The Class II Phosphoinositide 3-Kinase C2{beta} Is Not Essential for Epidermal Differentiation

Phosphoinositide 3-kinases (PI3Ks) regulate an array of cellularprocesses and are comprised of three classes. Class I PI3Ksinclude the well-studied agonist-sensitive p110 isoforms; however,the functions of class II and III PI3Ks are less well characterized.Of the three class II PI3Ks, C2 ${alpha}$ and C2ß are widelyexpressed in many tissues, including the epidermis, while C2 ${gamma}$ is confined to the liver. In contrast to the class I PI3K p110 ${alpha}$ ,which is expressed throughout the epidermis, C2ß wasfound to be localized in suprabasal cells, suggesting a potentialrole for C2ß in epidermal differentiation. OverexpressingC2ß in epidermal cells in vitro induced differentiationmarkers. To study a role for C2ß in tissue, we generatedtransgenic mice overexpressing C2ß in both suprabasaland basal epidermal layers. These mice lacked epidermal abnormalities.Mice deficient in C2ß were then generated by targetedgene deletion. C2ß knockout mice were viable and fertileand displayed normal epidermal growth, differentiation, barrierfunction, and wound healing. To exclude compensation by C2 ${alpha}$ ,RNA interference was then used to knock down both C2 ${alpha}$ and C2ßin epidermal cells simultaneously. Induction of differentiationmarkers was unaffected in the absence of C2 ${alpha}$ and C2ß.These findings indicate that class II PI3Ks are not essentialfor epidermal differentiation.

INTRODUCTION

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Introduction

The phosphoinositide 3-kinase (PI3K) family is conserved throughevolution and is implicated in a diverse array of biologic processes,including cell survival, proliferation, inflammation, adhesion,glucose metabolism, chemotaxis, and cancer. In mammals, thereare eight PI3K family members divided into three classes bysequence homology (8, 14, 18). All proteins share homologouskinase domains and can phosphorylate the 3-hydroxyl positionof the inositol head group of phosphoinositides. Class I PI3Ksexist as heterodimers and are divided into two subclasses. Theubiquitously expressed class Ia PI3Ks are activated by receptortyrosine kinases and their effectors, notably Ras. They arecomprised of a 110-kDa catalytic subunit (p110 ${alpha}$ , p110ß,or p110 ${delta}$ ) that is constitutively bound via amino-terminal sequencesto a regulatory subunit (p85 ${alpha}$ , p55 ${alpha}$ , p50 ${alpha}$ , p85ß, or p55 ${gamma}$ ).A major product of phosphorylation of phosphoinositide substratesby class Ia PI3Ks is phosphatidylinositol 3,4,5-triphosphate[PtdIns(3,4,5)P₃]. PtdIns(3,4,5)P₃ promotes membrane localizationand activation of a host of downstream effectors that containpleckstrin homology domains, including Akt, Sos, PDK-1, andPLC ${gamma}$ . PtdIns(3,4,5)P₃ action is opposed by phosphatases thatinclude PTEN and SHIP (1, 18). Class Ia PI3Ks are implicatedin a variety of cellular processes and have recently been foundas active mutant forms in a variety of human cancers (23). ClassIb PI3Ks act downstream of G-protein-coupled receptors and arecomposed of a catalytic subunit (p110 ${gamma}$ ) bound to a p101 regulatorysubunit. In contrast to the ubiquitous class Ia PI3Ks, classIb PI3Ks are primarily found in hematopoietic cells. Class IIIPI3K is composed of a catalytic homolog of the Vps34 protein,which is implicated in vesicle sorting, and a p150 regulatorysubunit. While diverse effects have been assigned to class IPI3Ks, the functions of class II and class III PI3Ks are stillbeing elucidated.

Class II PI3Ks have been a focus of increasing recent interest.In contrast to class I PI3Ks, these lipid kinases lack regulatorysubunits, phosphorylate PIP₂ poorly in vitro, and are constitutivelyassociated with cellular membranes. Class II PI3Ks include theubiquitously expressed PI3K C2 ${alpha}$ and C2ß proteins aswell as the liver-restricted C2 ${gamma}$ protein (13). Unlike class IPI3Ks, class II PI3Ks do not appear to be directly activatedby Ras. Class II PI3K C2 proteins do appear to associate withand function downstream of a number of transmembrane proteins,including clathrin, integrins, chemokine receptors, and growthfactor receptors (2, 4, 10, 14, 15, 21, 25, 31), and C2ßcan also be activated by other stimuli, such as lysophosphatidicacid, insulin and platelet aggregation (6, 20, 33). Like otherclass II members, PI3K C2ß contains a Ras bindingdomain, a PI kinase (PIK) domain, a catalytic domain, and aC2 domain (3, 14, 18). Although less well characterized thanclass I PI3Ks at the functional level, C2ß has recentlybeen implicated as being important in cell migration in severalepithelial lines (20) and in the differentiation of HL-60 hematopoieticcells by retinoic acid (27). While a number of class I PI3Kshave been disrupted in mice, the phenotypic effects of targeteddeletion of C2ß have not been reported.

Cutaneous epidermis is a stratified epithelial tissue that undergoescontinual, spatially controlled differentiation and self-renewalthroughout life. The processes governing the induction of differentiationin developmentally mature mammalian epidermis are not fullyunderstood. Given expression patterns suggestive of involvementin the differentiation of a variety of tissues (13), PI3Ks representpotential candidates for control of epidermal differentiation.Directly contradictory findings for a potential role for PI3Ksin this process, however, have recently been presented. Adenoviraloverexpression of active PI3K p110 ${alpha}$ inhibited expression of thekeratin 1/10 differentiation markers in cultured keratinocyteswhile dominant-negative p85 induced these markers, suggestingthat PI3K may prevent epidermal differentiation (24). In contrast,a more recent study demonstrated that PI3K inhibitors blockedcalcium-induced keratinocyte differentiation, suggesting thatintact PI3K function is required for this process (32). A limitationin both cases is that these studies relied only on culturedcells, and the effects of PI3K on epidermal differentiationin tissue have not been reported.

Here we have assessed the role of PI3K C2ß in epidermaltissue by generation of both transgenic and knockout mice. C2ßwas found to be expressed predominantly in suprabasal epidermallayers, suggesting a possible role in epidermal differentiation.While pharmacologic blockade of PI3K inhibited keratinocytedifferentiation in vitro and overexpression of wild-type C2ßenhanced it, these effects were not seen in tissue engineeredfor either gain or loss of C2ß function. Specifically,both C2ß overexpression in both basal and suprabasalepidermal compartments and C2ß gene disruption failedto alter epidermal growth, differentiation, barrier function,and wound healing. C2ß knockout mice lacking C2ßprotein expression in cutaneous and visceral tissues were viableand fertile, indicating that C2ß is dispensable fornormal development, survival, and reproduction. To examine potentialredundancy of class II PI3Ks in epidermal differentiation, simultaneousknockdown of both C2 ${alpha}$ and C2ß protein levels was achievedin epidermal cells by RNA interference; however, this also failedto block induction of differentiation. These findings indicatethat C2ß is dispensable for viability and for epidermalhomeostasis.

MATERIALS AND METHODS

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Materials and Methods

Cell culture and gene transfer. Coding sequences for human PI3K C2 ${alpha}$ (12), PI3K C2ß(3), PI3K p110 ${alpha}$ CAAX (30), and PI3K ${Delta}$ p85 (17) were subcloned intothe EcoRI/XhoI, BamHI, and BamHI sites of the LZRS vector (19),respectively. To generate deletions in the PI kinase, catalytic,and C2 domains of C2ß, the cDNA encoding the wild-typeversion of the enzyme was digested with FspI, EagI, and BsrG1/ClaI,respectively, and religated to generate in-frame deletions.All constructs were verified by restriction mapping and sequencing.Primary human keratinocytes were isolated and grown as describedpreviously (9). Retrovirus was prepared in human 293T packagingcells as described previously (11). Primary keratinocytes underwentretroviral transduction at a multiplicity of infection of 15without drug selection (22).

Targeting vector construction and generation of PI3K C2ß-deficient mice. A 3-kb PI3K C2ß genomic fragment containing exon 2,a 2.3-kb fragment containing exons 3 to 5, and a 4.4-kb fragmentcontaining exons 6 to 8 were amplified from 129/Sv mouse DNAby PCR. Primers were designed to incorporate EcoRI (3-kb fragment),BamHI (2.3-kb fragment), and NotI (4.4-kb fragment) restrictionenzyme cleavage sites for ligation into the targeting vector.After amplification by PCR, all exons and exon-intron borderswere sequenced. The 3-kb EcoRI fragment, the 2.3-kb BamHI fragment,and the 4.4-kb NotI fragment were inserted separately as theshort arm, loxP site-flanked fragment, and long arm, respectively,into a modified pPNT-loxP vector, which contained a neomycinand a thymidine kinase cassette. The targeting vector was linearizedwith PvuI and electroporated into R1 embryonic stem cells. Resistantcells were selected in the presence of G418 and ganciclovir.DNA was isolated from a total of 397 clones. Homologous recombinantswere screened by Southern blotting. Genomic DNA was digestedwith BamHI, and identified with probe 1, a specific PCR fragmentof 540 bases located downstream of the targeted PIK3C2B locus.Two clones, A7 and C6, were injected into C57BL/6 blastocysts,which were subsequently transferred into pseudopregnant femalesto generate chimeric offspring. The chimeras were crossed intoC57BL/6 mice for germ line transmission. The null allele wasgenerated by crossing the C2ß^fl^/+ line into the protamine-Credeleter line (PrmCre1). For genotyping, the genotypes of mutantmice were determined by PCR and confirmed by Southern blot analysisof genomic DNA from tail biopsies. Tail samples were collectedand digested with 40 µg proteinase K in 400 µl buffer(0.5% sodium dodecyl sulfate [SDS], 0.1 M NaCl, 50 mM Tris-HCl[pH 8], 2.5 mM EDTA) at 58°C overnight. Routine genotypingthrough PCR was performed with genomic DNA with specific primersfor the deleted allele (P1, 5'-TGTTAGAACCTGCCGCCTTTAC-3', andP2, 5'-CCGAATCAGCCTCATTTCCTCTC-3') and for the wild-type allele(P3, 5'-GGCACACACTAACCACAGCACC-3', and P4, 5'-TCGATGCACGT CTCTCCGC-3'). The PCR product for the deleted allele was 404 bp, whereasthe product for the wild-type allele was 251 bp. Genotypingof animals was confirmed by Southern blotting. Genomic DNA wasdigested with HindIII and identified by probe 2, a specificPCR fragment of 517 bases located within exon 2.

Total RNA isolation and reverse transcription-PCR. Total cellular RNA was isolated from cultured keratinocytesobtained from postnatal day 0 mice with the RNeasy minikit (QIAGEN,Valencia, CA) according to the manufacturer's instructions.First-strand cDNA synthesis was performed by using SuperscriptII RNase H^– reverse transcriptase (Invitrogen, Carlsbad,CA). RT-PCR was performed with a forward primer (RT1, 5'-ACACCTCTGGGAAACCTGTG-3')designed in exon 2 and a reverse primer (RT2, 5'-GCCTCTCTTGGAGATGGATG-3')designed in exon 7.

Histology and protein expression. Necropsies were performed on 6- to 8-week-old mice. For histologicalexamination, tissue was fixed in 10% buffered formalin and embeddedin paraffin, and 5-µm sections were stained with hematoxylinand eosin. For immunostaining, 5-µm skin cryosectionswere allowed to air dry for 10 min and permeabilized with coldacetone for 10 min. Sections were blocked with 1% bovine serumalbumin-phosphate-buffered saline (BSA-PBS) for 1 h and treatedwith the primary antibody diluted in 10% BSA-PBS overnight at4°C. Slides were then washed three times with PBS and incubatedfor 1 h with secondary antibodies with 2 mg/ml Hoechst (MolecularProbes, Eugene, OR). After three washes with PBS, slides weremounted in Vectashield (Vector Laboratories) and examined undera Zeiss 100M Axiovert microscope. The following panel of antibodieswas used in immunostaining: anti-mouse K14, anti-mouse K10,antiloricrin, antifilaggrin, and anti-mouse involucrin (Covance,Berkeley, CA); PI3K C2ß (BD Biosciences, San Jose,CA); anti-mouse Ki-67 (Dako, Carpinteria, CA); Cy3-conjugatedgoat anti-rabbit immunoglobulin G (IgG) and Cy3-conjugated goatanti-rat IgG (Jackson ImmunoResearch Laboratories). For immunoblotting,human keratinocyte extracts were homogenized in lysis buffer(20 mM Tris [pH 7.5], 150 mM NaCl, 1 mM EDTA, and 1% NP-40)with protease inhibitors (Complete Mini EDTA free; Roche, Indianapolis,IN) and phosphatase inhibitor mixture II (Sigma, St. Louis,MO). Mouse keratinocytes were lysed in lysis buffer (8 M urea,4% CHAPS {3-[(3-cholamidopropyl)-dimethylammonio]-1-propanesulfonate},10% 2-mercaptoethanol, 40 mM Tris [pH 8.0], 2.5 mM EDTA). Proteinextract was loaded at 20 to 100 µg/lane and subjectedto 10% SDS-PAGE. The following antibodies were used: PI3K p110 ${alpha}$ (Cell Signaling, Beverly, MA), PI3K C2 ${alpha}$ (a gift of Jan Domin),PI3K C2ß (BD Biosciences, San Jose, CA), human keratin1 and filaggrin (Babco), human involucrin (Sigma), ß-actin(Santa Cruz Biotechnology, Santa Cruz, CA), donkey anti-rabbitIgG-horseradish peroxidase (Amersham Biosciences, Piscataway,NJ), sheep anti-mouse IgG-horseradish peroxidase (Amersham),and donkey anti-goat IgG-horseradish peroxidase (Santa Cruz).

Generation of transgenic mice. The sequence encoding human PI3K C2ß (3) was subcloneddownstream of a 2,075-bp human keratin 14 (K14) promoter construct,which targets expression of C2ß to keratinocytes withinthe basal epidermal layer (26). In addition, the C2ßcoding sequence was subcloned downstream of a human keratin1 (HK1) promoter construct to target gene expression to keratinocytesin the suprabasal epidermal layers (16). Both constructs wereused to generate transgenic mice. Transgene integration wasconfirmed by PCR.

Wound healing and barrier analysis. Six-week old mice (C2ß^–/–, C2ß^+/–,C2ß^+/+) were anesthetized and shaved. Two full-thicknessskin biopsy punch wounds were made on either side of the midlineof the mouse, and the wound area was measured daily for 10 days.For transepidermal water loss, C2ß-deficient-mouseand control mouse skin were analyzed using an evaporimeter (Servomed,Stockholm, Sweden). To further assess the epidermal permeabilitybarrier by a ß-galactosidase skin permeability assay,unfixed and freshly isolated embryos were rinsed in PBS andthen immersed in 5-bromo-4-chloro-3-indolyl-ß-D-galactopyranoside(X-Gal) reaction mix at pH 4.5 [100 mM NaPO₄, 1.3 mM MgCl₂,3 mM K₃Fe(CN)₆, 3 mM K₄Fe(CN)₆ and 1 mg/ml X-Gal] and incubatedat room temperature overnight.

RNA interference. Human PI3K C2ß and PI3K C2 ${alpha}$ small interfering RNA (siRNA)pools were designed and synthesized by Dharmacon (Chicago, IL).Keratinocytes (10⁶) were electroporated with 200 pmol of theof the indicated siRNA oligonucleotide using the Amaxa nucleofectionkit (Amaxa, Gaithersburg, MD) according to the manufacturer'srecommended protocol. Twenty-four hours after nucleofection,the concentration of calcium in the medium was raised to 1.0mM to induce differentiation. Cells were harvested and analyzed48 h later.

RESULTS

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Results

Epidermal differentiation is blocked by PI3K inhibition and can be induced by C2ß in vitro. Conflicting data have been reported regarding a potential roleof PI3Ks in epidermal differentiation (24, 32). We thereforeexamined the effect of blocking PI3K function on differentiationof epidermal keratinocytes. To inhibit PI3K function, two approacheswere used: retroviral expression of a dominant-negative p85mutant ( ${Delta}$ p85) inhibitory for class Ia PI3Ks and addition of thepharmacologic inhibitor LY294002, which inhibits action by multipleclasses of PI3Ks (28, 29). While ${Delta}$ p85 failed to alter calcium-induceddifferentiation protein expression, LY294002 blocked it entirely(Fig. 1A). This suggested that function of non-class Ia PI3Ksmay be required for keratinocyte differentiation and raisedthe possibility that expression of active PI3Ks might induceit.

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FIG. 1. PI3K C2ß induces keratinocyte differentiation. (A) Expression of keratinocyte differentiation proteins keratin 1 and involucrin in the presence of low (0.07 mM [–]) or elevated (0.20 mM [+]) calcium in the medium. Cells were coincubated with the PI3K inhibitor LY294002 or transduced with retroviral vectors expressing either the PI3K ${Delta}$ p85 mutant dominant-negative for class Ia PI3K function or a LacZ marker control. Proteins blotted are shown at left. (B) PI3K protein distribution in human epidermis. Note p110 ${alpha}$ and C2 ${alpha}$ throughout the epidermis and the restriction of C2ß to suprabasal layers. Brackets delineate expression regions: orange, PI3K; green, collagen VII denoting the epidermal basement membrane; and blue, DAPI (4',6'-diamidino-2-phenylindole) nuclear stain. Bars = 100 µm. (C) Differentiation protein expression in keratinocytes expressing retrovirally introduced LacZ control, p110 ${alpha}$ , and C2ß. Retroviral expression constructs are noted at the top of each lane, and the blotted proteins are indicated at the left of each panel. (D) Differentiation marker protein expression in keratinocytes expressing retrovirally introduced PI3K C2 ${alpha}$ and LacZ control. (E) Deletion of the C2ß PI kinase (PIK ${Delta}$ ), catalytic (Cat ${Delta}$ ), or C-terminal C2 (C2 ${Delta}$ ) domain abolishes induction of keratinocyte differentiation. Immunoblot verification of expression of the mutants noted at the top of each lane is shown in the top panel, with molecular mass markers to show the size of each mutant. The proteins studied are shown at the left of each panel; retroviral expression of wild-type and mutant C2ß proteins invariably produced a doublet on immunoblotting.

To begin to address this possibility, we examined PI3K expressionin epidermis. While PI3K p110 ${alpha}$ and C2 ${alpha}$ protein were detected throughoutthe epidermis in both undifferentiated and differentiating layers,C2ß was confined to differentiating suprabasal layersof human epidermis (Fig. 1B), consistent with a potential C2ßrole in differentiation. In agreement with the lack of ${Delta}$ p85 effects,expression of active class I PI3K p110 ${alpha}$ failed to increase differentiationprotein expression under basal medium conditions (Fig. 1C).In contrast, the class II PI3K C2ß increased it strongly(Fig. 1C). Expression of the only other class II PI3K expressedin epidermis, C2 ${alpha}$ , failed to induce differentiation (Fig. 1D),indicating that this effect is specific to C2ß. Inductionof keratinocyte differentiation by C2ß required intactPIK, catalytic, and C2 domains, because expression of mutantC2ß proteins lacking these sequences failed to producethis effect (Fig. 1E). C2ß is thus expressed withinthe differentiating cell compartment of epidermal tissue invivo and can induce keratinocyte differentiation in vitro.

Transgenic mice with targeted epidermal C2ß expression are normal. To assess the effects of C2ß in tissue, transgenicmice that express increased levels of C2ß in the epidermiswere generated. To examine C2ß effects in both undifferentiatedand differentiated layers, the keratin 14 (K14) and keratin1 (HK1) promoters were used, respectively (Fig. 2A). Increasedexpression of C2ß protein was observed in epidermalkeratinocytes of both singly and doubly transgenic mice; becauseavailable C2ß antibodies do not work well for immunohistochemistryin murine tissue, immunoblotting of transgenic and wild-typecontrol littermate keratinocyte extracts was performed (Fig.2B).

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FIG.2. K14 and HK1-C2ß transgenic mice exhibit normal skin. (A) Transgene cassettes used to generate targeted expression of C2ß under control of the basal K14 promoter or suprabasal HK1 promoter. Three independent lines were generated for each construct and displayed similar phenotypes. (B) C2ß protein expression in keratinocyte extracts isolated from wild-type [tg(–)], singly transgenic [tg(+)], or doubly transgenic [tg(++)] mice. Actin expression is included as a loading control. (C) Histology of wild-type (–) and transgenic skin. Note normal architecture in all cases. Expression of keratin 14 and the differentiation proteins keratin 10, involucrin, filaggrin, and loricrin in (D) wild-type and HK1-C2ß and (E) K14-C2ß transgenic skin (orange, differentiation marker; blue, DAPI). Bars = 100 µm.

Targeted expression of C2ß in both undifferentiatedand differentiating epidermal layers failed to alter epidermalmorphology from that of normal (Fig. 2C). Additionally, increasedC2ß expression did not alter epidermal differentiationmarker expression patterns in tissue (Fig. 2D and E). Thesedata indicate that increased expression of C2ß invivo does not exert dramatic effects on epidermal differentiation.

Generation of C2ß knockout mice. The discrepancy between our in vitro and in vivo overexpressionfindings did not address a potential requirement for C2ßfunction in epidermal homeostasis. To study this, we undertooktargeted deletion of sequences at the murine PIK3C2B locus,which encodes C2ß. Exons 3 to 5 were flanked withloxP sites (Fig. 3A). Deletion of these sequences produces atruncated, nonfunctional protein lacking the PIK, catalytic,and C2 domains that are required for induction of keratinocytedifferentiation in vitro. C2ß-null mice were generatedby crossing C2ß^fl^/+ animals with protamine-Cre deletermice (PrmCre1); the progeny were then backcrossed to obtainC2ß^–/– mice that lacked C2ßexpression (Fig. 3B to E). Loss of targeted exons in C2ß-nullmice led to a total lack of C2ß protein, as detectedby immunoblotting to the amino terminus, in both epidermis (Fig.3F) and visceral tissues (Fig. 3G). Null mice were born andsurvived to adulthood at a normal Mendelian ratio. C2ßknockout mice were viable and fertile and displayed no detectableabnormalities on visual inspection and on histologic surveyof visceral tissues.

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FIG. 3. Targeted disruption of the mouse C2ß gene. (A) Targeting strategy. Partial restriction enzyme maps and schematic representation of the strategy for ablation of the C2ß gene. The PIK3C2B gene of 129Sv mice (wild-type [WT] allele), the targeting vector, the recombinant loxP-flanked locus (floxed allele), and the C2ß exon-deleted locus (deleted allele) are shown. Cleavage sites for BamHI (B) and HindIII (H) are marked. The locations of probes 1 and 2 for Southern analysis are indicated by closed bars, and primers for PCR analysis are shown as arrowheads. Exons are symbolized as numbered rectangles. Exon 1 encodes an untranslated region; the start codon is located in exon 2. (B) Southern blot analysis of BamHI-digested genomic DNA and hybridization to probe 1 reveal a 6-kb and an 8-kb band corresponding to wild-type and floxed alleles, respectively. (C) Southern hybridization for detection of the null allele. The HindIII fragments in the wild-type allele and deleted alleles are 8.3 kb and 5.8 kb, respectively, when detected with probe 2. (D) Mice were genotyped by PCR. The amplicon with primer pair 1 and 2 is 251 bp for the wild-type allele. The amplicon with primer pair 3 and 4 is 404 bp for the null allele. (E) Loss of normal C2ß mRNA transcript in C2ß^–/– mice. RNA was isolated from cultured keratinocytes. The forward primer was designed in exon 2, and the reverse primer was designed in exon 7. The wild-type allele yields a 678-bp amplicon, and the deleted allele yields a 301-bp amplicon. (F) Loss of epidermal C2ß protein in C2ß^–/– mice. Western blot analysis showing absence of C2ß protein expression in the knockout mice. Proteins were isolated from epidermal extracts and detected with an antiserum to C2ß. (G) Loss of C2ß protein in visceral tissues of C2ß^–/– mice.

Characterization of C2ß knockout mice. To examine a possible role for C2ß in epidermal homeostasis,epidermal tissue architecture, differentiation marker expressionand proliferative indices were analyzed. Epidermal thicknessand morphology appeared to be normal in C2ß knockoutmice (Fig. 4A). Differentiation marker expression was also localizedin a manner indistinguishable from normal (Fig. 4B). Epidermalproliferation was also normal, as measured by mitotic indicesusing the proliferation marker Ki-67 (Fig. 4C and D), and C2ß-nullkeratinocytes retained the capacity to induce differentiationmarker expression in vitro in response to calcium in a fashionsimilar to that of normal controls (Fig. 4E and F). C2ßknockout mice also healed with normal kinetics after wounding(Fig. 5A). They displayed normal epidermal barrier function,as judged by both X-Gal penetration and transepidermal waterloss (Fig. 5B, C). These findings indicate that C2ßis not essential for normal epidermal growth, differentiation,wound healing, or barrier formation.

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FIG. 4. C2ß^–/– mice display normal epidermal differentiation and proliferation. (A) Histology of back skin from C2ß wild-type, heterozygous, and null mice at 8 weeks of age. Note normal tissue architecture in C2ß-null skin. (B) Expression of keratin 14 and the differentiation markers keratin 10, involucrin, filaggrin, and loricrin in 8-week-old mice. Bars = 100 µm. (C) Ki-67 (orange) in tissue counterstained with DAPI (blue). Bars = 100 µm. (D) Percentage of Ki-67(+) epidermal cells in skin tissue from C2ß wild-type (+/+) and null (–/–) mice (three mice each; values are means ± standard deviations). (E) Filaggrin (orange)-expressing primary keratinocytes in culture from C2ß wild-type and null mice when cells were grown in low (0.07 mM)-calcium and higher (0.12 mM)-calcium media. (F) Quantitation of the percent of filaggrin-positive cells in C2ß wild-type and null murine keratinocytes after 24 h in 0.12 mM calcium (three independent experiments; values are means ± standard deviations).

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FIG. 5. Normal wound healing and barrier function in C2ß-deficient mice. (A) C2ß^–/– mice exhibited normal re-epithelialization. Wound area over a 10-day period following injury (three mice each; values are means ± standard deviations). (B) ß-Galactosidase epidermal permeability barrier assay of C2ß^–/– mice compared to the wild type. Note the lack of increased penetration of X-Gal through the epidermal barrier (as detected by blue staining) of the wild-type and C2ß^–/– mice. (C) Transepidermal water loss in newborn mice (three mice each; values are means± standard deviations).

Effects of simultaneous knockdown of C2 ${alpha}$ and C2ß. The lack of epidermal effects with C2ß loss couldbe due to compensation by C2 ${alpha}$ . We therefore simultaneously knockeddown expression of both proteins using RNA interference (RNAi)and examined the effects on keratinocyte differentiation invitro, the setting where C2ß effects were observed.RNA duplexes effectively diminished expression of both C2 ${alpha}$ andC2ß but did not abolish normal induction of differentiationmarker expression by calcium (Fig. 6). This finding suggeststhat the class II PI3Ks C2 ${alpha}$ and C2ß are not requiredfor epidermal differentiation.

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FIG. 6. Simultaneous C2 ${alpha}$ and C2ß knockdown fails to prevent keratinocyte differentiation marker expression. Human keratinocytes treated with duplex RNAs to C2 ${alpha}$ , C2ß, or C2 ${alpha}$ plus C2ß were exposed to high and low extracellular calcium concentrations for 2 days. The proteins blotted are shown at the left of each panel, and the RNAi used is at the top. Note the expression of the involucrin differentiation marker and its induction by calcium in the absence of C2 ${alpha}$ and C2ß proteins.

DISCUSSION

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Discussion

Here we have shown that PI3K C2ß is not essentialfor epidermal homeostasis. Because our gene deletion strategyalso produced C2ß protein loss in other somatic tissuesin addition to epidermis, these data indicate that C2ßis not required for normal development and postnatal viabilityin mice. This observation is surprising, given the discretephenotypes obtained with knockouts of class I PI3Ks (1, 8, 18),and argues for generation of multigene knockouts for class IIPI3Ks to look for genetic redundancy in development. Our knockdowndata suggest, however, that class II PI3Ks are dispensable forat least epidermal differentiation because simultaneous knockdownof both C2 ${alpha}$ and C2ß, the only class II PI3Ks expressedin epidermis, fails to impair differentiation protein induction.

Two conflicting studies have argued for (32) and against (24)a role for PI3K function in epidermal differentiation. Whilethe two studies used different sets of reagents and differentiationconditions, both were limited by exploring the role of PI3Kin this setting using wholly in vitro experiments. In vitroapproaches alone also proved misleading in the present studyand highlighted the need for in vivo genetic experiments, includingloss-of-function efforts via gene deletion, to uncover any requirementsfor PI3K isoform function in specific tissue settings. It isformally possible that multiple other PI3K isoforms cooperateto regulate this process. Future efforts to study this issuemay include multigene knockout animals to explore the impactsof deficiencies in multiple PI3K isoforms on epidermal developmentand differentiation.

The observation that PI3K pharmacologic inhibition blocks differentiationin vitro suggested a role for PI3Ks in this process. One potentialexplanation for the discrepancy between pharmacologic and geneticstudies is that inhibitors altered the function of another proteinindependent of the PI3K family, consistent with the known lackof complete specificity of multiple classes of kinase inhibitors.For example, both LY294002 and wortmannin, widely used inhibitorsof PI3K function, also effectively inhibit the function of themTOR kinase when used at identical concentrations (7). Additionally,the observed findings may represent a potential in vitro artifactwhere inhibitors function in a manner that does not reflectthe effects of inhibitor action in tissue. In agreement withthe latter possibility, we observed no effect of topical LY294002application for 8 weeks to normal mouse skin using an approachdemonstrated previously to achieve significant topical PI3Kinhibition in a cutaneous melanoma model (5). Addressing a potentialrole for alternative PI3K inhibitor-sensitive processes in epidermaldifferentiation will require further studies.

ACKNOWLEDGMENTS

This work was supported by the U.S. Veterans Affairs Officeof Research and Development and by grant no. AR43799 from theNational Institute for Arthritis and Musculoskeletal and SkinDiseases, National Institutes of Health.

We thank J. Domin for generous gifts of PI3K C2 ${alpha}$ antibody andcDNA reagents and A. Oro for the protamine-Cre deleter mice.

FOOTNOTES

* Corresponding author. Mailing address: Program in Epithelial Biology, 269 Campus Drive, Room 2145, Stanford, CA 94305. Phone: (650) 725-5266. Fax: (650) 723-8762. E-mail: khavari{at}CMGM.stanford.edu.

REFERENCES

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