Control of the retinal local RAS by the RPE: An interface to systemic RAS activity.

As many other organs, the retina has a local renin-angiotensin-system (RAS). All main elements of the RAS are active in the retina: renin, angiotensinogen, angiotensin-converting enzymes. The functional role of the intraretinal RAS is not fully understood. So far, histological and functional analysis point to a regulation of ganglion cell activity and maybe also of bipolar cell activity, but it is not clear how RAS contributes to retinal signal processing. In contrast to local RAS in other organs, the retinal RAS is clearly separated from the systemic RAS. The angiotensin-2 (AngII)/AngI ratio in the retina is different to that in the plasma. However, it appears that the retinal pigment epithelium (RPE), that forms the outer blood/retina barrier, is a major regulator of the retinal RAS by producing renin. Interestingly, comparable to the kidney, the renin production in the RPE is under control of the angiotensin-2 receptor type-1 (AT1). AT1 localizes to the basolateral membrane of the RPE and faces the blood side of the blood/retina barrier. Increases in systemic AngII reduce renin production in the RPE and therefore decrease the intraretinal RAS activity. The relevance of the local RAS for retinal function remains unclear. Nevertheless, it is of fundamental significance to understand the pathology of systemically induced retinal diseases such as hypertension or diabetes.

Correction: Individual and temporal variability of the retina after chronic bilateral common carotid artery occlusion (BCCAO).

[This corrects the article DOI: 10.1371/journal.pone.0193961.].

Individual and temporal variability of the retina after chronic bilateral common carotid artery occlusion (BCCAO).

Animal models of disease are an indispensable element in our quest to understand pathophysiology and develop novel therapies. Ex vivo studies have severe limitations, in particular their inability to study individual disease progression over time. In this respect, non-invasive in vivo technologies offer multiple advantages. We here used bilateral common carotid artery occlusion (BCCAO) in mice, an established model for ischemic retinopathy, and performed a multimodal in vivo and ex vivo follow-up. We used scanning laser ophthalmoscopy (SLO), ocular coherence tomography (OCT) and electroretinography (ERG) over 6 weeks followed by ex vivo analyses. BCCAO leads to vascular remodeling with thickening of veins starting at 4 weeks, loss of photoreceptor synapses with concomitant reduced b-waves in the ERG and thinning of the retina. Mononuclear phagocytes showed fluctuation of activity over time. There was large inter-individual variation in the severity of neuronal degeneration and cellular inflammatory responses. Ex vivo analysis confirmed these variable features of vascular remodeling, neurodegeneration and inflammation. In summary, we conclude that multimodal follow-up and subgroup analysis of retinal changes in BCCAO further calls into question the use of ex vivo studies with distinct single end-points. We propose that our approach can foster the understanding of retinal disease as well as the clinical translation of emerging therapeutic strategies.