Journal of Histochemistry and Cytochemistry, Vol. 49, 877-886, July 2001, Copyright © 2001, The Histochemical Society, Inc.


ARTICLE

Distribution of Biglycan and Decorin in Collateral and Cruciate Ligaments and Menisci of the Rabbit Knee Joint

Emma Kavanagh1,a and Doreen E. Ashhursta
a Department of Anatomy, St George's Hospital Medical School, Tooting, London, United Kingdom

Correspondence to: Doreen E. Ashhurst, Dept. of Anatomy, St George's Hospital Medical School, Tooting, London SW17 0RE, UK.


  Summary
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Summary
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Materials and Methods
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The small leucine-rich proteoglycans (PGs) biglycan and decorin, and their mRNAs, have been localized during neonatal development and aging (3 weeks to 2 years) of collateral and cruciate ligaments and of menisci of the rabbit knee joint. In the collateral ligaments, biglycan and decorin are found between the bundles of collagen fibers at all ages. In cruciate ligaments the PGs are primarily around the cells. In neonatal ligaments all the cells express the mRNAs for biglycan and decorin, but in the collateral ligaments the number expressing the mRNAs is reduced at 8 months. In 3–week menisci the PGs are uniformly distributed in the matrix, but by 8 months biglycan is present primarily in the central fibrocartilaginous regions, whereas decorin is found peripherally. In neonates, all the cells express the mRNAs but the number is reduced in 8-month menisci. The results illustrate the precise localizations of biglycan and decorin in healthy rabbit ligaments and menisci which, after injury, must be reproduced in the repair tissue for normal strength to be regained. (J Histochem Cytochem 49:877–885, 2001)

Key Words: biglycan, decorin, proteoglycans, mRNAs, rabbit knee joint, ligaments, menisci, in situ hybridization, immunohistochemistry


  Introduction
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Introduction
Materials and Methods
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THE KNEE is a hinge joint that is stabilized by ligaments and menisci. The collateral ligaments restrict the lateral and medial displacement of the femur and tibia relative to each other, while the cruciate ligaments prevent anterior or posterior movement. The menisci deepen the articulating surfaces of the tibial plateau. All are therefore crucial for stability of the knee joint and all are subject to injury, particularly in athletes, which may lead to the development of osteoarthritis. Experimental models of osteoarthritis frequently involve the transection of the collateral and cruciate ligaments and/or the menisci (see, e.g., Pond and Nuki 1973 ; Hashimoto et al. 1998 ; Neidel et al. 1998 ).

Ligaments and tendons are composed of bundles of collagen fibrils, of which the major component is Type I, but Types III, V, and VI collagen are also present (Amiel et al. 1984 ; Bray et al. 1993 ; Bland and Ashhurst 1996a , Bland and Ashhurst 1997 ). The organization of the fibrillar collagens changes during fetal and postnatal development in both the collateral and cruciate ligaments (Bland and Ashhurst 1996a ). Most studies of the proteoglycans (PGs) of ligaments relate to their glycosaminoglycan (GAG) content and are biochemical. In bovine collateral ligaments there are two populations of PGs. The larger population consists of small chondroitin sulfate/dermatan sulfate PGs, most of which are decorin, whereas the smaller population (about 20%) consists of large chondroitin sulfate/keratan sulfate PGs (Hey et al. 1990 ). One large chondroitin sulfate PG in bovine collateral ligament was identified as versican-like (Campbell et al. 1996 ). Chondroitin and dermatan sulfates and hyaluronan are present in collateral and cruciate ligaments of human and several other animals (Gassler et al. 1994 ; Watanabe et al. 1994 ).

Most mammalian menisci are fibrocartilaginous. The major collagen of menisci is Type I, but Types II, III, V, and VI collagen may also be present (Eyre and Wu 1983 ; Cheung 1987 ; McDevitt and Webber 1990 ; Bland and Ashhurst 1996b ). In rabbit fetal menisci, Types I, III, and V collagen are present, but at 3 weeks postnatal Type II collagen appears in the central region (Bland and Ashhurst 1996b ). There is little overlap of the regions containing Types I and II collagen in adult menisci, whereas Types III and V collagen are found throughout the tissue.

In adult pig and rabbit menisci the major GAG is chondroitin-6-sulfate, but there is some chondroitin-4-sulfate and dermatan sulfate (Webber et al. 1984 ; Scott et al. 1997 ). In the 20-week porcine meniscus biglycan is more abundant than decorin (Nakano et al. 1997 ; Scott et al. 1997 ). Aggrecan is the major PG in canine menisci, and its gene expression is reduced by immobilization of the joint (Djurasovic et al. 1998 ).

The distributions of biglycan and decorin during development and aging of both ligaments and menisci are unknown. There is little immunohistochemically detectable biglycan and decorin in fetal rabbit ligaments and menisci (unpublished observations). Biglycan and decorin and their mRNAs were localized therefore in the collateral and cruciate ligaments and in menisci of the rabbit from 3 weeks postnatal to 2 years. Their distribution between the fiber bundles in the ligaments persists throughout life. In menisci the initial uniform localization changes as fibrocartilage develops. Biglycan is preferentially located in that area. Some cells in these tissues express the mRNAs throughout life.


  Materials and Methods
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Materials and Methods
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Literature Cited

All reagents and labeled antibodies were purchased from Sigma (Poole, UK) and all restriction enzymes, polymerases and yeast tRNA from Roche (Lewes, UK), unless otherwise stated.

Preparation of Tissue for Microscopy
The medial and lateral collateral ligaments, anterior and posterior cruciate ligaments, and lateral and medial menisci were dissected from 3-, 6-, and 12–14-week, 8-month, and 2-year-old rabbit knee joints. Two or more rabbits were used at each stage. The tissues were fixed in 4% paraformaldehyde in 0.05 M Tris-HCl buffer, pH 7.3, for 18 hr, then washed extensively in buffer. After washing, the tissue was dehydrated in graded ethanols, cleared in methyl salicylate, and embedded in paraffin. Serial sagittal longitudinal sections were cut at 7 µm. For histological observations, sections were stained with hematoxylin and eosin.

Immunohistochemistry
Procedures for Antibodies to Biglycan and Decorin. Chicken polyclonal antibodies to purified bovine biglycan and to purified bovine decorin were a gift from Prof. D. Heinegård (Lund University, Sweden). The total IgG was purified as described by Heinegard et al. 1985 .

Sections were dewaxed and rehydrated before the following pretreatments that are usual for paraffin-embedded tissues: (a) 0.1% trypsin in 0.05 M Tris–saline, pH 7.8, with 0.1% CaCl2 at 37C for 1 hr to aid tissue permeability; (b) 2% hyaluronidase in PBS, pH 7.3, at 37C for 1 hr to remove GAGs and unmask epitopes; (c) 2% L-lysine in PBS for 15 min to reduce charged sites. The sections were washed in PBS between each treatment. To block nonspecific binding, the sections were incubated in heat-inactivated normal rabbit serum (Harlem Sera Labs; Loughborough, UK) with the addition of 4% bovine serum albumin (BSA) and 0.3% Triton X-100 for 30 min. This was drained from the slide and the primary antibody was added at a dilution of 1:1000 in 1% BSA. The sections were incubated overnight at 4C. After washing, the sections were incubated in alkaline phosphatase-labeled rabbit anti-chicken IgG antibodies for 90 min. The alkaline phosphatase label was localized using the following substrate: 5 µg naphthol AS-BI phosphate was dissolved in 1 drop dimethylformamide and added to 5 µg Fast Red TR in 10 ml veronal acetate buffer, pH 9.2. Levamisole (1 µg/ml) was added to inhibit endogenous alkaline phosphatase activity. The sections were incubated in substrate for 20 min, washed, and mounted in glycerin jelly.

For controls the primary antibody was replaced by normal chicken serum. At no time was there any binding in the controls.

In Situ Hybridization
cDNA probes to human biglycan and decorin were a gift from Dr. L. Fisher (NIH; Bethesda, MD) (Fisher et al. 1989 ); they recognize rabbit biglycan and decorin mRNAs in Northern blots (Demoor-Fossard et al. 1998 ). Antisense and sense probes were generated by linearizing with Kpn I and T3 polymerase and Xba I and T7 polymerase, respectively, for biglycan and with Bam HI and T7 polymerase and Kpn I and T3 polymerase, respectively, for decorin. Both probes were labeled with digoxigenin by in vitro transcription using the DIG-RNA labeling (SP6/T7) kit (Roche). The riboprobes are 1685 bp (biglycan) and 1600 bp (decorin) long. The transcripts were hydrolyzed at 60C for 40 min in 100 mM bicarbonate buffer to yield fragments of ~200 bp and were stored at -20C until use.

The sections were dewaxed and rehydrated. The following pretreatments were performed: (a) 0.2 N HCl for 20 min; (b) 6% H2O2 for 30 min; (c) proteinase K (20 µg/ml) for 10 min at 37C; (d) 4% paraformaldehyde in PBS for 20 min at 4C; (e) 0.1 M glycine twice for 10 min; (f) 0.25% acetic anhydride in triethanolamine (pH 8.0) for 10 min. Between each treatment the sections were washed in PBS. They were then dehydrated through graded ethanols and allowed to dry. Fifteen µl of hybridization solution was applied to each section. The hybridization solution (low stringency) contained 50% formamide, 10 mM Tris-HCl (pH 7.4), 1 mM EDTA, 1 x Denhardt's, 0.5% SDS, 600 mM NaCl, 10% dextran sulfate, 0.5 µg/ml yeast tRNA, and labeled antisense or sense probe. Hybridization was for 18 hr at 50C for biglycan mRNA and 45C for decorin mRNA. After hybridization, the coverslips were removed in 2 x SSC before rinsing in Tris–EDTA buffer. The sections were then treated with 20 µg/ml RNase in Tris–EDTA–NaCl buffer, pH 8.0. The sections were washed twice in 2 x SSC for 15 min, then in 1 x SSC for 10 min at 55C. A final wash in 1 x SSC was at room temperature. The digoxigenin label was detected using the Roche kit, except that 0.3% Triton X-100 was added to the antibody solution. This blocks the nonspecific binding in the cartilage matrices that arises after treatment with proteolytic enzymes (Bland et al. 1991 ). The sections were mounted in glycerin jelly.

At no time was there any reaction with the sense, i.e., control, probes.


  Results
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Materials and Methods
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The results are summarized in Table 1.


 
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Table 1. Binding of antibodies to biglycan and decorin in the matrix and expression of their mRNAs by cells of the collateral and cruciate ligaments and meniscia

Collateral Ligaments
Both lateral and medial collateral ligaments consist of bundles of collagen fibrils with spindle-shaped cells irregularly arranged between the fiber bundles. The number of cells appears to decrease with age (Fig 1 and Fig 6). Antibodies to biglycan and decorin are preferentially bound between the fiber bundles. They tend to be bound more strongly in young ligaments (Fig 2, Fig 4, Fig 7, and Fig 9). Biglycan and decorin mRNAs are expressed by most cells up to 14 weeks, but by 8 months the number of cells expressing the mRNAs has decreased (Fig 3, Fig 5, Fig 8, and Fig 10).



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Figures 1-5. Photomicrographs of the medial collateral ligament of a 6-week-old rabbit.

Figure 1. Bundles of collagen fibers with spindle-shaped cells in rows between them. H&E staining. Bar = 50 µm.

Figure 2. Biglycan (B) antibody binding; biglycan is located primarily between the fiber bundles (arrowheads in a). Bar = 20 µm.

Figure 3. ISH for biglycan mRNA. All cells are expressing the mRNA.

Figure 4. Decorin (D) antibody binding; decorin is located between the fiber bundles (arrowheads in a).

Figure 5. ISH for decorin mRNA. All cells are expressing the mRNA.

Figures 6-10. Photomicrographs of the medial collateral ligament of an 8-month-old rabbit.

Figure 6. Thick bundles of collagen fibrils are interspersed by spindle-shaped cells. H&E staining. Bar = 50 µm.

Figure 7. Biglycan (B) antibody binding; biglycan is located between the fiber bundles.

Figure 8. ISH for biglycan mRNA; only a few scattered cells are expressing the mRNA.

Figure 9. Decorin (D) antibody binding; decorin is located between the fiber bundles.

Figure 10. ISH for decorin mRNA; only a few cells are expressing the mRNA.

Cruciate Ligaments
The anterior and posterior ligaments are composed of parallel bundles of collagen fibrils separated by rows of large round cells (Fig 11). The binding of antibodies to biglycan and decorin is similar at all ages and is closely associated with the rows of cells (Fig 12 and Fig 14). Among the fibers, the binding is weaker and more variable. Both biglycan and decorin mRNAs are expressed by the cells throughout life (Fig 13 and Fig 15).



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Figures 11-14. The cruciate ligament of a 6-week-old rabbit.

Figure 11. The bundles of collagen fibers are separated by rows of rounded cells. H&E staining. Bar = 20 µm.

Figure 12. Biglycan (B) antibody binding; biglycan is located primarily around the cells (arrowheads).

Figure 13. ISH for biglycan mRNA; the majority of the cells are expressing the mRNA.

Figure 14. Decorin (D) antibody binding; decorin is located within the fiber bundles and around the cells (arrowheads).

Figure 15. ISH for decorin mRNA; most cells are expressing the mRNA.

Menisci
At 3 weeks postnatal, a fibrocartilaginous region starts to develop in the center of both the lateral and medial menisci (Fig 16) and it is much larger at 8 months (Fig 21). It is surrounded by a dense fibrous layer. At 3 weeks, both antibodies are bound throughout the matrix (Fig 17 and Fig 19). Thereafter, as the fibrocartilaginous regions develop, their PG content changes so that at 8 months these regions strongly bind antibodies to biglycan (Fig 22), whereas antibodies to decorin are bound only in the periphery of the fibrocartilage (Fig 24). Their distributions appear to be mutually exclusive. In non-cartilaginous regions, biglycan antibodies are bound around the cells. Biglycan, but not decorin, antibodies are bound in the surface fibrous tissue. The mRNAs for both biglycan and decorin are expressed by most of the cells at 3 and 6 weeks postnatal (Fig 18 and Fig 20), but with increasing maturity the numbers of cells expressing the mRNAs decreases (Fig 23 and Fig 25).



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Figures 16-20. A meniscus of a 3-week-old rabbit.

Figure 16. Random distribution of the cells, but in some internal areas in which fibrocartilage is developing (arrowheads) they are farther apart. H&E staining. Bar = 50 µm.

Figure 17. Biglycan (B) antibody binding; biglycan is present throughout the matrix, but antibody binding is stronger in some surface regions.

Figure 18. ISH for biglycan mRNA; all cells are expressing the mRNA.

Figure 19. Decorin (D) antibody binding; decorin is located throughout the matrix.

Figure 20. ISH for decorin mRNA; all cells are expressing the mRNA.

Figures 21-25. A meniscus of an 8-month-old rabbit.

Figure 21. The central fibrocartilaginous region with chondrocyte-like cells (arrowheads) and the peripheral fibrous layer. H&E staining. Bar = 50 µm.

Figure 22. Biglycan (B) antibody binding; biglycan is present throughout the matrix, but antibody binding is much stronger in the central cartilaginous region.

Figure 23. ISH for biglycan mRNA; only a few cells (arrowheads) are expressing the mRNA.

Figure 24. Decorin (D) antibody binding; decorin is located primarily in a region surrounding the cartilaginous area. Antibody binding is very weak both in the surface layers and in the cartilaginous region.

Figure 25. ISH for decorin mRNA; few cells (arrowheads) are expressing the mRNA.


  Discussion
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Materials and Methods
Results
Discussion
Literature Cited

Ligaments
The lateral and medial collateral ligaments are similar structurally and in their collagen content (Bland and Ashhurst 1996a ). Antibodies to biglycan and decorin localize these small PGs between the fiber bundles. Biochemical data suggest that 80% of the PG in mature rabbit medial collateral ligament is decorin, while the remaining 20% is biglycan and a large unidentified PG (Plaas et al. 2000 ). The immunohistochemical data do not indicate a predominance of decorin over biglycan in mature ligaments.

The cruciate ligaments differ in appearance from the collateral ligaments principally because the cells are round and in prominent rows. Both biglycan and decorin are primarily associated with the cells. The stronger binding of the biglycan antibody compared to that of the decorin antibody may indicate a greater concentration of this PG, but immunohistochemistry cannot be regarded as strictly quantitative.

Over the period from 3 weeks to the mature adult, the distribution of biglycan and decorin in rabbit knee ligaments does not change. Previous studies of PGs of ligaments have been restricted to the localization of their GAGs. Using electron microscopic histochemistry, Bray et al. 1990 , Bray et al. 1993 found chondroitin sulfate around the cells and in seams radiating between the bundles of collagen fibrils in human and rabbit medial collateral ligament. This agrees with the distributions of biglycan and decorin reported here.

Menisci
At 3 weeks postnatal, a Type II collagen-containing region develops in the inner part of the rabbit meniscus and persists as fibrocartilage throughout life (Bland and Ashhurst 1996b ). At 3 weeks biglycan and decorin are present throughout the fibrocartilage, but by 8 months their distributions are mutually exclusive. Biglycan is present in the center and decorin around the periphery of the fibrocartilage. There are no biochemical data on PGs in rabbit menisci, but data on 20-week porcine menisci indicates that biglycan comprises around 50% and decorin 30% of the small PGs present (Nakano et al. 1997 ; Scott et al. 1997 ). This may also be true in rabbits because the area occupied by biglycan is greater than that of decorin. An accumulation of biglycan with increasing age also occurs in rabbit articular cartilage, but here decorin is co-localized with biglycan (Kavanagh and Ashhurst 1999 ).

Functions of Biglycan and Decorin and Their Association with Collagens
Biglycan is said to be involved in matrix organization, and, together with decorin, in cell–matrix interactions and binding of growth factors (Hildebrand et al. 1994 ; Buckwalter and Mankin 1997 ). Decorin binds to both Types I and II collagen and may be involved in the control of fibrillogenesis (Hedbom and Heinegard 1993 ; Keene et al. 2000 ; Neame et al. 2000 ). Developing ligaments are formed primarily of Types I and V collagen; Type III appears in the collateral ligaments at 12 weeks and in the cruciate ligaments at 8 months (Bland and Ashhurst 1996a ). In neither the collateral nor the cruciate ligament can the acquisition of Type III collagen be correlated with changes in the biglycan or decorin content. In the 3-week meniscus Types I, III, and V collagen are present throughout the tissue, whereas Type II is just beginning to appear in the central regions (Bland and Ashhurst 1996b ). As this central fibrocartilaginous region develops, Type I collagen disappears. The findings presented here show that at 3 weeks both biglycan and decorin are co-localized in the meniscus, but that at 8 months only biglycan is found in the central fibrocartilage. Thus, biglycan co-localizes with Type II and decorin with Type I collagen in the adult rabbit meniscus (compare Fig 22 and Fig 24 with Fig 25 and 26 in Bland and Ashhurst 1996b ). The role of decorin in promoting fibrillogenesis must be fulfilled before its loss from the fibrocartilage. The function of biglycan in menisci has been related to the greater compressive forces on the inner region of the meniscus where it predominates (Nakano et al. 1997 ; Scott et al. 1997 ).

Expression of Biglycan and Decorin mRNAs
In both the ligaments and menisci, all cells express the mRNAs for biglycan and decorin during growth, i.e., up to 14 weeks, but, except in the cruciate ligaments, only a few cells express the mRNAs by 8 months when the rabbit is skeletally mature. The continuing expression of the mRNAs for biglycan and decorin by a few cells in the adult ligaments and menisci corresponds to our previous observations of rabbit articular cartilage (Kavanagh and Ashhurst 1999 ). PGs are therefore continually turned over throughout life in contrast to the collagens, whose mRNAs are not expressed by any cells after 8 months (Bland and Ashhurst 1996a , Bland and Ashhurst 1996b ).

Estimations of mRNA levels in human and rabbit ligaments indicate that expression of biglycan and decorin mRNAs continues throughout life (Boykiw et al. 1998 ; Lo et al. 1998 ). Similarly, quantification of biglycan and decorin mRNAs in rabbit knee menisci confirms their continued expression after skeletal maturity (Hellio Le Graverand et al. 1999 ). After injury, the level of biglycan, but not decorin, mRNA is elevated in both species (Boykiw et al. 1998 ; Lo et al. 1998 ). This agrees with the observation that in repairing rabbit medial collateral ligament the amount of biglycan increases, but decorin is barely detectable (Plaas et al. 2000 ).

Conclusion
Immunohistochemical studies show that matrix components, i.e, collagens, proteoglycans, and other molecules, are distributed in a specific pattern within each tissue. The strength and proper functioning of each ligament and meniscus are dependent on the unique organization of these molecules. During development they are laid down over a protracted period in a precise and sequential manner. The problem for tissue repair is not how to stimulate the cells to secrete the appropriate molecules but how to achieve their correct organization in the regenerated tissues.


  Footnotes

1 Present address: Department of Veterinary Basic Sciences, The Royal Veterinary College, London, UK.


  Acknowledgments

Supported by the Arthritis and Rheumatism Campaign UK (grant no. A052226).

We thank Prof D. Heinegård for the antibodies, Dr L. Fisher for the cDNA probes, and Ms Y.S. Bland for expert technical assistance.

Received for publication September 15, 2000; accepted January 26, 2001.


  Literature Cited
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Summary
Introduction
Materials and Methods
Results
Discussion
Literature Cited

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