Μελέτη μακρομορίων του εξωκυττάριου χώρου

Abstract

Proteoglycans participate in cellular interactions via modulating the effects of growth factors or with other mechanisms in early embryo. The majority of the functions of proteoglycans are associated with the glycosaminoglycan (GAG) chains. We used β-D-xyloside, an inhibitor of proteoglycan synthesis and specifically of GAG attachment to proteoglycan core proteins, to study proteoglycan functions in early chick embryo development. Low concentrations of β-xyloside which are known to affect differentially chondroitin but not heparan sulfate proteoglycan biosynthesis have provided a convenient tool for altering proteoglycan production. The protein patterns of xyloside-treated embryos showed a shift of radioactive peaks to lower molecular mass which could be attributed to the reduction of proteoglycan size as was demonstrated by chondroitinase ABC/AC II treatments. It was notable in our data that β-xyloside altered the chondroitin sulfate proteoglycan decorin to lower molecular mass while it did not seem to affect the size of the heparin sulfate proteoglycan perlecan. More protein was synthesized from xyloside-treated embryos at stage XII (morula) than from embryos at stage HH2 (initial primitive streak/early gastrula) when compared to the controls. This could have reflected an accelerated translation and/or mobilization of oogenetic transcripts in embryos at stage XII when proteoglycan metabolism was disrupted. Misregulation of proteoglycans by modulating the functionality of the protein and by influencing their expression level resulted in an inability of the early embryo to assemble a stable extracellular matrix that would have been normally produced. These changes were associated with the collapse of the typical blastula architecture and inhibition of the induction of mesoderm in the chick embryo. Induction of neuroectoderm required proteoglycans assembled before the initiation of gastrulation movements. However, sustained proteoglycan biosynthesis was required for the morphogenetic movements to form the neural tube and the rest of the embryonic axis. We also studied the spatiotemporal distribution pattern of link protein by immunofluorescence and immunoprecipitation and the role of this glycoprotein by blocking antibodies in the early chick embryo. The recognition of the link protein 1 (LP1, 48 kDa) and link protein 2 (LP2, 44 kDa) types was an important finding of our study. Link protein links several proteoglycans, such as aggrecan to hyaluronan, creating stable aggregates in the extracellular matrix and has a general function in the organization of the extracellular matrix. It is known that combinations of LP1 and LP2 create more stable complexes than the individual link protein molecule. This was also shown in our experiments, in that aggrecan (180kDa) co-precipitated with LP1 and LP2. Our immunofluorescent experiments showed that link protein expression was first detectable at the blastula stage (st. XIII) and its presence may be fundamental as the first extracellular matrix starts to assemble before the initiation of the first major cellular migrations during the gastrula stage. Link protein influorescence was strong in the cells ingressing through the primitive streak and in the migrating cells in embryos at stage HH3 (intermediate streak/mid-gastrula). At stage HH4 (definitive streak/late gastrula), link protein fluorescence was strong at the apical surface of the neural plate. At stage HH4-5 (head process), link protein fluorescence was strong at the apical surface of the neural folds, notochord and endoderm. At stage HH13 (19 somites), link protein fluorescence was intense in the encephalic vesicles, in the extracellular matrix, in the lumen of encephalic vesicles, intense in migrating neural crest cells, neural tube and in notochord, strong in gut lower wall, hard tube and dorsal aorta wall, intense in dermomyotome and strong in sclerotome in somites. By stage HH17 (29 somites), link protein fluorescence was strong in neuroepithelium and extracellular matrix in the lumen of the diencephalon, strong in neural crest cells, in the intraretinal space in the eye, in myocardium and endocardium, in dorsal aorta, in dermomyotome, the outer surface of pharyngeal arches wall of aortic arches and intense in thyroid rudiment. Inhibition of function of link protein by blocking antibodies showed that link protein was important in neuroepithelial tissue organization and neural tube closure, in normal differentiation of the neural tube to form the brain, in the morphogenesis of the heart tube, the dorsal aorta and gut and in somite epithelialization.