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. Author manuscript; available in PMC: 2013 Feb 1.
Published in final edited form as: Hum Genet. 2011 Jul 17;131(2):235–250. doi: 10.1007/s00439-011-1064-z

The Cell-Adhesion Gene PVRL3 is Associated with Congenital Ocular Defects

Salil A Lachke 1,2,, Anne W Higgins 3,†,, Maiko Inagaki 4, Irfan Saadi 1,§, Qiongchao Xi 1, Michelle Long 3, Bradley J Quade 3, Michael E Talkowski 5, James F Gusella 5, Atsuko Fujimoto 6, Michael L Robinson 7, Ying Yang 8, Quynh T Duong 9, Irit Shapira 10, Benny Motro 10, Jun Miyoshi 11, Yoshimi Takai 12, Cynthia C Morton 3, Richard L Maas 1,*
PMCID: PMC3279124  NIHMSID: NIHMS324425  PMID: 21769484

Abstract

We describe a male patient (patient DGAP113) with a balanced translocation, 46,XY,t(1;3)(q31.3;q13.13), severe bilateral congenital cataracts, CNS abnormalities and mild developmental delay. Fluorescence in situ hybridization (FISH) and suppression PCR demonstrated that the chromosome 3 breakpoint lies ~515 kb upstream of the PVRL3 gene, while the chromosome 1 breakpoint lies ~50 kb upstream of the NEK7 gene. Despite the fact that NEK7 is closer to a translocation breakpoint than PVRL3, NEK7 transcript levels are unaltered in patient DGAP113 lymphoblastoid cells and Nek7-deficient mice exhibit no detectable ocular phenotype. In contrast, the expression of PVRL3, which encodes the cell adhesion protein Nectin 3, is significantly reduced in patient DGAP113 lymphoblastoid cells, likely due to a position effect caused by the chromosomal translocation. Nectin 3 is expressed in the mouse embryonic ciliary body and lens. Moreover, Pvrl3 knockout mice as well as a spontaneous mouse mutant ari (anterior retinal inversion), that maps to the Pvrl3 locus, exhibit lens and other ocular defects involving the ciliary body. Collectively, these data identify PVRL3 as a critical gene involved in a Nectin-mediated cell-cell adhesion mechanism in human ocular development.

Keywords: Cataract, Lens, PVRL3, Nectin, Cell-Adhesion, Ciliary Body

INTRODUCTION

Among ocular defects affecting humans, opacity in the ocular lens – clinically termed cataract – is classified as congenital or age-related and remains the leading cause of blindness, affecting approximately 25 million individuals worldwide (Graw 2009). Congenital cataract, although less common than age-related cataract, is responsible for one-tenth of all childhood blindness and occurs in isolation or in association with other defects of ocular development (Bermejo and Martinez-Frias 1998; Hejtmancik 2008; Jensen and Goldschmidt 1971). To date, isolated cataracts have been mapped to approximately 30 loci, of which more than 20 are associated with mutations in specific genes (Shiels and Hejtmancik 2007). Approximately half of these known mutations are in genes that encode crystallins (CRYAA [OMIM 123580], CRYAB [OMIM 123590], CRYBB1 [OMIM 600929], CRYBB2 [OMIM 123620], CRYBB3 [OMIM 123630], CRYBA1 [OMIM 123610], CRYBA4 [OMIM 123631], CRYGC [OMIM 123680], and CRYGD [OMIM 1243690]), which are soluble proteins that are the major constituents of the vertebrate lens and play a role in maintaining lens transparency (Shiels and Hejtmancik 2007).

The remainder of the mutations are in functionally diverse genes which encode gap-junction connexin proteins (GJA3 [MIM 121015], GJA8 [OMIM 600897] (Mackay et al. 1999, Shiels et al. 1998)), a heat shock transcription factor (HSF4 [OMIM 602438) (Bu et al. 2002)), homeodomain, bZIP and forkhead transcription factors (PITX3 [OMIM 602669] (Semina et al. 1998), MAF [OMIM 177075] (Jamieson et al. 2002), FOXE3 [OMIM 601094] (Semina et al. 2001)), an aquaporin (MIP [OMIM 154050] (Berry et al. 2000)), a membrane protein (LIM2 [OMIM 154045] (Pras et al. 2002)), an ephrin receptor protein-tyrosine kinase (EPHA2 [OMIM 176946] (Shiels et al. 2008)) and cytoskeletal proteins (BFSP1 [OMIM 603307], (Ramachandran et al. 2007), BSFP2 [OMIM 603212] (Conley et al. 2000)). In addition, mutations in the developmental regulatory factors PAX6 ([OMIM 607108] (Glaser et al. 1994; Prosser et al. 1998)) and EYA1 ([OMIM 601653] (Azuma et al. 2000)) have been found to cause congenital cataracts, along with other ocular defects.

One approach to gene discovery in congenital ocular defects is to study affected individuals who carry balanced chromosomal rearrangements. Both translocations and inversions can disrupt or de-regulate genes at either of the two chromosomal breakpoints that occur with these types of rearrangements (Lachke et al. 2011). The Developmental Genome Anatomy Project (DGAP) seeks to identify genes disrupted by chromosomal breakpoints that are causative for human birth defects (http://dgap.pathology.org; Higgins et al. 2008). One individual, patient DGAP113, carried a t(1;3)(q31.3;q13.13) balanced translocation, severe bilateral congenital cataracts, mild developmental delay, an increased head circumference, and prominent extra-axial cerebrospinal fluid (CSF) spaces. This case thus afforded the opportunity to search for genes etiologic for the cataract phenotype. We sought definitive identification of the responsible gene(s) through an analysis of the expression of these genes in the subject’s lymphoblastoid cells, and by analysis of the homologous mouse genes and the corresponding mouse mutants. We present data that PVRL3 plays an important function in mammalian lens and ciliary body development, and that it represents the first Nectin family cell-cell adhesion protein associated with human ocular phenotype.

METHODS

Generation of Patient DGAP113 Cell Lines

All human study protocols were reviewed and approved by the Partners Health Care System Human Research Committee. Peripheral blood specimens were collected and lymphocyte cell transformation was performed using standard protocols (Bernacki et al. 2003) at the Massachusetts General Hospital Genomics Core Facility in the Center for Human Genetic Research (Boston, MA).

Cytogenetic Studies and Array CGH

The GTG-banded karyotype was evaluated at a resolution of 550 bands. Fluorescence in situ hybridization (FISH) probes used for mapping the breakpoints were derived from BACs selected from genomic analyses conducted with the University of California Santa Cruz (UCSC) Genome Browser and Database and the NCBI Human Genome Browser and Database. BACs from the RP1, RP3, RP4, RP5, RP6, RP11, and RP13 libraries were obtained from CHORI (Children’s Hospital Oakland Research Institute, Oakland, CA). BACs from the CTB, CTC, and CTD libraries were obtained from Invitrogen (Carlsbad, CA). DNA was isolated using a standard protocol consisting of alkaline lysis, neutralization, and ethanol precipitation (Qiagen, Valencia, CA). Isolated DNA was labeled directly with either SpectrumGreen- or SpectrumOrange-conjugated dUTP, using the Nick Translation Reagent Kit from Abbott Molecular/Vysis (Des Plaines, IL), or indirectly with biotin or digoxygenin using the DIG DNA Labeling Kit or Biotin DNA Labeling Kit (Roche Diagnostics, Indianapolis, IN). Cot-I DNA was added to suppress repetitive sequences, and probes were ethanol precipitated and re-suspended in Hybrisol containing 50% formamide (Abbott Molecular/Vysis). FISH was performed as previously described (Higgins et al. 2008). Array-based comparative genomic hybridization (aCGH) experiments were performed using Spectral Genomics 2600 BAC arrays (Houston, TX) at an average resolution of ~1 Mb to exclude associated overt deletions and duplications.

Southern Blot Analysis and Breakpoint Cloning

Southern blotting was performed by standard methods (Southern, 1975). BAC RP11-401A10 DNA sequences overlapping the breakpoint critical region were examined using Repeat Masker to identify regions to generate specific probes. Genomic DNA probes ranging from ~250 to 500 base pairs (bp) were generated from non-repetitive sequences by PCR. PCR products were labeled with the Megaprime DNA labeling Kit (Amersham Biosciences, Piscataway, NJ). Aberrant bands detected in patient DGAP113 subject samples but absent in control samples localized the breakpoints to within these restriction fragments. Rearrangement breakpoints were cloned using modifications of the suppression PCR protocol (Siebert et al. 1995) as described (Alkuraya et al. 2006). Cloned junction fragments were sequenced using standard Sanger sequencing methods.

Immunofluorescence Microscopy

Mouse lens coronal sections for immunohistochemistry were prepared from mouse embryos fixed in 4% PFA on ice for 30 min, treated with 30% sucrose for 4 hr and embedded in OCT for cryosectioning. Chicken serum (Abcam) (5% solution in 1X PBS) was used for blocking and primary antibody incubation was done overnight at 4°C. Chick secondary antibodies used were conjugated with either Alexa 488 or Alexa 594 fluorophores (Invitrogen). Commercial antibodies were obtained from the following sources and used at 1:100 dilutions: Nectin 3 antibody [103-A1] (Abcam, ab16913), PVRL1 (Nectin 1) antibody (Abcam, ab66985), and I+S Afadin antibody (Abcam, ab11338), E-Cadherin (Abcam ab76055), ZO-1 (Invitrogen, 339100). To verify Nectin 3 antibody specificity, we analyzed Nectin 3 in the eye and found it correlated with the previously reported Nectin 3 expression pattern (Inagaki et al. 2005). All immunofluorescence experiments were performed with primary and secondary antibody only controls, which exhibited no detectable signal. Unless otherwise noted, all images were obtained by confocal microscopy using a Leica model TCS SP2 instrument with optical sections of 0.6–1.0 µm. Digitized images were processed with Adobe Photoshop.

Mouse Husbandry

All mice were treated in accordance with the protocols established by the Association for Research in Vision and Ophthalmology (ARVO). The Animal Care and Use Committees of Kobe University (Hyogo, Japan), Columbus Children’s Research Institute (Columbus, OH) or Harvard Medical School (Boston, MA) approved all experimental protocols involving mutant mice and their controls. Wild type CD-1 outbred mice were obtained from Charles River Laboratories (Boston, MA) and used for immunohistochemical analyses. Mice were housed in a 14 h light to 10 h dark cycle, and mutant and littermate control mice were housed together to control for cage-dependent differences. The morning of vaginal plug discovery was taken as embryonic day E0.5. Mice used in this study were obtained from Kobe University, Miami University, Charles River Laboratories (Boston, MA), or from the laboratories of Dr. Y. Takai (Kobe University, Japan), Dr. M. Robinson (Miami University, OH), Dr. B. Motro (Bar-Ilan University, Israel) or Dr. R. Maas (Brigham and Women’s Hospital and Harvard Medical School). Mice at all sites were regularly screened for pathogens. Two independent Nek7 hypomorphic alleles were generated as gene trap insertions using mES cells obtained from BayGenomics Inc., and the Sanger Institute Gene Trap Resource (SIGTR). The targeted mES cells were subjected to blastocyst injection and germline competent chimeras were obtained and bred to achieve germline transmission. Nek7 heterozygotes were initially crossed to generate Nek7 homozygotes. Ocular phenotypic analyses were conducted using stereomicroscopy and histological sectioning. Degree of loss-of-function was analyzed by quantitative Reverse Transcriptase (qRT)-PCR. A third independently generated Nek7 null allele was analyzed for the presence of a lens phenotype (Salem et al. 2010).

Microarray Analysis of Mouse Embryonic Lens

Total RNA was extracted from several hundred micro-dissected mouse embryonic day 11 lenses or whole embryonic tissue minus the eye region at stages E10.5 through E12.5 using the RNeasy Mini Kit (Qiagen). Standard Affymetrix protocols were used to prepare cDNA and biotin labeled cRNA using in vitro transcription. Microarray analysis was performed on biological triplicates by hybridization to the Affymetrix Mouse 430 2.0 chip in the Biopolymers facility at Harvard Medical School. Around 150 lenses were used per replicate and the data analyzed as described previously (Choe et al. 2005). The lens microarray analyses will be described in greater detail elsewhere.

RNA Analysis of Lymphoblastoid Cells

Total RNA was extracted from lymphoblastoid cell lines using the RNeasy Mini Kit (Qiagen). An iScript cDNA Synthesis Kit (Bio-Rad) was used followed by both regular PCR as well as quantitative PCR using an iQ SYBR green kit and analysis on a LightCycler (Bio-Rad). 5’-GAGTTCTAAAGTTCCTGTTGC-3’ (NEK7-f5) and 5’-GAGGTATGACTTGCACAAAATA-3’ (NEK7-r5) were used for amplification of a 1001 bp product specific to human NEK7. 5’-GTTACATTCCCGCTTGGAAA-3’ (PVRL3-F) and 5’-CCCAGTCAATATGTGCAACG-3’ (PVRL3-R) were used for amplification of a 169 bp product specific to human PVRL3. β-Actin was used as a housekeeping gene and was amplified by the primers 5’-AGCCTCGCCTTTGCCGA-3’ (h-bActin-qF1) and 5’-CTGGTGCCTGGGGCG-3’ (h-bActin-qR1).

Genetic Mapping of the ari Mutation

Homozygous transgenic mice from line OVE401 that express FGF1 in the lens (Robinson et al., 1995) were maintained by brother-sister mating. After several generations of maintenance a litter of OVE401 pups contained several mice with microphthalmia. Outcrossing these microphthalmic pups with FVB/N inbred mice resulted in hemizygous transgenic litters with normal eye size, and intercrossing these F1 pups gave rise to microphthalmic offspring with a frequency of 25%; the transgene did not co-segregate with the microphthalmic phenotype. We determined that the microphthalmic phenotype was the result of an autosomal recessive mutation that spontaneously arose in the OVE401 transgenic mice, and named the mutation ari for anterior retinal inversion. The genetic location of the ari mutation was determined by a genetic screen using homozygous ari (non-transgenic) mice on an FVB/N background crossed to wild type C57BL/6 mice. All F1 mice were agouti and had normal eye size. F1 mice were backcrossed to homozygous FVB/N ari mice and the resultant backcross pups were collected for eye morphology and genomic DNA. Genomic DNA was tested for microsatellite polymorphisms between FVB/N and C57BL/6 and genotypes were compared with eye morphology to look for co-segregation and recombination between the microphthalmic phenotype and microsatellite polymorphisms. After an initial analysis of 24 backcross animals localized the ari mutation to mouse chromosome 16, we tested an additional 665 backcross progeny to localize the ari mutation to mouse chromosome 16 between D16Mit126 and D16Mit61.

In situ Hybridization Analysis of Pvrl3 Expression

Pvrl3 expression was examined in wild type FVB/N and isogenic ari homozygous mutant mice by in situ hybridization. In situ hybridizations were carried out according to the methods described in Robinson et al., 1995. using an antisense riboprobe consisting of a Pvrl3 retina EST clone (IMAGE 536340) labeled with 35S-UTP. A Pvrl3 sense riboprobe was used as a control, and exhibited no detectable signal. Sections were counterstained with hematoxylin and hybridization signals were viewed by dark field microscopy.

Analysis of PVRL3 Upstream Region on Chromosome 3:q13.13

The chromosome 3 region upstream of PVRL3 was analyzed using the University of California - Santa Cruz (UCSC) Genome Browser on Human Mar. 2006 (NCBI36/hg18) Assembly. Specifically, track settings for the ENCODE Enhancer- and Promoter-Associated Histone Mark (H3K4Me1) on 8 cell lines; the ENCODE Enhancer- and Promoter-Associated Histone Mark (H3K27Ac) on 8 cell lines; the ENCODE Enhancer- and Promoter-Associated Histone Mark (H3K4Me3) on 9 cell lines were used for analysis. This analysis indicated the presence of distinct loci in the PVRL3 upstream region with a high mono-methylated histone H3 lysine 4 (H3K4Me1) and histone 3 lysine 4 acetylation (H3K27Ac) content, compared to tri-methylated histone H3 lysine 4 (H3K4Me3). Taken with existing ChIP-Seq data for transcription factors in the same genomic region (Heintzman et al. 2007; Hon et al. 2008), this analysis suggests that the PVRL3 upstream region may contain potential long-range control elements that regulate Pvrl3 expression.

RESULTS

Clinical Phenotype of Patient DGAP113

A male individual of Hispanic descent was enrolled in the study as patient DGAP113. He carried an apparently balanced chromosomal rearrangement, 46,XY,t(1;3)(q32.1;13.2), and had severe bilateral congenital cataracts, mild developmental delay, and a head circumference greater than the 95th percentile. The cataracts were sufficiently severe that the physician was not comfortable in assigning them to a specific class/sub-type. No obvious defects in the ciliary body were noted. However, the ciliary epithelium can be potentially affected by decreased function of PVRL3 (for details see sections on PVRL3 mouse mutants). Because the ciliary epithelium is not easily observed in a standard ophthalmic exam, specialized techniques (e.g. use of high-resolution ultrasound) may be necessary to detect the presence of subtle abnormalities in cellular morphology or hypomorphic defects. Because such high-resolution techniques were not used at the time of the ocular exam of the patient, the presence of subtle defects in the ciliary epithelium (e.g. reduction in size or function) cannot be ruled out. A head MRI at about 6 months of age showed prominent bilateral frontal subarachnoid spaces that were interpreted as extra-axial CSF spaces, with normal morphology of the brain and ventricles. The orbits and sinuses appeared normal. There was no evidence of maternal rubella infection, or of other in utero or pregnancy complications, and there were no abnormal findings by ultrasound. Galactosemia and reducing substance tests were negative. No phenotype was observed in the parents. There was no consanguinity in this family. In addition, the parents’ karyotypes were normal. Therefore, the phenotype was interpreted to result from a de novo genetic rearrangement.

Molecular and Cytogenetic Analysis of Patient DGAP113

Cytogenetic analysis of metaphase chromosomes from peripheral blood lymphocytes revealed the patient DGAP113’s karyotype to be 46,XY,t(1;3)(q32.1;q13.2) (Fig. 1A,B). To refine the translocation breakpoints, FISH was performed on metaphase chromosomes with a series of labeled BAC clones that mapped to the reported cytogenetic breakpoint on chromosome 1. These experiments identified a clone, RP11-401a10, that demonstrated hybridization signals on the normal chromosome 1, der(1) and der(3), indicating that the chromosome 1 breakpoint lies within this clone (Fig. 1C). Clones that overlapped with RP11-401a10, namely, RP11-141e20 and CTD-2373e11, hybridized to der(1) and der(3) respectively, localizing the breakpoint within an 11.8 kb interval. Southern blot analysis, using PCR products generated from BAC RP11-401a10 as probes, further narrowed the breakpoint to an interval spanning 1397 bp (Fig. 1D,E).

Fig. 1.

Fig. 1

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Patient DGAP113 carries a balanced translocation between chromosomes 1 and 3. (A) GTG banded chromosomes of patient DGAP113. Arrows point to breakpoints on the derivative chromosomes. (B) Ideograms for chromosomes 1 and 3, and derivatives (der) 1 and 3. The derivatives represent the reported t(1;3)(q32.1;13.2) in patient DGAP113. Arrows point to breakpoints on the derivative chromosomes. (C) Hybridization of BAC RP11-401a10 to metaphase chromosomes reveals signals (arrows) on chromosome 1, der(1) and der(3), indicating the breakpoint on chromosome 1 lies within this genomic clone. (D) Southern blot analysis of patient DGAP113 (subject, S) and control (C) DNAs. Enzymes used are indicated at top. The probe was a PCR product generated from BAC RP11-401a10. Arrowheads indicate aberrant bands in the DGAP113 lane (S) indicating the break occurs within the region probed. Fragment sizes are from a DNA ladder. (E) Schematic representation of the rearranged loci as a result of the balanced translocation. Asterisk indicates breakpoint.

Suppression PCR was then performed on der(1) and the junction fragment cloned (Fig. 2A). On chromosome 1, the breakpoint occurred within a LINE element approximately 50 kb upstream of the NEK7 gene. The breakpoint occurred at nucleotide position 198076137 on chromosome 1, while it occurred at nucleotide position 110275770 on chromosome 3 in the human genome sequence GRCh37/hg19 assembly (February 2009). The location of the chromosome 3 breakpoint was similarly narrowed by FISH and regular PCR (data not shown). On chromosome 3 the breakpoint occurred within an LTR and was 515 kb upstream of the gene PVRL3 (Fig. 1E). The rearrangement resulted in the breakpoint lying 1219 kb downstream of the gene DPPA4 on der(3) and 174 kb downstream of the gene LHX9 on der(1) (Fig. 1E, Fig. 2A). Localization of the breakpoints with molecular techniques led to a revision of the karyotype to 46,XY,t(1;3)(q31.3;q13.13). Array comparative genomic hybridization (aCGH) was performed with DNA from the patient DGAP113’s lymphoblastoid cell line with a BAC array at ~1 Mb resolution across the genome to ensure that there were no overt submicroscopic imbalances at other locations in the genome. This analysis detected no chromosomal gains or losses (data not shown) although point mutations or other genomic aberrations below the limit of resolution cannot be ruled out. Therefore, these analyses identified NEK7, PVRL3, LHX9 and DPPA4, which are the closest genes flanking the two breakpoints, as potential candidate genes dysregulated in DGAP113.

Fig. 2.

Fig. 2

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Patient DGAP113 breakpoint resolution and reduced PVRL3 expression. (A) Sequence at the breakpoint is shown with an 11 bp insertion in the der(1) and an 4 bp insertion in the der(3) (inserted nucleotides are shown in white text). (B) Expression of mouse Nek7, Pvrl3, Lhx9 and Dppa4 genes in E11.5 mouse embryonic lens assayed by fluorescence signal intensity from individual microarray probes specific for each transcript. (C) RT-PCR analysis of PVRL3 and NEK7 transcripts in lymphoblastoid cells from patient DGAP113 and two control subjects. Control is indicated by β-ACTIN. (D) Quantitative RT-PCR analysis reveals that PVRL3 transcripts in patient DGAP113’s lymphoblastoid cells are reduced to ~40% of levels in control lymphoblastoid cells (defined as 100%), while NEK7 transcripts levels show no significant change. Asterisk indicates p < 0.05.

Pvrl3 and Nek7 are Expressed in the Mouse Lens

To determine whether any of the four candidate genes surrounding the breakpoints could be potentially involved in the pathogenesis of the patient DGAP113’s cataract phenotype, we examined the expression of the homologous mouse genes in the developing mouse lens. We dissected lenses from mouse embryos at embryonic day E11.5, a key time point in lens morphogenesis, and performed gene expression analyses by microarray. Our gene expression analyses showed high expression of the genes Nek7 and Pvrl3 in E11.5 lens tissues (Fig. 2B). On the other hand, the genes Lhx9 and Dppa4 showed no detectable expression in the E11.5 lens (Fig. 2B). These gene expression analyses suggested that PVRL3 and NEK7, which are proximate to the der(1) and der(3) breakpoints, respectively, warranted further investigation.

Reduced PVRL3 Expression in Patient DGAP113 Lymphoblastoid Cells

We hypothesized that either of the two chromosomal breakpoints, or both, might exert a position effect on NEK7 or PVRL3 and dysregulate their expression in the subject. Position effects on gene expression are well documented in human disease, and have been previously identified as a cause of cataract (Kleinjan and van Heyningen 1998, 2005).

To test this possibility, we examined the expression of NEK7 and PVRL3 in DGAP113 lymphoblastoid cells. Reverse Transcriptase (RT)-PCR analysis indicated that PVRL3 was down-regulated in patient DGAP113’s lymphoblastoid cells compared to controls (Fig. 2C). In contrast, NEK7 expression in patient DGAP113’s lymphoblastoid cells remained unaltered compared to controls. Moreover, characterization of multiple mouse mutants with Nek7 deficiency, including two independent hypomorphic alleles generated in this study, and an independently generated Nek7 null allele, demonstrated the absence of cataract, although Nek7 null homozygotes demonstrated a late embryonic or early post-natal lethal phenotype with growth retardation (Suppl. Fig. 1A–H; Suppl. Fig. 3; Salem et al. 2010). Next, to determine the extent to which PVRL3 expression was altered by its translocation to der(1) breakpoint, we conducted a quantitative-RT-PCR analysis in subject and control lymphoblastoid cells and estimated that PVRL3 transcripts were reduced to about 40% of control levels in patient DGAP113’s lymphoblastoid cells whereas, again, NEK7 transcript levels were unaffected (Fig. 2D). Exon and splice junction sequencing indicated the absence of intragenic mutations in PVRL3 (data not shown). These results indicate that PVRL3 expression is affected by the chromosomal rearrangement in patient DGAP113, likely by a position effect.

Lens Expressed Genes Encode Nectin 3-Interacting Proteins

To further examine the potential role of PVRL3 in the developing lens, we tested whether genes that encode Nectin 3-interacting proteins, curated from the literature, are also expressed in the lens. We focused on four putative Nectin 3-interacting proteins. PARD3 is essential for the polarized growth of cells and interacts via its PDZ domain with the carboxy terminal tail of Nectin 3 (Takekuni et al. 2003). MLLT4 (myeloid/lymphoid or mixed-lineage leukemia translocated 4), orthologous to Drosophila Trithorax, encodes the actin filament-binding protein Afadin, which is known to interact with Nectin 3 (Reymond et al. 2000; Satoh-Horikawa et al. 2000; Takekuni et al. 2003), as well as with JAG1, which also functions in lens development (Le et al. 2009; Saravanamuthu et al. 2009). Nectin 1 and Nectin 2 are Nectin family members that function as Ca2+-independent immunoglobulin-like cell-cell adhesion molecules; either interacts with Nectin 3 in heterophilic trans-interactions to establish adherens junctions (Satoh-Horikawa et al. 2000; Fabre et al. 2002; Takekuni et al. 2003).

We analyzed the E11.5 mouse embryo lens microarray database and found that all four genes are expressed in a significantly lens-enriched manner when compared to control whole embryonic tissues (Fig. 3). Thus, genes encoding proteins that interact with Nectin 3 and that can establish adherens junctions with Nectin 3 in other tissues are also expressed with PVRL3 in the developing mouse lens.

Fig. 3.

Fig. 3

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Transcripts encoding Nectin 3-interacting proteins are enriched in the developing mouse lens. Fold changes estimated from fluorescence signal intensity from individual microarray probes specific for each of the genes Pvrl1, Pvrl2, Pard3 and Mllt4 indicate enriched expression in mouse E11.5 lens compared to whole embryonic tissue. Signal from whole body (WB) embryonic tissue was normalized for each transcript to represent 1.0-fold expression. Asterisk indicates p < 0.05.

Nectin 3 is Expressed in the Lens

To determine the spatio-temporal expression pattern of Nectin 3 and of Nectin 3-interacting proteins in the developing lens, we performed immunofluorescence microscopy (IFM) on murine embryonic lens sections at different stages. In lens development, cells of the anterior epithelium of the lens (AEL) exit the cell cycle at the lens equatorial zone (EZ) and differentiate into posterior fiber cells (PFC) (Fig. 4A) (Lachke and Maas 2010). In later stages, fiber cells elongate along the anterior-posterior axis, fill the lens vesicle (LV), and eventually contact the posterior AEL, in which E-cadherin maintains the AEL cellular phenotype (Pontoriero et al. 2009).

Fig. 4.

Fig. 4

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Nectin 3 is expressed in the lens. (A) Schematic of early (left) and late (right) stages in lens development. Early stage depicts the lens vesicle (LV) stage when anterior epithelial cells of the lens (AEL, blue) exit the cell cycle in the equatorial zone (EZ) and differentiate into primary fiber cells (FC, yellow) in the posterior lens. At a later stage, fiber cells (FC, yellow) elongate, fill the LV cavity, and contact the apical surface of the AEL. In the central lens, fully mature fiber cells form “sutures” at their apical and basal surfaces, indicated by black vertical lines. (B) Immunofluorescence microscopy (IFM) of E13.5 mouse lens demonstrates Nectin 3 expression (red) in the AEL, being stronger near the transition zone. (B’) High magnification of boxed region in (B). Polarized Nectin 3 expression at the apical surface of the AEL (arrow). (C) IFM of E18.5 mouse lens demonstrates strong Nectin 3 expression (red) in the entire AEL. (C’) High magnification of boxed region in (C). Polarized Nectin 3 expression at the apical surface of the AEL (arrow). (D) IFM of E13.5 mouse lens demonstrates Nectin 3 (red) and Afadin (green) expression. (D’) High magnification of boxed region in (D). Polarized Nectin 3 (red) and Afadin (green) expression in the AEL (arrows). Co-localization is yellow. (E) IF of E18.5 mouse lens demonstrates Nectin 3 (red) and Afadin (green) expression. (E’) High magnification of boxed region in (E). Polarized Nectin 3 (red) and Afadin (green) expression (arrow). Co-localization is yellow. (F-F’) IFM of E13.5 lens indicates Nectin 1 expression in fiber cell compartment. (F) Nectin 3 (red) is expressed in AEL, Nectin 1 (green) in FCs. (F’) High magnification of boxed region in (F). At high magnification, co-localization between Nectin 1 and 3 is detected (yellow, arrow). Abbr.: AEL, Anterior epithelium of the lens; FC, Fiber cells. Asterisk denotes non-specific staining of the lens capsule. Scale bars: (B) and (B’) 15 µm, (C) 25 µm, (C’) 7 µm, (D) 5 µm, (D’) 4 µm, (E) 10 µm, (E’) 5 µm.

We first analyzed Nectin 3 expression in lens development. At E13.5, Nectin 3 was expressed in the AEL, and appeared to asymmetrically localize to the apical surface of anterior epithelial cells, which face the fiber cell compartment (Fig. 4B,B’). As lens development progresses, Nectin 3 immunoreactivity increases from equatorial to the anterior central AEL (Suppl. Fig. 2A,A’), and at E18.5, Nectin 3 was intensely expressed in the entire subset of AEL that contacted fiber cells (Fig. 4C, C’). At E13.5, Afadin (MLLT4) was present in the mouse AEL and co-localized with Nectin 3 (Fig. 4D,D’). The Afadin-Nectin 3 co-localization was even more striking at E18.5 (Fig. 4E, E’). At E13.5, Nectin 1 was present in fiber cells adjacent to the Nectin 3-expressing AEL cells (Fig. 4F,F’). Previously, Nectin 2 was reported in both AEL and fiber cells at E11.5 (Okabe et al. 2004). These results indicate that Nectin 3 and four of its potential interacting proteins are coordinately expressed in overlapping patterns during lens development.

Nectin 3 Exhibits Polarized Localization in the Anterior Epithelium of the Lens (AEL)

To determine whether Nectin 3 is expressed in the AEL or fiber cells we performed IFM. We analyzed E18.5 mouse lens sections using antibodies against Nectin 3 and the lens-epithelial-specific marker E-Cadherin (Fig. 5A–C, A’–C’). In addition, we also analyzed E18.5 lens sections using antibodies against Nectin 3 and the protein ZO-1 (Fig. 5D–F, D’–F’), which co-localizes in the anterior epithelium/fiber cell interface (Nguyen et al. 2005; Inagaki et al. 2005) and which we found to localize apical to Nectin 3 in epithelial cells. The intracellular E-Cadherin - Nectin 3 - ZO-1 expression domains were progressively ordered in AEL cells from basal to apical, respectively, conforming to the pattern observed in other epithelia. Location of the ZO-1 expression domain - apical relative to Nectin 3 - in the AEL confirms that Nectin 3 is expressed and localized within the AEL and/or the AEL-fiber cell interface.

Fig. 5.

Fig. 5

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Nectin 3 is expressed in anterior epithelium of the lens (AEL). (A) IFM analysis of E18.5 mouse lens demonstrates Nectin 3 expression (red) in the AEL. (A’) High magnification of boxed region in (A). (B) IFM analysis of the same lens section, stained with E-Cadherin (green) in the AEL. (B’) High magnification of boxed region in (B). (C) Merged image from (A) and (B). (C’) High magnification of boxed region in (C) demonstrates that Nectin 3 expression localizes (arrowhead) apically with respect to E-Cadherin expression (arrow). Co-localization is yellow. (D) IFM analysis of E18.5 mouse lens demonstrates Nectin 3 expression (red) in the AEL. (D’) High magnification of boxed region in (D). (E) IFM analysis of the same lens section stained with ZO-1 (green) in the AEL. (E’) High magnification of boxed region in (E). (F) Merged image from (D) and (E). (F’) High magnification of boxed region in (F) demonstrates that Nectin 3 localizes (arrow) largely basally to ZO-1 expression (arrowhead). Co-localization is yellow. Abbr.: AEL, Anterior epithelium of the lens; FC, Fiber cells. Asterisk denotes non-specific staining of the lens capsule. Scale bars: (C) 4 µm, (C’) 7 µm, (F) 10 µm, (F’) 4 µm.

Nectin 3 and Afadin Co-localize in Cerebral Ventricular Ependymal Epithelium

To test if Nectin 3 was also expressed in brain, we performed immunofluorescence microscopy on mouse embryonic brain tissues. At E13.5, Nectin 3 was expressed in the epithelial (ependymal) cells lining the cerebral ventricles (Fig. 6A). Nectin 3 protein was localized near the apical surface that faces the ventricular lumen (Fig. 6A’). Afadin was also strongly expressed in a similar manner in the ventricular epithelium and substantially overlapped with Nectin 3 protein (Fig. 6B,B’,C,C’). Thus, Nectin 3 and Afadin are co-expressed in a polarized manner at the apical surface of the epithelial ependymal cells lining the mouse cerebral ventricles. This finding may prove relevant to the bi-frontal subarachnoid space phenotype in patient DGAP113.

Fig. 6.

Fig. 6

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Nectin 3 shows polarized localization in ventricular epithelium. (A) IFM analysis of E13.5 mouse brain demonstrates Nectin 3 expression in the epithelial cells lining of the ventricles. (B) These cells also express the actin filament-binding protein Afadin. (C) Co-localization of Nectin 3 and Afadin. (A’–C’) High magnification of regions in (A–C). Abbr.: Ep, Ependyma; Lu, Lumen; Vz, Ventricular zone. Scale bars: (A–C) 40 µm, (A’–C’) 4 µm.

Lens and other Ocular Defects in Pvrl3-null mice

Previous characterization of Pvrl3 null mutants revealed that Nectin 3 and Nectin 1 function via heterophilic trans-interactions to mediate apex-apex adhesion between pigmented and non-pigmented cell layers of the ciliary body epithelium (Inagaki et al. 2005). We further analyzed these Pvrl3 null mutant mice to determine if they also exhibit a lens defect. At postnatal day P1, Pvrl3 null mutant eyes exhibited microphthalmia and an absence of vitreous and aqueous humors, compared to littermate controls (Fig. 7A–C, F). In addition, in contrast to control lenses, Pvrl3 null mutant lenses had small, slit-like separations in the central cortical fiber cells adjacent to the AEL (Fig. 7D, G). These small, slit-like separations were also present in the peripheral cortical region of fiber cells adjacent to the AEL (Fig. 7E, H). Thus, Pvrl3 homozygous null mutants have microphthalmia and lens defects in the region where the AEL associates with fiber cells and where Nectin 3 and its potential interacting partners (Nectin 1 and 2) are expressed. In addition, in contrast to Pvrl3 nullizygotes, Pvrl3 heterozygous mice had no lens defects. Thus in the mouse, Pvrl3 nullizygosity is required to phenocopy the proband’s PVRL3-related lens cataract phenotype.

Fig. 7.

Fig. 7

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Pvrl3 null mouse mutant exhibits lens and multiple ocular defects. (A) Eye of wild type (WT) 6 wk old mouse. (B) Eye of aged-matched Pvrl3 null 6 wk old mouse (−/−) that exhibits microphthalmia. (C) H&E stained coronal section of P1 wild type (WT) mouse eye. (D) High magnification of (C) showing region between lens AEL and FC compartments. (E) High magnification of (C) showing region between lens and anterior retina. (F) H&E stained coronal section of P1 Pvrl3 homozygous knockout mouse eye (Pvrl3−/−). (G) High magnification of (F) showing lens region between AEL and FCs. Note the presence of small slit-like separations in FCs (black asterisk) and disruption of fiber cell morphology, hallmarks of certain types of cataract. Also note severe reduction of the anterior chamber (white asterisk), normally present between the cornea and AEL. Also note the presence of eosinophillic material in the anterior chamber and the vitreous chamber in Pvrl3 −/− mutants. (H) High magnification of (F) showing region between lens and anterior retina. Note small slit-like separations between AEL and FCs (black asterisk). Abbr.: AEL, Anterior epithelium of the lens; AR, Anterior retina; C, Cornea; FC, Fiber cells. Scale bar: 1mm.

Cataracts and Other Ocular Defects in a Spontaneous Mouse Mutant at the Pvrl3 Locus

To gain further insight into the role of Pvrl3 in ocular development, we analyzed a spontaneous mouse ocular mutant, ari (anterior retinal inversion) that likely results from a regulatory mutation in Pvrl3. ari is an autosomal recessive microphthalmia mutant that arose in the transgenic mouse line OVE401 (Robinson et al., 1995). ari homozygotes, in the original FVB/N genetic background, manifest retinal inversion (the anterior retinal tip is folded backwards onto itself, giving an ‘inverted’ appearance), abnormal ciliary body morphogenesis, absent vitreous, and the development of bilateral cataracts (Fig. 8A-B’). An initial genome scan with 24 backcross animals ((FVB/N-ari × C57BL/6) X FVB/N-ari) localized the genetic position of the underlying mutation to mouse chromosome 16, segregating independently of the original OVE401 transgene. Further refinement of the genetic position of ari, based on an analysis of 656 backcross progeny, localized it to a 2.3 Mb region spanning from 422 kb upstream to 1.8 Mb downstream of the Pvrl3 transcription unit (Suppl. Fig. 3A,B; Suppl. Table 1). However, sequencing of Pvrl3 exons and splice junctions in ari mutants failed to detect an intragenic mutation (data not shown).

Fig. 8.

Fig. 8

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ari homozygous mouse mutants exhibit cataracts and multiple ocular defects. (A) Wild type littermate with normal size eye (WT). (A’) ari/ari homozygous mutant mice with microphthalmia. Both (A) and (A’) are from ((FVB/N-ari × C57BL/6) × FVB/N-ari) backcross progeny. (B) H&E stained section of P27 wild type eye. (B’) H&E stained section of P27 ari/ari mutant eye (FVB/N background) demonstrates anterior retinal inversion (black arrow), lack of vitreous (asterisk), and a defect in lens fiber cells (white arrow). (C) Hematoxylin stained section demonstrates morphology and (D) section in situ analysis of E15.5 wild type mouse demonstrates normal Pvrl3 expression (arrow) in the prospective ciliary epithelia (ce), which consists of both pigmented epithelium (pe) and non-pigmented epithelium (npe) (darkfield image). (C’) Hematoxylin stained section demonstrates aberrant morphology and (D’) section in situ analysis on the retinal margin of a P1 ari mouse mutant demonstrates reduced Pvrl3 expression (asterisk) in the prospective ciliary epithelia. The retina region including the developing ciliary body is outlined by the dashed line, with retinal pigment epithelium indicated by a black arrow. Abbr.: ce, prospective ciliary epithelium; npe, non-pigment epithelium; pe, pigment epithelium; r, retina.

Next, we tested if Pvrl3 expression in developing ocular tissues was affected as a result of the ari mutation. Section in situ analyses of E15.5 and P1 mouse eyes revealed that the Pvrl3 expression domain in the prospective ciliary epithelia in ari homozygous mice was reduced to background levels (Fig. 8C-D’; Suppl. Fig. 4C-D’). Surprisingly, Pvrl3 expression in the embryonic and postnatal lens of ari homozygotes appeared similar to wild type (data not shown). These results suggest the existence of distinctly regulated Pvrl3 expression domains in different ocular tissues.

DISCUSSION

Association of Patient DGAP113 Ocular Phenotype with Reduced PVRL3 Expression

Molecular analysis of patient DGAP113, a male child with a balanced translocation between chromosomes 1 and 3, suggested that the dysregulated expression of any of four candidate genes, DPPA4, LHX9, NEK7 or PVRL3, alone or in combination, could be potentially responsible for the patient DGAP113’s ocular and CNS phenotypes. The breakpoint on chromosome 3 lies about 1219 kb downstream of DPPA4 and about 515 kb upstream of PVRL3, with the breakpoint on chromosome 1 about 174 kb downstream of LHX9 and about 50 kb upstream of NEK7. Because none of these four genes were directly disrupted by either breakpoint, and because the proband’s genome appeared otherwise intact by aCGH, we hypothesized that a position effect, by either or both breakpoints, on any of these genes, alone or in combination, most likely accounts for patient DGAP113’s phenotype. Position effects that act upon human genes to cause disease, including cataract, are well documented, with distances ranging from 10 kb to 1.2 Mb (Kleinjan and van Heyningen 1998; 2005). Indeed, position effect dysregulation of genes important in eye development, including PAX6, MAF, and FOXC1 (Lauderdale et al. 2000; Jamieson et al. 2002; Davies et al. 1999), and of genes important in brain development, such as SHH and SIX3 (Roessler et al. 1997; Wallis et al. 1999), have been reported.

To test this hypothesis and to determine whether dysregulation of any of the four candidate genes played a role in patient DGAP113’s phenotype, we analyzed the developmental expression of the homologous mouse genes. Both Nek7 and Pvrl3, but not Dpp4a or Lhx9, were expressed in both the developing mouse lens and CNS. Nek7 (Never in mitosis gene A-related Kinase 7) encodes a NIMA-related protein kinase that controls initiation of mitosis and is expressed in the CNS (Feige and Motro 2002; Kandli et al. 2000; Kimura and Okano 2001; O'Connell MJ et al. 2003; OMIM 606848). Pvrl3 (Poliovirus Receptor-Like 3) encodes an immunoglobulin-like cell adhesion protein, Nectin 3, which interacts with the protein Afadin, and can establish adherens junctions in co-operation with cadherin-catenin molecules in epithelial cells (Reymond et al. 2000; Satoh-Horikawa et al. 2000; Ogita et al. 2010; OMIM 607147). Based on the expression pattern of these genes, we prepared and made use of existing mouse mutants for Nek7 and Pvrl3. First, we obtained two mouse ES cell lines containing Nek7 gene trap insertion alleles and used these to generate hypomorphic Nek7 mutants. In addition, we analyzed a targeted Nek7 null allele (Salem et al. 2010) and demonstrated no overt lens or ocular phenotype in hetero- or homozygotes at stage P5. Despite a clear reduction or absence in Nek7 transcript or protein levels, these hypomorphic or null mutant mice did not exhibit any consistent homozygous phenotype. Moreover, NEK7 expression was not significantly altered in patient DGAP113’s lymphoblastoid cells lines compared to normal controls. Collectively, these results suggest that alterations in NEK7 expression do not contribute significantly to the DGAP113 cataract phenotype.

In view of these findings, we hypothesized that PVRL3 deficiency, as a result of a position effect engendered by patient DGAP113’s translocation, was the most likely cause of patient DGAP113’s cataract phenotype. Of note, patient DGAP113’s translocation separates the PVRL3 upstream genomic region, which is retained on der(3), from the PVRL3 gene, which is translocated to der(1). Consistent with this, and in contrast to NEK7, PVRL3 expression was reduced to approximately 40% of wild type levels in patient DGAP113’s lymphoblastoid cells. In this context, the fact that Pvrl3 heterozygous mice do not display a lens phenotype, whereas Pvrl3 homozygotes do, is not unexpected because nullizygosity in mouse is frequently required to recapitulate a human haploinsufficiency phenotype (Lachke et al. 2011; Sandilands et al. 2003; Seidman and Seidman, 2002; White et al. 1998). However, because Pvrl3 is expressed in multiple ocular tissues, these animals cannot address the question of an autonomous requirement for Pvrl3 function in specific ocular tissues. Moreover, the patient DGAP113 had severe bilateral cataracts but did not exhibit overt ciliary body defects. On the other hand, the Pvrl3 null mouse mutants exhibit both lens and ciliary epithelial defects. The basis for this discrepancy may lie in the difference in the nature of the Pvrl3 mutation between the mouse and the human. Alternately, the potential anatomic effects of defective ciliary epithelial function may differ between mice and humans. Nonetheless, the overall conclusion that reduced Pvrl3 function in the eye results in a lens defect in the mouse and human is consistent with all mutant alleles studied, in both human and mouse.

Interestingly, analysis of the potential chromatin structure of the PVRL3 upstream region in eight human cell lines, using the UCSC genome browser (see Methods), revealed the presence of potential long-range regulatory elements (Supp. Fig. 5). It is possible that separation of the PVRL3 upstream region from the PVRL3 transcription unit may separate lens-specific - but not ciliary body-specific - control elements, therefore accounting for the lack of obvious ciliary body phenotypes in the patient. For example, consistent with separate tissue-specific control elements, the ari mutant illustrates how Pvrl3 expression in ciliary epithelia and lens can be de-coupled. In sum, Pvrl3 expression in the developing mouse lens and CNS, and reduced expression of PVRL3 in patient DGAP113 lymphoblastoid cells, support the view that reduced PVRL3 expression contributes to in the ocular phenotype in patient DGAP113.

The Role of Pvrl3 in Ocular Development and Cataract Formation

To obtain more definitive evidence for this hypothesis, we analyzed the ocular phenotype in two strains of Pvrl3 loss-of-function mice. While patient DGAP113 also exhibits a CNS phenotype of prominent bi-frontal subarachnoid spaces, the developing lens constitutes a highly tractable system in which to ask questions about developmental mechanisms, due to its well-defined embryology and underlying gene regulatory network (GRN) (Donner et al. 2006; Lachke and Maas 2010).

In lens development, various cell adhesion molecules are dynamically expressed in both the AEL and fiber cell compartments (Beebe et al. 2001; Xu et al. 2002). Notably, differentiating fiber cells begin to elongate in the apical-basal axis and have distinct adherens junctions near their apical and basal surfaces (Beebe et al. 2001; Kuszak et al. 1995). Through their respective apical surfaces, fiber cells at this stage are in direct contact with the cells of the AEL. These contacts are lost as fiber cells cease to elongate, and this loss is associated with a loss of adherens complexes (Bassnett and Beebe, 2004). It is thus highly attractive to hypothesize that cell-adhesion proteins may function in these differentiation events.

The PVRL gene family encodes proteins termed Nectins that mediate cell-cell adhesion between similar or diverse epithelial cells through homophilic or heterophilic interactions, or through interaction with cadherins (Takai 2008a, b). Nectins show exclusive localization to adherens junctions (AJs) between neighboring cells, and are active in diverse cellular functions including cell movement, proliferation, survival, and differentiation (Barron et al. 2008; Mizoguchi et al. 2002; Ogita et al. 2008; 2010). Although E-cadherin and N-cadherin are expressed in the lens and are implicated in lens development, they can form only homophillic trans-interactions and thus may have their function largely restricted to cell-cell contacts between homologous cells. In contrast, because Nectins can form both homophillic or heterophillic trans-interactions and thus mediate cell-cell junctions in heterologous cells (e.g., AEL and fiber cells), they may have a function, non-overlapping and independent of cadherins, in the lens. Moreover, Nectin-mediated AJs are weaker than cadherin-mediated AJs, which may also reflect their utility in establishing cell-cell contacts that are necessarily temporary between migrating cells (fiber cells) and their stationary partners (AEL). Thus, they comprise good candidates to mediate the cell-cell adhesion interactions essential to normal lens development.

For example, Nectin proteins also interact with Afadin, which itself binds to actin filaments. Afadin interacts with ZO-1, a tight junction component, which is expressed in the apical part of AEL, in the same region as Nectin 3 (Nielsen et al. 2003; Nguyen et al. 2005). It is tempting to speculate that Nectin 3 is involved in establishing adherens junctions between individual cells of the AEL, and also between cells of the AEL and migrating fiber cells. If so, PVRL3 deficiency may lead to defects in cell adhesion in the AEL, or in the association of AEL and differentiating fiber cells. This may in turn disrupt fiber cell morphology, resulting in the formation of the slit-like separations in fiber cells that we observed, and culminating in cataract. This defect could also occur by reduced Nectin 3 interaction with other Nectin 3 interacting proteins such as PARD3, which interacts with CDC42 to generate cell polarity; CDC42 itself is implicated in lens epithelial invagination (Fig. 9A) (Chauhan et al. 2009). Reduced interactions between Nectin 3 and Nectin 1 or 2 proteins could also logically be expected to contribute to a cataract phenotype (Fig. 9B,C). Moreover, because heterophilic interactions of Nectin molecules can activate intracellular signaling, reduced Nectin 3 may also reduce signaling in the AEL or in fiber cells. Interestingly, in ari mutant mice, which exhibit cataracts, Pvrl3 expression is reduced in the prospective ciliary epithelia but minimally affected in lens. This observation suggests that lens defects can be caused by Pvrl3 deficiency in the ciliary epithelia. In the human patient however, ciliary body defects were not detected and the ocular orbits appeared normal - suggestive of normal ocular fluids. Together, these observations argue against an overt ciliary body-based aspect of PVRL3 function as the primary pathogenic mechanism in the patient. An autonomous requirement for Pvrl3 in the lens or the ciliary epithelium can only be conclusively addressed through the study of conditional null alleles in mice.

Fig. 9.

Fig. 9

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Model for Nectin 3 function in the lens. (A) Protein interaction map of Nectin 3 and its known interacting partners, demonstrated to be expressed in the developing lens. Lines with black dots indicate direct interaction between proteins. Nectin 3 directly interacts with proteins that also function in lens development; mutations in some cause microphthalmia, lens and other ocular defects in mice. Abbr.: Lens dev., lens development; Microph, microphthalmia. (B–D) Model for how reduced PVRL3 expression may cause cataract formation. (B) The lens is composed of cells of the AEL (blue) that differentiate into fiber cells (yellow) in the posterior lens. Fiber cells in the process of elongation are apposed to cells of the AEL at their apical surfaces and come in direct contact with them through adhesive molecules (red). As these elongating fiber cells migrate to the central part of the lens, there is a rearrangement of adhesive molecules in mature fiber cells, which fuse at their anterior and basal surfaces with fiber cells from opposing ends to form sutures. Region of the anterior lens is highlighted by dashed black line in (C). (C) Nectin 3 protein is localized at the apical surface of the AEL and faces the apical surface of elongating FCs. Nectin 2 is also expressed in the AEL. Nectin 1 and 2 proteins localize to the apical surface of elongating FCs. Homo or heterophilic interactions between these molecules function to establish adherens junctions between individual cells of the AEL (Nectin 3-Nectin 3 or Nectin 3-Nectin 2 interactions), or between individual cells of the AEL and elongating FCs (Nectin 3-Nectin 2, Nectin 3-Nectin 1, Nectin 1-Nectin 2, Nectin 2-Nectin 2 interactions). Inside the cell, Nectin proteins interact with Afadin molecules (red circles) which themselves bind to F-actin (orange lines). Reduced PVRL3 expression in the AEL leads to a reduction in AEL-FC association, formation of slit-like separations and culminating in cataract formation. The model shown does not preclude an additional contribution to the lens phenotype from Nectin 3 expression in the ciliary epithelium. Abbr.: AEL, Anterior epithelium of the lens; FCs, Fiber cells; AJ, adherens junction; TJ, tight junction.

Lastly, a mechanism similar to that proposed in lens development involving defects in cell adhesion could also potentially account for the CNS phenotype in patient DGAP113. Nectin 3 is very specifically expressed in a polarized fashion long with Afadin at the apical surfaces of the ependymal cells that line the cerebral ventricles and subarachnoid space. The apical surfaces of ependymal cells are covered with the cilia and microvilli that are responsible for CSF circulation and resorption, respectively, and are also the site of tight junctions between adjacent ependynal cells. Defects at the apical surface of ependymal cells could ostensibly alter the dynamics of CSF resorption, and account for the expanded subarachnoid space phenotype in patient DGAP113.

In sum, we provide the first example of a nectin protein that is connected to human ocular disease. Data presented in this study lays the groundwork for further investigations into the function of Nectin 3 in ocular and CNS development, and into whether this function is indeed mediated through interactions with other proteins in ocular development, in particular in lens and ciliary body formation. Finally, it will be interesting to test if individuals with similar or overlapping phenotypes also have mutations in PVRL3 or in its presumptive regulatory regions.

Supplementary Material

1

ACKNOWLEDGEMENTS

We thank the subject and his relatives for participating in the Developmental Genome Anatomy Project and Heather Ferguson, Chantal Kelly and Shahrin Ahsan for assistance as study coordinators. This work was supported by NIH grants 5R01EY10123-15 (RLM), 5R01HD060050-02 (RLM), 5P01GM061354-07 (CCM, RLM, JFG, BJQ), R01EY021505 (SAL), R01EY12995 (MLR), and T35-EY07151 (QTD). All experiments comply with the current laws of the countries (U.S., Israel and Japan) in which they were performed.

Footnotes

SUPPLEMENTAL DATA

Supplemental data include five figures and one table and can be found with this article online.

The authors declare no conflicts of interest.

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