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© The Rockefeller University Press, 0021-9525/2000//1499 $5.00
The Journal of Cell Biology, Volume 150, Number 6, , 2000 1499-1506

Embryonic Lethality of Molecular Chaperone Hsp47 Knockout Mice Is Associated with Defects in Collagen Biosynthesis

^a Core Research for Evolutional Science and Technology (CREST), Japan Science and Technology Corporation (JST), and Department of Molecular and Cellular Biology, Institute for Frontier Medical Sciences, Kyoto University, Sakyo-ku, Kyoto, 606-8397, Japan
^b Field of Regeneration Control, Institute for Frontier Medical Sciences, Kyoto University, Sakyo-ku, Kyoto, 606-8397, Japan
^c Behavioral Genetics Lab, Brain Science Institute (BSI), RIKEN, Wako, Saitama, 351-0198, Japan
^d Department of Molecular Morphology, Kitasato University Graduate School of Medicine, Sagamihara, Kanagawa, 228-8555, Japan
Department of Molecular and Cellular Biology, Institute for Frontier Medical Sciences, Kyoto University, Sakyo-ku, Kyoto, 606-8397, Japan.(81) 75 751 3848

Triple helix formation of procollagen after the assembly of three -chains at the C-propeptide is a prerequisite for refined structures such as fibers and meshworks. Hsp47 is an ER-resident stress inducible glycoprotein that specifically and transiently binds to newly synthesized procollagens. However, the real function of Hsp47 in collagen biosynthesis has not been elucidated in vitro or in vivo. Here, we describe the establishment of Hsp47 knockout mice that are severely deficient in the mature, propeptide-processed form of 1(I) collagen and fibril structures in mesenchymal tissues. The molecular form of type IV collagen was also affected, and basement membranes were discontinuously disrupted in the homozygotes. The homozygous mice did not survive beyond 11.5 days postcoitus (dpc), and displayed abnormally orientated epithelial tissues and ruptured blood vessels. When triple helix formation of type I collagen secreted from cultured cells was monitored by protease digestion, the collagens of Hsp47+/+ and Hsp47+/– cells were resistant, but those of Hsp47–/– cells were sensitive. These results indicate for the first time that type I collagen is unable to form a rigid triple-helical structure without the assistance of molecular chaperone Hsp47, and that mice require Hsp47 for normal development.

Key Words: gene targeting • extracellular matrix • collagen fibril • basement membrane • type I collagen

© 2000 The Rockefeller University Press

	Introduction

Top Abstract Introduction Materials and Methods Results Discussion References

 
As many as 19 types of collagen have been discovered, and each of them has been shown to have a different function. Interstitial collagens like type I and type III are major constituents of the extracellular matrix (ECM) that supports body structure. Nonfibrillar collagen type IV is exclusively found in basement membranes where it provides a scaffold for other ECM components. Others, known as FACIT (fibril-associated collagens with interrupted triple helices) collagens, such as types IX, XII, and XIV, associate with the surfaces of fibril collagens and modify their interactive properties. All collagens have characteristic Gly-Xaa-Yaa (glycine-any amino acid-any amino acid) triplet repeats in their amino acid sequences and form unique triple-helical structures. Mutations that impair the formation of this structure have been identified as the cause of various collagen-related diseases, including osteogenesis imperfecta and Ehlers-Danlos syndrome (Davidson and Berg 1981; Prockop and Kivirikko 1995). The formation of rigid triple helix structures should, thus, be important for collagen function.

During protein synthesis, many proteins known as molecular chaperones interact and assist folding of newly synthesized polypeptides. ER-resident chaperones, including BiP, calnexin, and calreticulin, are involved in folding and translocation of a number of secretory and membrane proteins (for reviews, see Bergeron et al. 1994; Hebert et al. 1995), including collagens. In contrast, Hsp47 is unique in terms of its substrate specificity; that is, it binds exclusively to procollagens and collagens (for reviews, see Nagata 1996, Nagata 1998). The expression and accumulation of various types of collagens are strictly and spatio-temporally regulated in various tissues during mammalian development. The expression of Hsp47 in various cell lines and tissues is closely correlated with the expression levels of various types of collagens under nonstressful conditions (Leivo et al. 1980; Masuda et al. 1994, Masuda et al. 1998).

Hsp47 was shown to transiently bind to newly synthesized procollagen, and to dissociate from procollagen during its transport from the ER to the cis-Golgi compartment (Satoh et al. 1996). When cells were treated with , '-dipyridyl to inhibit prolyl 4-hydroxylation, the secretion of procollagen was prevented and procollagen bound to Hsp47 was retained in the ER (Nakai et al. 1992; Satoh et al. 1996). From these corroborations, Hsp47 has been considered to function as a collagen-specific molecular chaperone and provide a quality control mechanism specific for procollagen maturation (Nagata 1996, Nagata 1998). However, the precise role of Hsp47 as a molecular chaperone in collagen biosynthesis/maturation and mouse development has not yet been elucidated. To address this point, we disrupted Hsp47 alleles by homologous recombination in mice by taking advantage of the fact that the Hsp47 gene exists as a single copy in vertebrates, including human, mouse, rat, chicken, and zebrafish. Here, we show that the disruption of Hsp47 caused severe abnormality in the accumulation of properly processed mature molecules of type I collagen in the embryos, resulting in embryonic lethality before 11.5 days postcoitus (dpc). The truncated form of type IV collagen was also not discovered in Hsp47–/– embryos.

Collagen fibers and basement membranes were hardly detected in knockout mice that displayed abnormally oriented epithelial tissues and ruptured blood vessels. We also report here the establishment of Hsp47–/– fibroblastic cell lines, and show the importance of Hsp47 in the formation of rigid triple helix of type I procollagen by monitoring the protease sensitivity of secreted procollagen.

	Materials and Methods

Top Abstract Introduction Materials and Methods Results Discussion References

 
Gene Targeting
A gene targeting vector was constructed as follows: first, a 9-kb BamHI genomic DNA fragment containing exon 3–6 of the C57BL/6J mouse Hsp47 gene was subcloned, and a neomycin-resistance gene expression cassette, MC1NeoPA (Stratagene), was then inserted between the two XhoI sites of the Hsp47 gene fragment. The 5' flank/neo/3' flank was excised at the KpnI cleavage sites and subcloned into pMCDT-A (Yagi et al. 1990). This targeting vector was linearized and electroporated into E14 embryonic stem (ES) cells derived from mouse strain 129/Ola. ES cells carrying the disrupted allele were microinjected into blastocysts of mouse strain C57BL/6J to produce chimeric mice. Heterozygotes were subsequently bred with both C57BL/6J and ICR to produce mouse lines of C57BL/6J x 129/Ola and ICR x 129/Ola hybrid background, respectively.

Reverse Transcription (RT)-PCR
Total RNA was isolated from 9.5 dpc embryos and RT-PCR was done with an RNA-PCR kit (TaKaRa) using the following primers: Hsp47 forward, 5'-CTGCAGTCCATCAACGAGTGGGC-3'; Hsp47 reverse, 5'-ATGGCGACAGCCTTCTTCTGC-3'; β-actin forward, 5'-CTAAGGCCAACCGTGAAAAGA-3'; β-actin reverse, 5'-AGAGGCATACAGGGACAGCA-3'.

Western Blotting
Proteins extracted from whole embryo at 9.5 dpc were separated by electrophoresis through an 8% SDS-polyacrylamide gel, transferred to nitrocellulose filters (Schleicher and Schell), and probed with a mouse monoclonal anti-Hsp47 antibody (SPA470; StressGen Biotechnologies), rabbit polyclonal antitype I collagen C-telopeptide (LF-67; Fisher et al. 1995), antilaminin, antifibronectin serum, rat monoclonal anti-2(IV) collagen antibody (A22; Sado et al. 1995), or mouse monoclonal anti 1(III) collagen antibody. Peroxidase-conjugated secondary antibodies were used and immunocomplexes were revealed by an ECL detection reagent (Amersham Pharmacia Biotech).

Histological Analysis
Embryos were excised for histological examination, fixed for 1 h in 10% neutralized formalin, and embedded in paraffin. 4-µm thick sections were stained with Gomori's silver impregnation method for reticular fiber. For electron microscopic observation, samples from the Hsp47 null embryos and their normal littermates were processed routinely as described (Tsunenaga et al. 1998).

Establishment of Hsp47-deficient Cells and Protease Digestion of Secreted Collagen
Hsp47+/+, Hsp47+/–, and Hsp47–/– cell lines were established from 8.5 dpc embryos by the method adopted for the establishment of 3T3 cell line as described (Todaro and Green 1963), and genotype analysis was performed by Southern and Northern blot analyses. Protease digestion of secreted collagen was performed as follows. Cells were labeled with 50 µl/ml of L-[2, 3-³H]-proline for 8 h, and the medium containing equal amount of TCA-insoluble radioactivity was used for protease digestion with a mixture of 100 µg/ml trypsin and 250 µg/ml chymotrypsin for 1–5 min at 37°C. Aliquots were treated with 50 µg/ml pepsin overnight at 4°C. Transient transfection of murine Hsp47 cDNA was performed with lipofectamine (GIBCO BRL) as specified by the manufacturer. 50 µg/ml of L-ascorbic acid phosphate magnesium salt N-hydrate was included in all the experiments.

	Results

Top Abstract Introduction Materials and Methods Results Discussion References

 
The Hsp47 gene was disrupted in murine ES cells by the use of the targeting vector shown in Fig. 1 a. Heterozygous mice, which appeared phenotypically normal, were intercrossed to generate homozygous Hsp47–/– mice. Homozygosity for the Hsp47 mutation resulted in embryonic lethality in both C57BL/6 x 129/Ola and ICR x 129/Ola genetic backgrounds. Although homozygous new born mice and embryos after 11.5 dpc were never obtained, the null mutant embryos were recovered with the expected Mendelian ratios at 9.5 dpc and 10.5 dpc (data not shown). The homozygosity of Hsp47–/– mice was determined by Southern blotting using 9.5 dpc embryos (Fig. 1 b). The absence of Hsp47 expression in the null mutant embryo was confirmed at the mRNA level by RT-PCR (Fig. 1 c), and at the protein level by Western blot analysis (Fig. 1 d). The number of somites was consistently smaller in Hsp47 homozygotes than in the wild/heterozygotic littermates from 9.5 dpc (Table ) and neural tube closure was delayed (data not shown), suggesting growth retardation in the knockout embryos. At 10.5 dpc, the mutant embryos were more translucent compared with their wild-type littermates (Fig. 1 f), probably reflecting the low cell density of their bodies, and were so fragile that they could not be manipulated with forceps. The body was shrunken, and the number of erythrocytes decreased before death (data not shown).

View larger version (60K): [in this window] [in a new window] [Download PPT slide]   Figure 1 Targeted disruption of the Hsp47 gene and characterization of the null phenotype. a, Homologous recombination with the targeting vector deletes exon IV and part of exon V, and simultaneously inserts a neomycin-resistance gene. Arrows indicate the orientation of neomycin-resistance gene and DT-A cassettes. Arrowheads indicate the location of primers used in RT-PCR assay. B, BamHI; K, KpnI; X, XhoI. b, Southern blot analysis demonstrating the genotypes of the offspring. A 3' flanking probe shown as FC in a detects a 9-kb BamHI fragment in wild-type genomic DNA and a 6-kb fragment in the targeted allele in mice. Targeted ES clones were confirmed using a 5' external probe (not shown). c, RT-PCR analysis was performed for the offspring using primers shown in a. n, Denotes the lane of negative control in which reactions are performed without RNA. d, Immunoblot analysis of Hsp47 was performed for wild-type, heterozygotic, and homozygotic null mice. B shows the positive control lane with the extract of Balbc/3T3 cells. Lateral views of 9.5 dpc (e) and 10.5 dpc (f) Hsp47–/– homozygous embryos (right) and wild type (left). Embryos were observed before (f) and after (e) fixation with 10% formaldehyde. Bars, 1 mm.

In contrast to Northern analysis, Western blot analysis (Fig. 2) revealed that the mature, propeptide-cleaved 1(I) chain (Fig. 2, ***) was hardly detectable in Hsp47 deficient mice. Instead, the levels of immature procollagen and its intermediately processed forms (Fig. 2, * and **), especially the collagen chain with C-propeptide (pC) form of 1(I) collagen (Fig. 2, **), were higher in Hsp47 deficient mice than in the wild-type or heterozygous littermates. In normal mouse tissues, a low molecular weight form of type IV collagen was detected as previously reported (Iwata et al. 1996), but this form of 2(IV) collagen (arrow) was undetectable in the mutant embryos (Fig. 2, middle). Type II collagen could not be detected, probably because it was poorly expressed at this stage of development (data not shown). No differences in the molecular forms of type III collagen, laminin (Fig. 2, LMN), or fibronectin (Fig. 2, FN) were evident between Hsp47+/+, Hsp47+/–, and Hsp47–/– mice, at least as detected by Western blot analysis.

View larger version (24K): [in this window] [in a new window] [Download PPT slide]   Figure 2 Western blot analyses using specific antibodies against 1(I), 1(III), and 2(IV) chains of collagen, fibronectin (FN), and laminin (LMN) were performed for proteins prepared from 9.5 dpc whole embryos. * and *** in blots for 1(I) collagen indicate pro- and mature 1(I) chains, respectively. ** indicates the pC form of 1(I) chain, because this band is not recognized by the anti–N-propeptide antibody (data not shown).

View larger version (194K): [in this window] [in a new window] [Download PPT slide]   Figure 3 Silver impregnation analysis of 9.5 dpc wild-type (a and c) and homozygous (b and d) embryos. Neuroepithelium and underlying mesenchyme (a and b), and surface ectoderm and underlying mesenchyme (c and d) were analyzed. Hsp47–/– embryos had poorly developed reticular fibers in their mesenchymal tissues (b and d) compared with wild-type embryos (a and c). The basement membrane was hardly detected between the neuroepithelium of the neural tube and the surrounding mesenchymal tissue (b) of the Hsp47–/– embryos, whereas it was clearly detected as black staining in wild-type embryos (a). Neuroepithelium organization was disordered and cell division (arrowheads) was abnormally (closer to the mesenchymal tissue) detected in the cell layer of the neuroepithelium in Hsp47–/– embryos (b). Bars, 20 µm. Electron microscopic observation of the ectoderm in wild-type (e) and Hsp47–/– embryos (f). In e, a bundle of collagen fibrils (arrow) can be seen to reach out towards the lamina densa and to be distributed in the lamina fibroreticularis. The lamina densa (arrowhead) appears as a continuous sheet with a width of 30 nm positioned under the ectoderm (E) and the lamina lucida. The lamina densa (arrowhead) of the ectoderm (E) was interrupted (double arrowhead) and collagen fibrils were hardly discernible in Hsp47–/– embryos (f). The lamina densa seen in Hsp47–/– embryos was 30–50 nm in width, thicker than that in Hsp47+/+ embryos. Bar, 100 nm. Giemsa staining of Hsp47–/– embryos of 10.5 dpc shows the discontinuity of endothelial cells surrounding blood vessels (g, arrowhead) and the leakage of erythropoetic cells (g, arrows). Neuroepithelial cells also were also shown to leak out of the neural tube (h) by Giemsa staining. Bar, 50 µm.

View larger version (55K): [in this window] [in a new window] [Download PPT slide]   Figure 4 Altered protease-sensitivity of procollagen secreted from Hsp47–/– cells. a, The culture media of Hsp47+/+, Hsp47+/–, and Hsp47–/– cells labeled with L-[2, 3-3H]-proline were digested with a pepsin alone at 4°C overnight or a mixture of trypsin and chymotrypsin at 37°C for indicated periods. Arrowheads indicate the positions of collagen 1(I) and 2(I) chains, respectively. b, Transient expression of Hsp47 cDNA in Hsp47–/– cells restored the protease-resistance of collagen chains secreted from the cells. Collagen chains secreted from nonlabeled cells were digested with pepsin alone or with a mixture of trypsin and chymotrypsin, and were detected by Western blotting using rabbit anti–rat 1(I) polyclonal antiserum. The right shows the level of Hsp47 protein detected by anti-Hsp47 mAb (SPA470) after transient transfection with empty vector (mock) or murine Hsp47 expression vector (MH47).

	Discussion

Top Abstract Introduction Materials and Methods Results Discussion References

The phenotypes of Hsp47–/– mice resembled those of Mov13 mice in terms of the embryonic lethality (Schnieke et al. 1983; Lohler et al. 1984), but were more severe. Mov13 mice, with the exception of osteoblastic lineages, are defective in type I collagen production and die before 13.5 dpc (or 16.5 dpc in rare cases) with the mesenchymal necrotic cell death phenotype. The growth of Mov13 and wild-type embryos could not be distinguished until 12 dpc, whereas growth retardation and deficient fibril formation was already apparent in Hsp47–/– embryos at 9.5 dpc. The more severe phenotypes of Hsp47 disruptants may reflect pleiotropic roles for Hsp47 during the maturation of not only type I procollagen, but other procollagens as well, which can be supported by the fact that Hsp47 can interact with types I to V collagens in vitro (Natsume et al. 1994). Indeed, PAM staining (data not shown) and electron microscopic observations (Fig. 3e and Fig. f) indicated that the formation of the basement membrane, whose most important constituent is type IV collagen, was impaired in Hsp47 disrupted embryos. This is consistent with the fact that type IV collagen had the altered character as shown in Western blot analysis (Fig. 2).

As shown in Fig. 4, type I procollagens secreted from Hsp47–/– cells were sensitive to protease digestion, whereas those secreted from Hsp47+/+ or Hsp47+/– cells were resistant to such treatments. As the digestion by the combination of trypsin and chymotrypsin is a well established method for detecting the formation of the rigid triple helix of procollagen, the result shown in Fig. 4 demonstrated that the procollagen secreted from Hsp47–/– cells did not form correctly aligned triple helices. Furthermore, the fact that the transfection of Hsp47 gene into Hsp47–/– cells resulted in the restoration of triple helix formation of the procollagen clearly suggests the important role of Hsp47 in the correct triple helix formation of procollagens in the ER. Hsp47 has been shown to interact preferentially with the triple-helical conformation of procollagens (Koide et al. 2000; Tasab et al. 2000), whereas prolyl 4-hydroxylase (P-4H) interacts with the monomeric chain. It is assumed that Hsp47 binds to and stabilizes the triple helix forms of procollagens to avoid their wasteful unfolding in the ER and that, during heat shock, expression of Hsp47 is induced to prevent thermal denaturation (Koide et al. 2000; Tasab et al. 2000). Indeed, it is reported that procollagen within the cell is more thermostable than the isolated protein (Bruckner and Eikenberry 1984), suggesting the existence of the mechanism that can prevent the collagen triple helix from heat denaturation.

Procollagen conversion to collagen is catalyzed extracellularly by procollagen N-proteinase (PNPase) and procollagen C-proteinase (PCPase), which cleave the N-propeptide and C-propeptide of procollagen, respectively (Peltonen et al. 1985). As shown in Fig. 2, pC1(I) and pN1(III) chains, as well as mature 1(III) chains, were detected in Hsp47–/– mice, suggesting that procollagens were secreted from the cells. The activities of these processing enzymes would not be different in Hsp47–/– mice, since processing of type III collagen in wild-type and heterozygous mice was not different from that in homozygous mice. Rather, the conformation of procollagens in Hsp47–/– mice may be incorrectly aligned, so that it would be incompatible with the efficient processing of the propeptides. This speculation is supported by the fact that the sensitivity to proteases are differed between procollagens in the medium of Hsp47+/+ and Hsp47–/– cells (Fig. 4; discussed above). The removal of the COOH-terminal propeptide of type I collagen is known to be necessary for fibril formation (Peltonen et al. 1985; Adachi et al. 1997). So the physiological effects of Hsp47 disruption, such as the deficiency in fibril formation observed by silver impregnation and EM (Fig. 3b, Fig. d, and Fig. f), can be explained by the accumulation of pro1(I) and pC1(I) molecules in Hsp47-deficient embryos. Western blotting data of Fig. 2 showed that the processing of type III procollagen occurs correctly. As discussed by Bächinger et al. 1980, one possible explanation is that type III procollagen may have an intrinsic ability to form the triple-helical structure more easily than type I collagen. However, at present, we cannot exclude the possibility that type III collagen in homozygous embryos have some conformational abnormalities that cannot be detected by Western blot analysis.

It has been widely held for a long time that collagen, after proline hydroxylation, possesses the intrinsic ability to form the triple helix structure without the intervention of any other cellular protein. However, the results in this paper showing abnormal conformation of collagen molecules secreted from Hsp47–/– cells and accumulation of procollagen in knockout mice clearly indicate that the native collagen structure requires a specific molecular chaperone. The secretion of collagens with aberrant triple helices could result in the loss of tissue integrity and cell viability through impaired constitution of fibrils and basement membranes, which finally result in embryonic lethality. Thus, Hsp47 is an essential chaperone protein specific for collagen maturation and for normal mouse development. Although we have established in this report that targeting of Hsp47 causes aberrant biosynthesis of collagen, it should be carefully examined whether or how Hsp47 is involved in the quality control mechanism of procollagen biosynthesis.

The cyclophilin homologue, NinaA, was reported to function as a rhodopsin-specific chaperone and to be essential for rhodopsin biogenesis in Drosophila melanogaster using transgenic flies harboring mutant ninaA genes (Baker et al. 1994). Like NinaA, Hsp47 exhibits substrate specificity, but other chaperones, such as BiP, protein disulfide isomerase (PDI), calnexin, and calreticulin in the ER do not have such specificity. Thus, Hsp47 is the first substrate-specific molecular chaperone to be identified in mammals. P-4H and PDI have also been shown to act as chaperones in the biosynthetic pathway of collagens. Further study of the Hsp47-deficient cell line should increase our understanding of the secretory process of procollagens, that is, define how each chaperone acts in collagen biosynthesis, and allow a more refined analysis of the characteristic features of other types of secreted collagens, including their precise physical natures.

	Acknowledgments

 
We are very thankful to Drs. Y. Ninomiya and Y. Sado for antitype IV collagen antibody, L. Fisher for antitype I collagen C–telopeptide antiserum, M. Hayashi for antilaminin antiserum, A. Ohshima for mouse monoclonal anti–1(III) antibody. We also thank Drs. K. Yasuda, M. Matsuda, and T. Marutani for assistance with animal care, and Dr. Y. Yasuda for valuable comments.

This study was partly supported by a Grant-in-aid for Scientific Research on Priority Areas (No. 09276102) and Academic Frontier Project from the Ministry of Education, Science, Sports and Culture of Japan.

Naoko Nagai's present address is Institute for Molecular Science of Medicine, Aichi Medical University, Nagakute, Aichi 480-1195, Japan.

Abbreviations used in this paper: ECM, extracellular matrix; ES, embryonic stem; dpc, days postcoitus; P-4H, prolyl 4-hydroxylase; pC, collagen chain with C-propeptide; RT, reverse transcription.

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This Article Abstract Full Text (PDF, 390K) PPT slides of all figures Alert me when this article is cited Citation Map Services Email this article Similar articles in this journal Similar articles in PubMed Alert me to new content in the JCB Download to citation manager Citing Articles Citing Articles via CrossRef Citing Articles via Google Scholar Google Scholar Articles by Nagai, N. Articles by Nagata, K. Search for Related Content PubMed PubMed Citation Articles by Nagai, N. Articles by Nagata, K. Social Bookmarking                            What's this?