Gene expression of collagen types IIA and IX correlates with ultrastructural events in early osteoarthrosis: new applications of the rabbit meniscectomy model.

OBJECTIVE: To examine the phenotypic expression and geographic distribution of collagens in early stages of osteoarthrosis and their relationship to ultrastructural events in cartilage. METHODS: In situ hybridization was used to localize articular expression of total type II (A+B) and type IX collagen at 2 and 4 weeks in the rabbit meniscectomy model of osteoarthrosis. The expression of the developmental marker collagen IIA was analyzed at the same time points. Articular cartilage structure was examined by scanning electron microscopy. RESULTS: Little difference was found in total type II or type IX collagen gene expression for operated versus control limbs at 2 weeks. Gene expression for collagen types IIA and IX was found to be site-specific by the 4 week period and was largely limited to the meniscectomy site. At 4 weeks, this activity was correlated with site-specific alterations in chondrocyte morphology, qualitative changes in the collagen matrix, and articular surface delamination on microscopy. CONCLUSION: Gene expression for collagen types IIA and IX is site-specific and correlates with ultrastructural changes in cartilage in this model of early osteoarthrosis. We present the first known report of the distribution of type IX collagen gene expression in any model of osteoarthrosis. These findings support the central importance of matrix interactions in osteoarthrosis and suggest that early phases of repair involve re-expression of a developmental sequence by chondrocytes.

Chondrogenesis in the regenerating antler tip in red deer: expression of collagen types I, IIA, IIB, and X demonstrated by in situ nucleic acid hybridization and immunocytochemistry.

The annual regrowth of antlers in male deer is a unique example of complete bone regeneration occurring in an adult animal. Growth is initiated at the distal antler tip, which is similar to the epiphyseal growth plate in some respects. However, there is some debate as to whether this process represents "true" endochondral ossification. As part of the characterization of the developmental process in pre-osseus antler tissue, we have studied, by in situ hybridization, the spatial expression of mRNAs for types I, II, and X collagen. Viewed in a coronal plane, type I procollagen mRNA was observed in skin, the fibrous perichondrium, and the densely cellular area immediately adjacent to the perichondrium. Below this area, as cells began to assume a columnar arrangement and coincident with the appearance of a vasculature and synthesis of a cartilaginous matrix, transcripts for types I, IIA, IIB procollagen and X collagen were detected. Further down in the cartilage zone, the pattern of type I procollagen mRNA expression was altered. Here, the signal was detected only in a morphologically distinct subpopulation of small, flattened cells within the intercellular matrix at the periphery of the columns of chondrocytes. The alternative splice form of type II procollagen mRNA (IIA), characteristic of chondroprogenitor cells (Sandell et al. [1991] J. Cell Biol. 114:1307-1319), was expressed by a subset of cells in the upper region of the columns, indicating that this zone contains a population of prechondrocytic cells. Positive hybridization to type IIA was most abundant in these cells. In contrast, transcripts for the other procollagen splice form (IIB) and type X collagen were expressed by chondrocytes throughout the whole of the cartilage region studied. The translation and export of type II collagen and type X collagen were confirmed by detecting specific immunoreactivity for each. The spatial distribution of immunoreactivity for collagen types II and X was consistent with that of corresponding mRNAs. These data demonstrate for the first time the distinct pattern of expression of genes for major cartilage matrix macromolecules, the expression of the differentially spliced form of type II procollagen mRNA (IIA), and specifically the co-localization of types II and X collagen in the developing antler tip. Taken together, they strongly indicate that antler growth involves an endochondral process.

Collagen gene expression during development of avian synovial joints: transient expression of types II and XI collagen genes in the joint capsule.

The developmental sequence of the embryonic joint has been well studied morphologically. There are, however, no definitive studies of cell function during joint development. In order to begin to understand the differentiation events that contribute to joint formation, we examined the expression of collagen mRNAs encoding types I, IIA, IIB, and XI. In situ hybridization was performed on chicken embryo hind limb buds and digits from day 7 to day 18 (Hamburger and Hamilton stages 31-44). In the day 7 (stage 31) limb bud, there was a condensation of mesenchyme forming the primitive tarsal and metatarsal bones that showed abundant expression of type IIA procollagen message, but no type IIB or type alpha 1(XI) message. By day 8 (stage 33), co-expression of types IIA, and type XI procollagen mRNAs was observed in the condensations, with expression of IIB restricted to early chondrocytes with metachromatically staining matrix. At this stage, DNA fragmentation characteristic of apoptosis was observed in cells near the midline of the interzone region between the developing anlagen, and in areas between and around the individual digits of the paddle. The presumptive apoptotic cells were more numerous at day 9 (stage 35), and were not found in the developing joint at subsequent time points, including the initiation of spatial cavitation of the joint. From days 11-18, type IIA procollagen mRNA was expressed in flattened cells at the surface of the anlagen, and in the perichondrium and in the developing joint capsule; type IIB mRNA message was found only in chondrocytes. Type XI mRNA was expressed by all type II-expressing cells. Alpha 1(I) mRNA was expressed early by cells of the interzone and capsule, but as cavitation progressed, the type I expressing cells of the interzone merged with the superficial layer of the articular surface. Thus, at the time of joint cavitation, there was a distinct pattern of expression of procollagen messages at the articular surface, with type I being outermost, followed by morphologically similar cells expressing type IIA, then chondrocytes expressing type IIB. The progenitor cells expressing type IIA message define a new population of cells. These cell populations contribute to the molecular heterogeneity of the articular cartilage, and these same populations likely exist in the developing joints of other species. The transient transcription of type II and type XI collagen genes, characteristic of chondrocytes, by cells in the joint capsule demonstrates that these cells may have chondrogenic potential.

Alternative splice form of type II procollagen mRNA (IIA) is predominant in skeletal precursors and non-cartilaginous tissues during early mouse development.

Type II collagen, generally considered to be characteristic of cartilage, has been localized in specific non-cartilaginous structures during embryogenesis and development of the skeleton. Type II procollagen is synthesized in two different forms generated by alternative splicing of exon 2 in the precursor mRNA transcript. One form (type IIA procollagen) contains a large cysteine-rich domain in the NH2-terminal propeptide, while the second form (type IIB procollagen) does not. These two forms are spatially expressed during development and chondrogenesis with the type IIB procollagen mRNA primarily expressed by chondrocytes while the IIA form is expressed in chondroprogenitor cells (Sandell et al. [1991] J. Cell Biol. 114:1307-1319). The present study demonstrates that the early non-cartilage expression, by somites, mesenchymal and epithelial cells, is predominantly the alternate splice form, type IIA procollagen mRNA. Later in development, the type IIB mRNA splice form is expressed by chondrocytes. During the development of intramembranous bones, such as the mandible, type IIA procollagen mRNA is also expressed. In this tissue, the splice form does not switch to type IIB mRNA and no cartilage is formed. These results show that expression of type IIA mRNA, whether by epithelial or mesenchymal cells, precedes formation of overt skeletal structures.