The transient expression of type II collagen at tissue interfaces during mammalian craniofacial development

Using immunocytochemical techniques, the spatiotemporal distribution of the major collagen isoform of cartilage, type II collagen, has been investigated during early craniofacial development in the mouse embryo. Early and transient expression was associated with the otic and optic vesicles, the ventrolateral surfaces of the developing brain, olfactory conchi, endocardial and mesocardial tissues, the lateral and basal surfaces of the pharyngeal endoderm and beneath the ectoderm of the branchial arches. A number of these locations are sites of epithelial-mesenchymal tissue interaction believed to generate the component parts of the chondrocranium; here, type II collagen appears transiently in advance of overt chondrogenesis in the mesenchyme. At such sites, immunofluorescence is typically localised along the basal surface of the epithelial partner, with the strongest reaction detected between the basal aspects of the otic and rhombencephalic epithelia. Immunoelectron microscopy, using pre-embedding immunostaining and a protein G-gold technique, reveals that the type II collagen is adjacent to, but not integral with, the basal laminae. Gold particles are clearly associated with 10-15 nm fibrils of the extracellular matrix in the reticulate lamina region. The pattern of type II collagen expression in the mouse closely correlates with that demonstrated previously in the quail, indicating a high degree of phylogenetic conservation between these two vertebrate species. These findings are consistent with the hypothesis that the pattern of epithelial secretion of type II collagen, or a coexpressed matrix molecule, constitutes a morphogenetic signal, realised as a matrix-mediated tissue interaction, and specifying the form of the vertebrate chondrocranium. Three-dimensional reconstruction of early type II collagen distribution, and of the subsequent chondrocranial cartilages, reveals that chondrocranial form can be derived from a 'pre-pattern' of epithelially derived type II collagen expressed at epithelial-mesenchymal tissue interfaces.     

Widespread distribution of type II collagen during embryonic chick development

Type II collagen is a major component of hyaline cartilage, and has been suggested to be causally involved in promoting chondrogenesis during embryonic development. In the present study we have performed an immunohistochemical analysis of the distribution of type II collagen during several early stages of embryonic chick development. Unexpectedly, we have found that type II collagen is widely distributed in a temporally and spatially regulated fashion in basement membranes throughout the trunk of the embryo at stages 14 through 19, including regions with no apparent relationship to chondrogenesis. Immunohistochemical staining with two different monoclonal antibodies against type II collagen, as well as with an affinity-purified polyclonal antibody, is detectable in the basement membranes of the neural tube, notochord, auditory vesicle, dorsal/lateral surface ectoderm, lateral/ventral gut endoderm, mesonephric duct, and basal surface of the splanchnic mesoderm subjacent to the dorsal aorta, and at the interface between the epimyocardium and endocardium of the developing heart. In contrast, immunoreactive type IX collagen is detectable only in the perinotochordal sheath in the trunk of the embryo at these stages of development. Thus type II collagen is much more widely distributed during early development than previously thought, and may be fulfilling some as yet undefined function, unrelated to chondrogenesis, during early embryogenesis.     

Acquisition of type IX collagen by the developing avian primary corneal stroma and vitreous

Previous investigations from our laboratory and others have demonstrated that type II collagen, once thought to be a cartilage-specific molecule, is also a component of both the primary corneal stroma and the vitreous of embryonic chickens. In the present immunohistochemical study we have examined the expression in these embryonic matrices of another "cartilage-specific" collagen, type IX, along with type II. In the cornea, type IX collagen is in the primary stroma, but is not detectable in the mature, secondary stroma. Even within the primary stroma this collagen has a brief, transitory existence. It first appears in the peripheral stroma at the time the endothelial cells begin to migrate along its posterior surface, and spreads throughout the stroma during the following 24-36 hr. The epitopes on type IX collagen then suddenly become undetectable just before this matrix swells and becomes populated by the periocular mesenchymal cells (future keratocytes). In comparison, collagen type II (along with type I) is present in the stroma before and long after these events. Deposition of immunodetectable type IX collagen in the developing corneal stroma thus seems to be independent of type II. In the vitreous, we observed type IX collagen along with type II as soon as authentic vitreous could be identified and at all subsequent stages of development. In this tissue, therefore, the expression of collagen types IX and II appears to be coordinate.     

IMMUNOHISTOCHEMICAL LOCALIZATION OF TYPE I AND II COLLAGENS IN THE INVOLUTING CHICK NOTOCHORDS IN VIVO AND IN VITRO

Embryonic chick notochords were studied during their metabolically active and involuting periods for the expression of collagen type I and II. The staining was carried out on notochords in vivo at stage 20 and stage 35 and on mesenchyme-contaminated and mesenchyme-free notochords at stage 20, which were cultured in vitro for 6 days. The results show that type II collagen is demonstrable in the notochords, at all the examined stages, both in vivo and in vitro. However, the expression of type I collagen was stage-dependent in vivo and in vitro. At stage 20, the perinotochordal sheath is positively immunostained for collagen type I, but the notochord itself is negative. At stage 35, the perinotochordal sheath as well as the notochord are positively immunostained for collagen type I. The mesenchyme-contaminated and the mesenchyme-free notochords and their sheaths are also positively immunostained for the type I collagen after6 days in vitro. The current results, at late developmental stages, indicate that the involuting notochords express collagen type I, which seems not to be altered by changing the micro-environment in vivo.     

Immunofluorescent localization of collagen types I, II, and III in the embryonic chick eye.

The appearance and distribution of type I, II, and III collagens in the developing chick eye were studied by specific antibodies and indirect immunofluorescence. At stage 19, only type I collagen was detected in the primary corneal stroma, in the vitreous body, and along the lens surface. At later stages, type I collagen was located in the primary and secondary corneal stroma and in the fibrous sclera, but not around the lens. Type II collagen was first observed at stage 20 in the primary corneal stroma, neural retina, and vitreous body. It was particularly prominent at the interface of the neural retina and vitreous body and, from stage 30 on, in the cartilaginous sclera. The primary corneal stroma consisted of a mixture of type I and II collagens between stages 20 and 27. Invasion of the primary corneal stroma by mesenchyme and subsequent deposition of fibroblast-derived collagen corresponded with a pronounced increase of type I collagen, throughout the entire stroma, and of type II collagen, in the subepithelial region. Type II collagen was also found in Bowman's and Descemet's membranes. A transient appearance of type III collagen was observed in the corneal epithelial cells, but not in the stroma (stages 20–30). The fully developed cornea contained both type I and II collagens, but no type III collagen. Type III collagen was prominent in the fibrous sclera, iris, nictitating membrane, and eyelids.     

花背蟾蜍角膜早期形态发生中胶原合成的放射自显影研究

本实验以~3H-脯氨酸为标记物,用放射自显影方法研究了花背蟾蜍眼的早期发育中胶原的合成、分布以及对角膜早期形态发生的作用。结果表明,角膜上皮从开始形成即合成胶原,并在角膜上皮基底面聚积。在角膜开始透明时,角膜上皮、内角膜和晶状体的胶原合成速率都明显增加,提示与角膜分化密切相关。     

Keratan sulfate expression during avian craniofacial morphogenesis

Summary Using the monoclonal antibody MZ15 in immunocytochemical and ultrastructural studies we have been able to determine the spatiotemporal pattern of keratan sulfate (KS) distribution during quail craniofacial morphogenesis. KS-containing proteoglycans are found associated with invaginating placodes (olfactory, lens and otic), in developing pronephric tubules, notochord, pharynx and endocardium, and display developmental regulation. The appearance of such proteoglycans (PGs) during placode morphogenesis is particularly striking and we suggest that they may be an important component of the extracellular matrix which has been previously implicated in mediating the morphogenetic interactions and cell movements occurring at these sites. The otic vesicle during stage 18–22 displays a notable asymmetric distribution of KS-containing PGs. The role that these molecules may play and the reasons for this regionalization are, as yet, unclear but it is conceivable that the distribution of proteoglycans at this stage reflects subsequent differentiative events during otocyst development. Furthermore, our ultrastructural observations indicate that over the developmental period studied (H & H stages 8–22) keratan sulfate exists in at least two proteoglycan forms. Some spatiotemporal correlation has been found to exist between the distributions of KS-containing PGs and type II collagen as previously reported by Thorogood et al. (1986). We suggest that the proteoglycan detected at such sites is cartilage-specific proteoglycan and that it plays an important role, together with type II collagen, in the “signalling” mechanism which specifies the subsequent pattern of the chondrocranium. It is proposed that this interaction at epithelio-mesenchymal interfaces in the developing head parallels the matrix-mediated tissue interaction between notochord and somites which results in the formation of the cartilaginous primordia of the vertebrae from the sclerotomes as reported by Lash and Vasan (1978).     

Axial structure of the heterotypic collagen fibrils of vitreous humour and cartilage

We have compared the axial structures of negatively stained heterotypic, type II collagen-containing fibrils with computer-generated staining patterns. Theoretical negative-staining patterns were created based upon the "bulkiness" of the individual amino acid side-chains in the primary sequence and the D-staggered arrangement of the triple-helices. The theoretical staining pattern of type II collagen was compared and cross-correlated with the experimental staining pattern of both reconstituted type II collagen fibrils, and fibrils isolated from adult and foetal cartilage and vitreous humour. The isolated fibrils differ markedly in both diameter and composition. Correlations were significantly improved when a degree of theoretical hydroxylysine glycosylation was applied, showing for the first time that this type of glycosylation influences the negative-staining pattern of collagen fibrils. Increased correlations were obtained when contributions from types V/XI and IX collagen were included in the simulation model. The N-propeptide of collagen type V/XI and the NC2 domain of type IX collagen both contribute to prominent stain-excluding peaks in the gap region. With decreasing fibril diameter, an increase of these two peaks was observed. Simulations of the fibril-derived staining patterns with theoretical patterns composed of proportions of types II, V/XI and IX collagen confirmed that the thinnest fibrils (i.e. vitreous humour collagen fibrils) have the highest minor collagen content. Comparison of the staining patterns showed that the organisation of collagen molecules within vitreous humour and cartilage fibrils is identical. The simulation model for vitreous humour, however, did not account for all stain-excluding mass observed in the staining pattern; this additional mass may be accounted for by collagen-associated macromolecules.     

Ultrathin-layer microelectrophoretic determination of lactate dehydrogenase isoenzymes in corneal and conjunctival epithelium of the cow

In order to evaluate the impact of tissue oxygenation on the distribution pattern of lactate dehydrogenase isoenzymes, activities of the isoenzymes were measured in microdissected samples of bovine tissue. A highly sensitive ultrathin-layer electrophoretic technique was used to determine the distribution pattern of lactate dehydrogenase isoenzymes in basal, intermediate and superficial layers of the epithelium of central and peripheral cornea and in the epithelium of the bulbar conjunctiva. Measurements revealed almost homogeneous intraepithelial distribution patterns of lactate dehydrogenase isoenzymes in both tissues. In the cornea the lactate dehydrogenase isoenzymes 4 and 5, which are regarded to be specialized for anaerobic glucose metabolism, were found to predominate. In the well-oxygenated conjunctival epithelium most of the activity could be ascribed to the lactate dehydrogenase isoenzyme 3. In contrast to the isoenzymatic activities, total activity of lactate dehydrogenase was inhomogeneously distributed; maximum activities were found in the basal layer of corneal epithelium and in the intermediate layer of conjunctival epithelium. The results indicate that oxygen supply is relevant rather for the intraepithelial distribution of total enzyme activity than for the expression of lactate dehydrogenase isoenzymes.Parts of this study were presented as an inaugural dissertation to the Medical Faculty of the University of Basel by K. Krieger     

Synthesis of type III collagen by fibroblasts from the embryonic chick cornea

Synthesis of collagen types I, II, III, and IV in cells from the embryonic chick cornea was studied using specific antibodies and immunofluorescence. Synthesis of radioactively labeled collagen types I and III was followed by fluorographic detection of cyanogen bromide peptides on polyacrylamide slab gels and by carboxymethylcellulose chromatography followed by disc gel electrophoresis. Type III collagen had been detected previously by indirect immunofluorescence in the corneal epithelial cells at Hamburger-Hamilton stages 20--30 but not in the stroma at any age. Intact corneas from embryos older than stage 30 contain and synthesize type I collagen but no detectable type III collagen. However, whole stromata subjected to collagenase treatment and scraping (to remove epithelium and endothelium) and stromal fibroblasts from such corneas inoculated in vitro begin synthesis of type III collagen within a few hours while continuing to synthesize type I collagen. As demonstrated by double-antibody staining, most corneal fibroblasts contain collagen types I and III simultaneously. Collagen type III was identified biochemically in cell layers and media after chromatography on carboxymethylcellulose be detection of disulfide-linked alpha l (III)3 by SDS gel electrophoresis. The conditions under which the corneal fibroblasts gain the ability to synthesize type III collagen are the same as those under which they lose the ability to synthesize the specific proteoglycan of the cornea: the presence of corneal-type keratan sulfate.     

On the role of type IX collagen in the extracellular matrix of cartilage: type IX collagen is localized to intersections of collagen fibrils

The tissue distribution of type II and type IX collagen in 17-d-old chicken embryo was studied by immunofluorescence using polyclonal antibodies against type II collagen and a peptic fragment of type IX collagen (HMW), respectively. Both proteins were found only in cartilage where they were co-distributed. They occurred uniformly throughout the extracellular matrix, i.e., without distinction between pericellular, territorial, and interterritorial matrices. Tissues that undergo endochondral bone formation contained type IX collagen, whereas periosteal and membranous bones were negative. The thin collagenous fibrils in cartilage consisted of type II collagen as determined by immunoelectron microscopy. Type IX collagen was associated with the fibrils but essentially was restricted to intersections of the fibrils. These observations suggested that type IX collagen contributes to the stabilization of the network of thin fibers of the extracellular matrix of cartilage by interactions of its triple helical domains with several fibrils at or close to their intersections.     

A comparison of the immunohistochemical localization of type I and type II collagens in craniofacial cartilages of the rat.

The immunohistochemical localization of types I and II collagen was examined in the following 4 cartilaginous tissues of the rat craniofacial region: the nasal septal cartilage and the spheno-occipital synchondrosis (primary cartilages), and the mandibular condylar cartilage and the cartilage at the intermaxillary suture (secondary cartilages). In both primary cartilages, type II collagen was present in the extracellular matrix (ECM) of the whole cartilaginous area, but type I collagen was completely absent from the ECM. In the secondary cartilages, type I collagen was present throughout the cartilaginous cell layers, and type II collagen was restricted to the ECM of the mature and hypertrophic cell layers. These observations indicate differences in the ECM components between primary and secondary craniofacial cartilages, and that these differences may contribute to their modes of chondrogenesis.     

Ultrastructural aspects of the production of extracellular matrix components by the chick embryonic notochord in vitro

The morphology of extracellular matrix (ECM) components and of the cell organelles, particularly the Golgi complex and its derived structures, implicated in the production of ECM in the chick embryonic notochord have been studied by transmission electron microscopy. Isolated notochordal fragments were cultured in suspension in liquid medium. Native striated collagen fibrils with a period of 540 A were observed in the perinotochordal sheath. Fine granular and filamentous materials suggestive of proteoglycans have been observed in intercellular spaces and under the basal lamina of the notochordal sheath. Golgi mature vesicles with structures resembling the previously described segment-long-spacing (SLS)-like aggregates and secretory vesicles probably containing proteoglycans or condensed collagen precursors have also been observed.     

Secretion of collagen types I and II by epithelial and endothelial cells in the developing chick cornea demonstrated by in situ hybridization and immunohistochemistry

Cells involved in the synthesis of collagen types I and II in the cornea of developing chick embryos have been studied by using in situ hybridization and immunohistochemistry. Corneas processed for in situ hybridization with the type I and II collagen probes demonstrated specific mRNAs in the epithelium of embryos at stage 18 with an increase at stages between 26 and 31, and then gradual decrease to the background level in the next several days. In the endothelium, a small amount of specific mRNA was recognized through these stages. In the stroma, only sections hybridized with the type I probe demonstrated mRNA in fibroblasts. Immunostaining demonstrated specific collagen types in the stroma at sites which were closely associated with cells containing specific mRNAs. Both collagens type I and II were present beneath the epithelium as narrow bands at stage 18; as the thicker primary stroma at stages 20 and 26; and as subepithelial, subendothelial and stromal staining at stage 31. Thereafter, type I collagen was increased in the stroma but it was also noted in the subepithelial and, to a lesser degree, subendothelial regions, whereas type II collagen was gradually confined to the subendothelial matrix. Electron microscopic examination of sections from 5-day-old (stage-27) embryo corneas using antibodies against the carboxyl propeptides of type I and II procollagens revealed the presence of these procollagens within the cisternae of the endoplasmic reticulum and Golgi vesicles in both epithelial and endothelial cells. In the epithelial cells both the periderm and basal cells contained these procollagens within the cytoplasmic organelles. These results indicate that not only the epithelial cells, but also the endothelial cells secrete collagen types I and II during the formation of the primary corneal stroma and for several days after invasion of fibroblasts.     

Apoptosis of Chondrocytes in Transgenic Mice Lacking Collagen II

Previous work demonstrated that collagen fibrils were not detectable in the cartilage of transgenic mice homozygous for targeted inactivation of the collagen II gene. In the present work, we used the same mice to show that chondrocytes undergo apoptosis in the absence of collagen II, the major component of the extracellular matrix of cartilage. The chondrocytes in the homozygous mice had condensed nuclei, fragmentation of nuclear DNA, and decreased levels of the Bcl-2 protein. These results provide direct evidence that cartilage extracellular matrix lacking collagen II cannot support the survival of chondrocytes. In addition, the results suggest that apoptosis may play a role in degenerative connective tissue diseases such as osteoarthritis in which there is extensive tissue loss.     

Independent deposition of collagen types II and IX at epithelial-mesenchymal interfaces

Previous studies have demonstrated the presence of type II collagen (in mature chickens predominantly a 'cartilage-specific' collagen) in a variety of embryonic extracellular matrices that separate epithelia from mesenchyme. In an immunohistochemical study using collagen type-specific monoclonal antibodies, we asked whether type IX collagen, another 'cartilage-specific' collagen, is coexpressed along with type II at such interfaces. We confirmed that, in the matrix underlying a variety of cranial ectodermal derivatives and along the ventrolateral surfaces of neuroepithelia, type II collagen is codistributed with collagen types I and IV. Type IX collagen, however, was undetectable at those sites. We observed immunoreactivity for type IX collagen only within the notochordal sheath, where it first appeared at a later stage than did collagen types I and II. We also observed type II collagen (without type IX) beneath the dorsolateral ectoderm at stage 16; this correlates with the period during which limb ectoderm has been reported to induce the mesoderm to become chondrogenic. Finally, in older hind limbs we observed subepithelial type II collagen that was not associated with subsequent chondrogenesis, but appeared to parallel the formation of feathers and scales in the developing limb. These observations suggest that the deposition of collagen types II and IX into interfacial matrices is regulated independently, and that induction of mesenchymal chondrogenesis by such matrices does not involve type IX collagen. Subepithelial type IX collagen deposition, on the other hand, correlates with the assembly of a thick multilaminar fibrillar matrix, as present in the notochordal sheath and, as shown previously, in the corneal primary stroma.     

Control of corneal differentiation by extracellular materials. Collagen as a promoter and stabilizer of epithelial stroma production

The primary stroma of the cornea of the chick embryo consists of orthogonally arranged collagen fibrils embedded in glycosaminoglycan (GAG) produced by the epithelium under the early inductive influence of the lens. The experiments reported here were designed to test whether or not the collagen of the lens basement lamina is capable of stimulating corneal epithelium to produce primary stroma. Enzymatically isolated 5-day-old corneal epithelia were grown for 24 hr in vitro in the presence of ³⁵SO₄ or proline-³H on various substrata. Epithelia cultured on lens capsule synthesized 2.5 times as much GAG (as measured by incorporation of label into CPC precipitable material) and almost 3 times as much collagen (assayed by hot TCA extraction or collagenase sensitivity) as when cultured on Millipore filter or other noncollagenous substrata. A similar stimulatory response was observed when epithelium was combined with chemically pure chondrosarcoma collagen, NaOH-extracted lens capsule, vitreous humor, frozen-killed corneal stroma or cartilage, or tendon collagen gels; in the latter case, the magnitude of the effect can be shown to be related to concentration of the collagen in the gel. All of the collagenous substrata stimulate not only extracellular matrix production, but also polymerization of corneal-type matrix, as judged by ultrastructural criteria and by the association of more radioactivity with the tissue than the medium. Since purified chondrosarcoma collagen is as effective as lens capsule, the stimulatory effect on collagen and GAG synthesis by corneal epithelium is not specific for basal lamina (lens capsule) collagen.     

Distribution of connective tissue proteins in chick muscle spindles as revealed by monoclonal antibodies: a unique distribution of brachionectin/tenascin

The distribution of chick muscle spindles of eight connective tissue proteins (collagen types I, IV, V, and VI, laminin, heparan sulfate, fibronectin, and brachionectin/tenascin) was examined by immunofluorescent histochemistry. Intrafusal fibers were surrounded by layers of collagen type VI and fibronectin, and by an external lamina containing collagen type IV, laminin, and heparan sulfate. Most of these layers displayed a different pattern of staining at the sensory region of the equator than at the polar region. The crescent-like sheath that caps each intrafusal fiber and sensory terminal at the equator was strongly positive for collagen type I and weakly positive for collagen type V. The outer spindle capsule contained laminin, heparan sulfate, collagen types IV and VI, brachionectin/tenascin, fibronectin, and to a lesser degree also collagen types I and V. Brachionectin/tenascin had the narrowest distribution of any of the connective tissue macromolecules studied. It was found only in the outer capsule and in the coverings of blood vessels and nerves associated with the outer capsule.     

The notochordal sheath in amphioxus--an ultrastructural and histochemical study

The notochord and notochordal sheath of 10 adult amphioxus were investigated ultrastructurally and histochemically. The notochord in amphioxus consists of parallel notochordal cells (plates) and each plate consists of parallel thicker and thinner fibrils and numerous profiles of smooth endoplasmic reticulum situated just beneath the cell membrane. Histochemical staining shows that the notochordal plates resemble neither the connective tissue notochordal sheath nor the typical muscular structure myotomes. The notochordal sheath has a complex three-layered organization with the outer, middle and inner layer The outer and middle layer are composed of collagen fibers of different thickness and course, that correspond to collagen type I and collagen type III in vertebrates, respectively, and the inner layer is amorphous, resembles basal lamina, and is closely attached to the notochord by hemidesmosome junctions. These results confirm the presence of collagen fibers and absence of elastic fibers in amphioxus.     

High level of endostatin in epididymal epithelium: protection against primary malignancies in this organ?

Rete testis and epididymis are rare locations for primary tumors or metastasis. Assuming that this may be related to expression level of angiogenic inhibitors, we focused our study on the expression pattern of collagen 18/endostatin. In situ hybridization and immunohistochemistry for collagen 18 and endostatin were carried out on sections of human rete testis and epididymis as well as on epididymal adenoma and human testicular tissue with or without carcinoma in situ (CIS). In situ hybridization revealed strong expression of collagen 18 mRNA in rete testis, efferent ducts and epididymal duct. Immunostaining showed collagen 18 in epithelium and basement membrane as well as in blood vessels of rete testis. Further, in both efferent ducts and epididymal duct, collagen 18 was mainly localized in the basement membrane of these ducts and of the blood vessel wall. Endostatin immunostaining was localized in the epithelium of rete testis, efferent ducts and epididymal duct. This pattern of endostatin staining was absent in epididymal adenoma tissue while tumor associated blood vessels exhibited strong endostatin staining. No endostatin staining was detectable in normal germinal epithelium and CIS cells while Leydig cells exhibited strong endostatin staining. High endostatin expression in epididymis may protect this organ against tumor development. Gene therapeutic strategies providing high expression of endostatin in normal epithelia may be useful to prevent tumor development.