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J Biol Chem, Vol. 274, Issue 31, 22053-22059, July 30, 1999
,,
**
From the Department of Periodontology, Harvard School
of Dental Medicine, Boston, Massachusetts, 02115, the
§ Department Cell Biology, Harvard Medical School, Boston,
Massachusetts, 02115, the ¶ Department of Orthodontics, University
of Alabama at Birmingham School of Dentistry, Birmingham, Alabama
35213, and The Jane and Jerry Weintraub Center for
Reconstructive Biotechnology, Division of Advanced Prosthodontics,
Biomaterials and Hospital Dentistry, UCLA School of Dentistry,
Los Angeles, California 90095
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ABSTRACT |
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 ABSTRACT
 INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
REFERENCES
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This paper reports the identification of two
structural variations in the NC1 domain of rat and mouse type XII
collagen. The long NC1 domain encoding 74 amino acids showed homology
to chicken type XII and XIV collagens. The short NC1 domain was
composed of 19 amino acids. Through genomic DNA analyses, two
alternative exons were identified, each of which contained the variable
NC1 sequence. With the amino-terminal NC3 splicing alternatives, we propose here a new descriptive nomenclature: types XIIA-1 and XIIB-1
which include a long NC1 sequence encoded by exon 1 (from the 3'-end),
and types XIIA-2 and XIIB-2 which include a short NC1 sequence encoded
by exon 2. Types XIIA-1 and XIIB-1, the predominant transcripts in
15-day old mouse embryos, showed decreased expression in 17-day old
embryos when type XIIB-2 expression was sustained at constant levels.
In adult mice, type XIIB-1 associates with ligament and tendon, whereas
type XIIB-2 is expressed in various other tissues. The long NC1 domain
contains an extended acidic region (pI = 3.4) followed by a
terminal basic region (pI = 13.8). Because the short NC1 domain
lacks these features, structural variations in the type XII collagen
NC1 domain suggests different functional roles in a tissue-specific fashion.
The primary structure of chicken and mouse type XII collagen has
been determined from overlapping cDNAs and suggests that type XII
collagen may interact in several ways with other matrix molecules
(1-3). For example, the amino-terminal region of type XII collagen
forms three "finger-like" projections, the NC3 domains (see Fig. 1)
(4) which contain multiple repeats of fibronectin type III-like
subunits, the domain A of von Willebrand factor, a region homologous to
the NC4 domain of type IX collagen, as well as RGD sequences. Because
of its adhesive structure, it has been proposed that this region of
type XII collagen may play a role in the interactions between
extracellular matrix molecules and cells, thus contributing to the
physical state of the extracellular matrix (5).
The carboxyl-terminal region of type XII collagen contains
triple-helical domains (COL1 and COL2) interrupted and flanked by
non-triple-helical domains (NC1 and NC2)
(Fig. 1). This structural feature is
characteristic of a class of collagens, the Fibril Associated Collagen with
Interrupted Triple helices or
FACIT1 (4, 6). Fibril
association through the carboxyl-terminal region has been postulated
for members of the FACIT class of molecules. The details of such
association with cartilage type II collagen fibrils have been
characterized for type IX collagen (7-10). In type XII collagen, the
"fibril association region" makes up less than 10% of the molecule
and is thought to be integral to molecular interactions with type I
collagen fibrils. However, although there is indirect evidence
available to support such an interaction (5, 11-13), the details of
type XII collagen "fibril association" have not yet been fully
elucidated.
INTRODUCTION
TOP
ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
REFERENCES
View larger version (17K):
[in a new window]
Fig. 1.
Schematic drawing of type XII collagen
structure composed of the amino-terminal NC3 domain of multiple repeats
of fibronectin type III and von Willebrand factor A domain sequences
and the carboxyl-terminal Fibril Associated Region
containing the NC1, COL1, NC2, and COL2 domains.
One obstacle is the considerable difference in the NC1 domain structure
of chicken and mouse type XII collagens. Chicken type XII collagen
contains a long NC1 domain composed of 76 amino acids (1, 2), whereas
mouse type XII collagen has only a 22-amino acid NC1 domain (3). The
purpose of this study was to determine the structure of the carboxyl
region of mammalian type XII collagen. In this report, we present
evidence for two structural variations in the NC1 domain of type XII
collagen that are generated by alternative splicing in a
tissue-specific fashion.
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EXPERIMENTAL PROCEDURES |
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ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
REFERENCES
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cDNA Cloning and Sequencing-- To obtain cDNAs encoding the COL2, NC2, COL1, and NC1 domains of rat and mouse type XII collagen, the 3'-rapid amplification of cDNA ends was adapted (14) using poly(A)+ RNA isolated from adult rat and mouse maxillary dento-alveolar tissues or total RNA from neonatal mouse skin. Site-directed coding and nested primers were designed based on the previously reported sequence of rat (15) and mouse cDNAs (3). Primers 5'-GGT CCT CCA GGC CCT CAG GG-3' and 5'-(CAU)4 CCA GGA GAA CCG GGT CGC CA-3' were used to clone rat type XII collagen cDNAs. Primers 5'-TGG CAG TGC TGG AGC CAG AGG AG-3', 5'-(CAU)4 TAT TGT GAT TCA TCC-3', and 5'-(CUA)4 TGA AAA ATG CCT CTT TTG-3' were used to clone mouse type XII collagen cDNAs. PCR products were analyzed on Southern blots and cloned into the pAMP 1 vector (Cloneamp system, Life Technologies, Inc.) or the T vector (pT7 Blue vector, Novagen). The DNA sequences were determined by the chain-termination method (16).
Exon-Intron Structure Analysis and Sequencing of Genomic DNA
Clones--
Tail tissue from rats and mice were used to isolate
genomic DNA samples. Two separate 3'-PCR primers (5'-CAA ACT GTA AGC
AGC ACT-3' and 5'-TGA AAA ATG CCT CTT TTG-3') were designed to encode the reverse and complementary sequences of each of the different 3'-untranslated regions of type XII collagen cDNAs. Common
5'-primers were designed from the coding sequence of the COL1 and NC1
domains: 5'-TAT TGT GAT TCA TCC-3' and 5'-ATT CAT CCC AGT GTG CCA GCA
T-3'. Either a conventional PCR or long range PCR protocol (TaqPlus system, Stratagene) was used to amplify the 
1(XII) collagen gene fragments, which were then confirmed by Southern blots. The initial experiments suggested that the exon involved in the short NC1 variant
was located on the 5'-side of the exon involved in the long NC1
variant. To confirm this exon orientation, a separate PCR experiment
was performed using a coding primer within the "short NC1" exon,
5'-GGT TCC GGC TAA CAA ACT-3', and the anti-coding primer in the
"long NC1" exon, 5'-GCA GCG ACT CTA TGT TCA TAG TCT TGC AAA-3'.
These PCR products were cloned and sequenced to identify the
exon-intron junctions.
RNA Transfer Blot Analysis--
A multiple tissue RNA transfer
blot with poly(A)+ RNA from whole mouse 7-, 11-, 15-, and 17-day old
embryos was purchased from CLONTECH. Hybridization
probes were generated from the subcloned fragments of exon 1 and exon
2, separately encoding "long NC1" and "short NC1" specific
sequences. In some experiments, an antisense-rich linear amplification
PCR was used to prepare the hybridization probes. As a positive
control, cDNA of a 370-bp HindIII fragment (MRK)
encoding the mouse type XII collagen NC3 domain was used (3). A mouse
-actin probe was used as a housekeeping gene control.
Ribonuclease Protection Assay--
Mouse clones SB#2 and SB#3,
containing a 153-bp insert of the long NC-1 variant and a 102-bp insert
of the short NC-1 variant, respectively, were used to synthesize
riboprobes labeled with [32P]UTP (MAXIscript, Ambion).
The MRK clone containing a 370-bp insert of mouse type XII collagen NC3
domain sequence and mouse -actin were used as a positive control and
as a housekeeping gene control. The ribonuclease protection experiment
was performed with 20 µg of total RNA from each of the following
mouse tissues: sternal cartilage, dento-alveolar tissue, eye, skin, and
tail; the protected bands were analyzed using a computerized program (Kodak Digital Science 1D).
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RESULTS |
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TOP
ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
REFERENCES
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Two rat type XII collagen cDNAs were cloned: AK#M, a 1813-bp
sequence (GenBankTM U57362); and AK#G, an 862-bp sequence
(GenBankTM U57361). DNA sequencing revealed that both
cDNAs encoded homologous DNA sequences for the COL2, NC2, and COL1
domains of 1(XII) collagen chains (Table
I). However, the AK#M and AK#G clones
contained striking sequence differences in the NC1 domain (74 and 19 aa, respectively) and in the 3'-untranslated regions (862 and 76 bp, respectively) (Table I and Fig. 2). When
compared with the published chicken type XII collagen sequence, these
rat clones showed highly conserved nucleotide sequences (COL2, 81%;
NC2, 87%; and COL1, 79%) as well as amino acid sequence homology
(COL2, 94%; NC2, 98%; and COL1, 93%).
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The isolated mouse type XII collagen cDNA, ER#K (GenBankTM U57095), exhibited a sequence highly homologous to the rat AK#G clone with a short NC1 domain (19 aa; 100% homology) and a short 3'-untranslated region (63 bp long) (Table I and Fig. 2). Four of four mouse clones, which were amplified from the neonatal mouse skin total RNA sample, contained identical sequences, with the exception that the poly(A) tail varied from A19 to A60. The separately isolated mouse cDNA from the dento-alveolar tissue total RNA sample, SB#1, contained a long NC1 sequence (74 aa long) that was 93% homologous to the rat clone AK#M (Table I and Fig. 2).
The data, based on these cDNAs, suggested the presence of
alternative exons in the 3'-end of the 1(XII) gene. Rat and mouse genomic DNAs were examined by PCR analyses; two alternative exons were
identified (Fig. 3). Exon 1 (from the
3'-end) encoded the variable sequence of the long NC1, whereas exon 2 (from the 3'-end) encoded the variable sequence of the short NC1. Both
exons 1 and 2 contained separate translational termination codons (TAA
and TGA, respectively) and separate 3'-untranslated regions. At the terminal end of exon 2, we detected the poly(A) signal consensus sequences
AATACT in the rat gene and AATACA in the mouse gene (Fig.
3). An exon-intron junction was detected at the beginning of each of
the variable sequences. The split codon exon junction structure
generates G AG (Glu) at the 17th amino acid residue of the long NC1
domain and G GT (Gly) at the 17th amino acid residue of the short NC1
domain (Figs. 2 and 3). Thus, an alternative splicing mechanism is
strongly suggested to generate the long and short NC1 domains of type
XII collagen.
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Exon 3 (from the 3'-end) encoded the common NC1 sequence and part of the COL1 domain. The intron sizes between exons 1 and 2 and between exons 2 and 3 were estimated at 1.4 and 1.1 kilobase pairs, respectively. DNA sequence analyses revealed that the previously reported mouse NC1 domain sequence (3) matched the intron sequence immediately to the 3'-side of exon 3 (Fig. 3).
Type XII collagen transcripts also contain separate alternative
splicing variants, at the 5'-region of the 1(XII) gene, that generate the long and short NC3 domains, or type XIIA and XIIB, respectively. Poly(A)+ RNA from mouse embryos at days 15 and 17 showed
the presence of both type XIIA (approximately 10 kb) and XIIB
(approximately 7-8 kb) collagen mRNAs using MRK (mouse type XII
collagen NC3 domain) as a probe. When a fragment of mouse genomic DNA
containing the exon 1 sequence (long NC1) was used as a probe, both the
10- and 7-8-kb forms of type XII collagen mRNA were positively
recognized. The expression pattern of long NC1 type XII collagen was
similar to the pattern of the mRNA recognized by the MRK probe,
which peaked in 15-day old mouse embryos and decreased in 17-day old
embryos (Fig. 4). The exon 2 probe (short NC1) recognized primarily the 7-8-kb form of type XIIB collagen mRNA but only weakly hybridized
with a 10-kb type XIIA collagen mRNA. The expression of short NC1
type XIIB collagen mRNA remained constant during the late stages
(15- and 17-day old) of mouse embryo development (Fig. 4).
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The relative mRNA levels of type XII collagen varied among the
different tissue specimens (cartilage, dento-alveolar tissue, eye,
skin, and tail). The ribonuclease protection assays revealed an
exceedingly high level of expression of type XII collagen with the long
NC1 domain in dento-alveolar and tail tissue specimens compared with
other mouse tissues and revealed moderate expression in cartilage
(Fig. 5). Expression of type XII collagen
with the short NC1 domain in the mouse was noticeably present in all
tissues tested (Fig. 5).
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DISCUSSION |
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TOP
ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
REFERENCES
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The newly discovered sequence variations in the NC1
domain of rat and mouse type XII
collagen indicated the following characteristic substructures. At the
amino-terminal end of the NC1 domain immediately adjacent to the COL1
domain, there is a "common region" that contains 16 amino acid
residues, which are 100% conserved in rat and mouse NC1 variants
(Fig. 6). The short NC1 domain found in
the rat AK#G and mouse ER#K clones extends three additional amino acid
residues from the common region prior to the termination codon. The
short NC1 domain sequence, with a total of 19 amino acid residues,
shows great similarity to the previously reported 22-amino acid mouse NC1 domain sequence deduced from cDNA mc102T (3) (Table I). However, based on the differences between the amino acid and nucleotide sequences at the carboxyl end of the coding region and the
3'-untranslated regions, the newly discovered short NC1 sequence should
be considered distinct. These short NC1 sequences contain two conserved
locations of cysteinyl residues, one at the end of the COL1 domain and
the other at the fifth position in the NC1 domain. This structure is
homologous to the corresponding domain of type IX collagen chains,
which were recently shown to possess all the necessary information for
chain selection and trimer assembly in vitro (17).
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The long NC1 sequence of rat and mouse type XII collagen exhibited structural homology with chicken type XII collagen. Following the common region, a stretch of amino acids containing aspartic acid and glutamic acid residues forms the "acidic extension region" (Fig. 6), with a calculated pI of 3.4. The acidic extension region is further followed by a short polypeptide composed of nearly 40% basic amino acid residues, the "basic terminal region," with a calculated pI of 13.8. These characteristic sub-structures of the long NC1 domain of type XII collagen seem to be shared with the corresponding domain of type XIV collagen. Type XII and XIV collagens belong to the FACIT family and show significant structural homology. However, histolocalization of these collagens appears to be somewhat different (18-21). In vitro experiments indicate that type XIV collagen appears to interact with a dermatan sulfate glycosaminoglycan (GAG) side chain of decorin (22). Because the type XIV collagen NC1 domain contains a typical sulfated GAG binding sequence, it has been postulated that type XIV collagen interacts with type I collagen fibril through decorin. In contrast, the molecular interaction between type XII collagen, type I collagen, and proteoglycans is not yet fully understood (13). The newly discovered NC1 domain isoforms may provide a long awaited clue toward elucidating the molecular interaction of type XII collagen.
Our rat and mouse 1(XII) collagen genomic DNA sequence data further
defined two alternative exons 1 and 2 that encode the long and short
NC1 domain isoforms, respectively (Fig. 3). The previously reported NC1
domain sequence in mice (3) did not match the NC1 domain sequences
found in this study, rather it matched the sequence of the intron
immediately following exon 3.
RNA transfer blot analyses indicated that the poly(A)+ RNA sample isolated from 15- and 17-day old mouse embryos contained both type XIIA (10 kb) and type XIIB (7-8 kb) mRNAs that are due to alternative splicing in the NC3 domain (Fig. 1) (2, 23, 24). It was noted that the exon 1 and exon 2 type XII collagen genomic DNA probes hybridized to the types XIIA and XIIB mRNAs to different degrees (Fig. 4). In light of the NC3 splicing alternatives (type XIIA and XIIB), we propose here a new descriptive nomenclature: 1) type XIIA-1, contains long NC3 domain and long NC1 domain; 2) type XIIA-2, contains long NC3 domain and short NC1 domain; 3) type XIIB-1, contains short NC3 domain and long NC1 domain; and 4) type XIIB-2, contains short NC3 domain and short NC1 domain.
Types XIIA-1 and XIIB-1 include a long NC1 variable sequence encoded by
exon 1 (from the 3'-end), and types XIIA-2 and XIIB-2 include a short
NC1 variable sequence encoded by exon 2. These 5'-end (NC3) and 3'-end
(NC1) alternative splicing mechanisms seem to be coordinately regulated
during 1(XII) gene transcription. Type XIIA collagen (long NC3) is
expressed primarily in embryonic tissues, whereas type XII collagen in
adult tissues is predominantly the type XIIB species with the short NC3
domain. The ribonuclease protection assay examining adult mouse tissues
further reveals that the type XII collagen long NC1 domain probe is
protected in dento-alveolar tissue and tail tissue, which contain
periodontal ligament and tail tendon, respectively. Because chicken
type XII collagen derived from tendon is homologous to type XIIB-1, we speculate that the long NC1 domain may play a tissue-specific role essential to ligament/tendon extracellular matrix organization.
In contrast, type XIIB-2 collagen with the short NC1 domain appears to be more widely expressed (Fig. 5). Sugrue et al. (25) reported that when monoclonal antibody 75d7 (generated against a synthetic peptide encoding a portion of the long NC1 domain of chicken type XII collagen) was used, the bone tissue including periosteum lacked any immunostaining. However, when another monospecific antibody (generated against a fusion peptide containing a nonvariant-region of the NC3 domain of mouse type XII collagen) was used, the entire periosteum of the long bone and membranous bones was stained (26). The implication of these previously published conflicting results is that newly defined type XIIB-2, which lacks the 75d7 epitope sequence in the long NC1 domain, may be predominantly present in periosteum. It is interesting to note that in nonligament/tendon tissues, type XII collagen localizes at the tissue interface zones such as the perichondreum of cartilage (18, 19, 25), the periosteum of bone (20, 26), the epimysium, perimysium, and endomysium of skeletal muscle (20), and Descemet's membrane of cornea (26, 27). The short NC1 domain of type XII collagen may play a functional role at these tissue interface zones. The deduced sequence of the short NC1 domain contains a potential recipient site for O-serine-linked oligosaccharides at the carboxyl end. It is unknown, however, if this site is post-translationally modified.
These results seem to suggest that the selection of the 3'-end
alternative splicing is dependent on the tissue type and function. The
newly discovered variations in the NC1 domain of type XII collagen can
provide a clue as to the puzzling tissue distribution of type XII
collagen in structurally and functionally diverse adult tissues. It is
tempting to speculate that type XII collagen may contribute to
different extracellular matrix organizations in these adult tissues,
potentially through altering the fibril association schemes through its
NC1 domain.
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ACKNOWLEDGEMENTS |
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We thank Drs. M. Gordon (Rutgers University College of Pharmacy) and R. Mayne (University of Alabama at Birmingham) for constructive comments.
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FOOTNOTES |
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* This study was supported in part by National Institutes of Health Grants DE07010 (to A. M. K.), DE00351 (to N. Y. K.), AR36820 (to B. R. O.), and ITI Foundation (to I. N., and N. Y. K.).The costs of publication of this article were defrayed in part by the payment of page charges. The article must therefore be hereby marked "advertisement" in accordance with 18 U.S.C. Section 1734 solely to indicate this fact.
The nucleotide sequence(s) reported in this paper has been submitted to the GenBankTM/EMBL Data Bank with accession number(s) U57095, U57361, and U57362.
** To whom correspondence should be addressed: The Jane and Jerry Weintraub Center for Reconstructive Biotechnology, UCLA School of Dentistry, 10833 Le Conte Ave., Los Angeles, CA 90095. Tel.: 310-794-7612; Fax: 310-206-4201; E-mail: ichiron@dent.ucla.edu.
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ABBREVIATIONS |
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The abbreviations used are: FACIT, Fibril Associated Collagen with Interrupted Triple helices; PCR, polymerase chain reaction; bp, base pair(s); kb, kilobase(s).
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REFERENCES |
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TOP
ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
REFERENCES
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,
and basic amino acid residues are indicated with 
.