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(American Journal of Pathology. 2006;168:1288-1298.)
© 2006 American Society for Investigative Pathology

ADP-Ribosylation Factor-Like 3 Is Involved in Kidney and Photoreceptor Development

From Lexicon Genetics, Incorporated, The Woodlands, Texas

	Abstract

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ADP-ribosylation factor-like 3 (Arl3) is a member of a small subfamily of G-proteins involved in membrane-associated vesicular and intracellular trafficking processes. Genetic studies in Leishmania have shown that the Arl3 homolog is essential for flagellum biogenesis. Mutations in a related human family member, Arl6, result in Bardet-Biedl syndrome in humans, which is characterized by genital, renal, and retinal abnormalities, obesity, and learning deficits. As part of our large-scale phenotypic screen, mice deficient for the Arl3 gene were generated and analyzed. Arl3 (–/–) mice were born at a sub-Mendelian ratio, were small and sickly, and had markedly swollen abdomens. These mutants failed to thrive, and all died by 3 weeks of age. The (–/–) mice exhibited abnormal development of renal, hepatic, and pancreatic epithelial tubule structures, which is characteristic of the renal-hepatic-pancreatic dysplasia found in autosomal recessive polycystic kidney disease. Absence of Arl3 was associated with abnormal epithelial cell proliferation and cyst for-mation. Moreover, mice lacking Arl3 exhibited photoreceptor degeneration as early as postnatal day 14. These results are the first to implicate Arl3 in a ciliary disease affecting the kidney, biliary tract, pancreas, and retina.

Several mouse models develop lesions bearing a close resemblance to human PKD in terms of pathogenesis and disease progression.^3-7 These models have proven very useful in elucidating the roles of altered cell proliferation, cell differentiation, extracellular matrix composition, ionic transport, and oncogene expression in the development of PKD. The best characterized models are the congenital PKD mouse (cpk)³ and the Oak Ridge PKD mouse (Tg737/orpk).⁴ Although murine models of PKD share many features in common in the kidney, there is some variation in extrarenal cystic disease. Mandell and colleagues⁵ described a congenital polycystic kidney mutation (cpk) in the mouse that closely resembles human ARPKD because of concurrent cystogenesis in the liver and pancreas. These mutants die from a rapid progressive renal insufficiency and do not develop biliary ductal plate malformations.^6,7 PKD associated with a hypomorphic allele of the Tg737 polaris gene also closely resembles the clinical features of human ARPKD. The (Tg737/orpk) mutants develop renal cysts, biliary-dysgenesis, pancreatic cysts, and skeletal defects.⁸ In addition to these defects, the targeted deletion of the Tg737 gene causes loss of embryonic nodal cilia, disruption of LR axis specification, and embryonic lethality.⁸

Many of the proteins involved in human PKDs have been localized to the primary cilia, including PKD1, PKD2,^9,10 fibrocystin,¹¹ and inversin.¹² Similarly, PKD-related proteins in mice (polycystin-1 and -2, cystin, and polaris) have also been localized to the primary cilia.^9,13 These findings suggest that the primary cilium plays a key role in normal physiological functions of renal epithelia and that defects in ciliary function contribute to the pathogenesis of PKD. In particular, in the renal tubule lumen, the projecting primary cilia are believed to act in a sensory role in cilia function.¹⁴ More recently others have suggested that the intraflagellar transport protein, IFT88, and the Caenorhabditis elegans homolog of Tg737 are essential for photoreceptor assembly and maintenance.^14-16 Here the localized protein expression in cilia coupled with the process of intraflagellar transport (IFT), which involves the transport of cargo from the axoneme to the flagellar or cilia tip, is associated with Tg737/polaris protein function. Proper assembly and maintenance of cilia or flagella are dependent on IFT.^17,18

The ADP-ribosylation factors (ARFs) and ARF-like (ARL) proteins are small GTP-binding proteins that regulate a wide variety of intracellular signaling and vesicular trafficking pathways¹⁹ that may include the movement of cellular components within cilia.²⁰ Relatively little has been reported about the in vivo function or the physiological role of Arl3. Arl3 is a Ras-related small GTP-binding protein, is similar to other ADP-ribosylation factor (ARF) family members, binds guanine nucleotides, but lacks ARF activity.²¹ Interestingly, an Arl3 homolog has been localized within the Leishmania flagella and is essential for flagellum biogenesis.²² In addition, Arl3 is found in the ciliary compartment groups implicated in outer segment development and ciliogenesis²³ as well as in humans in the connecting cilium of retinal photoreceptor cells.²⁴ Arl3 has been shown to interact with the X-linked retinitis pigmentosa protein (RP2), and mutations in RP2 result in a severe form of retinal degeneration involving the rod photoreceptors.²⁵ This association suggests the possibility that Arl3 dysfunction might also be involved in the pathobiology of retinal degenerative diseases.

Using embryonic stem (ES) cells derived from the OmniBank gene-trap library,²⁶ we have discovered a PKD defect and abnormal photoreceptor development in mice lacking Arl3. These results provide the first genetic evidence that Arl3 is associated with PKD and implicate Arl3 in photoreceptor development. We describe these pleiotropic defects, which implicate Arl3 as another genetic model that supports a growing ciliary-related disease paradigm.

	Materials and Methods

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Generation of Arl3 Mutant ES Cells and Mice

The construction of the OmniBank gene-trap library has been described.^26,27 Arl3 mutant mice were generated by microinjection of OST 263303 ES cells into host blastocysts using standard methods.²⁸ The precise genomic insertion site of the retroviral gene-trapping vector in the Arl3 gene was determined by inverse genomic polymerase chain reaction (PCR).²⁹

Mouse Genotyping

Oligonucleotide primers (LTR2, 5'-AAATGGCGTTACTTAAGCTAGCTTGC-3'; A 5'-GGTCATCTGGCCCATAACTAATCA-3'; and B 5'-CCGGGACTGGAGTTAGTAGTGGTT-3') were used in a multiplex reaction to amplify corresponding Arl3 alleles (wild-type, +/+; mutant, –/–). Diluted mouse tail lysate containing 20 ng of genomic DNA was used as a template for PCR in a 50-µl reaction volume containing 3.5 mmol/L MgCl₂. PCR conditions were as follows: 94°C for 15 seconds, 65°C for 30 seconds (then decrease 1°C per cycle), 72°C for 40 seconds, for 10 cycles; followed by 94°C for 15 seconds, 55°C for 30 seconds, 72°C for 40 seconds, for 30 cycles. Amplified products were separated on 3% agarose gels.

Arl3 Reverse Transcriptase (RT)-PCR

RNA was extracted from kidney and spleen using a bead homogenizer and RNAzol (Ambion, Austin, TX) according to the manufacturer’s instructions. Reverse transcription was performed with SuperScript II (Invitrogen, Carlsbad, CA) and random hexamer primers, according to the manufacturer’s instructions. PCR amplification (95°C, 30 seconds; 59°C, 45 seconds; 70°C, 60 seconds.) was performed for 30 cycles using primers complementary to exons 1 and 2 of the Arl3 gene, flanking the insertion site of the vector (primer C: 5'-GCGGAGG AGGAGGAGGAGGGACTCG-3', primer D: 5'-GTAGTCTTGCCCGCG TTGTCCA-3'). Control primers to the mouse ß-Actin gene (accession number M12481) were 5'-GGCTGGCCGGGACCTGACGGACTACCTCAT-3' and 5'-GCCTAGA AGCACTTGC GGTGCACGATGGAG-3'. Arl3 RT-PCR products were verified by sequencing.

Mouse Husbandry

Mice were housed in a barrier facility at 24°C on a fixed 12-hour light/dark cycle and were fed rodent chow no. 5001 (Purina, St. Louis, MO) ad libitum. Procedures involving animals were conducted in conformity with Institutional Animal Care and Use Committee guidelines that are in compliance with state and federal laws and the standards outlined in the Guide for the Care and Use of Laboratory Animals (National Research Council, 1996).

Tissue Pathology

Tissues were collected from knockout mice and age-matched control mice up to 3 weeks of age and were immersion-fixed in 10% neutral buffered formalin. All tissues were embedded in paraffin, sectioned at 4 µm, mounted on positively charged glass slides (Superfrost Plus; Fisher Scientific, Pittsburgh, PA) and stained with hematoxylin and eosin (H&E) for histopathological examination. Immunohistochemistry was also performed on formalin-fixed, paraffin-embedded tissues. We detected proliferating cells using antibodies to Ki-67 protein.

Ki-67 Immunohistochemistry

For immunohistochemistry, 4-µm sections were first deparaffinized in xylene and rehydrated in phosphate-buffered saline (PBS); then endogenous peroxidase activity was blocked by incubation in 3.0% hydrogen peroxide in PBS for 5 minutes. For antigen retrieval, sections were immersed in citrate buffer (pH 6.0) for 20 minutes in a steamer preheated to 95°C. Primary antibody (1:30 rat anti-mouse Ki-67; DAKO, Glostrup, Denmark) was applied for 1 hour. After rinsing, sections were incubated for 1 hour in a 1:400 dilution of the biotinylated secondary antibody (rabbit anti-rat IgG; Vector Laboratories, Burlingame, CA). Bound antibodies were detected by an avidin-biotin complex method (Elite ABC kit, Vector Laboratories) with 3,3'-diaminobenzidine as chromogenic substrate following the manufacturer’s instructions. Negative controls included substitution of nonimmune serum for the primary antibody and omission of the primary antibody. After counterstaining with hematoxylin, sections were mounted with Permount (Fisher Scientific).

Ophthalmic Histopathology

Ophthalmic histopathology was conducted on mice at different postnatal ages. Mice were euthanized, and eyes were removed and placed in Davidson’s fixative (Poly Scientific, Bayshore, NY) overnight at room temperature. The following morning, eyes were processed in paraffin, cut at a thickness of 5 µm, and stained with H&E. For immunohistochemistry, mice were deeply anesthetized with (per) ketamine (7.5 mg/ml), xylazine (0.38 mg/ml), and acepromazine (0.074 mg/ml), delivered at 10 ml/kg body weight followed by perfusion with 4% paraformaldehyde in 0.1 mol/L sodium phosphate-buffered saline (PBS) (pH 7.2). Eyes were removed and incubated in PBS containing 25% sucrose and embedded in tissue-freezing medium (Triangle Biomedical Sciences, Durham, NC). Sections were cut at a thickness of 12 to 16 µm and mounted on Fisher Superfrost/Plus slides.

Fluorometric Terminal dUTP Nick-End Labeling (TUNEL), Anti-Rhodopsin, and PNA Assays

Dying cells were detected using the Dead-End fluorometric TUNEL system (catalog no. G3250; Promega, Madison, WI) per the manufacture’s recommendations. Primary antibodies were diluted in 5% normal goat serum (Vector Laboratories) in PBS. Dilutions were as follows: mouse anti-rhodopsin at 1:100,000 (Chemicon, Temecula, CA) and fluorescein-conjugated peanut agglutinin (PNA) at 1:250 (Vector Laboratories). Alexa 594 goat anti-mouse (diluted at 1:400) was used to detect primary mouse antibodies. Coverslips were applied using mounting media (Vectashield, Vector Laboratories). Digital images were obtained with a Hamamatsu ORCA II cooled charge-coupled device camera mounted on an Olympus BX60 microscope. Images were acquired in Adobe Photoshop version 6.0 and saved at a resolution of 300 ppi. Figures were assembled in Photoshop, and minimal adjustments were made to the figure contrast to obtain the best micrograph.

Electron Microscopy Studies

For the electron microscopy studies, mice at postnatal day 9 were anesthetized as described above and perfused with 3.5% glutaraldehyde in 0.1 mol/L phosphate buffer. Eyes were removed, and retinas were incubated in the same fixative overnight. Tissue was then incubated in 2% osmium tetroxide, stained with 2% uranyl acetate, and embedded in Spurr’s resin. Semithin sections were stained with 1% toluidine blue. Ultrathin sections were obtained and collected in formvar-coated slot grids and subsequently stained with lead citrate.

	Results

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Mouse ES Cells

ES cells carrying a mutation in the Arl3 gene (accession number NM_019718) were obtained from OmniBank, a library of gene-trapped ES cell clones identified by a corresponding OmniBank Sequence Tag (OST).^26,27 Inverse genomic PCR²⁹ analysis of DNA from this clone confirmed the insertion of the gene-trapping retroviral vector in intron 1 of the Arl3 gene on chromosome 19, downstream of the initiation codon in exon 1 (Figure 1A) . OST 263303 cells were used to generate mice heterozygous for the Arl3 mutation using standard methods,²⁸ and genotypes were confirmed by multiplex PCR on genomic DNA (Figure 1B) . Interbreeding of Arl3 heterozygote mice gave rise to fewer (–/–) animals than predicted by a standard Mendelian distribution with 56 wild-type (+/+), 90 heterozygous (+/–), and 20 homozygous (–/–) mice. We confirmed the disruption of Arl3 transcription by the gene-trapping vector by reverse transcriptase (RT)-PCR using primers complementary to Arl3 exons 1 and 2, flanking the site of integration of the vector. Arl3 (+/+) transcript was not detected in tissues of Arl3 (–/–) mice (Figure 1C) .

View larger version (37K): [in this window] [in a new window]   Figure 1. A: Gene trap mutation of the Arl3 gene. SA, splice acceptor sequence; Neo, neomycin resistance gene (arrow indicates transcription start site). B: Genotyping strategy. Primers A and B flank the genomic insertion site in intron 1 and amplify a product for the (+/+) allele. The LTR2 primer, complementary to the gene-trapping vector, and primer B amplify the mutated allele. C: Arl3 RT-PCR. Primers C and D are complementary to Arl3 exons 1 and 2 flanking the insertion site of the gene-trapping vector. RT-PCR using primers C and D shows absence of endogenous message in the kidney and spleen of (–/–) animals. RT, reverse transcription.

Male and female (–/–) Arl3 mice were identifiable within a few days of birth by a pronounced distention of their flanks caused by severe bilateral renomegaly (Figure 2, A and B) . The Arl3 (+/–) mice were normal in all phenotypic screens between 8 to 16 weeks of age (data not shown). This analysis included observations in radiology, immunology, blood chemistry, behavior, and cardiology. Grossly, all Arl3 (–/–) mice exhibited abnormal development of renal, hepatic, and pancreatic epithelial tubule structures, characteristic of the renal-hepatic-pancreatic dysplasia reported in ARPKD. The renal cysts continued to enlarge after birth and the mice were euthanized before reaching 3 weeks of age (Figure 2, C and D) . The kidneys were uniformly enlarged, light tan to white in color, and had a spongy consistency. Innumerable translucent and minute cystic structures were observed throughout the renal cortex and medulla. The gall bladder was severely distended, and extrahepatic bile ducts were dilated. In the liver the portal tracts were prominent. The pancreas was very small and consisted of dilated ducts and cysts surrounded by reduced amounts of parenchymal tissue. All other tissues examined displayed no pathologies and no laterality defects were seen in the (–/–) Arl3 mice.

View larger version (83K): [in this window] [in a new window]   Figure 2. A: A normal age-matched (+/+) mouse on the bottom shows the small size of Arl3 (–/–) on top with distended sides. B: A typical Arl3 (–/–) mouse at 3 weeks of age is shown, note the enlarged flanks. C: An Arl3 (+/+) mouse is shown for comparison. D: In the Arl3 (–/–) mouse, the pronounced distention of the flanks was caused by severe bilateral renomegaly (1.2 x 1 x 1 cm, white arrows). The kidneys were uniformly enlarged by innumerable translucent and minute cystic structures throughout the organ. The pancreatic ducts, gall bladder, and bile ducts were enlarged and tortuous (red arrows).

View larger version (133K): [in this window] [in a new window]   Figure 3. Representative photomicrographs of kidneys, pancreas, and liver from Arl3 (+/+) and (–/–) mice at postnatal day 10. A: In (+/+) mice, there are numerous Ki-67-positive cells in the densely packed cortical tubules of the kidney. Note the relative absence of staining in the medulla and papilla. The inset shows at higher magnification the marked difference in cortical and medullary staining. B: In (–/–) mice, there are myriad fluid-filled cysts in both the cortex and medulla. These cysts involve all segments of the nephron, including proximal and distal tubules, collecting ducts, and even glomerular Bowman’s spaces (black arrows). C: In Arl3 (–/–) mice, numerous proliferating cells are present in cystic collecting ducts as well as cortical tubules as shown by Ki-67 staining (brown). D: Prominent lesions in the pancreas of Arl3 knockout mice include widespread cystic dilatation of intralobular pancreatic ducts accompanied by atrophy and loss of exocrine pancreas tissue. Note the disorganized, small, irregular nests of exocrine cells surrounded by loose interstitial tissues (red arrows). E: In many cystic pancreatic ducts, more than 80% of the epithelial cells were Ki-67-positive. F: Scattered individual cells lining the cystic pancreatic ducts were positive for insulin by immunohistochemistry. G: Liver section from Arl3 (+/+) mice shows the normal diameter of intrahepatic bile ducts. H: In Arl3 (–/–) mice, the intrahepatic bile ducts were often distorted by multiple segmental and saccular dilatations. Scale bars, 100 µm (E, G, and H).

Immunohistochemical detection of Ki-67, a nuclear nonhistone protein present only in proliferating cells, revealed significant differences between postnatal day 9 (–/–) Arl3 knockout mice and age-matched (+/+) controls in the kidneys, gall bladder, extrahepatic common bile ducts, and pancreatic ducts. As expected in rapidly growing mice of this age, proliferating cells (Ki-67-positive) were numerous in the renal cortex of both (+/+) and (–/–) mice. However, marked differences between (–/–) mice and (+/+) mice were noted in the collecting duct epithelium of the renal medulla and papilla. In (+/+) littermates, Ki-67-positive cells were relatively rare in the kidney medulla (Figure 3A) . In contrast, in Arl3 knockout mice, numerous proliferating cells lined the cystic medullary collecting ducts as well as the cortical tubules and cystic glomeruli (Figure 3C) .

Pancreatic Lesions and Immunohistochemical Detection of Ki-67 Antibody

Prominent lesions were also present in the pancreas of Arl3 knockout mice. There was a marked reduction in total pancreatic mass because of atrophy and hypoplasia of exocrine pancreas tissue. Distinct pancreatic lobules were absent, and most remaining pancreatic acini were disorganized and consisted of small irregular nests of cells surrounded by loose interstitial tissues (Figure 3D) . There was widespread cystic dilatation of intralobular pancreatic ducts, and in some areas the duct walls were thickened by an inflammatory infiltrate and fibrosis. Immunohistochemistry showed that there were very few Ki-67-positive epithelial cells lining the normal pancreatic ducts of (+/+) mice (not shown). However, in some areas of the (–/–) mice, more than 80% of the cystic pancreatic duct epithelial cells were Ki-67-positive (Figure 3E) . These results are consistent with an association between widespread cystic dilatation of pancreatic ducts and increased cell proliferation. Interestingly, even with the atrophy and loss of exocrine pancreas tissue, a few of the cells lining the cystic pancreatic ducts were also positive for insulin (Figure 3F) .

Biliary Lesions and Immunohistochemical Detection of Ki-67 Antibody

In all (–/–) mice, gross and microscopic lesions consistent with ductal plate malformation were present in the biliary tract. The most notable lesion was the massive distention of the gall bladder and extrahepatic common bile ducts. Within the portal areas of the liver, there were increased numbers of intrahepatic bile ducts that were often distorted by multiple segmental and saccular dilatations (Figure 3H) . In most areas, there was only a slight increase in periductular connective tissue. However, in some areas the dilated bile ducts contributed to stagnation of bile and ascending bacterial infections, resulting in a multifocal acute suppurative cholangitis. Portal inflammation and fibrosis were present in the areas where dilated intrahepatic bile ducts were filled with degenerating neutrophils and bacteria. In Arl3 knockout mice, Ki-67 immunohistochemistry labeled the majority of epithelial cells lining the gall bladder and some extrahepatic bile ducts but relatively few cells lining the intrahepatic ducts. In contrast, in (+/+) littermates (not shown), few cells lining the gall bladder or extrahepatic biliary ducts were Ki-67-positive. This again suggests that rapid cell proliferation promotes the massive distention of the gall bladder and extrahepatic common bile ducts. Overall, these results indicate that the pathological deterioration of Arl3 neonates is because of abnormal duct development in the kidney, liver, and pancreas.

Ophthalmological Histopathology

The general histological appearance of retinas obtained from (–/–) mice is similar to that in either (+/+) or (+/–) littermates at postnatal day 7 (not shown) or postnatal day 9 (Figure 4) . The ganglion cell layer and inner nuclear layer (INL) are apparent, and the outer nuclear layer (ONL) is populated with photoreceptors in both the (+/+) (Figure 4A) and (–/–) mice (Figure 4B) . At the light microscopic level, developing inner segments (ISs) and outer segments (OSs) of photoreceptors are apparent above the ONL in (+/+) mice (Figure 4A) . In contrast, at postnatal day 9 the ISs and OSs appear rudimentary at this age in mice lacking Arl3 (Figure 4B) compared to those of (+/+) controls.

View larger version (163K): [in this window] [in a new window]   Figure 4. Histological and ultrastructural appearance of retinas obtained from postnatal day 9 mice. A: (+/+) Retina stained with H&E reveals three cellular layers (ONL, outer nuclear layer; INL, inner nuclear layer; and GCL, ganglion cell layer). Photoreceptors are located in the ONL and their inner segments (IS) and outer segments (OS) are located directly beneath the retinal pigment epithelium (RPE). B: Three cell layers are apparent in mice lacking Arl3. However, the region containing the OS and IS appears shortened at this age. C: Electron microscopy of (+/+) outer retina at postnatal day 9. Photoreceptor ISs are located above the outer limiting membrane (OLM) and contain basal bodies (arrow). Connecting cilia (arrowheads) are also prominent at this age. Developing OS disks (asterisks) are located beneath the retinal pigment epithelium (RPE). Scale bar represents 50 µm in A, B and 2 µm in C, D. D:Mice lacking Arl3 exhibit a paucity of OS disks, although basal bodies (arrow) are present.

At postnatal day 13 cone OSs can be identified with peanut agglutinin stain (PNA) conjugated to fluorescein. In (+/+) mice PNA reacted strongly with both the IS and OS associated with cone photoreceptors (Figure 5A) . In contrast, (–/–) animals lacked any detectable cone OSs, although ISs were strongly labeled with PNA (Figure 5B) . Rods were examined with an antibody recognizing rhodopsin. In (+/+) mice intense rhodopsin immunoreactivity was associated with rod OSs (Figure 5C) . Weaker immunoreactivity was detected in IS at the dilutions of the antibody used in these studies. In contrast, intense rhodopsin immunoreactivity was associated with cell bodies of rod photoreceptors in mice lacking Arl3 (Figure 5D) . Specific labeling of rod OSs was not observed in the region located adjacent to the retinal pigment epithelium. These results suggest that development of both rods and cones is impaired in mice lacking Arl3.

View larger version (39K): [in this window] [in a new window]   Figure 5. Analysis of cone and rod photoreceptors in retinas obtained from postnatal day 13 mice. Cones were visualized in the (+/+) (A) or (–/–) (B) retina with PNA conjugated to fluorescein. In (+/+) retina, the OS and IS located beneath the retinal pigment epithelium are intensely labeled with PNA. In contrast, only cone ISs are apparent in mice lacking Arl3. C and D: Rods were labeled with an antibody specific for rhodopsin. C: In (+/+) retinas, strong rhodopsin immunoreactivity is present in OSs located directly above the IS. This reactivity corresponds to the rod OS disks. D: (–/–) animals failed to shown specific OS staining. Rod photoreceptor cell bodies were strongly reactive for rhodopsin antibodies, indicating an accumulation of this photopigment in the absence of Arl3. Scale bar, 75 µm (B).

View larger version (83K): [in this window] [in a new window]   Figure 6. TUNEL-histochemistry on sections obtained from postnatal day 13 mice. A: Nomarski image of the (+/+) retina shown in B. The optic nerve head is at the top left of the image. B: Several TUNEL-positive cells (arrowheads) are present in the INL at this age. These cells represent naturally occurring cell death during retinal development. C: Nomarski image of the (–/–) retina shown in D. D: Many TUNEL-positive cells (arrowheads) are located in the ONL in the absence of Arl3. TUNEL-positive cells in the INL (arrows) are also present, but their density appears similar to the (+/+) shown in B. Scale bar, 100 µm (D).

	Discussion

Top Abstract Materials and Methods Results Discussion References

Mutations that disrupt the assembly and/or physiological function of the primary apical cilium of tubular epithelia have been shown to be involved in the pathogenesis of PKD. Human proteins involved in PKD have been localized to the primary cilia, including PKD1, PKD2,^9,10 fibrocystin,¹¹ and inversin.¹² Likewise, murine PKD-related proteins polycystin-1 and -2, cystin, and polaris have also been localized to the primary cilia.^9,13 In fact, most of the identified human genes disrupted in PKD encode proteins that have been localized to the primary cilia of renal tubular epithelial cells.^36,37 A role for specialized primary cilia has been proposed for the chemosensory, photosensory, and mechanosensory functions of olfactory neurons, retinal photoreceptors, and renal epithelium, respectively.^33,38 We speculate that the mechanosensory renal primary cilia that respond to shear forces associated with luminal flow and thereby modulate renal tubular epithelial cell proliferation and differentiation are dysfunctional in the Arl3 mutant mice.

The primary epithelial cilium is important for differentiation of polarized epithelial cells, and both structural and functional defects in cilia result in PKD.¹³ The role of primary cilia in the pathogenesis of PKD was first suggested by findings in Tg737/orpk mice. Mutation of polaris (Tg737/orpk), which is localized in ciliary axonemes and basal bodies, interferes with the assembly of primary cilia, resulting in short stunted primary cilia in the kidney, retina, and at the embryonic node.^16,34 The assembly, maintenance, and function of cilia depend on IFT particles or rafts containing protein cargo that are transported bidirectionally along the ciliary axoneme.³⁹ Kinesin-II, a motor protein, moves anterograde to the tip of the cilium. The tissue-specific inactivation of the kinesin KIF3A subunit abolishes anterograde transport and results in viable offspring dying of PKD by 21 days.⁴⁰ The morphologically normal cilia of cpk (cystin), inv (inversin), and Pkd2 mutant mice^12,35,41,42 are co-localized to the primary cilia, and cystin expression overlaps with polaris.^13,43 Moreover, fibrocystin co-localizes with polycystin-2 in the basal bodies and primary cilia of renal cells. Arl3’s status as a small GTP-binding protein suggests that it may regulate intracellular signaling, vesicular trafficking pathways,¹⁹ and/or movement of cellular components within or along cilia.²⁰ We speculate that Arl3 may serve as a regulator in the process to polarize the ciliated epithelial cells and prevent mislocalization of critical proteins via IFT. Our observation of the mislocalization of rhodopsin in Arl3 (–/–) rod cell bodies supports this hypothesis.

Controlled proliferation and differentiation of epithelial cells is critical for the maintenance of normal renal tubule diameter and structure. It is believed that structural and/or functional defects in the mechanosensory primary apical cilia disrupt normal cell cycle regulation or differentiation of renal epithelial cells. Our findings of increased cell proliferation in the collecting ducts of the kidney and in the cystic pancreatic ducts, external hepatic ducts, and gall bladder (Figure 3, D and E) are consistent with the hypothesis that PKD is the result of disrupted cell-cycle regulation and differentiation of renal epithelial cells. Interestingly, primary cilia may have a sensory function that helps to regulate intracellular calcium concentration ([Ca²⁺]_i) and maintain the differentiated renal epithelial phenotype.⁴⁴ Maintenance of this phenotype is characterized by controlled fluid secretion and cell proliferation requiring precise functional coordination of cAMP and Ras/Raf/MEK/ERK signaling by [Ca²⁺]_i. Primary cilia-localized proteins mutated in human ADPKD and ARPKD, as well as in several animal models, are thought to have a sensory function and contribute to the regulation of the ([Ca²⁺]_i). Therefore, the mutations causing PKD may hinder the negative feedback mechanism controlling cAMP and Ras/Raf/MEK/ERK signaling and result in increased fluid secretion and cell proliferation. Arl3 is an Arf subfamily member of the Ras protein superfamily, so it will be interesting to study the potential for aberrant signaling by [Ca²⁺]_i in the Arl3 (–/–) mouse.

The importance of abnormal proliferation and/or differentiation of renal epithelium in the pathogenesis of PKD has been noted in many systems. Cell responses to the primary cilia mechanoreceptors appear to help maintain the ratio of normal tubule-duct diameter to luminal flow by modulating epithelial cell proliferation and differentiation. With dysfunctional or absent primary cilia, the loss of sensory signals that normally inhibits cell proliferation may give rise to increased cell division and tubular dilatation. For example, renal cells lacking functional mouse KIF3A do not have primary cilia and exhibit increased proliferation and apoptosis, apical mislocalization of the epidermal growth factor receptor, increased expression of ß-catenin and c-myc, and inhibition of p21(CIP1).⁴⁰ In human ADPKD, elevated expression levels of the proto-oncogene c-myc expression are also seen.⁴⁵ Rodent models of PKD using transgenic mice overexpressing c-myc in the renal tubular epithelium correlate with increased proliferation rates.^45,46 Our findings in the Arl3 (–/–) mice showing that tubular dilatation is associated with proliferation of cells lining the collecting ducts (Figure 3C) , suggests a role for Arl3 in modulating cell proliferation.

The association of renal and retinal diseases with ciliary dysfunction is becoming increasingly more appreciated.⁴⁷ Several lines of circumstantial data suggest that Arl3 might be important for retinal photoreceptor biology. Arl3 is predominantly localized in the connecting cilia in both rod and cone photoreceptors and co-localizes with microtubules in vitro.²⁴ Moreover, Arl3 interacts with the retinitis pigmentosa protein 2 (RP2), a plasma membrane-associated protein whose molecular function remains to be identified.²⁴ Mutations in RP2 cause X-linked retinitis pigmentosa (XLRP), a genetically heterogeneous disease resulting in severe retinal degeneration.²⁵ Recombinant Arl3 also interacts with the delta subunit of rod-specific cyclic GMP phosphodiesterase, a key effector molecule in visual transduction.⁴⁸

The most striking features of the retina in mice lacking Arl3 are the abundance of TUNEL-positive photoreceptors and rhodopsin mislocalization in rod cell bodies. These defects are not attributable to a lack of connecting cilia in photoreceptors because basal bodies and connecting cilia are discernible at the ultrastructural level in mice deficient in Arl3. Rhodopsin synthesis and transport to the OS is an area of intense investigation and the fact that mutations in the rhodopsin gene that affect trafficking to OSs cause retinitis pigmentosa in humans.⁴⁹ Rhodopsin is packed in vesicles and transported from the Golgi apparatus to the distal end of the IS. Rhodopsin vesicles appear to fuse with the plasma membrane at the level of the basal bodies. Genetic evidence and immunoelectron microscopy have revealed several proteins involved in active transport of opsins from the IS to the OS.⁵⁰ Rhodopsin mislocalization to cell bodies implies that Arl3 may facilitate transport of this photopigment from the Golgi apparatus to the connecting cilia.

Some of the Arls have been localized to the Golgi apparatus, others such as Arl3 have been associated with microtubules and mutations in related proteins in several species result in abnormal vesicle trafficking. Photoreceptor disks and visual pigments are transported via the connecting cilium (photosensory primary cilia) at a rapid rate, and this transportation is dependent on IFT.¹⁷ This study does not address the precise cellular function of Arl3, but in light of the mislocalization of rhodopsin, we speculate that Arl3 regulates the trafficking of proteins critical for the function and maintenance of photoreceptor OSs. Although only rhodopsin was studied here, it is likely that disruption of Arl3 function impairs transport of other proteins into rods and cones as well. Nevertheless, the lack of obvious OSs and abnormally shortened ISs in our findings demonstrates that Arl3 is required for photoreceptor development and survival.

Our data indicate that Arl3 is important in renal, liver, and pancreatic function as well as photoreceptor development. We have presented here a mouse model with PKD and photoreceptor defects that we suggest are attributable to abrogated mechanosensory and photosensory cilia function. The presence of apparently normal cilia in the Arl3 (–/–) mice suggests that the primary defect is not structurally defective cilia, but that Arl3 function may be critical for proper regulation of the intracellular transport process and/or Ca⁺⁺ signaling and proliferation. The Arl3 (–/–) knockout mouse model provides a useful tool for further studies of PKD, photoreceptor development, and the potential role of primary ciliary function in a wide variety of disease states.

	Acknowledgements

 
We thank Drs. Alex Turner, Liz Richter, and the external reviewers for their thoughtful suggestions and critical reading of this manuscript; and Laura Kirkham and Jeni Hyland for their careful attention to animal care and breeding.

	Footnotes

 
Address reprint requests to Jeffrey J. Schrick, Lexicon Genetics Inc., 8800 Technology Forest Pl., The Woodlands, TX 77381. E-mail: jschrick{at}lexgen.com

Supported by Lexicon Genetics, Incorporated.

Accepted for publication December 20, 2005.

	References

Top Abstract Materials and Methods Results Discussion References

 

1. Zerres K, Rudnik-Schoneborn S, Senderek J, Eggermann T, Bergmann C: Autosomal recessive polycystic kidney disease (ARPKD). J Nephrol 2003, 16:453-458[Medline]
2. Zerres K, Rudnik-Schoneborn S, Steinkamm C, Becker J, Mucher G: Autosomal recessive polycystic kidney disease. J Mol Med 1998, 76:303-309[CrossRef][Medline]
3. Preminger GM, Koch WE, Fried FA, McFarland E, Murphy ED, Mandell J: Murine congenital polycystic kidney disease: a model for studying development of cystic disease. J Urol 1982, 127:556-560[Medline]
4. Moyer JH, Lee-Tischler MJ, Kwon HY, Schrick JJ, Avner ED, Sweeney WE, Godfrey VL, Cacheiro NL, Wilkinson JE, Woychik RP: Candidate gene associated with a mutation causing recessive polycystic kidney disease in mice. Science 1994, 264:1329-1333[Abstract/Free Full Text]
5. Mandell J, Koch WK, Nidess R, Preminger GM, McFarland E: Congenital polycystic kidney disease. Genetically transmitted infantile polycystic kidney disease in C57BL/6J mice. Am J Pathol 1983, 113:112-114[Medline]
6. Gattone VH, II, MacNaughton KA, Kraybill AL: Murine autosomal recessive polycystic kidney disease with multiorgan involvement induced by the cpk gene. Anat Rec 1996, 245:488-499[CrossRef][Medline]
7. Guay-Woodford LM, Green WJ, Lindsey JR, Beier DR: Germline and somatic loss of function of the mouse cpk gene causes biliary ductal pathology that is genetically modulated. Hum Mol Genet 2000, 9:769-778[Abstract/Free Full Text]
8. Murcia NS, Richards WG, Yoder BK, Mucenski ML, Dunlap JR, Woychik RP: The Oak Ridge polycystic kidney (orpk) disease gene is required for left-right axis determination. Development 2000, 127:2347-2355[Abstract]
9. Yoder BK, Hou X, Guay-Woodford LM: The polycystic kidney disease proteins, polycystin-1, polycystin-2, polaris, and cystin, are co-localized in renal cilia. J Am Soc Nephrol 2002, 13:2508-2516[Abstract/Free Full Text]
10. Nauli SM, Alenghat FJ, Luo Y, Williams E, Vassilev P, Li X, Elia AE, Lu W, Brown EM, Quinn SJ, Ingber DE, Zhou J: Polycystins 1 and 2 mediate mechanosensation in the primary cilium of kidney cells. Nat Genet 2003, 33:129-137[CrossRef][Medline]
11. Ward CJ, Yuan D, Masyuk TV, Wang X, Punyashthiti R, Whelan S, Bacallao R, Torra R, LaRusso NF, Torres VE, Harris PC: Cellular and subcellular localization of the ARPKD protein; fibrocystin is expressed on primary cilia. Hum Mol Genet 2003, 12:2703-2710[Abstract/Free Full Text]
12. Morgan D, Eley L, Sayer J, Strachan T, Yates LM, Craighead AS, Goodship JA: Expression analyses and interaction with the anaphase promoting complex protein Apc2 suggest a role for inversin in primary cilia and involvement in the cell cycle. Hum Mol Genet 2002, 11:3345-3350[Abstract/Free Full Text]
13. Hou X, Mrug M, Yoder BK, Lefkowitz EJ, Kremmidiotis G, D’Eustachio P, Beier DR, Guay-Woodford LM: Cystin, a novel cilia-associated protein, is disrupted in the cpk mouse model of polycystic kidney disease. J Clin Invest 2002, 109:533-540[CrossRef][Medline]
14. Haycraft CJ, Swoboda P, Taulman PD, Thomas JH, Yoder BK: The C. elegans homolog of the murine cystic kidney disease gene Tg737 functions in a ciliogenic pathway and is disrupted in osm-5 mutant worms. Development 2001, 128:1493-1505[Abstract]
15. Pazour GJ, Baker SA, Deane JA, Cole DG, Dickert BL, Rosenbaum JL, Witman GB, Besharse JC: The intraflagellar transport protein, IFT88, is essential for vertebrate photoreceptor assembly and maintenance. J Cell Biol 2002, 157:103-113[Abstract/Free Full Text]
16. Pazour GJ, Rosenbaum JL: Intraflagellar transport and cilia-dependent diseases. Trends Cell Biol 2002, 12:551-555[CrossRef][Medline]
17. Eley L, Turnpenny L, Yates LM, Craighead AS, Morgan D, Whistler C, Goodship JA, Strachan T: A perspective on inversin. Cell Biol Int 2004, 28:119-124[CrossRef][Medline]
18. Sloboda RD: Intraflagellar transport and the flagellar tip complex. J Cell Biochem 2005, 94:266-272[CrossRef][Medline]
19. Memon AR: The role of ADP-ribosylation factor and SAR1 in vesicular trafficking in plants. Biochim Biophys Acta 2004, 1664:9-30[Medline]
20. Takai Y, Sasaki T, Matozaki T: Small GTP-binding proteins. Physiol Rev 2001, 81:153-208[Abstract/Free Full Text]
21. Cavenagh MM, Breiner M, Schurmann A, Rosenwald AG, Terui T, Zhang C, Randazzo PA, Adams M, Joost HG, Kahn RA: ADP-ribosylation factor (ARF)-like 3, a new member of the ARF family of GTP-binding proteins cloned from human and rat tissues. J Biol Chem 1994, 269:18937-18942[Abstract/Free Full Text]
22. Cuvillier A, Redon F, Antoine JC, Chardin P, DeVos T, Merlin G: LdARL-3A, a Leishmania promastigote-specific ADP-ribosylation factor-like protein, is essential for flagellum integrity. J Cell Sci 2000, 113:2065-2074[Abstract]
23. Avidor-Reiss T, Maer AM, Koundakjian E, Polyanovsky A, Keil T, Subramaniam S, Zuker CS: Decoding cilia function: defining specialized genes required for compartmentalized cilia biogenesis. Cell 2004, 117:527-539[CrossRef][Medline]
24. Grayson C, Bartolini F, Chapple JP, Willison KR, Bhamidipati A, Lewis SA, Luthert PJ, Hardcastle AJ, Cowan NJ, Cheetham ME: Localization in the human retina of the X-linked retinitis pigmentosa protein RP2, its homologue cofactor C and the RP2 interacting protein Arl3. Hum Mol Genet 2002, 11:3065-3074[Abstract/Free Full Text]
25. Schwahn U, Lenzner S, Dong J, Feil S, Hinzmann B, van Duijnhoven G, Kirschner R, Hemberger M, Bergen AA, Rosenberg T, Pinckers AJ, Fundele R, Rosenthal A, Cremers FP, Ropers HH, Berger W: Positional cloning of the gene for X-linked retinitis pigmentosa 2. Nat Genet 1998, 19:327-332[CrossRef][Medline]
26. Zambrowicz BP, Friedrich GA, Buxton EC, Lilleberg SL, Person C, Sands AT: Disruption and sequence identification of 2,000 genes in mouse embryonic stem cells. Nature 1998, 392:608-611[CrossRef][Medline]
27. Zambrowicz BP, Abuin A, Ramirez-Solis R, Richter LJ, Piggott J, BeltrandelRio H, Buxton EC, Edwards J, Finch RA, Friddle CJ, Gupta A, Hansen G, Hu Y, Huang W, Jaing C, Key BW, Jr, Kipp P, Kohlhauff B, Ma ZQ, Markesich D, Payne R, Potter DG, Qian N, Shaw J, Schrick J, Shi ZZ, Sparks MJ, Van Sligtenhorst I, Vogel P, Walke W, Xu N, Zhu Q, Person C, Sands AT: Wnk1 kinase deficiency lowers blood pressure in mice: a gene-trap screen to identify potential targets for therapeutic intervention. Proc Natl Acad Sci USA 2003, 100:14109-14114[Abstract/Free Full Text]
28. Joyner AL: Gene Targeting: A Practical Approach 2000:pp 133-175 Oxford University Press Oxford
29. Orosz DE, Woost PG, Kolb RJ, Finesilver MB, Jin W, Frisa PS, Choo CK, Yau CF, Chan KW, Resnick MI, Douglas JG, Edwards JC, Jacobberger JW, Hopfer U: Growth, immortalization, and differentiation potential of normal adult human proximal tubule cells. In Vitro Cell Dev Biol Anim 2004, 40:22-34[CrossRef][Medline]
30. Obata S, Usukura J: Morphogenesis of the photoreceptor outer segment during postnatal development in the mouse (BALB/c) retina. Cell Tissue Res 1992, 269:39-48[CrossRef][Medline]
31. Farrar GJ, Kenna PF, Humphries P: On the genetics of retinitis pigmentosa and on mutation-independent approaches to therapeutic intervention. EMBO J 2002, 21:857-864[CrossRef][Medline]
32. Young RW: Cell death during differentiation of the retina in the mouse. J Comp Neurol 1984, 229:362-373[CrossRef][Medline]
33. Alenghat FJ, Nauli SM, Kolb R, Zhou J, Ingber DE: Global cytoskeletal control of mechanotransduction in kidney epithelial cells. Exp Cell Res 2004, 301:23-30[CrossRef][Medline]
34. Pazour GJ, Dickert BL, Vucica Y, Seeley ES, Rosenbaum JL, Witman GB, Cole DG: Chlamydomonas IFT88 and its mouse homologue, polycystic kidney disease gene tg737, are required for assembly of cilia and flagella. J Cell Biol 2000, 151:709-718[Abstract/Free Full Text]
35. Pazour GJ: Intraflagellar transport and cilia-dependent renal disease: the ciliary hypothesis of polycystic kidney disease. J Am Soc Nephrol 2004, 15:2528-2536[Abstract/Free Full Text]
36. Zhang Q, Taulman PD, Yoder BK: Cystic kidney diseases: all roads lead to the cilium. Physiology (Bethesda) 2004, 19:225-230[CrossRef][Medline]
37. Pan J, Wang Q, Snell WJ: Cilium-generated signaling and cilia-related disorders. Lab Invest 2005, 85:452-463[CrossRef][Medline]
38. Schwartz EA, Leonard ML, Bizios R, Bowser SS: Analysis and modeling of the primary cilium bending response to fluid shear. Am J Physiol 1997, 272:F132-F138[Medline]
39. Rosenbaum JL, Witman GB: Intraflagellar transport. Nat Rev Mol Cell Biol 2002, 3:813-825[CrossRef][Medline]
40. Lin F, Hiesberger T, Cordes K, Sinclair AM, Goldstein LS, Somlo S, Igarashi P: Kidney-specific inactivation of the KIF3A subunit of kinesin-II inhibits renal ciliogenesis and produces polycystic kidney disease. Proc Natl Acad Sci USA 2003, 100:5286-5291[Abstract/Free Full Text]
41. Ricker JL, Gattone VH, II, Calvet JP, Rankin CA: Development of autosomal recessive polycystic kidney disease in BALB/c-cpk/cpk mice. J Am Soc Nephrol 2000, 11:1837-1847[Abstract/Free Full Text]
42. Signor D, Wedaman KP, Orozco JT, Dwyer ND, Bargmann CI, Rose LS, Scholey JM: Role of a class DHC1b dynein in retrograde transport of IFT motors and IFT raft particles along cilia, but not dendrites, in chemosensory neurons of living Caenorhabditis elegans. J Cell Biol 1999, 147:519-530[Abstract/Free Full Text]
43. Watanabe D, Saijoh Y, Nonaka S, Sasaki G, Ikawa Y, Yokoyama T, Hamada H: The left-right determinant inversin is a component of node monocilia and other 9+0 cilia. Development 2003, 130:1725-1734[Abstract/Free Full Text]
44. Torres VE: Therapies to slow polycystic kidney disease. Nephron Exp Nephrol 2004, 98:e1-e7[CrossRef][Medline]
45. Trudel M, Barisoni L, Lanoix J, D’Agati V: Polycystic kidney disease in SBM transgenic mice: role of c-myc in disease induction and progression. Am J Pathol 1998, 152:219-229[Abstract]
46. Trudel M, D’Agati V, Costantini F: C-myc as an inducer of polycystic kidney disease in transgenic mice. Kidney Int 1991, 39:665-671[Medline]
47. Eley L, Yates LM, Goodship JA: Cilia and disease. Curr Opin Genet Dev 2005, 15:308-314[CrossRef][Medline]
48. Linari M, Hanzal-Bayer M, Becker J: The delta subunit of rod specific cyclic GMP phosphodiesterase, PDE delta, interacts with the Arf-like protein Arl3 in a GTP specific manner. FEBS Lett 1999, 458:55-59[CrossRef][Medline]
49. Wolfrum U, Schmitt A: Rhodopsin transport in the membrane of the connecting cilium of mammalian photoreceptor cells. Cell Motil Cytoskeleton 2000, 46:95-107[CrossRef][Medline]
50. Sung CH, Tai AW: Rhodopsin trafficking and its role in retinal dystrophies. Int Rev Cytol 2000, 195:215-267[Medline]

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