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Peripherin-2 and Rom-1 have opposing effects on rod outer segment targeting of retinitis pigmentosa-linked peripherin-2 mutants

  • Scientific Reports 7, Article number: 2321 (2017)
  • doi:10.1038/s41598-017-02514-5
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Mutations in the photoreceptor outer segment (OS) specific peripherin-2 lead to autosomal dominant retinitis pigmentosa (adRP). By contrast, mutations in the peripherin-2 homolog Rom-1 cause digenic RP in combination with certain heterozygous mutations in peripherin-2. The mechanisms underlying the differential role of peripherin-2 and Rom-1 in RP pathophysiology remained elusive so far. Here, focusing on two adRP-linked peripherin-2 mutants, P210L and C214S, we analyzed the binding characteristics, protein assembly, and rod OS targeting of wild type (perWT), mutant peripherin-2 (perMT), or Rom-1 complexes, which can be formed in patients heterozygous for peripherin-2 mutations. Both mutants are misfolded and lead to decreased binding to perWT and Rom-1. Furthermore, both mutants are preferentially forming non-covalent perMT-perMT, perWT-perMT, and Rom-1-perMT dimers. However, only perWT-perMT, but not perMT-perMT or Rom-1-perMT complexes could be targeted to murine rod OS. Our study provides first evidence that non-covalent perWT-perMT dimers can be targeted to rod OS. Finally, our study unravels unexpected opposing roles of perWT and Rom-1 in rod OS targeting of adRP-linked peripherin-2 mutants and suggests a new treatment strategy for the affected individuals.


The tetraspanin peripherin-2 is exclusively expressed in outer segments (OS), specific light detecting compartments of photoreceptors. Peripherin-2 forms homo- and heteromeric protein complexes in OS. The core homomeric peripherin-2 unit is the non-covalent tetramer, which can also assemble into covalently linked octamers and higher-order oligomers1,2,3. These homomeric peripherin-2 complexes are crucial for proper OS morphology and architecture4. Peripherin-2 also forms heteromeric complexes with its homolog Rom-1, however, the functional importance of these complexes remained unclear2, 5, 6. Autosomal dominant retinitis pigmentosa (adRP) is the most frequent hereditary retinal disorder characterized by progressive loss of vision due to rod photoreceptor degeneration. Mutations in the peripherin-2 gene (PRPH2) are among the most common causes for adRP7, 8. Interestingly, despite the high sequence identity (approx. 35%) and the high structural conservation of Rom-1 and peripherin-22, 9, mutations in Rom-1 are not clearly linked to monogenic adRP. Some homozygous Rom-1 mutations, however, cause digenic RP in combination with a heterozygous mutation in PRPH2, suggesting that Rom-1 could function as genetic modifier that shapes the disease progression10, 11. Nevertheless, the molecular mechanisms underlying the postulated modifier function of Rom-1 have not been determined yet12. The majority of adRP-linked peripherin-2 mutants are located within the large loop domain connecting the transmembrane domain 3 and 4, also known as EC2 or D2 loop domain13, 14. Some adRP-linked peripherin-2 mutants in EC2 were shown to influence the subunit assembly15, 16. In this context, it was postulated that peripherin-2 tetramerization is crucial for rod OS targeting. However, this conclusion was drawn from experiments addressing pure homotypic perMT complexes16. Nevertheless, due to the autosomal dominant fashion of PRPH2-linked adRP, different combinations of peripherin-2 protein complexes (perWT-perWT, perMT-perMT, perWT-perMT, Rom-1-perWT, and Rom-1-perMT) can be formed in heterozygous patients carrying wild type and mutant PRPH2 alleles. In addition, each of these complexes can exist in different equilibria of mono-, di- and tetramers and higher-order oligomers, respectively. This high complexity precluded a more accurate investigation of how subunit assembly might influence the rod OS targeting of the single peripherin-2 protein complexes.

In previous studies, we provided a proof-of-principle for FRET-based quantitative analysis of protein-protein interactions in isolated rod and cone OS17,18,19. Recently, we also reported that the two adRP-linked mutations (perP210L and perC214S) located within the highly conserved tetraspanin PxxCC motif are mislocalized to rod inner segments (IS) when expressed in wild type mice using adeno-associated virus (AAV) vectors20. Other studies demonstrated that perC214S affects homotypic mutant interactions and the heteromerization with Rom-121, 22. Despite these findings, little is known about the specific binding characteristics of this and other peripherin-2 mutants to perWT or Rom-1 in their native environment (e.g. rod OS). Moreover, the precise contribution of perWT and Rom-1 on binding properties, subunit assembly, and rod OS targeting of the respective perWT-perMT and Rom-1-perMT complexes is not clear. Nevertheless, such information is crucial to understand the full complexity of PRPH2-linked adRP and for developing successful treatments for the disease. Here, combining different methods we provide novel insights into the binding characteristics, subunit assembly, and rod OS targeting of perP210L and perC214S mutants. We show that perWT and Rom-1 form heterodimers with both peripherin-2 mutants. However, only perWT-perMT but not Rom1-perMT complexes could be targeted to rod OS suggesting unexpected opposing roles of peripherin-2 and Rom-1 in rod OS targeting of adRP-linked peripherin-2 mutants.


perC214S and perP210L show reduced binding to perWT and Rom-1

In our recent work, we demonstrated that, in contrast to perC214S and perP210L, eight additional disease-linked peripherin-2 D2 loop domain mutants did not affect rod OS targeting20 (Fig. 1a). One possible mechanism, which might explain the mislocalization of perC214S and perP210L in rod photoreceptors, is that these mutants might affect binding to perWT and/or to Rom-1. To examine this possibility, we performed co-immunoprecipitation (co-IP) experiments from HEK293T cells co-transfected with the respective peripherin-2 mutants and perWT or Rom-1, respectively. Only perC214S and perP210L attenuated the binding to perWT, while binding of other peripherin-2 mutants to perWT remained unaffected (Fig. 1b). Very similar results were obtained in co-IPs addressing the binding of the single peripherin-2 mutants to Rom-1 (Fig. 1c).

Figure 1
Figure 1

Effects of peripherin-2 mutants on protein-protein interactions and D2 loop folding. (a) left, Topology of peripherin-2. The dashed rectangle highlights the distal part of the D2 loop. Right, Schematical enlargement of the distal D2 loop showing the hitherto identified disease-linked peripherin-2 mutations in this region (highlighted in green). The position of mutants analyzed in (b–d) are marked by red arrows (for perP210L and perC214S) or by black arrowheads in case of the remaining mutants. The calculated protease cleavage sites from d are indicated by a white (corresponding to the 42.5 kDa band) or black (corresponding to the 52.4 kDa band) pacman. The position of the peptide (aa 201–220) used for the competition assay shown in (e) (pept201–220) is highlighted by the gray line. (b–c) Co-Immunoprecipitations (co-IPs) from membrane preparations of HEK293T cells transiently transfected with the respective N-terminally citrine-tagged mutants and C-terminally myc-tagged perWT (perWT-myc) (b) or Rom-1 (Rom-1-myc) (c) using the myc-specific antibody (anti-myc). The single mutants were detected using the GFP-antibody, which also specifically recognizes citrine. IB, immunoblotting. (d) Protease cleavage experiments on membrane preparations from HEK293T cells transiently transfected with the single citrine-tagged peripherin-2 mutants as indicated. The molecular weight of the single bands (arrows) was calculated from five independent western blot experiments. (e) Co-IPs from membrane preparations of HEK293T cells co-transfected with myc- and citrine-tagged perWT in presence (left lane, 10 mM) or absence of the peptide.

P210 and C214 are crucial for the proper folding of the distal D2 loop

The proline at position 210 (P210) and the cysteine at position 214 (C214) are part of the highly conserved tetraspanin PxxCC motif, whose function has not been clearly determined yet. The reduced binding of perC214S and perP210L to perWT suggests that these residues could either i) be crucial for proper folding of peripherin-2 or ii) represent the protein-protein interaction interface. Using CD spectroscopy, a recent study suggested that C214S impedes protein folding by increasing the percentage of ß-sheets concomitant with a decrease in helices in the D2 loop23. However, it remained unclear which part(s) of the D2 loop is (are) affected by this mutation. To address this issue more directly, we established a protease digestion assay on membrane preparations from HEK293T cells expressing citrine-tagged WT and mutant peripherin-2 transgenes. For this purpose, we took advantage of the fact that endogenously expressed proteases are regularly present in these preparations. In addition, membrane preparations are expected to retain the native protein structure as they are isolated without detergents or reducing agents. Protein cleavage occurs on the exposed domain regions, which are accessible for endogenous proteases. Accordingly, improper protein folding could lead to masking of existing or to an exposure of hidden protease cleavage sites. Using a GFP antibody that recognizes the N-terminal citrine tag of our peripherin-2 constructs, we could detect three peripherin-2 bands at 61.5 kDa, 52.4 kDa and 42.5 kDa (Fig. 1d). The calculated size of full-length citrine-tagged peripherin-2 is 66.5 kDa, however, even in presence of protease inhibitors, the full-length perWT was always detected as a 61.5 kDa band. By contrast, the 52.4 kDa and 42.5 kDa could only be detected in the protease cleavage assay in the absence of protease inhibitors and upon incubation of the samples at 37 °C. Using the 61.5 kDa band as reference, we calculated the cleavage sites for the 42.5 kDa and for the 52.4 kDa band. The cleavage site for the 42.5 kDa band corresponds to the peripherin-2 region around the highly conserved tetraspanin CCG motif (Fig. 1a). This band was also present in all peripherin-2 mutants suggesting proper folding at this part of the protein. By contrast, the 52.4 kDa band was completely absent for perC214S and perP210L, whereas other mutations did not show any considerable differences to perWT. The protease cleavage site for the 52.4 kDa band is calculated to be located within the distal part of the D2 loop domain next to the transmembrane domain 4 (Fig. 1a). Hence, these results suggest that perC214S and perP210L lead to a structural rearrangement of the distal part of the D2 loop domain.

A recent study suggested that peripherin-2 residues 165–182 are crucial for homomeric interactions24. However, it remained unclear whether the perC214S and perP210L residues or flanking regions might also contribute to this type of interactions. To test this possibility, we performed a peptide competition assay using a peptide corresponding to the residues 201–220 of native human peripherin-2. Provided that the positions P210 and C214 participate in peripherin-2 homomerization, this peptide should compete with the binding and, hence, result in a reduction of homomeric protein-protein interactions. However, in subsequent co-IP experiments even in the presence of a very high peptide concentration (10 mM), we could not detect any decrease in peripherin-2 binding compared to the peptide-free approach (Fig. 1e). This suggests that this region is not directly involved in homomeric peripherin-2 protein-protein interactions.

Quantification of perWT, perMT, and Rom-1 protein-protein interactions in HEK293T cells using FRET

Recently, we reported that three cube FRET is suitable for quantification of homomeric and heteromeric interactions of different photoreceptor specific proteins including peripherin-2. In particular, it has been demonstrated that FRET can be used to calculate the relative binding affinities of these proteins in HEK293T cells17. Consequently, using this approach we examined the binding properties of the different homo- and heteromeric perWT, perMT, and Rom-1 protein complexes. Binding curves can be calculated if the relative expression of the FRET fluorophores (given as molar ratio, MR) varies between the single FRET measurements. By plotting the FRET efficiency (EA) values against the corresponding cerulean/citrine MR, we observed a sufficient variability of the FRET fluorophore expression for each combination. The maximal FRET efficiency (EAmax) was calculated from the binding curve for saturable binding as described previously17 and is proportional to the binding strength of the respective protein complex in the equilibrium. Analysis of EAmax for the different perWT and perMT combinations allowed us to draw several important conclusions. First, robust and unusually high EAmax values could be observed for the perWT only FRET pair (34.2%, Fig. 2a and Supplementary Table 1). These values are close to the highest theoretically possible 40% FRET efficiency for proteins tagged with bulky fluorophores like citrine or cerulean and highlight the strength of protein-protein interactions in homomeric peripherin-2 complexes. Second, EAmax was only slightly decreased for the perP210L only (30.7%) and perC214S only (26.47%) FRET pairs when compared to perWT only (Fig. 2b,c and Supplementary Table 1), suggesting that mutants are still largely capable of self-interacting. By contrast, both, perWT-perP210L (9.44%) and the perWT-perC214S (8.58%) combinations, led to a robust decrease in EAmax (Fig. 2d,e and Supplementary Table 1). Next, we also determined the EAmax values for Rom-1 co-expressed with each, perWT and perMT. When compared to perWT only, EAmax for the Rom-1-perWT interaction was noticeably lower (15.64%) indicating that heteromeric Rom-1-perWT complexes bind less tight than their homomeric perWT only counterparts (Fig. 2f and Supplementary Table 1). Second, both, Rom-1-perP210L and Rom-1-perC214S combinations, led to reduced EAmax values when compared to the Rom-1-perWT interaction (6.58% and 6.32%, respectively, Fig. 2g,h and Supplementary Table 1). Finally, we also calculated the percentage of EAmax reduction for both peripherin-2 mutants relative to perWT only and to the perWT-Rom-1 FRET pair. When compared to perWT only, the EAmax values were reduced to 28% for the perWT-perP210L and to 25% for the perWT-perC214S FRET pair, respectively. By contrast, relative to the Rom-1-perWT FRET pair, the EAmax values were reduced to 42% for the Rom-1-perP210L and to 40% for the Rom-1-perC214S combination, respectively (Supplementary Table 1). This suggests that binding of both peripherin-2 mutants to perWT is more strongly affected than binding to Rom-1.

Figure 2
Figure 2

Quantification of homo- and heteromeric perWT, perMT, and Rom-1 protein-protein interactions using FRET. (a–h) FRET experiments from living HEK293T cells transiently co-transfected with the respective citrine- (citr) or cerulean (cer)-tagged peripherin-2 or Rom-1 constructs as indicated. To obtain the binding curves, FRET efficiency (EA) was plotted against the cerulean/citrine molar ratio (cer/citr MR). The dots represent mean values of 1–7 single FRET measurements ± SEM. EAmax, maximal FRET efficiency. The single EAmax, values and the numbers of independent measurements (n) for each combination are summarized in Supplementary Table 1.

Taken together, our FRET results indicate that, although with reduced efficiencies, both mutants in principle retain their ability to self-interact and to form complexes with perWT or with Rom-1.

Subunit assembly of homo- and heteromeric perWT, perMT, and Rom-1 complexes

Sucrose density gradient centrifugation (SDGC) allows for a separation of different covalently or non-covalently linked protein complexes across a sucrose gradient according to their specific molecular weight. Using SDGC, previous studies analyzed the impact of peripherin-2 mutants including perC214S on homotypic perMT-perMT or heterotypic Rom-1-perMT interactions on subunit assembly16, 21, 22, 25. To examine the complexes which can be formed in heterozygous patients more systematically, we performed a set of sedimentation velocity experiments of differentially tagged perWT, perMT, and Rom-1 combinations (perWT only, perP210L only, perC214S only, perWT-perP210L, perWT-perC214S, Rom-1-perWT, Rom-1-perP210L, and Rom-1-perC214S) transiently expressed in HEK293T cells. In line with previous work, we found the perWT complexes only in sucrose gradient fractions containing the non-covalent tetramers as well as in fractions containing the disulfide-linked octamers under non-reducing conditions (Fig. 3a). By contrast, when expressed alone, perP210L was primarily detected as monomer, non-covalent dimer, and aggregates, but some complexes were also found as disulfide-linked tetramers and octamers (Fig. 3b). Similar to perP210L, perC214S was predominantly detected in monomer, non-covalent dimer, and aggregate fractions when expressed alone (Fig. 3c). In presence of perWT, perP210L was primarily detected in the fractions containing monomers and non-covalent dimers, and only weak signal was found in the non-covalent tetramer fractions (Fig. 3d). Moreover, in this combination the SDGC pattern for perWT slightly differed from the perWT only situation. The most striking difference was that a substantial perWT signal could now also be seen in the non-covalent dimer fractions (Fig. 3d). Given that no considerable amounts of perWT were detectable in this fraction for perWT only (cf. Fig. 3a), we concluded that the non-covalent dimer fraction most likely consists of perWT-perP210L dimers. When co-expressed with perC214S, perWT reasonably decreased the percentage of perC214S aggregates (Fig. 3e). Moreover, in presence of perWT the majority of perC214S was found in the non-covalent dimer fractions and as perC214S monomers. However, in contrast to the perWT-perP210L combination, a strong perC214S signal could also be detected in the non-covalent tetramer fractions. Finally, in the perWT-perC214S combination, we could also robustly detect perWT in the non-covalent dimer fractions (Fig. 3e). Taking into account that perWT alone does not homodimerize (cf. Fig. 3a) and that perC214S alone does not form non-covalent tetramers (cf. Fig. 3c), we concluded that the non-covalent dimer and tetramer fractions in the perWT-perC214S combination most likely contain perWT-perC214S dimers and tetramers, respectively (Fig. 3e).

Figure 3
Figure 3

SDGC of different perWT, perMT, and Rom-1 combinations. Shown are representative immunoblots (left panel) and the corresponding statistics (right panel) for each C-terminally myc- or flag-tagged combination as indicated. Each blot consists of 11 fractions collected across the 5–20% sucrose gradient. All fractions were normalized to the DNA standard mixed to the protein solution prior to SDGC as described in the methods section. The single peripherin-2 or Rom-1 complexes can be found in following fractions: octamers: fraction 3–6; tetramers: fraction 6–8; dimers: fraction 9–10; monomers: fraction 10–11. Immunoblottings were performed with antibodies recognizing either the myc-tag (first row of the left panel) or the flag-tag (second row of the left panel), respectively. For quantification, the percentage of total immunoreactivity related to the number of single fractions for non-covalent or covalent complexes and aggregates was plotted against the 11 collected fractions. The fractions containing the non-covalent dimers are highlighted by a dashed rectangle. The single values (percentages and numbers of independent experiments) for all combinations are summarized in Supplementary Table 2. Fractions containing the DNA standards (975 kDa, 325 kDa, 130 kDa and 49 kDa) are marked accordingly.

Next, we analyzed the SDGC fractions from HEK293T cells co-expressing Rom-1-perWT, Rom-1-perP210L, and Rom-1-perC214S complexes. As expected, in the Rom-1-perWT combination a robust Rom-1 signal was found in non-covalent tetramer fractions (Fig. 3f). In addition, Rom-1 was also detected in non-covalent dimer and monomer fractions. No considerable amounts of perWT were found in these fractions suggesting that no Rom-1-perWT heterodimers are present under these conditions (Fig. 3f). When analyzing Rom-1-perP210L and Rom-1-perC214S combinations, the perP210L and perC214S mutants were almost exclusively found in the non-covalent dimer and monomer fractions (Fig. 3g,h). In contrast to the Rom-1 signal from the Rom-1-perWT combination, in presence of the perP210L and perC214S mutants Rom-1 was almost exclusively detected in dimer and monomer fractions (Fig. 3g,h). Based on this, we concluded that Rom-1 predominantly forms non-covalent dimers with both mutants.

Taken together, our SDGC results suggest that perWT-perMT and Rom-1-perMT protein complexes are mainly built of non-covalent dimers.

Rod OS targeting of homo- and heteromeric perWT, perMT, and Rom-1 complexes

Our FRET and SDGC experiments from HEK293T cells strongly suggest that both peripherin-2 mutants are in principle capable of forming complexes with perWT and Rom-1. This prompted us to analyze the protein targeting of these complexes in rod photoreceptors. For this purpose, we used rAAV vector gene delivery to express various combinations of perWT, Rom-1, and perMT and analyze their transport/localization in mouse photoreceptors. It has been shown previously that subretinal co-administration of two rAAVs encoding different transgenes results in very high co-transduction efficiencies in rods17. For delivery to rod photoreceptors, rAAV vectors with a rod specific human rhodopsin promoter were used. To allow for discrimination between perWT or Rom-1 and perMT expression, we fused cerulean to the N-terminus of perWT and Rom-1, and citrine to the N-terminus of perMT, respectively. The rAAVs containing the different peripherin-2 and Rom-1 constructs were subretinally injected to P14 wild type mice. Subsequent analysis of peripherin-2 localization was examined four weeks post injection by detecting citrine and cerulean fluorescence on retinal slices from injected animals. When expressed alone, citrine and cerulean were retained in the rod IS (Suppl. Fig. 1). In accordance with our previous observations20, both mutants were also completely mislocalized to the IS (Fig. 4a,b). The localization pattern of perP210L and perC214S was remarkably different. perP210L showed a spotted large vesicular-like expression, whereas perC214S was distributed throughout the rod IS. Interestingly, however, simultaneous co-delivery of titer-matched perWT and perMT led to a noticeable rescue and substantial rod OS targeting of perP210L and perC214S (Fig. 4c,d). In addition, the rAAV-mediated co-delivery of perWT also rescued the vesicle-like expression pattern of perP210L in the rod IS (Fig. 4c). Finally, we also assessed whether co-administration of titer-matched rAAVs expressing transgenic Rom-1 together with perP210L or perC214S leads to a similar rescue effect. When co-expressed with perWT, both, Rom-1 and perWT were exclusively found in rod OS (Fig. 5a). However, transgenic Rom-1 did not noticeably promote perMT protein targeting to the OS. By contrast, a substantial amount of transgenic Rom-1, most likely the Rom-1-perMT heterodimers, was retained in the rod IS (Fig. 5b,c).

Figure 4
Figure 4

Rod OS targeting of perWT-perMT complexes. (a–d) Confocal images of immunostained retinas injected with citrine-tagged mutants (citr-perP210L (a) and citr-perC214S (b)), or co-injected with the respective mutants and the N-terminally cerulean-tagged perWT (cer-perWT, (c–d)). CNGB1a antibody (B1a, red) was used for specific staining of rod OS. Scale bar, 30 µm.

Figure 5
Figure 5

Rod OS targeting of Rom-1-perWT/MT complexes. Confocal images of immunostained retinas co-injected with C-terminally cerulean-tagged Rom-1 (Rom-1-cer) and citr-perWT (a), citr-perP210L (b), and citr-perC214S (c). Scale bar, 30 µm.

Taken together, these experiments demonstrate that simultaneous co-delivery of transgenic perWT rescues the targeting of the perP210L and perC214S mutants to rod OS. However, simultaneous co-delivery of transgenic Rom-1 and perP210L or perC214S resulted in substantial retention of Rom-1 in the rod IS. In combination with the results obtained from SDGC experiments, these findings strongly indicate that perWT-perMT, but not Rom-1-perMT heterodimers, can be efficiently targeted to rod OS.

Analysis of the perWT-perMT binding properties in rod OS using FRET

FRET and co-IP experiments in HEK293T cells revealed a reduced apparent binding of both peripherin-2 mutants to perWT. This finding could be best explained by decreased binding affinities of the perWT-perMT interaction and/or decreased initial binding kinetics of the mutants to perWT. However, in HEK293T cells co-transfected with perWT and perMT each mutant can also exist as monomers or could undergo self-interactions (i.e. as dimers or aggregates, cf. Fig. 3b–e). As all these combinations would contribute to the overall FRET signal, the apparent reduction of EAmax in HEK293T cells does not allow for discrimination between the mechanisms described above. To examine this issue directly, we took advantage of the fact that perMT targeting to rod OS is rescued only upon co-delivery of transgenic perWT. Consequently, in contrast to HEK293T cells, in rescued rod OS all perMT protein must be arranged in complexes with perWT. This happenstance allowed us to draw direct conclusions about the perWT-perMT binding properties under close-to-native conditions by measuring FRET in isolated “rescued” rod OS. For this purpose, we co-injected wild type mice on P14 with the respective perWT and perMT FRET pairs. At four weeks post injection we isolated the rod OS and measured FRET on single OS co-expressing both, cerulean-tagged perWT and citrine-tagged perMT (Fig. 6a–c). Robust FRET signals could be measured for all combinations. Importantly, the cerulean/citrine molar ratios substantially varied between the single rod OS, which also allowed us to calculate the binding curves. Remarkably, in contrast to the FRET results from HEK293T cells, the EAmax from isolated rod OS was either increased in case of the perWT-perP210L pair or very close to that of the perWT only interaction for the perWT-perC214S combination (Fig. 6d–f and Supplementary Table 1). These findings indicate that the robust reduction in the perWT-perMT interaction observed from co-IP and FRET experiments in HEK293T cells does not result from reduced binding affinity, but is most likely caused by a decrease in initial binding kinetics of perMT to perWT.

Figure 6
Figure 6

FRET experiments in rod OS of retinas co-injected with perWT and perMT AAV-vectors. (a–c) Representative confocal images of FRET channels showing a single OS co-expressing cer-perWT and citr-perWT(a), cer-perWT and citr-perP210L (b), or cer-perWT and citr-perC214S (c). Scale bar, 2 µm. (d–f) Binding curves of the corresponding FRET measurements for the single combinations displayed in (a–c). The dots represent mean values of 1–7 single FRET measurements ± SEM. The single EAmax, values and the numbers of independent measurements (n) for each combination are summarized in Supplementary Table 1.


By analyzing the molecular mechanisms of two adRP-linked peripherin-2 mutants, we provide evidence for a novel role of peripherin-2 and its homolog Rom-1 in the pathophysiology of rod photoreceptors. We show for the first time that rod OS targeting of peripherin-2 mutants can be rescued in vivo by simultaneous co-delivery of perWT using rAAV-mediated gene transfer. This finding is important for understanding the peripherin-2 biology in photoreceptors and has implications for the development of future gene therapies for patients with PRPH2 mutations. Peripherin-2 is crucial for proper rod OS structure and development. This function was proposed to be dose-dependent in rods suggesting that reduced dosage of peripherin-2 (less than 60–80% of the wild type level) induces retinal degeneration26, 27. In line with the postulated dose-dependency, transgenic mice expressing the perC214S mutant show reduced amounts of mutant protein in rod OS (due to mislocalization or protein degradation) which results in haploinsufficiency22. Interestingly, genetic supplementation of perWT on the perC214S mutant background led to a noticeable rescue of the retinal function28. Although helpful in initial stages of therapy development, the application spectrum of genetic supplementation is restricted to model organisms. By contrast, rAAV-mediated gene delivery has proven to be a very promising technique for therapeutic intervention on retinal diseases like retinitis pigmentosa in mammals29,30,31,32. Our data suggest that rAAV-mediated gene supplementation of perWT could support a rescue of perMT targeting defects to rod OS in adRP patients carrying mislocalizing peripherin-2 mutations. We could not detect any detrimental effects on outer nuclear layer (ONL) thickness in fully developed retinas of WT animals co-injected with perWT and perMT transgenes six months post injection (Suppl. Fig. 2). However, we cannot exclude the possibility that rescue of perMT rod OS targeting by perWT gene supplementation would initiate retinal degeneration in patients heterozygous for these mutations. Consequently, prior to gene therapy, the long-term effects of the mutant rescue on retinal degeneration should be tested in appropriate animal models.

In mice co-injected with rAAVs expressing labeled peripherin-2 and Rom-1 transgenes, it is not possible to estimate the contribution of the endogenous murine peripherin-2 and Rom-1 on the perMT rescue. However, our observation that both mutants are mislocalized to the rod IS and lead to reduced protein expression suggests that the endogenous protein levels were not sufficient to rescue perMT localization. Of note, in heterozygous transgenic knock-in mice expressing perC214S, the mutant protein remains in the inner segments and is highly prone to degradation22. These results are very similar to our observations from wild type mice injected with the transgenic perC214S mutant. With respect to this finding, it can be concluded that the rAAV-mediated delivery of transgenic perC214S mutant to wild type mice largely reflects the native situation in mice heterozygous for this mutant. The fact that perC214S is not targeted to rod OS suggests that perWT-perC214S complexes most likely are not formed under these conditions. However, as discussed above, additional rAAV-mediated delivery of perWT presumably exceeds the critical levels necessary for perWT-perMT complex formation, highlighting the critical role of peripherin-2 dosage in pathophysiology of photoreceptors.

Our study also provides novel insights into the structural impacts of perP210L and perC214S on folding of the D2 loop domain. We show that perP210L and perC214S lead to a structural rearrangement of the distal part of the D2 loop domain around the aa position 260. It is conceivable that perP210L and perC214S may also lead to structural changes in other parts of the D2 loop, which could not be covered by our assay. However, our data suggest that folding changes induced by perP210L and perC214S most likely do not elicit structural rearrangements of the proximal half of the D2 loop close to the highly conserved tetraspanin CCG motif.

P210 and C214 are located within the PxxCC motif, which is conserved among most tetraspanins33. While both cysteine residues of the motif were shown to be involved in intramolecular peripherin-2 disulfide bond formation21, 34, the role of the proline residue remained unknown. Peripherin-2 belongs to the subfamily of non-conventional tetraspanins34, thus, it remains to be clarified if the PxxCC motif has a similar role on protein folding in other tetraspanins. Interestingly, other mutants in close proximity to the P210 and C214 position (i.e. perV209I or perS212T) did not change the accessibility of the proteases in our assay. This emphasizes the crucial role of the proline at position 210 and cysteine at position 214 for the proper folding of the D2 loop domain. Furthermore, our results suggest that the apparent reduction of perMT binding to perWT in co-IP and in FRET experiments from HEK293T cells is most likely caused by protein misfolding. Our FRET experiments on isolated rod OS indicate that this apparent decrease in binding to perWT does not result from reduced binding affinities, but rather seems to be a consequence of reduced initial binding kinetics of perP210L and perC214S to perWT. In other words, this suggests that the first step of perMT binding to perWT is impeded, however, once bound, the affinity of both mutants to perWT remains largely unchanged. These results are well matched on our peptide competition assay indicating that the PxxCC motif does not represent the interface for homomeric peripherin-2 interactions. EAmax values resulting from the transgenic perWT were higher in HEK293T cells compared to the rod OS. This difference could be caused by non-labeled endogenous peripherin-2 or Rom-1 in the retina, which are also expected to bind to transgenic perWT (incomplete labeling). However, the perWT EAmax values from isolated rod OS are still in a very high range highlighting the suitability of the FRET approach to addressing peripherin-2 oligomerization in these compartments.

When correlating our results from SDGC to those obtained from rod OS targeting experiments (Fig. 7 and Suppl. Fig. 3), two very important conclusions could be drawn: 1) Non-covalent perWT-perMT dimers can be formed and targeted to rod OS. 2) Non-covalent Rom-1-perMT heterodimers are stacked in the inner segments. The first deduction is very surprising as non-covalent tetramerization was considered to be crucial for peripherin-2 targeting to rods16. This conclusion was drawn from different sets of experiments in previous studies: i) When analyzing perWT complexes isolated from OS, no dimers could be detected35. ii) Tetramerization-deficient peripherin-2 mutants could not be targeted to rod OS16. iii) Peripherin-2 mutants which preferentially form homodimers are not targeted to rod OS16. However, none of these experiments is sufficient to state if perWT-perWT or perWT-perMT dimers can also be targeted to rod OS. First, perWT does not form dimers in SDGC experiments when expressed alone, which explains its absence in rod OS under physiological conditions. Second, only rod OS targeting of pure perMT complexes was examined so far16. Consequently, to the best of our knowledge, this is the first study addressing the principle capability of perWT-perMT dimers to be targeted to rod OS. The finding that Rom-1-perMT heterodimers cannot be targeted to rod OS suggests that Rom-1 cannot fully compensate for the peripherin-2 function in rods under these conditions. Currently, one can only speculate about the physiological role of these opposing effects of peripherin-2 and Rom-1 in terms of binding and targeting of misfolded peripherin-2 mutants. A recent study revealed that Rom-1 promotes the trafficking of the Y141C peripherin-2 mutant in vitro and converts the cone-dominant pattern dystrophy to RP phenotype in vivo12. Similar effects are not expected to occur for the C214S or P210L mutation, as Rom-1 cannot promote targeting of these mutants to rod OS. Together, these findings indicate that Rom-1 might play a yet undefined role in pathophysiology of retinal diseases as a mutation-dependent disease modifier.

Figure 7
Figure 7

Rod OS targeting of perMT dimeric complexes. The rod photoreceptor localization of different perMT-containing dimers (perWT-perMT, Rom-1-perMT and perMT only) is symbolized by a dashed rectangle. The position of the D2 loop is highlighted in red and the D2 loop misfolding caused by perMT is symbolized by an incision.

Rom-1 and peripherin-2 are also expressed in cones and many mutations in peripherin-2 (but not in Rom-1) are linked to retinal diseases primarily affecting cone photoreceptors13. Despite some advances, the molecular mechanisms underpinning this differential penetrance of peripherin-2 mutants in rods and cones are still not fully understood. In light of our results, it is tempting to speculate that Rom-1 might be one of the key players shaping the penetrance of peripherin-2 mutants in rods and cones. Finally, in the context of gene therapy, the postulated novel function of Rom-1 raises the possibility that the efficiency of gene supplementation therapy of adRP-associated peripherin-2 point mutations could be improved by co-delivering peripherin-2 with Rom-1.



The studies were carried out in accordance with the approved guidelines of the local committee of laboratory animal care (District Government of Upper Bavaria) and German Laws on animal welfare (Tierschutzgesetz). Anesthesia was performed by intraperitoneal injection of ketamine (40 mg/kg body weight) and xylazine (20 mg/kg body weight). Euthanasia was performed by cervical dislocation.

Molecular biology

For expression in rods, the single human peripherin-220 and Rom-1 transgenes were subcloned to the pAAV2/8 YF vector30 containing the human Rhodopsin (hRHO) promoter using standard cloning techniques. For expression in HEK293T cells (LentiX 293 T Cell Line, Clontech Laboratories, Mountain View, CA, USA), the peripherin-2 and Rom-1 transgenes were subcloned to the standard pcDNA3.1 vector (Invitrogen, Waltham, MA, USA). Peripherin-2 mutants were introduced by site directed mutagenesis (QuikChange Lightning Site-Directed Mutagenesis Kit, Agilent Technologies, Santa Clara, CA, USA). All transgenes were sequenced prior to use.

Protein biochemistry

For co-immunoprecipitations (co-IPs) transiently transfected HEK293T cells were harvested 48 hours post transfection and membrane preparations were conducted as described36. Co-IPs were performed with the anti-myc antibody (9B11, Cell Signaling Technology, Danvers, MA, USA) using Protein G magnetic beads (Novex, Thermo Fisher Scientific, Waltham, MA, USA) according to the manufacturer’s protocol.

For western blotting, injected retinas of light adapted wild type C57BL6/J animals were used four weeks post injection. The dissected retinas were homogenized in membrane preparation buffer using the Potter S homogenizer (B. Braun Diessel Biotech, Melsungen, Germany).

For peptide competition assay, the peripherin-2 peptide (peptide sequence CDGRYLVDGVPFSCCNPSSPR) was obtained from jpt Innovative Peptide Solutions (Berlin, Germany). The peptide was added to the respective membrane preparation and the solution was incubated with the myc-antibody-coupled magnetic beads for 30 min at room temperature. The co-IPs containing the peptide-free membrane preparations were processed under identical conditions. For the native protease cleavage assay, membrane preparations36 of transfected HEK293T cells were incubated for 5 h at room temperature (RT) and processed for western blotting. No protease inhibitors were added to the membrane preparations prior to the incubation. For immunoblotting, antibodies were used in following dilutions: mouse anti-myc (see above), 1:2000; mouse anti-GFP (Clontec, Takara Bio Inc., Shiga, Japan), 1:2000; mouse anti-ATPase (anti alpha3, ab2826, Abcam, Cambridge, UK), 1:2000.

Sucrose density gradient centrifugation

For sucrose density gradient centrifugation, HEK293T cells were transiently transfected with the respective peripherin-2 constructs. Cells were harvested 48 h post transfection and homogenized in a lysis buffer comprising 0.5% Triton X-100, 150 mM NaCl and 2 mM CaCl2 using the Potter S homogenizer (see above). Continuous density gradients of 5–20% (wt/vol) sucrose were prepared by underlayering 0.5 ml of 5%, 10%, 15% and 20% sucrose containing 0.1% Triton X-100 and 10 mM N-ethylmaleimide (Sigma-Aldrich, St. Louis, MO, USA). The gradient was left at RT for 1 h to facilitate diffusion and chilled on ice for 30 min prior to sample application. To determine the weight of single peripherin-2 and Rom-1 protein complexes in each immunoblot, DNA standards of defined molecular weights (75 bp–20.000 bp, i.e. 49 kDa–13,000 kDa, GeneRuler 1 kb Plus (Thermo Fisher Scientific, Waltham, MA, USA)) were mixed to lysates containing 200 µg of the respective proteins. The mixture was carefully layered on top of the gradient and centrifuged at 46,700 rpm for 2 h at 4 °C in a Beckman Coulter Optima L-80K Ultracentrifuge (Beckman Coulter Biomedical GmbH, Munich, Germany). Afterwards, the centrifuge tube was punctured and fractions were collected dropwise (5 drops/tube). Fractions from each sucrose gradient were separately used for immunoblotting with myc- or flag-specific antibodies and for agarose gel electrophoresis to detect the DNA standards. The suitability of DNA standards was first validated for perWT only. As shown in Fig. 3a, perWT gives rise to well-defined fractions of non-covalent tetramers, covalent octamers, and high-order oligomers. The molecular weight of the DNA in the same fractions very nicely correlated with the molecular weights of the corresponding perWT complexes. Therefore, for each of the remaining immunoblots, DNA standards were used to determine the fractions containing the different perWT, perMT, or Rom-1 complexes.

Photometric FRET Measurements

3 cube FRET was performed as described in detail in Butz et al.37 with modifications published in Becirovic et al. and Nguyen et al.18, 19. Briefly, transfected HEK293T cells and isolated rod OS were measured in a FRET imaging solution comprising 2 mM CaCl2, 10 mM glucose, 10 mM HEPES sodium salt, 5 mM KCl, 1 mM MgCl2, 140 mM NaCl, pH 7.4, at RT. 3 cube FRET measurements were conducted using a Leica DMI6000B inverted fluorescent microscope (Leica, Wetzlar, Germany) in combination with a photomultiplier detection system including a photomultiplier tube (Horiba, London, Ontario, Canada). As excitation source, a DeltaRamX monochromator was used and FRET data were acquired with FelixGX software (Horiba, London, Ontario, Canada). FRET filter cubes were as follows (excitation, dichroic mirror, emission): cerulean/CFP (ET436/20 × ; T455lp; ET480/40m), FRET (ET436/20 × ; T455lp; ET535/30m) and citrine/YFP (ET500/20 × ; T515lp; ET535/30m) (Chroma technology, Vermont, USA). The fluorescence intensities were measured in single cells co-expressing varying, but sufficient levels of cerulean- and citrine-tagged proteins with the respective filter cube. Subsequent FRET ratios (FR) were calculated from the signal intensities according to the 3 cube FRET equation described in Shaltiel et al.38. Apparent FRET efficiencies (EA) at given cerulean/citrine molar ratios (MR) were obtained from equation (1):

E A =[FR1] ε citrine ( 436 ) ε cerulean ( 436 )

εcitrine and εcerulean represent the setup specific average molar extinction coefficients for the fluorophores citrine or cerulean, respectively. FRET data were analyzed using FelixGX software (see above) and Excel (Microsoft Corporation, Redmond, Washington, USA).

Binding curves were calculated using equation (2):

E A = E Amax MR K + MR

EAmax is the maximal FRET efficiency that can be calculated for saturated donor concentrations and K is an analogon of the dissociation constant. Ex vivo FRET experiments were conducted on single rod OS isolated from six pooled retinas for each FRET pair.

rAAV preparation and subretinal injections

The production of single-strand AAVs (rAAV 2/8 YF) containing the hRHO promoter and the subretinal injection technique were described previously30. 1010 rAAV particles were delivered subretinally to wild type C57Bl6/J mice by a single injection on postnatal day 14. Four weeks post injection, all injected retinas were analyzed for fluorescence using scanning laser ophthalmoscopy (Spectralis, Heidelberg Engineering, Dossenheim, Germany).

Preparation of outer segments

A detailed procedure of rod OS preparation was described recently17, 19. Briefly, mice were sacrificed four weeks post injection and the isolated retinas were collected in a 1.5-ml reaction tube containing 100 µl of PBS. The OS were separated from the retina by vortexing for 15–30 s and centrifuging for 30 s at 500 × g. Afterwards the OS containing supernatant was collected and used for subsequent FRET measurements.

Immunohistology and Confocal Microscopy

For immunohistology, wild type C57BL6/J mice were injected on P14 with the respective rAAV particles. Four weeks post injection, the retinas were dissected and processed for immunohistology as described39. Retinal and OS images were obtained by the TCS SP8 confocal scan microscope (Leica, Wetzlar, Germany), acquired with the LASX software (Leica, Wetzlar, Germany), and processed with the ImageJ software (National Institutes of Health, Bethesda, MD, USA). We used the rabbit anti-CNGB1a antibody (1:10.00040) as marker for rod outer segments. Citrine was excited with the 514 nm laser and detected with the Hybrid (HyD) detector using a 520–540 nm emission filter. Cerulean was excited using the 448 nm laser and detected via the HyD detector with a 460–480 nm emission filter. Images were taken using the 40x and 63x objectives.

Confocal scanning laser ophthalmoscopy and optical coherence tomography

Confocal scanning laser ophthalmoscopy (cSLO) and optical coherence tomography (OCT) were performed 6 months post injection using a modified Spectralis HRA + OCT system (Heidelberg Engineering, Dossenheim, Germany) as described recently41. Fluorescence signals were examined at 488 nm excitation for citrine/cerulean detection (BP 550/49 nm emission filter).


All values are given as mean ± SEM, and n is the number of trials. For multiple comparisons one-way ANOVA followed by the Tukey’s test was used.

Data availability

All data generated or analyzed during this study are included in this published article (and its Supplementary Information files).

Additional Information

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  1. 1.

    Goldberg, A. F. & Molday, R. S. Subunit composition of the peripherin/rds-rom-1 disk rim complex from rod photoreceptors: hydrodynamic evidence for a tetrameric quaternary structure. Biochemistry 35, 6144–6149 (1996).

  2. 2.

    Stuck, M. W., Conley, S. M. & Naash, M. I. PRPH2/RDS and ROM-1: Historical context, current views and future considerations. Prog. Retin. Eye. Res. 52, 47–63 (2016).

  3. 3.

    Goldberg, A. F. Role of peripherin/rds in vertebrate photoreceptor architecture and inherited retinal degenerations. Int. Rev. Cytol. 253, 131–175 (2006).

  4. 4.

    Goldberg, A. F., Moritz, O. L. & Williams, D. S. Molecular basis for photoreceptor outer segment architecture. Prog. Retin. Eye. Res. 55, 52–81 (2016).

  5. 5.

    Moritz, O. L. & Molday, R. S. Molecular cloning, membrane topology, and localization of bovine rom-1 in rod and cone photoreceptor cells. Invest. Ophthalmol. Vis. Sci. 37, 352–362 (1996).

  6. 6.

    Loewen, C. J. & Molday, R. S. Disulfide-mediated oligomerization of Peripherin/Rds and Rom-1 in photoreceptor disk membranes. Implications for photoreceptor outer segment morphogenesis and degeneration. J. Biol. Chem. 275, 5370–5378 (2000).

  7. 7.

    Daiger, S. P., Sullivan, L. S. & Bowne, S. J. Genes and mutations causing retinitis pigmentosa. Clin. Genet. 84, 132–141 (2013).

  8. 8.

    Ferrari, S. et al. Retinitis pigmentosa: genes and disease mechanisms. Curr. Genomics 12, 238–249 (2011).

  9. 9.

    Bascom, R. A. et al. Cloning of the cDNA for a novel photoreceptor membrane protein (rom-1) identifies a disk rim protein family implicated in human retinopathies. Neuron 8, 1171–1184 (1992).

  10. 10.

    Dryja, T. P., Hahn, L. B., Kajiwara, K. & Berson, E. L. Dominant and digenic mutations in the peripherin/RDS and ROM1 genes in retinitis pigmentosa. Invest. Ophthalmol. Vis. Sci. 38, 1972–1982 (1997).

  11. 11.

    Kajiwara, K., Berson, E. L. & Dryja, T. P. Digenic retinitis pigmentosa due to mutations at the unlinked peripherin/RDS and ROM1 loci. Science 264, 1604–1608 (1994).

  12. 12.

    Conley, S. M., Stuck, M. W., Watson, J. N. & Naash, M. I. Rom1 converts Y141C-Prph2-associated pattern dystrophy to retinitis pigmentosa. Hum. Mol. Genet. (2017).

  13. 13.

    Boon, C. J. et al. The spectrum of retinal dystrophies caused by mutations in the peripherin/RDS gene. Prog. Retin. Eye. Res. 27, 213–235 (2008).

  14. 14.

    Stenson, P. D. et al. The Human Gene Mutation Database: building a comprehensive mutation repository for clinical and molecular genetics, diagnostic testing and personalized genomic medicine. Hum. Genet. 133, 1–9 (2014).

  15. 15.

    Goldberg, A. F. & Molday, R. S. Defective subunit assembly underlies a digenic form of retinitis pigmentosa linked to mutations in peripherin/rds and rom-1. Proc. Natl. Acad. Sci. USA. 93, 13726–13730 (1996).

  16. 16.

    Loewen, C. J., Moritz, O. L., Tam, B. M., Papermaster, D. S. & Molday, R. S. The role of subunit assembly in peripherin-2 targeting to rod photoreceptor disk membranes and retinitis pigmentosa. Mol. Biol. Cell 14, 3400–3413 (2003).

  17. 17.

    Becirovic, E. et al. Peripherin-2 couples rhodopsin to the CNG channel in outer segments of rod photoreceptors. Hum. Mol. Genet. 23, 5989–5997 (2014).

  18. 18.

    Nguyen, O. N. et al. Peripherin-2 differentially interacts with cone opsins in outer segments of cone photoreceptors. Hum. Mol. Genet. 25, 2367–2377 (2016).

  19. 19.

    Becirovic, E. et al. AAV Vectors for FRET-Based Analysis of Protein-Protein Interactions in Photoreceptor Outer Segments. Front. Neurosci. 10, 356 (2016).

  20. 20.

    Becirovic, E. et al. In Vivo Analysis of Disease-Associated Point Mutations Unveils Profound Differences in mRNA Splicing of Peripherin-2 in Rod and Cone Photoreceptors. PLoS Genet. 12, e1005811 (2016).

  21. 21.

    Goldberg, A. F., Loewen, C. J. & Molday, R. S. Cysteine residues of photoreceptor peripherin/rds: role in subunit assembly and autosomal dominant retinitis pigmentosa. Biochemistry 37, 680–685 (1998).

  22. 22.

    Stricker, H. M., Ding, X. Q., Quiambao, A., Fliesler, S. J. & Naash, M. I. The Cys214–> Ser mutation in peripherin/rds causes a loss-of-function phenotype in transgenic mice. Biochem. J. 388, 605–613 (2005).

  23. 23.

    Chakraborty, D., Rodgers, K. K., Conley, S. M. & Naash, M. I. Structural characterization of the second intra-discal loop of the photoreceptor tetraspanin RDS. FEBS J. 280, 127–138 (2013).

  24. 24.

    Ding, X. Q., Stricker, H. M. & Naash, M. I. Role of the second intradiscal loop of peripherin/rds in homo and hetero associations. Biochemistry 44, 4897–4904 (2005).

  25. 25.

    Ding, X. Q. et al. The R172W mutation in peripherin/rds causes a cone-rod dystrophy in transgenic mice. Hum. Mol. Genet. 13, 2075–2087 (2004).

  26. 26.

    Kedzierski, W. et al. Deficiency of rds/peripherin causes photoreceptor death in mouse models of digenic and dominant retinitis pigmentosa. Proc. Natl. Acad. Sci. USA. 98, 7718–7723 (2001).

  27. 27.

    Nour, M., Ding, X. Q., Stricker, H., Fliesler, S. J. & Naash, M. I. Modulating expression of peripherin/rds in transgenic mice: critical levels and the effect of overexpression. Invest. Ophthalmol. Vis. Sci. 45, 2514–2521 (2004).

  28. 28.

    Nour, M., Fliesler, S. J. & Naash, M. I. Genetic supplementation of RDS alleviates a loss-of-function phenotype in C214S model of retinitis pigmentosa. Adv. Exp. Med. Biol. 613, 129–138 (2008).

  29. 29.

    Rossmiller, B., Mao, H. & Lewin, A. S. Gene therapy in animal models of autosomal dominant retinitis pigmentosa. Mol. Vis. 18, 2479–2496 (2012).

  30. 30.

    Koch, S. et al. Gene therapy restores vision and delays degeneration in the CNGB1(−/−) mouse model of retinitis pigmentosa. Hum. Mol. Genet. 21, 4486–4496 (2012).

  31. 31.

    Petrs-Silva, H. & Linden, R. Advances in gene therapy technologies to treat retinitis pigmentosa. Clin. Ophthalmol. 8, 127–136 (2014).

  32. 32.

    Ali, R. R. et al. Restoration of photoreceptor ultrastructure and function in retinal degeneration slow mice by gene therapy. Nat. Genet. 25, 306–310 (2000).

  33. 33.

    Seigneuret, M., Delaguillaumie, A., Lagaudriere-Gesbert, C. & Conjeaud, H. Structure of the tetraspanin main extracellular domain. A partially conserved fold with a structurally variable domain insertion. J. Biol. Chem. 276, 40055–40064 (2001).

  34. 34.

    Conley, S. M., Stuck, M. W. & Naash, M. I. Structural and functional relationships between photoreceptor tetraspanins and other superfamily members. Cell. Mol. Life Sci. 69, 1035–1047 (2012).

  35. 35.

    Goldberg, A. F., Moritz, O. L. & Molday, R. S. Heterologous expression of photoreceptor peripherin/rds and Rom-1 in COS-1 cells: assembly, interactions, and localization of multisubunit complexes. Biochemistry 34, 14213–14219 (1995).

  36. 36.

    Much, B. et al. Role of subunit heteromerization and N-linked glycosylation in the formation of functional hyperpolarization-activated cyclic nucleotide-gated channels. J. Biol. Chem. 278, 43781–43786 (2003).

  37. 37.

    Butz, E. S. et al. Quantifying macromolecular interactions in living cells using FRET two-hybrid assays. Nat. Protoc. 11, 2470–2498 (2016).

  38. 38.

    Shaltiel, L. et al. Complex regulation of voltage-dependent activation and inactivation properties of retinal voltage-gated Cav1.4 L-type Ca2+ channels by Ca2+ -binding protein 4 (CaBP4). J. Biol. Chem. 287, 36312–36321 (2012).

  39. 39.

    Michalakis, S. et al. Impaired opsin targeting and cone photoreceptor migration in the retina of mice lacking the cyclic nucleotide-gated channel CNGA3. Invest. Ophthalmol. Vis. Sci. 46, 1516–1524 (2005).

  40. 40.

    Huttl, S. et al. Impaired channel targeting and retinal degeneration in mice lacking the cyclic nucleotide-gated channel subunit CNGB1. J. Neurosci. 25, 130–138 (2005).

  41. 41.

    Schon, C. et al. Loss of HCN1 enhances disease progression in mouse models of CNG channel-linked retinitis pigmentosa and achromatopsia. Hum. Mol. Genet. 25, 1165–1175 (2016).

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The authors thank Berit Noack and Nadja Gießl for their excellent technical support. This work was supported by the Deutsche Forschungsgemeinschaft, grant number BE 4830/1-1 (to E.B.), and Deutsche Forschungsgemeinschaft SFB 870 P05 and P15, TRR 152 P06 (to C.W-S). The funders had no role in study design, data collection and analysis, decision to publish, or preparation of the manuscript.

Author information

Author notes

  1. Sybille Böhm and Lisa M. Riedmayr contributed equally to this work.


  1. Center for Integrated Protein Science Munich CiPSM, Ludwig-Maximilians-Universität München, Munich, Germany

    • Sybille Böhm
    • , Lisa M. Riedmayr
    • , O. N. Phuong Nguyen
    • , Toni Liebscher
    • , Elisabeth S. Butz
    • , Christian Schön
    • , Stylianos Michalakis
    • , Christian Wahl-Schott
    • , Martin Biel
    •  & Elvir Becirovic
  2. Department of Pharmacy – Center for Drug Research, Ludwig-Maximilians-Universität München, Munich, Germany

    • Sybille Böhm
    • , Lisa M. Riedmayr
    • , O. N. Phuong Nguyen
    • , Toni Liebscher
    • , Elisabeth S. Butz
    • , Christian Schön
    • , Stylianos Michalakis
    • , Christian Wahl-Schott
    • , Martin Biel
    •  & Elvir Becirovic
  3. Department of Biology, Animal Physiology, Friedrich-Alexander Universität Erlangen-Nürnberg, Erlangen, Germany

    • Andreas Gießl


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E.B. designed research; E.B., S.B., L.M.R., O.N.P.N., A.G., T.L., and E.S.B performed research; E.B., S.B., L.M.R., C.S., S.M., C.W.S., and M.B. analyzed data; E.B., S.B., L.M.R., S.M., and M.B. wrote the paper.

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The authors declare that they have no competing interests.

Corresponding author

Correspondence to Elvir Becirovic.

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