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Kidney failure in mice lacking the tetraspanin CD151

¹ Division of Cell Biology, The Netherlands Cancer Institute, 1066 CX Amsterdam, Netherlands
² Department of Pathology, Academic Medical Center, University of Amsterdam, 1105 AZ Amsterdam, Netherlands
³ Department of Otorhinolaryngology, Radboud University Nijmegen Medical Center, 6500 HC Nijmegen, Netherlands

Correspondence to Arnoud Sonnenberg: a.sonnenberg{at}nki.nl

Top Abstract Introduction Results and discussion Materials and methods References

 

The tetraspanin CD151 is a cell-surface molecule known for its strong lateral interaction with the laminin-binding integrin 3ß1. Patients with a nonsense mutation in CD151 display end-stage kidney failure associated with regional skin blistering and sensorineural deafness, and mice lacking the integrin 3 subunit die neonatally because of severe abnormalities in the lung and kidney epithelia. We report the generation of Cd151-null mice that recapitulate the renal pathology of human patients, i.e., with age they develop massive proteinuria caused by focal glomerulosclerosis, disorganization of the glomerular basement membrane, and tubular cystic dilation. However, neither skin integrity nor hearing ability are impaired in the Cd151-null mice. Furthermore, we generated podocyte-specific conditional knockout mice for the integrin 3 subunit that show renal defects similar to those in the Cd151 knockout mice. Our results support the hypothesis that CD151 plays a key role in strengthening 3ß1-mediated adhesion in podocytes.

Abbreviations used in this paper: ABR, auditory brainstem response; FP, foot process; GBM, glomerular basement membrane; GESD, glomerular epithelial slit diaphragm; pAb, polyclonal antibody.

	Introduction

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Tetraspanins form a family of small proteins that are expressed in virtually all cell types and tissues (Boucheix and Rubinstein, 2001; Hemler, 2005). They consist of short intracellular termini, four transmembrane domains, and one small and one large extracellular loop that contain two highly conserved cysteine motifs. Tetraspanins oligomerize into tetraspanin-enriched microdomains, in which they associate with integrins, Ig superfamily members, growth factor receptors, and proteoglycans. Tetraspanin-enriched microdomains modulate diverse cellular activities, such as adhesion strengthening, migration, signal transduction, and proliferation (Hemler, 2005). The importance of proper tetraspanin function is demonstrated by several human diseases; distinct mutations in A15 (TSPAN7) and RDS (TSPAN22) cause X-linked mental retardation and retinal dystrophy, respectively (Travis et al., 1989; Zemni et al., 2000). A nonsense mutation in CD151 (TSPAN24) leads to end-stage hereditary nephropathy associated with pretibial epidermolysis bullosa and sensorineural deafness (Karamatic Crew et al., 2004).

CD151 is expressed in epithelia, endothelia, muscle cells, renal glomeruli, proximal and distal tubules, Schwann cells, platelets, and dendritic cells (Sincock et al., 1997; Sterk et al., 2002). Extensive biochemical studies have shown that CD151 is the primary tetraspanin associated with the laminin-binding integrins 3ß1, 6ß1, 6ß4, and 7ß1 (Sterk et al., 2000, 2002; Boucheix and Rubinstein, 2001; Hemler, 2005). The interaction of CD151 with 3ß1 is particularly strong and occurs at high stoichiometry (Yauch et al., 1998).

Integrins are ß heterodimeric cell surface proteins that dynamically link the extracellular matrix and/or adjacent cells to the intracellular cytoskeleton (van der Flier and Sonnenberg, 2001; Hynes, 2002). In epithelial cells, the integrins 3ß1 and 6ß4 are mainly present in the basolateral compartment, where they bind to the basement membrane component laminin-5. Although much more severe, the phenotypes associated with mutations in Itga3, Itga6, and Itgb4 share features with the phenotype of patients with truncated CD151, indicating that the CD151–3ß1 and CD151–6ß4 heterotrimers are functionally important. Mice that lack the ß4 subunit suffer from extensive detachment of the epidermis, and patients without functional 6ß4 display junctional epidermolysis bullosa (Borradori and Sonnenberg, 1999; Uitto and Pulkkinen, 2001). Mice without 3 exhibit the mild skin blistering associated with ruptured basement membranes and die shortly after birth because of severe abnormalities in the epithelia of lung and kidney (Kreidberg et al., 1996; DiPersio et al. 1997).

In the renal glomerulus, podocytes are anchored to the glomerular basement membrane (GBM) via 3ß1 and dystroglycans (Mundel and Shankland, 2002). The interdigitating foot processes (FPs) of podocytes are connected by glomerular epithelial slit diaphragms (GESDs) consisting of nephrin, podocin, P-cadherin, and other proteins, which are linked directly or indirectly to the cytoskeleton. Both disturbed podocyte–GBM anchoring and podocyte–podocyte interaction at the level of GESDs lead to the loss of FPs, a dysfunctional filtration barrier, and, ultimately, to glomerulosclerosis and renal failure (Pavenstädt et al., 2003).

We report the generation of knockout mice for Cd151 that show severe renal failure caused by progressive abnormalities of the GBM, loss of podocyte FPs, glomerulosclerosis, and cystic tubular dilation. Furthermore, we show that mice with a targeted deletion of the 3 subunit in podocytes have a similar, although more severe, phenotype.

	Results and discussion

Top Abstract Introduction Results and discussion Materials and methods References

 
Cd151-null mice were generated (Fig. S1, available at http://www.jcb.org/cgi/content/full/jcb.200603073/DC1), born at the expected Mendelian ratio (0.28 ^(+/+): 0.49 ^(+/–): 0.23 ^(–/–); n = 86), and appeared to be healthy and normal at first observation. However, urine analysis of Cd151^–/– mice by SDS-PAGE revealed that all mice developed proteinuria before 3 wk of age, which is indicative of kidney dysfunction (Fig. 1 A). Both the onset and the degree of proteinuria were variable. Nevertheless, all knockout mice had to be killed before the age of 9 mo because of substantial loss of body weight. A quantitative immunoassay of urinary albumin showed high levels of this protein in Cd151^–/– mice that increased with age and reached a plateau at 6 wk (3 mo follow up; unpublished data). In contrast, only traces of albumin were present in the urine of wild-type and Cd151^+/– mice (Fig. 1, B and C). As expected, the severity of the renal pathology among Cd151^–/– littermates also varied considerably (Fig. 2, A and B), and there were animals with mildly or severely affected kidneys in the same litter. Histological examination of the mildly affected kidneys showed focal glomerulosclerosis, and interstitial fibrosis and inflammation (Fig. 2, D and G). The GBM of some capillary loops was abnormally thick and formed extensive spikes (Fig. 2 J). EM revealed that the GBM was laminated and that FPs in contact with the abnormal GBM were effaced (Fig. 3, A–C). On the vascular side, the endothelium was swollen and fenestrations were occasionally lost (Fig. 3, B and C). Severely affected kidneys were contracted and their capsules granulated because of cortical degeneration (Fig. 2 B). Light microscopy showed extensive glomerulosclerosis in several stages, tuft adhesions to Bowman's capsule with extracapillary cell proliferation and fibrosis, and marked expansion of the mesangial matrix. Proximal tubuli were either dilated and contained PAS-positive protein casts or they displayed degeneration of varying severity (Fig. 2, E and H). Furthermore, we observed periglomerular fibrosis and focal interstitial inflammation in close proximity to interlobular blood vessels (unpublished data). Silver staining showed the glomeruli to be segmentally or globally sclerosed with extensive deposits of basement membrane components (Fig. 2 K), an observation that could be confirmed by ultrastructural analysis (unpublished data). To investigate at what age GBM defects occur, we subjected kidneys of newborn and 1-wk-old Cd151^–/– mice to EM. Although many capillary loops of newborn Cd151^–/– mice already have a laminated GBM, it seems that spike formation does not occur until the mice are 1-wk-old (unpublished data). Together, these observations suggest that the mild abnormalities found in some of the mice represent early stages of the severe phenotype in the other mice. Tubular changes may be secondary to massive glomerular protein leakage, but may also reflect dysfunction of the tubules themselves.

View larger version (31K): [in this window] [in a new window]   Figure 1. Massive albuminuria in Cd151–/– and 2.5P-Cre; Itga3fl/fl mice. (A) Age at which proteinuria was first detected by SDS-PAGE in Cd151–/– and 2.5P-Cre; Itga3fl/fl mice. (B) 24-h urinary albumin concentration in 6-wk-old mice as determined by competitive ELISA. Each bar represents the arithmetic mean ± the SD with P values, as determined by homoscedastic two-tailed t test, shown above it and the number of analyzed animals shown underneath. (C) Coomassie brilliant blue–stained gel showing the presence of albumin in the urine of Cd151–/– mice in a group of three litters (1 µl urine per lane; age, 6 wk).

View larger version (162K): [in this window] [in a new window]   Figure 2. Glomerular and tubular abnormalities in mutant mice. Kidneys of Cd151–/– and 2.5P-Cre; Itga3fl/fl mice reveal mild (left column) and severe (middle and right columns) renal pathology. Although the mildly affected kidneys of a 3-mo-old Cd151–/– mouse show a relatively smooth and intact surface (A), histological examination reveals protein casts (D, arrow), inconspicuous interstitial fibrosis, mesangial hypercellularity (G, open arrowhead), and mild glomerular sclerosis (G, open arrow). The GBM shows partial thickening and spike formation (J, inset). Severe lesions of another 3-mo-old Cd151–/– mouse are characterized by a granular surface (B) caused by extensive glomerular collapsing sclerosis, periglomerular fibrosis, and focal interstitial inflammation and fibrosis (E, H, and K). The glomeruli show segmental (H, 1) and global (H, 2) attachment of glomerular tufts to Bowman's capsule, parietal epithelial crescents (H, 2), and hypercellularity, capillary collapse, and sclerosis (H, 3). Proximal tubuli show cystic dilation (E, arrowheads) and degeneration, as well as protein casts indicative of proteinuria (E and H, arrows). Silver staining indicates excessive GBM damage in some glomeruli (K). Severely affected kidneys of a 6-wk-old 2.5P-Cre; Itga3fl/fl mouse reveal prominent protein casts and some extremely dilated proximal tubuli (F and I, arrows). The glomeruli are partially sclerosed and show substantial damage of the GBM (L). Bars, 50 µm.

View larger version (180K): [in this window] [in a new window]   Figure 3. Electron micrographs reveal GBM abnormalities and FP effacement in kidneys of mildly affected Cd151–/– and 2.5P-Cre; Itga3fl/fl, but not 2.5P-Cre; Itga3+/fl, mice. (A) Glomeruli of Cd151–/– mice (3-mo-old) show abnormal capillary loops characterized by GBM thickening and loss of the regular pattern of podocyte FPs. (B) Peripheral glomerular capillary with a luminal thrombocyte and loss of fenestrations (arrowhead). The GBM is irregularly thickened and shows protrusions toward the capsular space (*). Podocyte FPs are partially lost (arrows). (C) Irregular GBM showing lamination, thickening, and protrusions (*). The endothelium is swollen and fenestrations are partially lost (arrowheads), as are podocyte FPs (arrows). Glomeruli of 6-wk-old 2.5P-Cre; Itga3+/fl mice do not show abnormalities (D), whereas all glomeruli of 2.5P-Cre; Itga3fl/fl mice exhibit severe structural changes (E and F). (E) Abnormally thickened GBM with protrusions throughout the glomerulus. (F) Podocyte FPs are completely lost (arrows) and GBM protrusions (*) are present along the entire length of the capillary loops. Solid lines point to normal structures (GBM and FPs), whereas dotted lines indicate abnormal thickening of the GBM and effacement of FPs. Bc, Bowman's capsule; Cs, capsular space; E, erythrocyte; Ec, endothelial cell; Fp, foot process; Lb, lamina basalis (GBM); Pdc, podocyte; T, thrombocyte; V, vascular lumen. Bars: (A, D, and E) 10 µm; (B, C, and F) 2 µm.

View larger version (184K): [in this window] [in a new window]   Figure 4. Histological analysis of Cd151–/– and 2.5P-Cre; Itga3fl/fl mice. Immunofluorescence analysis of kidneys from 3-mo-old wild-type (left column), mildly affected, and severely affected Cd151–/– (second and third column), and 6-wk-old 2.5P-Cre; Itga3+/fl and 2.5P-Cre; Itga3fl/fl mice (columns four and five). The respective proteins are shown in green and red, yielding yellow upon colocalization. Nuclei are counterstained with TOPRO (blue). (A–C) Up-regulation of tenascin-C in the mildly affected, and of fibulin-2 in the severely affected, Cd151–/– glomeruli. (D and E) 2.5P-Cre; Itga3+/fl glomeruli show little presence of tenascin-C, whereas both tenascin-C and fibulin-2 are present in glomeruli of 2.5P-Cre; Itga3fl/fl mice. (F–I) Integrin 3 and 6 are localized in glomeruli and tubules, respectively, in both wild-type and mildly affected Cd151–/– kidneys, as well as in the kidneys of 2.5P-Cre; Itga3+/fl mice. (J) Hardly any 3 is present in the glomeruli of 2.5P-Cre; Itga3fl/fl mice, whereas 6 is normally distributed in the tubules. (K and N) Staining of nidogen shows regular GBMs in both wild-type and 2.5P-Cre; Itga3+/fl mice. (L and M) Unusually strong nidogen staining of the GBM of peripheral capillary loops in both mildly and severely affected Cd151–/– kidneys (arrowheads). Note the extracapillary accumulation of nidogen (arrow) and massive capillary collapse (ß1 staining) in the severely affected kidneys. (O) Nidogen also accumulates in the capsular space of 2.5P-Cre; Itga3fl/fl mice (arrow). Glomeruli are not collapsed, but show an abnormally thick GBM (arrowhead) with protrusions (open arrow). (P–T) Podocin is present along the glomerular tuft in wild-type, mildly affected Cd151–/–, and 2.5P-Cre; Itga3+/fl mice, but absent in severely affected Cd151–/– and 2.5P-Cre; Itga3fl/fl mice. Staining of laminin-10 shows sclerosed glomeruli in Cd151–/– mice (R) and GBM thickening (arrowhead) with protrusions (open arrow) in 2.5P-Cre; Itga3fl/fl mice (T). (U–W) Nephrin is lost in some glomeruli of mildly affected Cd151–/– mice, but in all glomeruli of the severely affected Cd151–/– mice. There is massive up-regulation of the collagen 2 (IV) in the severe Cd151–/– phenotype (W) which is further characterized by hypercellularity in both the interstitium and glomeruli (C, H, M, R, and W; blue channel). (X and Y) Nephrin is also reduced in 2.5P-Cre; Itga3fl/fl mice as compared with the conditional heterozygote, whereas the collagen 2 (IV) is hardly up-regulated. Insets K–O, green channel (nidogen); Inset T, red channel (laminin-10). Bar, 50 µm.

Because Cd151-null mice can form normal GBMs with a regular FP pattern (Fig. 3 A) and expression of both 3 and 6 in the glomeruli and tubules appeared to be normal (Fig. 4, F–H), we suggest that the function of 3 in development is not affected by the absence of CD151. Instead, we propose that reduced integrin 3ß1-mediated adhesion is the main cause of the phenotype observed in our Cd151^–/– mice. The filtration of plasma exerts considerable mechanical stress on the filtration barrier. Podocyte FPs, thus, have to withstand substantial mechanical forces. Indeed, CD151 appears to be involved in adhesion strengthening because adhesions mediated by CD151–6ß1 complexes tolerate stronger mechanical forces than those mediated by 6ß1 alone (Lammerding et al., 2003). A similar effect has been suggested for CD151–3ß1 complexes (Nishiuchi et al., 2005). Thus, FPs without CD151 might not be able to withstand prolonged transcapillary pressure, a phenomenon that is also responsible for the renal manifestations in the Alport's syndrome after several years of life in patients with an abnormal GBM caused by collagen type IV mutations (Kalluri et al., 1997). Epithelial cells may become partially detached, leading to a compensatory production of new basement membrane components. As a result, the GBM thickens and spikes are formed, as has also been described in membranous nephropathy (Minto et al., 1998). Correct reassembly of basement membranes upon injury is impaired in the skin of Cd151-null mice (Cowin et al., 2006). If the absence of CD151 is similarly important for GBM repair, this vicious circle would indeed result in glomerular malfunction. As shown by ultrastructural and immunofluorescent analysis, glomerulosclerosis precedes the loss of GESD components, leading to the aforementioned renal pathology.

The assumption that CD151 is important for maintaining glomerular architecture upon mechanical stress is in accordance with the observation that glomeruli develop normally and that abnormalities only occur after several weeks or months. Furthermore, it explains differences in the rate of progression among littermates, as the degree of intraglomerular hydrostatic pressure depends on several genetic and epigenetic factors. Differences in genetic background might also explain why Cd151-null mice that have been previously described did not show renal failure as observed in our mice (Wright et al., 2004). In conclusion, we show that the renal manifestations in our mice lacking CD151 are similar to those in patients with a mutated CD151. Our data support in vitro studies pointing to a role of CD151 in adhesion strengthening, thus, suggesting that CD151–3ß1 complexes have an essential function in vivo.

	Materials and methods

Top Abstract Introduction Results and discussion Materials and methods References

 
Urine analysis
Urine from mice younger than 3-wk-old were collected by applying gentle dorsal pressure to the caudal area of the animal. Older mice were placed in metabolic cages for 24 h. Samples were either analyzed by SDS-PAGE, followed by Coomassie Brilliant blue staining, or by competitive ELISA using the Albuwell M kit that was obtained from Exocell.

Histological analysis
Sections of kidneys were prepared, fixed for 1 d in EAF (ethanol, acetic acid, and formaldehyde), and stained with PAS-D, HE, or Jones' methenamine silver. Images were taken with PL APO objectives (10x/0.25 NA, 40x/0.95 NA, and 63x/1.4 NA oil; Carl Zeiss MicroImaging, Inc.) on an Axiovert S100/AxioCam HR color system using AxioVision 4 software (Carl Zeiss MicroImaging, Inc.).

Ultrastructural analysis
After fixation in Karnovsky buffer for 48 h, the material was post-fixed with 1% osmiumtetroxide, the tissue samples were block-stained with 1% uranyl acetate, dehydrated in dimethoxypropane, and embedded in epoxyresin LX-112. LM sections were stained with toluidine blue. EM sections were stained with tannic acid, uranyl acetate, and lead citrate, and then examined using a transmission electron microscope (Philips CM10; FEI). Images were acquired using a digital transmission EM camera (Morada 10–12; Soft Imaging System) using Research Assistant software (RvC).

Antibodies
Rat mAbs used in this study were 4G6 against laminin-10 (provided by L. Sorokin, University of Münster, Münster, Germany), GoH3 against 6, MB1.2 against ß1 (a gift from B.M. Chan, University of Western Ontario, London, Canada), LAT-2 against tenascin-C (van der Flier et al., 1997), and 346-11A against ß4 (Abcam). Y. Sado (Shigei Medical Research Institute, Yamada, Japan) provided the rat mAbs H11, H22, H31, RH42, M54, and B66 against the mouse collagen IV chains 1, 2, 3, 4, 5, and 6, respectively. Rabbit polyclonal antibodies (pAbs) directed against mouse nidogen and mouse fibulin-2 were generous gifts from T. Sasaki (Max Planck Institute for Biochemistry, München, Germany); pAbs against nephrin and podocin were from H. Holthöfer (University of Helsinki, Helsinki, Finland), and C. Antignac (Cochin Biomedical Research Institute, Paris, France). The pAbs against keratin 1 and 14 were purchased from BabCO. Immunization of New Zealand rabbits with the cytoplasmic tail of human 3A fused to GST and the peptide CKENLKDTMVKRYHQSGHEGVSSAVDKLQQEFH coupled to KLH (Pierce Chemical Co.) yielded pAbs 141742 against 3A and 140190 against CD151, respectively. Texas red– and FITC-conjugated secondary antibodies were purchased from Invitrogen.

Immunofluorescence microscopy
Tissues from adult mice were collected and embedded in cryoprotectant (Tissue-Tek O.C.T.; Sakura Finetek Europe). Cryosections were prepared, fixed in ice-cold acetone, blocked with 2% BSA in PBS, and incubated for 45 min with primary antibodies undiluted (LAT-2, GoH3, MB1.2, 4G6) or diluted 1:2 (H22), 1:50 (346-11A), 1:100 (anti–fibulin-2, anto-podocin, anti-nephrin, and 141742), 1:250 (anti-nidogen), and 1:300 (anti-keratin 1 and 14), followed by incubation with secondary antibodies diluted 1:200 for 45 min. Samples were analyzed at 37°C using a 63x/1.4 HCX PL APO CS objective on a TCS SP2 AOBS confocal microscope (both from Leica). Images were acquired using LCS 2.61 (Leica) and processed using CorelDRAW Graphics Suite 12 (Corel).

Online supplemental material
Fig. S1 shows the targeting strategy and molecular analysis of recombinant embryonic stem cells and Cd151 knockout mice. Fig. S2 shows the histology and immunofluorescence analysis of keratins 1 and 14 on back skin samples from wild-type and Cd151^–/– mice, as well as auditory hearing thresholds of wild-type, Cd151^+/–, and Cd151^–/– mice upon click and tone burst stimuli, as determined by ABR measurements. The Supplemental materials and methods describes the generation of transgenic mice, immunoblotting, and ABR measurements. Online supplemental material is available at http://www.jcb.org/cgi/content/full/jcb.200603073/DC1.

	Acknowledgments

 
We are grateful to Dr. L.B. Holzman for generously providing the 2.5P-Cre transgenic mice, and to Drs. C. Antignac, A. Bradley, B. Chan, B. Lane, H. Holthofer, Y. Sado, and T. Sasaki for providing reagents. We would like to thank Dr. K. Wilhelmsen and I. Kuikman for the generation of antibodies against CD151 and the integrin 3 subunit.

This work was supported by grants from the Dutch Cancer Society and the Netherlands Kidney Foundation.

Submitted: 16 March 2006

Accepted: 5 September 2006

	References

Top Abstract Introduction Results and discussion Materials and methods References

 

Assad, L., M.M. Schwartz, I. Virtanen, and V.E. Gould. 1993. Immunolocalization of tenascin and cellular fibronectins in diverse glomerulopathies. Virchows Arch. B Cell Pathol. Incl. Mol. Pathol. 63:307–316.[Medline]

Borradori, L., and A. Sonnenberg. 1999. Structure and function of hemidesmosomes: more than simple adhesion complexes. J. Invest. Dermatol. 112:411–418.[CrossRef][Medline]

Boucheix, C., and E. Rubinstein. 2001. Tetraspanins. Cell. Mol. Life Sci. 58:1189–1205.[CrossRef][Medline]

Cowin, A.J., D. Adams, S.M. Geary, M.D. Wright, J.C. Jones, and L.K. Ashman. 2006. Wound healing is defective in mice lacking tetraspanin CD151. J. Invest. Dermatol. 126:680–689.[CrossRef][Medline]

DiPersio, C.M., K.M. Hodivala-Dilke, R. Jaenisch, J.A. Kreidberg, and R.O. Hynes. 1997. 3ß1 integrin is required for normal development of the epidermal basement membrane. J. Cell Biol. 137:729–742.[Abstract/Free Full Text]

Hemler, M.E. 2005. Tetraspanin functions and associated microdomains. Nat. Rev. Mol. Cell Biol. 6:801–811.[CrossRef][Medline]

Hsia, H.C., and J.E. Schwarzbauer. 2005. Meet the tenascins: multifunctional and mysterious. J. Biol. Chem. 280:26641–26644.[Free Full Text]

Hynes, R.O. 2002. Integrins: bidirectional, allosteric signaling machines. Cell. 110:673–687.[CrossRef][Medline]

Kalluri, R., C.F. Shield, P. Todd, B.G. Hudson, and E.G. Neilson. 1997. Isoform switching of type IV collagen is developmentally arrested in X-linked Alport syndrome leading to increased susceptibility of renal basement membranes to endoproteolysis. J. Clin. Invest. 99:2470–2478.[Medline]

Karamatic Crew, V., N. Burton, A. Kagan, C.A. Green, C. Levene, F. Flinter, R.L. Brady, G. Daniels, and D.J. Anstee. 2004. CD151, the first member of the tetraspanin (TM4) superfamily detected on erythrocytes, is essential for the correct assembly of human basement membranes in kidney and skin. Blood. 104:2217–2223.[Abstract/Free Full Text]

Kreidberg, J.A., M.J. Donovan, S.L. Goldstein, H. Rennke, K. Shepherd, R.C. Jones, and R. Jaenisch. 1996. 3ß1 integrin has a crucial role in kidney and lung organogenesis. Development. 122:3537–3547.[Abstract]

Lammerding, J., A.R. Kazarov, H. Huang, R.T. Lee, and M.E. Hemler. 2003. Tetraspanin CD151 regulates 6ß1 integrin adhesion strengthening. Proc. Natl. Acad. Sci. USA. 100:7616–7621.[Abstract/Free Full Text]

Minto, A.W., R. Kalluri, M. Togawa, E.C. Bergijk, P.D. Killen, and D.J. Salant. 1998. Augmented expression of glomerular basement membrane specific type IV collagen isoforms (3-5) in experimental membranous nephropathy. Proc. Assoc. Am. Physicians. 110:207–217.[Medline]

Moeller, M.J., S.K. Sanden, A. Soofi, R.C. Wiggins, and L.B. Holzman. 2003. Podocyte-specific expression of Cre recombinase in transgenic mice. Genesis. 35:39–42.[CrossRef][Medline]

Mundel, P., and S.J. Shankland. 2002. Podocyte biology and response to injury. J. Am. Soc. Nephrol. 13:3005–3015.[Free Full Text]

Nishiuchi, R., N. Sanzen, S. Nada, Y. Sumida, Y. Wada, M. Okada, J. Takagi, H. Hasegawa, and K. Sekiguchi. 2005. Potentiation of the ligand-binding activity of integrin 3ß1 via association with tetraspanin CD151. Proc. Natl. Acad. Sci. USA. 102:1939–1944.[Abstract/Free Full Text]

Pavenstädt, H., W. Kriz, and M. Kretzler. 2003. Cell biology of the glomerular podocyte. Physiol. Rev. 83:253–307.[Abstract/Free Full Text]

Sincock, P.M., G. Mayrhofer, and L.K. Ashman. 1997. Localization of the transmembrane 4 superfamily (TM4SF) member PETA-3 (CD151) in normal human tissues: comparison with CD9, CD63, and 5ß1 integrin. J. Histochem. Cytochem. 45:515–525.[Abstract/Free Full Text]

Sterk, L.M., C.A. Geuijen, L.C. Oomen, J. Calafat, H. Janssen, and A. Sonnenberg. 2000. The tetraspan molecule CD151, a novel constituent of hemidesmosomes, associates with the integrin 6ß4 and may regulate the spatial organization of hemidesmosomes. J. Cell Biol. 149:969–982.[Abstract/Free Full Text]

Sterk, L.M., C.A. Geuijen, J.G. van den Berg, N. Claessen, J.J. Weening, and A. Sonnenberg. 2002. Association of the tetraspanin CD151 with the laminin-binding integrins 3ß1, 6ß1, 6ß4 and 7ß1 in cells in culture and in vivo. J. Cell Sci. 115:1161–1173.[Abstract/Free Full Text]

Strom, A., A.I. Olin, A. Aspberg, and A. Hultgardh-Nilsson. 2006. Fibulin-2 is present in murine vascular lesions and is important for smooth muscle cell migration. Cardiovasc. Res. 69:755–763.[Abstract/Free Full Text]

Travis, G.H., M.B. Brennan, P.E. Danielson, C.A. Kozak, and J.G. Sutcliffe. 1989. Identification of a photoreceptor-specific mRNA encoded by the gene responsible for retinal degeneration slow (rds). Nature. 338:70–73.[CrossRef][Medline]

Uitto, J., and L. Pulkkinen. 2001. Molecular genetics of heritable blistering disorders. Arch. Dermatol. 137:1458–1461.[Free Full Text]

van der Flier, A., and A. Sonnenberg. 2001. Function and interactions of integrins. Cell Tissue Res. 305:285–298.[CrossRef][Medline]

van der Flier, A., A.C. Gaspar, S. Thorsteinsdóttir, C. Baudoin, E. Groeneveld, C.L. Mummery, and A. Sonnenberg. 1997. Spatial and temporal expression of the ß1D integrin during mouse development. Dev. Dyn. 210:472–486.[CrossRef][Medline]

Wada, J., H. Zhang, Y. Tsuchiyama, K. Hiragushi, K. Hida, K. Shikata, Y.S. Kanwar, and H. Makino. 2001. Gene expression profile in streptozotocin-induced diabetic mice kidneys undergoing glomerulosclerosis. Kidney Int. 59:1363–1373.[CrossRef][Medline]

Wright, M.D., S.M. Geary, S. Fitter, G.W. Moseley, L.M. Lau, K.C. Sheng, V. Apostolopoulos, E.G. Stanley, D.E. Jackson, and L.K. Ashman. 2004. Characterization of mice lacking the tetraspanin superfamily member CD151. Mol. Cell. Biol. 24:5978–5988.[Abstract/Free Full Text]

Yauch, R.L., F. Berditchevski, M.B. Harler, J. Reichner, and M.E. Hemler. 1998. Highly stoichiometric, stable, and specific association of integrin 3ß1 with CD151 provides a major link to phosphatidylinositol 4-kinase, and may regulate cell migration. Mol. Biol. Cell. 9:2751–2765.[Abstract/Free Full Text]

Zemni, R., T. Bienvenu, M.C. Vinet, A. Sefiani, A. Carrie, P. Billuart, N. McDonell, P. Couvert, F. Francis, P. Chafey, et al. 2000. A new gene involved in X-linked mental retardation identified by analysis of an X;2 balanced translocation. Nat. Genet. 24:167–170.[CrossRef][Medline]

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• Fumagalli, M., Cagliani, R., Pozzoli, U., Riva, S., Comi, G. P., Menozzi, G., Bresolin, N., Sironi, M. (2009). Widespread balancing selection and pathogen-driven selection at blood group antigen genes. Genome Res 19: 199-212 [Abstract] [Full Text]  
• Margadant, C., Raymond, K., Kreft, M., Sachs, N., Janssen, H., Sonnenberg, A. (2009). Integrin {alpha}3{beta}1 inhibits directional migration and wound re-epithelialization in the skin. J. Cell Sci. 122: 278-288 [Abstract] [Full Text]  
• Chien, C.-W., Lin, S.-C., Lai, Y.-Y., Lin, B.-W., Lin, S.-C., Lee, J.-C., Tsai, S.-J. (2008). Regulation of CD151 by Hypoxia Controls Cell Adhesion and Metastasis in Colorectal Cancer. Clin. Cancer Res. 14: 8043-8051 [Abstract] [Full Text]  
• Barreiro, O., Zamai, M., Yanez-Mo, M., Tejera, E., Lopez-Romero, P., Monk, P. N., Gratton, E., Caiolfa, V. R., Sanchez-Madrid, F. (2008). Endothelial adhesion receptors are recruited to adherent leukocytes by inclusion in preformed tetraspanin nanoplatforms. JCB 183: 527-542 [Abstract] [Full Text]  
• Yanez-Mo, M., Barreiro, O., Gonzalo, P., Batista, A., Megias, D., Genis, L., Sachs, N., Sala-Valdes, M., Alonso, M. A., Montoya, M. C., Sonnenberg, A., Arroyo, A. G., Sanchez-Madrid, F. (2008). MT1-MMP collagenolytic activity is regulated through association with tetraspanin CD151 in primary endothelial cells. Blood 112: 3217-3226 [Abstract] [Full Text]  
• Baleato, R. M., Guthrie, P. L., Gubler, M.-C., Ashman, L. K., Roselli, S. (2008). Deletion of Cd151 Results in a Strain-Dependent Glomerular Disease Due to Severe Alterations of the Glomerular Basement Membrane. Am. J. Pathol. 173: 927-937 [Abstract] [Full Text]  
• Yang, X. H., Richardson, A. L., Torres-Arzayus, M. I., Zhou, P., Sharma, C., Kazarov, A. R., Andzelm, M. M., Strominger, J. L., Brown, M., Hemler, M. E. (2008). CD151 Accelerates Breast Cancer by Regulating {alpha}6 Integrin Function, Signaling, and Molecular Organization. Cancer Res. 68: 3204-3213 [Abstract] [Full Text]  
• Borza, C. M., Borza, D.-B., Pedchenko, V., Saleem, M. A., Mathieson, P. W., Sado, Y., Hudson, H. M., Pozzi, A., Saus, J., Abrahamson, D. R., Zent, R., Hudson, B. G. (2008). Human Podocytes Adhere to the KRGDS Motif of the {alpha}3{alpha}4{alpha}5 Collagen IV Network. J. Am. Soc. Nephrol. 19: 677-684 [Abstract] [Full Text]  
• Vaughan, M. R., Quaggin, S. E. (2008). How Do Mesangial and Endothelial Cells Form the Glomerular Tuft?. J. Am. Soc. Nephrol. 19: 24-33 [Abstract] [Full Text]  

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