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© The Rockefeller University Press, 0021-9525/2000//563 $5.00
The Journal of Cell Biology, Volume 151, Number 3, , 2000 563-572

Cytokeratins 8 and 19 in the Mouse Placental Development

^a Banyu Tsukuba Research Institute (Merck), Tsukuba, Ibaraki 300-2611, Japan
^b National Institute of Radiological Sciences, Inage-ku, Chiba 263-8555, Japan
^c Research Institute for Microbial Diseases, Osaka University, Suita, Osaka 565-0871, Japan
^d The Burnham Institute, La Jolla, California 92037
^e Graduate School of Pharmaceutical Sciences, University of Tokyo, Bunkyo-ku, Tokyo 113-0033, Japan
Laboratory of Biomedical Genetics, Graduate School of Pharmaceutical Sciences, University of Tokyo, Bunkyo-ku, Tokyo 113-0033, Japan.81-3-5841-477881-3-5841-4859

To investigate the expression and biological roles of cytokeratin 19 (K19) in development and in adult tissues, we inactivated the mouse K19 gene (Krt1-19) by inserting a bacterial β-galactosidase gene (lacZ) by homologous recombination in embryonic stem cells, and established germ line mutant mice. Both heterozygous and homozygous mutant mice were viable, fertile, and appeared normal. By 7.5–8.0 days post coitum (dpc), heterozygous mutant embryos expressed lacZ in the notochordal plate and hindgut diverticulum, reflecting the fact that the notochord and the gut endoderm are derived from the axial mesoderm-originated cells. In the adult mutant, lacZ was expressed mainly in epithelial tissues. To investigate the possible functional cooperation and synergy between K19 and K8, we then constructed compound homozygous mutants, whose embryos died 10 dpc. The lethality resulted from defects in the placenta where both K19 and K8 are normally expressed. As early as 9.5 dpc, the compound mutant placenta had an excessive number of giant trophoblasts, but lacked proper labyrinthine trophoblast or spongiotrophoblast development, which apparently caused flooding of the maternal blood into the embryonic placenta. These results indicate that K19 and K8 cooperate in ensuring the normal development of placental tissues.

Key Words: embryo • endoderm • epithelium • keratin • trophoblasts

© 2000 The Rockefeller University Press

	Introduction

Top Abstract Introduction Materials and Methods Results Discussion References

 
Cytokeratin-intermediate filaments are encoded by a multigene family of 20 related polypeptides. They are expressed mainly in epithelial cells depending on the extent of differentiation (Moll et al. 1982). Cytokeratin proteins are classified into two types: smaller and acidic type I, and larger and more basic type II (Steinert and Roop 1988). In simple epithelia, they form cytokeratin filaments through obligate heteropolymerization of the type I and type II proteins in particular combinations. For example, cytokeratin 8 (K8) and cytokeratin 18 (K18); K8, K18, and K19; or cytokeratin 7 (K7), K8, K18 and K19 (Moll et al. 1982; Lane et al. 1983; Sun et al. 1984; Quinlan et al. 1985). The smallest type I cytokeratin, K19 (Mr; 40 kD) was first recognized as a distinct form in squamous cell carcinoma lines (Wu and Rheinwald 1981). Cytokeratins share a common structural organization: a central -helical rod domain flanked by head and tail domains. Although K19 has a highly conserved central -helical rod essential for filament formation (Steinert and Roop 1988) and the head domain, it is distinguished from other cytokeratins by lacking a tail domain (Bader et al. 1986; Ichinose et al. 1989; Lussier et al. 1989; Stasiak et al. 1989). The gene encoding mouse K19 (Krt1-19) is located on chromosome 11, in the immediate neighborhood of the K15 gene (Krt1-15), separated by only 4 kb (Lussier et al. 1990; Nozaki et al. 1994). The human K19 gene (KRT19) is located on chromosome 17 (Bader et al. 1988). While K19 and K15 are coexpressed in certain cell types, they are not in others (Ichinose et al. 1989; Nozaki et al. 1994). K19 is one of the most representative proteins of epithelial cells such as those in the intestine, kidney collecting ducts, gallbladder, mesothelium, and secretory glands (Moll et al. 1982; Sun et al. 1984; Quinlan et al. 1985; Bosch et al. 1988). In the mouse blastocyst trophectoderm, K19 is induced after K8 and K18 upon implantation (Jackson et al. 1980; Nozaki et al. 1988; Takemoto et al. 1991; Tamai et al. 1991). In the mouse embryo proper, K19 mRNA becomes detectable by 9.5 days post coitum (dpc) (Lussier et al. 1989), and is probably expressed earlier (Jackson et al. 1981; Franke et al. 1982). Differentially expressed individual cytokeratins, including K19, are remarkably stable markers in various types of carcinomas even when other markers have been lost (Kasper et al. 1987; Pujol et al. 1993; Moll 1994). Accordingly, cytokeratins are used for carcinoma subtyping regarding the extent of differentiation and their origins, especially for metastatic foci. Progress has been made in understanding the functions of cytokeratins in the skin. Point mutations in cytokeratin genes (Fuchs 1994; McLean and Lane 1995) and transgenic (Vassar et al. 1991) or knockout mice have indicated a structural function for epidermal keratins (for a review, see Magin 1997). Homozygous mutant embryos for the simple epithelia type K8 gene (Krt2-8) are retarded in growth and suffer from internal bleeding, with an abnormal accumulation of erythrocytes in the fetal liver (Baribault et al. 1993, Baribault et al. 1994). These alterations are consistent with a placental or extraembryonic deficiency. While this mutation shows a 94% penetrance in the C57BL/6 background, the proportion of viable homozygotes increases in the FVB/N background, and colorectal hyperplasia and inflammation are observed in adults that escape embryonic lethality. Recently, K8 and K18 have been shown to confer resistance to tumor necrosis factor–induced apoptosis (Caulin et al. 2000). Based on its structure and tissue distribution, K19 has been suggested to counterbalance type II keratins (Ecker 1988; Stasiak et al. 1989). To determine the expression pattern and function of K19, we have constructed a Krt1-19 null mutant allele by knocking in a lacZ cassette at the translation initiation site. We also generated compound homozygotes of Krt1-19 and Krt2-8 mutations and found that homozygous embryos are not viable due to defective placental tissues, a phenotype not observed in the simple homozygous mutants.

	Materials and Methods

Top Abstract Introduction Materials and Methods Results Discussion References

 
Construction of a Krt1-19 Targeting Vector
A recombinant clone containing the mouse Krt1-19 was isolated from a 129/Sv genomic library using a 1.4-kb full-length K19 cDNA fragment as a probe as previously characterized (Ichinose et al. 1989; Nozaki et al. 1994). A 6.5-kb SalI–KpnI fragment containing a part of exon 1 and a 641-bp KpnI–BglII fragment downstream from a KpnI site in exon 1 were excised from this recombinant phage and subcloned in the pUC19 vector. The ATG translation initiation codon in exon 1 was converted to a KpnI site. A 365-bp KpnI fragment in exon 1 was replaced with a cassette containing a lacZ reporter and PGKneobpA (Soriano et al. 1991). Thus, the targeting vector pJBX carried a long homology arm of 6.1 kb.

Transfection of Embryonic Stem Cells and Selection of Targeted Clones
D3a2 embryonic stem (ES) cells (Shull et al. 1992) were cultured on neomycin-resistant (neo^r) mouse embryonic fibroblasts (Oshima et al. 1995). 50 µg of the targeting vector were linearized at the unique Sse8387I site and electroporated into 10⁷ ES cells at 250 V and 500 µF. 24 h later, 150 µg/ml (titer) of G418 (Geneticin; Sigma-Aldrich) was added. 7 d later, single colonies were isolated and cultured in duplicate. G418-resistant colonies were screened for homologous recombination by PCR using oligonucleotide primers: one complementary to neo^r; PGK^r (5'-CTA AAG CGC ATG CTC CAG ACT-3') and the other located 92-bp downstream from the 3' BglII site in Krt1-19; K19-R2G (5'-AAG AGC TCC CTG ACT AGA TTC AAG TTA ACT-3'). 35 cycles of amplification were performed (denaturation, 1 min at 94°C; hybridization, 2 min at 60°C; and elongation, 2 min at 72°C) in 50 µl reaction mixtures containing 50 pmol of each oligonucleotide, 1 U Taq polymerase (TAKARA), 0.5 U Perfect Match^® (Stratagene), and 1 µl of the crude cell lysate in each mixture. As shown in Fig. 1 (below), only homologous recombinants showed a 739-bp band. Candidates for homologous recombinants were expanded and verified by Southern hybridization with probes either internal (a 630-bp PstI–XbaI fragment containing the neo^r segment of pPGKneobpA) or external (a 556-bp fragment located downstream from the 3' BglII site) to the targeting vector sequence.

View larger version (29K): [in this window] [in a new window] [Download PPT slide]   Figure 1 Inactivation of the mouse K19 gene (Krt1-19) by homologous recombination. (a) Structures of the wild-type allele, targeting vector pJBX, and the targeted allele. The targeting vector contained two regions of homology to the genomic DNA, sandwiching a lacZ reporter-neo selection cassette. Homologous recombination resulted in deletion of most of exon 1, and the lacZ reporter was transcribed from the Krt1-19 promoter. Filled boxes represent exons; noncoding regions are shown as solid lines. Arrowheads indicate the positions of the PCR primers for genotyping: KO PCR, primers for the targeted allele, and WT PCR, primers for the wild-type allele. The probe for Southern hybridization is shown as a solid line. RI, EcoRI site. Arrows beneath the lacZ reporter-neo selection cassette show the transcriptional directions. (b) Genotype analysis of the wild-type, heterozygous, and homozygous mutant mouse tail DNAs. (Top) Transmission of the targeted allele to the progeny as determined by PCR. KO, targeted allele (739 bp); WT, wild-type allele (958 bp). (Bottom) Southern hybridization analysis. The EcoRI fragments of 4.5 and 1.6 kb derived from the wild-type and targeted alleles, respectively. (c) Northern hybridization analysis of K19 mRNA in the wild-type, heterozygous, and homozygous mice. 10 µg of the total RNA purified from the colon (c), or small intestine (i) were loaded in each lane and probed with a K19 cDNA probe (Ichinose et al. 1989). The arrowhead indicates the size of the K19 mRNA (1.4 kb).

Histochemical Localization of the β-Galactosidase Activity
For the timing of embryos, the morning of the vaginal plug was considered as 0.5 dpc. When removed from the decidua, embryos were staged according to Kaufman 1992 and genotyped as described above using DNA extracted from the yolk sac or from the embryo itself. To detect the β-galactosidase activity, the samples were incubated at 30°C for 30 min to 3 h, depending on their sizes in a staining solution (5 mM potassium ferricyanide, 5 mM potassium ferrocyanide, 1 mg/ml X-gal in PBS). For paraffin sectioning, samples were fixed in 4% paraformaldehyde according to the standard procedures.

Immunohistochemistry
For immunofluorescence staining, tissues were fixed in 100% methanol at 4°C for 10 min, rinsed in PBS, and embedded in the O.C.T. compound. The frozen sections were prepared at 20-µm thickness, followed by incubation in 0.3% H₂O₂/PBS for 30 min at room temperature. Sections of embryos and adult tissues were incubated with a blocking solution (3% BSA, 5% goat serum, and 0.2% Triton X-100 in PBS) for 1 h at room temperature. The primary antibodies TROMA-1, -2, and -3 raised against K8, K18, and K19, respectively, were obtained from Dr. Kemler (Max-Planck Institute of Immunology, Freiburg, Germany; Kemler et al. 1981; Boller et al. 1987), and were used at a dilution of 1:10 and incubated with the specimens for 1 h at room temperature. Antibodies against K7 and Kip2 were purchased from Euro-Diagnostica and Santa Cruz Biotechnology, Inc., respectively. Sections were washed, and then incubated with FITC-conjugated secondary antibodies (Amersham, UK). For peroxidase-coupled reactions, tissues were fixed in 4% paraformaldehyde or 70% ethanol and embedded in paraffin. Sections were incubated with peroxidase-conjugated secondary antibodies (Amersham Pharmacia Biotech) using a substrate kit (Vector Laboratories) according to the manufacturer's protocol.

In Situ Hybridization of Whole Mount Embryos
Whole mount in situ hybridizations of the 9.0–9.5-dpc embryos were carried out as described previously (Saga et al. 1996) using digoxigenin-UTP–labeled single-strand RNA probe. The K19 probe was transcribed from a K19 cDNA fragment (Ichinose et al. 1989).

	Results

Top Abstract Introduction Materials and Methods Results Discussion References

 
Disruption of the Mouse K19 Gene (Krt1-19) by Homologous Recombination in ES Cells
To construct Krt1-19 knock out mice, one of the Krt1-19 alleles was inactivated by homologous recombination in ES cells. The translation initiation site of Krt1-19 was disrupted so that a bacterial lacZ gene was placed under the control of the Krt1-19 promoter (Fig. 1 a). 200 G418-resistant clones were analyzed, and three independent homologous recombinant candidates were isolated. Homologous recombination in these ES clones were verified further by PCR and Southern analyses (Fig. 1 b). All three recombinant ES lines were injected into C57BL/6 (B6) blastocysts and two germ line chimeras were generated. About half of their agouti offspring carried the knockout allele. The heterozygous mutant mice were viable, fertile, and appeared normal.

Upon intercrosses of heterozygous mutants, the distribution of the wild type (+/+), heterozygous (+/–), and homozygous (–/–) mice were not significantly different from the expected Mendelian ratio in the F₁ and B6 backcross mice (Table ). In the FBV/N backcross offspring, however, the homozygote numbers were smaller than expected (P < 0.05). While the reason for this phenomenon remains to be investigated, the FVB/N K19 mutant was maintained thereafter as homozygotes because they survived and reproduced without affecting the litter size or the sex ratio (data not shown). The homozygous Krt1-19 mutants did not show any particular phenotypic changes, and appeared identical to their heterozygous and wild-type littermates in their gross anatomy, histology, and behavior. Up to the age of 20 mo, we have not observed any difference in changes associated with aging.

View larger version (57K): [in this window] [in a new window] [Download PPT slide]   Figure 2 Immunofluorescence staining of K19, K8, K18, and K7 in the K19 gene heterozygous and homozygous mutant mouse intestines. Frozen sections of the adult mice were fixed with methanol and stained with TROMA-3 (anti–K19), -1 (anti–K8), and -2 (anti–K18), and an anti–K7 mAb.

In the preimplantation embryo, the trophectoderm cells of the blastocyst were stained only very weakly with X-gal. In the 6.0-dpc embryos, β-galactosidase was expressed only in the ectoplacental cone. In the 7.0-dpc embryo, the enzyme activity was detected mainly at the ectoplacental cone (data not shown). In the late primitive streak stage, β-galactosidase was expressed in the embryo proper, at the notochordal plate, and the node (Fig. 3, a and b). Shortly after (7.5–8.5 dpc), an arch-shaped staining appeared in the posterior embryo (Fig. 3 c). The diameter of this arch became smaller thereafter and the staining was localized in the hindgut pocket. When the foregut and hindgut invaginations were formed, the endodermal cells lining them expressed β-galactosidase (Fig. 3d and Fig. e). Later (9.0–9.5 dpc), β-galactosidase expression was limited to the primitive gut and the notochord (Fig. 3, f–h). In vivo, cytokeratins are not stable unless type I and type II polypeptides are copolymerized (Kulesh et al. 1989). To confirm the expression patterns monitored by the β-galactosidase activity, the K19 mRNA and protein were analyzed in the embryos. Expression of the endogenous Krt1-19 gene essentially corresponded to the β-galactosidase activity, although there were subtle differences in the signal intensities (data not shown).

View larger version (98K): [in this window] [in a new window] [Download PPT slide]   Figure 3 Expression of the β-galactosidase gene (Krt1-19-lacZ) in the heterozygous mouse embryos at 7.5–9.0 dpc. (a and b) A representative embryo at 7.5 dpc in the anterior and posterior views, respectively. Note the β-galactosidase activity in the notochordal plate, node, and ectoplacental cone. (c) A representative embryo at 8.5 dpc in the posterior view. Note the β-galactosidase activity in an arch pattern (arrows). (d and e) Another embryo at 8.5 dpc in the anterior (d) and posterior (e) views. Note that this embryo is more progressed in development than that in c: the arch pattern of the β-galactosidase staining at the hindgut (e, arrows) is much smaller than that seen in the embryo shown in c. Also note the staining inside the foregut in d (arrow). (f and g) A representative embryo at 9.0 dpc. (h) A transverse section of the same embryo shown in f and g (Eosin counterstaining). hf, head fold; nc, notochordal plate; nd, node; pg, primitive gut. All dissection micrographs (whole mount in situ staining) were taken under a dark-field illumination, except a and g, which were in a bright field. Bar, 100 µm.

View larger version (132K): [in this window] [in a new window] [Download PPT slide]   Figure 4 Colocalization of K8 and K19 in the mouse extra embryonic tissues. Immunohistochemical staining of the wild-type embryos in utero at 7.5 dpc with TROMA-3 (anti–K19), TROMA-1 (anti–K8), and anti–Kip2 antibodies. Note that K19 and K8 are expressed in the cytoplasm, whereas Kip2 is in the nucleus. (a and b) Staining for K19. (c and d) Staining for K8. (e and f) Staining for Kip2. epc, ectoplacental cone; gc, giant cells; glc, glycogen cells; pe, parietal yolk sac endoderm; ve, visceral yolk sac endoderm. Note that a, c, and e are serial sections, while b, d, and f are a higher magnification of the sections in a, c, and e, respectively, Bars: a, c, and e, 100 µm; b, d, and f, 50 µm.

View larger version (70K): [in this window] [in a new window] [Download PPT slide]   Figure 5 Smaller placentas and embryo growth retardation in the K8/K19 compound homozygous mutant concepti. (a) A Krt2-8 (–/–):Krt1-19 (–/–) conceptus at 9.75 dpc. Note a red lesion (arrowhead). (b) A Krt2-8 (–/–):Krt1-19 (–/–) embryo, showing a retarded growth. (c) A Krt2-8 (+/+):Krt1-19 (–/–) conceptus at 9.75 dpc. Arrow indicates the implantation site. (d) A Krt2-8 (+/+):Krt1-19 (–/–) embryo as a control. Note that a and c, and b and d, were photographed at the same magnifications. (e) Comparison of the placenta between a K8/K19 compound homozygote and a simple K19 homozygote, stained for β-galactosidase at 9.75 dpc. (–/–,–/–) Compound homozygote [i.e., Krt2-8 (–/–):Krt1-19 (–/–)]; (+/+,–/–) simple K19 homozygote [Krt2-8 (+/+):Krt1-19 (–/–)]. (f) A higher magnification of the compound homozygous conceptus in e.

View larger version (91K): [in this window] [in a new window] [Download PPT slide]   Figure 6 Comparison of the placental regions at 10.5 dpc between the K8/K19 compound homozygotes and simple K19 homozygotes. (Left) Sections from the K8/K19 compound homozygous concepti [Krt2-8 (–/–):Krt1-19 (–/–)]. (Right) Sections from the simple K19 homozygous concepti [Krt2-8 (+/+):Krt1-19 (–/–)]. (Stained for β-galactosidase with hematoxylin counterstaining.) Note the lesion with the maternal blood (*) and the degenerated allantoic tissue with less vascularization compared with the healthy giant cells and the spongiotrophoblasts in b, d, f and h. In the normal placenta, β-galactosidase (K19) was expressed in the giant cells and the spongiotrophoblasts, but not in the allantois or the labyrinthine trophoblasts. Note the degeneration in the spongiotrophoblasts and the labyrinthine trophoblasts in the compound homozygotes. Arrows in g indicate nucleated embryonic erythrocytes. al, allantois; e, embryonic blood; gc, giant cells; lb, labyrinthine trophoblast; m, maternal blood; sp, spongiotrophoblast. Bars, 100 µm.

View larger version (84K): [in this window] [in a new window] [Download PPT slide]   Figure 7 Degeneration of the placenta in the K8/19 compound homozygous concepti at 9.5 dpc; comparison with the K19 homozygous controls. (a–f) Double staining with X-gal for the β-galactosidase activity (greenish blue), and with a specific antibody for Kip2 (brown), followed by a light counterstaining with hematoxylin. Note that the greenish tinge of the blue color for X-gal is due to an electronic enhancement; and that Kip2 is expressed in the nuclei. *The placental lesion; al, allantois; gc, giant cells; lb, labyrinthine trophoblast; and sp, spongiotrophoblast. (g and h) Staining for K7 by indirect immunofluorescence microscopy. Note that image g was electronically enhanced more than h. (Left) Samples of the K8/K19 compound homozygotes [Krt2-8 (–/–):Krt1-19 (–/–)]. (Right) Samples of the simple K19 homozygotes [Krt2-8 (+/+):Krt1-19 (–/–)]. Bars: (a–f) 100 µm; (g and h) 1 µm.

	Discussion

Top Abstract Introduction Materials and Methods Results Discussion References

 
Our results suggest that the K19 promoter is active in the gut epithelium both in embryos and adults. At 8.0 dpc, β-galactosidase was expressed in an arch pattern in the posterior embryo. And this expression was soon restricted to the inner wall of the hindgut pocket. If K19 is expressed in the stem cells of the endoderm, this arch-shaped cluster of cells is likely to be the precursor of the hindgut endoderm. Use of the K19 expression as a marker may help understand the gut differentiation and development in embryos and adults. Taking advantage of this finding, we recently constructed a gene knockin mouse strain in which a bacteriophage P1-derived recombinase gene cre was placed under the control of the K19 gene promoter (Krt1-19^cre). This mouse strain has turned out to be very useful in introducing conditional mutations in a gut-specific manner, because a floxed β-catenin–stabilizing mutation caused thousands of polyps in the intestines of the offspring when crossed with the Krt1-19^cre mice (Harada et al. 1999).

Type I cytokeratins, K18 and K19 can copolymerize with type II cytokeratins such as K8 and/or K7. Our results suggest that depletion of K19 per se does not interfere with embryonic development or postnatal life in the mouse, even though K19 is expressed at substantial levels in the developing embryo and in the adult. Given the evolutionary conservation of K19 across the vertebrates, it is reasonable to assume that K19 plays an important role that confers a selective advantage. It remains to be investigated whether K19 null mice show changes in such characteristics as tumor development or wound healing. Defects may become apparent in the K19 null mice when they are exposed to a less-protected environment rather than laboratory conditions. The absence of an overt phenotype may be due to compensatory functions of K18, which is coexpressed in the extraembryonic tissues, and K20, which is also coexpressed in the intestine (Moll et al. 1990; Calnek and Quaroni 1993). If K19 and K8 contribute to the same function, the two mutant alleles should interact genetically. Our results confirmed this prediction: the compound homozygous embryos have a more severe phenotype than embryos deficient in only one of the two genes. In the FVB/N background, >50% of the homozygous K8 null embryos survive to adulthood (Baribault et al. 1993). However, no compound homozygotes were found among >200 newborn pups. This result indicates a marked increase in the penetrance of the lethal phenotype to 100% in the compound homozygotes, possibly at an earlier stage than K8 homozygotes. The compound homozygous embryos have defects in the placenta, the major site of gas and metabolite exchanges between the maternal and fetal blood. The mouse placenta consists of three morphologically distinct trophoblast layers; namely, the labyrinthine trophoblast, spongiotrophoblast, and giant cell layers (Rossant 1995; Rossant and Croy 1985). In the compound homozygous placenta, giant trophoblasts were increased in number, whereas the spongiotrophoblasts and labyrinthine trophoblasts were decreased. Failure to properly form the chorioallantoic placenta results in embryonic lethality at midgestation (Cross et al. 1994; Copp 1995). Recent gene knockout results show that the placental development is controlled by such genes as basic helix-loop-helix transcription factors Mash2 (Guillemot et al. 1994) and Hand1 (Riley et al. 1998), orphan nuclear receptor Errb (Luo et al. 1997), and Ets2 (Yamamoto et al. 1998). In FVB/N K8 knockout mice that escape embryonic lethality, partial hepatectomy results in gross structural alterations and explanted hepatocyte death (Loranger et al. 1997). This may reflect hypersensitivity to tumor necrosis factor (TNF), which is moderated by K8 and K18 (Caulin et al. 2000). The primary cause of early embryonic lethality of K8 homozygous mutants is likely due to placental malfunction because, in the B6 background, K8-deficient embryos are rescued by aggregation with tetraploid embryos (Kupriyanov and Baribault 1998; Baribault, unpublished results). This leads to an intriguing consideration that TNF family cytokines may be involved in the placental abnormalities of both B6 K8-deficient embryos and the FVB/N compound homozygotes described here, because TNF is implicated in trophoblast function (Rasmussen et al. 1999).

Our results indicate that compound K8 and K19 homozygous mutants, in a permissive genetic background for K8 homozygotes, are defective in the development of placental tissues. K8 deficiency results in the complete loss of both K18 and K19 filaments in the liver and yolk sac (Baribault and Oshima 1991; Baribault et al. 1993). Why is the phenotype of the compound homozygotes more severe than the simple K8 homozygotes? Perhaps K8 is not the only type II keratin functional in the midgestational placenta. Indeed, low levels of K7 are detectable in embryonic placenta in addition to K18 and K19 (Fig. 7). The removal of K8 results in the degradation of K18 and most K19. However, the residual K19 that is polymerized with K7 would remain in the K8 homozygotes, whereas K19 is also removed in the compound homozygotes. The residual weak signal for K7 in the compound homozygotes may be due to K7/K8 heteropolymers.

It is worth noting that K18 null mice are viable, fertile, and show a normal life span. This may be due to compensation by K19. Old K18 null mice, however, develop a distinctive liver pathology with abnormal hepatocytes containing K8 aggregates (Mallory bodies). Additionally, in the K18 null mice, K7 was absent or markedly reduced in the uterus, where K7, 8, 18, and 19 are to be coexpressed. This observation indicates that cytokeratins have distinct assembly characteristics particular to the specific tissues (Magin et al. 1998).

In conclusion, we have constructed a K19 gene knockout mouse strain, the homozygotes of which were viable, fertile, and appeared normal. When the mutation was introduced into a viable K8 gene knockout mouse strain, however, the compound homozygous embryos died in utero due to defects in the placenta. These results indicate that K19 and K8 cooperate in ensuring the normal development of placental tissues.

	Acknowledgments

 
We thank M. Oshima and Y. Saga for helpful discussions, and R. Kemler for the gift of the TROMA-1, -2, and -3. We also thank N. Sugimoto, R. Nakajima, and H. Oshima for technical assistance.

This work was supported in part by the Joint Research Fund between The University of Tokyo and Banyu Pharmaceutical Co., grants from Monbusho (MESSC) and the Organization for Pharmaceutical Safety and Research of Japan, and grant CA42302 from the National Cancer Institute.

Submitted: 9 June 2000

Revised: 16 August 2000

Accepted: 12 September 2000

Dr. Ishikawa's present address is Department of Pharmacology, Graduate School of Medicine, Kyoto University, Sakyo-ku, Kyoto 606-8501, Japan. Dr. Bösl's present address is Zentrum für Molekulare Neurobiologie, Universität Hamburg, Hamburg, D-20246, FRG. Dr. Baribault's present address is Deltagen Inc., San Carlos, CA 94061.

Abbreviations used in this paper: dpc, days post coitum; ES, embryonic stem; K, cytokeratin.

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