and A30P missense mutations demonstrated that the alpha-synuclein gene may be responsible for the development of at least some cases of familial Parkinsons disease. Despite intense interest in the members of the synuclein family, their function(s) and exact role in the diseases remained unknown. Here we describe a new member of the synuclein family, which we term synoretin, and show that it is expressed in different retinal cells, as well as in the brain, and it may affect the regulation of signal transduction through activation of the Elk1 pathway.

γ-Synuclein: Seeding of α-Synuclein Aggregation and Transmission between Cells

Protein misfolding and aggregation is a ubiquitous phenomenon associated with a wide range of diseases. The synuclein family comprises three small naturally unfolded proteins implicated in neurodegenerative diseases and some forms of cancer. α-Synuclein is a soluble protein that forms toxic inclusions associated with Parkinsons disease and several other synucleinopathies. However, the triggers inducing its conversion into noxious species are elusive. Here we show that another member of the family, γ-synuclein, can be easily oxidized and form annular oligomers that accumulate in cells in the form of deposits. Importantly, oxidized γ-synuclein can initiate α-synuclein aggregation. Two amino acid residues in γ-synuclein, methionine and tyrosine located in neighboring positions (Met(38) and Tyr(39)), are most easily oxidized. Their oxidation plays a key role in the ability of γ-synuclein to aggregate and seed the aggregation of α-synuclein. γ-Synuclein secreted from neuronal cells into conditioned medium in the form of exosomes can be transmitted to glial cells and cause the aggregation of intracellular proteins. Our data suggest that post-translationally modified γ-synuclein possesses prion-like properties and may induce a cascade of events leading to synucleinopathies.