Histochemical analysis of extracellular matrix material during embryonic mouse lens morphogenesis in an aphakic strain of mice

Extracellular matrix material (ECM) present during early lens morphogenesis was analyzed histochemically in normal CFW mice and mutant strain aphakia by the Alcian blue 8GX, pH 2.5, Alcian blue 8GX, pH 2.5/periodic acid-Schiff combined, high-iron diamine, and van Gieson methods. At lens placode formation, the optic vesicle basal lamina in both strains was higher in sulfated glycosaminoglycan content than was the ectodermal basal lamina. In the aphakia strain, ECM components were observed intercellularly in the presumptive neural retina and lens rudiment of some specimens. This observation was peculiar to the aphakia strain. At the lens cup stage (10.5 days), the interface ECM became less uniformly dense in the CFW strain, resulting in the formation of a fibrillar structure in the widening interspace area. In contrast, the interface ECM in the mutant strain stained solidly and continuously for acidic materials, particularly sulfated glycosaminoglycans, for a full 2 days longer than in the normal strain. The optic cup and lens rudiment remained closely apposed and intercellular ECM components were observed in these tissues in most mutant specimens throughout these stages. The exact mechanism resulting in these intercellular deposits is unknown, although it is possible that they are either pulled along on the cell surface away from the interface ECM during cell shape changes related to the cell cycle or that they are secreted abnormally due to some disturbed cellular polarity. It is unclear at this time if these abnormalities of the ECM in the aphakia strain play a role in the pathogenesis of the multiple eye anomalies, or if they are a secondary effect of the gene mutation.     

The extracellular matrix between the optic vesicle and presumptive lens during lens morphogenesis in an anophthalmic strain of mice

Extracellular matrix material present during early lens morphogenesis in anophthalmic strain ZRDCT-Ch mice was studied histochemically by the Alcian blue 8GX pH 2.5, Alcian blue 8GX pH 2.5/periodic acid-Schiff combined, high iron diamine, and Van Gieson methods. Observed staining patterns were compared with results from an analysis of a normal strain of mice (E.H. Webster, Jr., A.F. Silver, and N.I. Gonsalves, 1983, Develop. Biol. 100, 147-157). No differences in constituents were found between the strains in staining patterns of the ectodermal basal lamina. However, the optic vesicle basal lamina in the anophthalmic strain was found to have a relatively lower staining intensity for sulfated glycosaminoglycan associated with it than was observed in the normal strain, although these mutant optic vesicles were morphologically normal. Results from this and the earlier study on normal mice indicate that one function of sulfated glycosaminoglycan in early lens morphogenesis may be to serve as a cementing medium between the optic and lens rudiments. This sulfated glycosaminoglycan deficiency on the anophthalmic optic vesicle basal lamina is temporally correlated with and may be causally related to precocious lens cup formation and frequently observed separation of the normally adherent eye rudiments. Conclusions drawn from this study are consistent with the speculation of H.B. Chase and E.B. Chase (1941, J. Morphol. 68, 279-301) that there may be abnormal contact between the optic vesicle and presumptive lens ectoderm in the mutant strain, although there is a differing view on the cause of the abnormal contact.     

花背蟾蜍眼早期形态发生中其主要部分空间联系的研究

本文用扫描电镜研究了花背蟾蜍眼早期形态发生中视泡和预定晶状体、晶状体和预定角膜上皮间的紧密接触,此后在接触处出现间隙,其中存在呈网状的原纤维(fibril),这些原纤维的数量随两侧相连组织的分化,表现出增多、减少和逐渐消失的规律性变化,据此推测其成分属细胞外基质,对促进相连组织的分化起重要作用。     

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.     

Localization of newly synthesized precursors of basal lamina in the regenerating planarian as revealed by autoradiography

Autoradiography has been carried out to investigate the site of synthesis of the basal lamina in the regenerating planarian, Dugesia japonica. Since the basic collagenous structures of the basal lamina arose from RR-positive amorphous precursor, [³H]proline, [³H]glucose and [³⁵S]sodium sulphate were used as radioactive precursors of collagen, unsulphated and sulphated GAG respectively. Cytoplasm of the most regenerating epidermal cells was heavily labeled with [³H]proline during epithelization. A quantitative uptake analysis of [³H]proline indicates a progressive decline in the amount of labeled precursor in the epidermis with a corresponding increase in deposition of the labeled collagen at the presumptive basal lamina. Several myoblasts at the subepidermal region were highly labeled with both [³H]glucose and [³⁵S]sodium sulphate. Silver grains of these labeled precursors were also present in the presumptive portion of basal lamina. These observations suggest that the regenerating epidermal cell is the only site of synthesis of the basal lamina collagen while the myoblast exclusively secretes extracellular GAG. Some of the GAG may be closely associated with the amorphous zone.     

The turnover of basal lamina glycosaminoglycan correlates with epithelial morphogenesis

The mouse embryonic submandibular epithelium begins as a single bud from the floor of the mouth which, under the influence of its surrounding mesenchyme, grows and forms lobules that subsequently branch repetitively. The lobular morphology of the 13-day epithelium is maintained by its basal lamina which is a continuous layer on the interlobular clefts but is interrupted on the distal aspects of the lobules. The structural integrity of this lamina is dependent upon its glycosaminoglycan (GAG) which, by histochemistry, is more abundant on the interlobular clefts than on the distal lobules. We have investigated the basis for these regional differences in the lamina by examining the synthesis and degradation of total GAG as well as the accumulation and loss of laminar GAG during the morphogenesis of the 13-day gland. Autoradiography and histochemistry show that laminar GAG is rapidly turning over. Although it is relatively stable in the interlobular clefts, GAG is rapidly degraded on the distal lobules. This difference can account for the regional variation in basal laminar GAG accumulation. The results of incorporation kinetics and precursor pool specific activities of total epithelial GAG show that the rate of GAG synthesis is greater than its rate of degradation in the base of the lobules, which includes the interlobular clefts. In contrast, during morphogenesis, the rate of GAG degradation becomes greater than its rate of replacement in the distal lobules. The epithelial stalk appears to be in the steady state regarding GAG metabolism. We propose (a) that the rapid laminar GAG degradation on the distal lobules produces the interruptions in the lamina, allowing epithelial growth and expansion, and (b) that the metabolic stability of laminar GAG on the interlobular clefts maintains the integrity of this lamina which serves as a cellular constraint. The results are consistent with a model for epithelial morphogenesis in which the mesenchyme remodels the lamina, which in turn, dictates epithelial morphology. Regulation of basal lamina turnover may be a general mechanism for controlling the behavior of epithelial cell populations.     

The basal lamina of the postnatal mammary epithelium contains glycosaminoglycans in a precise ultrastructural organization

The mammary epithelium was investigated to determine whether glycosaminoglycans (GAG) are components of the basal lamina of epithelia undergoing postnatal morphogenesis. Isolated epithelial tissues from midpregnant mice produce substantial amounts of GAG, consisting predominantly of hyaluronic acid and heparan sulfate. The basal surfaces of mammary epithelia at various postnatal developmental stages show GAG, as demonstrated by histochemistry and by autoradiography coupled with enzyme susceptibility. Electron microscopy using ruthenium red staining reveals polyanionic components, presumably GAG, within the epithelial basal lamina. Detailed ultrastructural analyses of tannic acid-treated and ruthenium red-stained material demonstrate that the lamina contains a two-dimensional symmetrical array of tetragonally ordered components colsely associated with the basal plasma membrane. This array is similar to that found in the hyaluronate-containing lamina of embryonic epithelia. A structurally ordered complex of GAG-containing macromolecules may characterize the basal lamina of all epithelia which undergo morphogenetic changes in cell shape.     

Localisation of laminin and fibronectin during rat lens morphogenesis

Abstract. Immunofluorescence clearly localised laminin and fibronectin in the basement membranes of ocular epithelia through all stages of rat lens differentiation. Some fibronectin is also localised around the mesodermal cells associated with the epithelia. At 10 days of embryonic development, the presumptive lens ectoderm and optic veiscle are closely associated, and the "interspace" between the two tissues contains only a few mesodermal cells. Later, as the mesoderm is excluded and the lens palcode invaginates to form the lens pit, there is a marked increase in the concentration of both laminin and fibronectin in the interspace. At about 13 days, the interspace widens, and there is fluorescence for both glycoproteins in the basement membranes of the optic cup and lens vesicle; as the lens capsule thickens, the fluorescence for laminin increases in the latter. The unlabelled peroxidase anti-peroxidase (PAP) method shows that 'blebs' and 'blisters' of basement membranes, particularly from the optic vesicle, appear to give rise to cords of fibronectin- and laminin-positive material. These cords extend into the interspace and are associated with flocculent and fibrillar material. Therefore, the glycoproteins probably combine with other extracellular matrix (ECM) constituents, e.g. collagen, to form a network of fibrils in the interspace. This network must provide good adhesion between the lens placode and the optic vesicle so that invagination is co-ordinated to form the lens pit and the optic cup, respectively. It is suggested that, in addition to providing good adhesion between the tissues, this laminin- and fibronectin-rich ECM may stimulate the formation of basal extensions and cytoplasmic processes, particularly from the lens placode, and therefore, initiate the ectoderm to form lens placode.     

Expression of J1/tenascin in the crypt-villus unit of adult mouse small intestine: implications for its role in epithelial cell shedding.

The localization of the extracellular matrix recognition molecule J1/tenascin was investigated in the crypt-villus unit of the adult mouse ileum by immunoelectron microscopic techniques. In the villus region, J1/tenascin was detected strongly in the extracellular matrix (ECM) between fibroblasts of the lamina propria. It was generally absent in the ECM at the interface between subepithelial fibroblasts and intestinal epithelium, except for some restricted areas along the epithelial basal lamina of villi, but not of crypts. These restricted areas corresponded approximately to the basal part of one epithelial cell. In J1/tenascin-positive areas, epithelial cells contacted the basal lamina with numerous microvillus-like processes, whereas in J1/tenascin-negative areas the basal surface membranes of epithelial cells contacted their basal lamina in a smooth and continuous apposition. In order to characterize the functional role of J1/tenascin in the interaction between epithelial cells and ECM, the intestinal epithelial cell line HT-29 was tested for its ability to adhere to different ECM components. Cells adhered to substratum-immobilized fibronectin, laminin and collagen types I to IV, but not to J1/tenascin. When laminin or collagen types I to IV were mixed with J1/tenascin, cell adhesion was as effective as without J1/tenascin. However, adhesion was completely abolished when cells were offered a mixture of fibronectin and J1/tenascin as substratum. The ability of J1/tenascin to reduce the adhesion of intestinal epithelial cells to their fibronectin-containing basal lamina suggests that J1/tenascin may be involved in the process of physiological cell shedding from the villus.     

硫酸糖胺聚糖(Sulfated Glycosaminoglycans)在花背蟾蜍眼早期形态发生中的合成

本文用放射自显影追踪注射入胚胎的~(35)S-硫酸盐的方法,研究了花背蟾蜍早期形态发生时眼的各部分组织和细胞外基质中的硫酸糖胺聚糖(Sulfated Glycosaminoglycans简称:硫酸GAG)的合成,并分析了其在眼形态发生中的作用。结果表明:1.在眼早期形态发生时,合成的硫酸GAG主要是硫酸软骨素。2.眼各部分组织中在即将分化时硫酸GAG合成率增高,分化开始后逐渐下降到原基形成时的水平。3.在晶状体被诱导时,在视杯和晶状体相互贴近的组织及两者间的细胞外基质中硫酸GAG的合成率明显增加,提示这是晶状体诱导的重要因素。4.角膜上皮形成时即向角膜上皮下层和细胞外基质分泌硫酸GAG;角膜上皮透明时,合成更多的硫酸角质素。     

Differential response of embryonic cells to culture on tissue matrices.

Cell responses to different natural substrates have been followed by scanning microscopy in order to evaluate the role of these substrates in morphogenesis. Matrix has been isolated then repopulated with suspensions of embryonic cells from chick skin, spinal ganglia, duodenal epithelium and heart. In some cases outgrowth from amphibian embryonic tissue was used. Basal lamina of the Xenopus tail may be exposed by freezing and thawing the tissue, or by EDTA treatment. The underlying lamella of orthogonally oriented collagen fibers may be exposed by use of trypsin or hyaluronidase. Trypsin causes more clumping of collagen fibers and a coarser texture of the matrix. On trypsin isolated basement lamella, nerve cell processes grow out on the surface and show no strong tendency to penetrate the lamella while skin mesenchymal cells commonly burrow among the collagen plies. Epithelial cells remain on the surface. On the basal lamina mesenchymal cells ruffle in early stages of culture, then flatten. Epithelial cells flatten rapidly on the lamina. These differences in cell response are in some cases closely related to cell behavior in vivo and suggest that cells show a selective response to the chemical composition of the substrate as well as to its physical conformation.     

Mesenchyme cells degrade epithelial basal lamina glycosaminoglycan

We investigated whether turnover of basal lamina glycosaminoglycan (GAG), an active process during epithelial morphogenesis, involves the mesenchyme. Fixed, prelabeled, isolated mouse embryo submandibular epithelia were prepared retaining radioactive surface components, as determined by autoradiographic and enzymatic studies, and a basal lamina, as assessed by electron microscopy. Recombination of mouse embryo submandibular mesenchyme with these epithelia stimulates the release of epithelial radioactivity when the labeled precursor is glucosamine or glucose but not when it is amino acid. The release is linear with time during 150 min incubation. Augmented release of epithelial label requires living mesenchyme which must be close proximity with the epithelia. Although heterologous mesenchymes, including lung, trachea, and jaw, stimulate the release of submandibular epithelial label, epithelial tissues do not. The label released by intact submandibular mesenchyme from prelabeled epithelia is in GAG and in two unique fractions: heterogeneous materials of tetrasaccharide or smaller size and N-acetylglucosamine. Enzymatic treatment of the heterogeneous materials revealed the presence of glycosaminoglycan-derived oligosaccharides. These unique products were not obtained by incubating prelabeled epithelia with a mesenchymal cell extract, suggesting that intact mesenchymal cells are required. N-Acetylglucosamine was also released when mesenchyme was recombined with living prelabeled epithelia which contained labeled basal laminar GAG. Our results establish that submandibular epithelial basal lamina GAGs are degraded by submandibular mesenchyme. We propose that one mechanism of epithelial-mesenchymal interaction is the degradation of epithelial basal laminar GAG by mesenchyme.     

Ontogeny of the basal lamina in the sea urchin embryo

The patterns of expression for several extracellular matrix components during development of the sea urchin embryo are described. An immunofluorescence assay was employed on paraffin-sectioned material using (i) polyclonal antibodies against known vertebrate extracellular matrix components: laminin, fibronectin, heparan sulfate proteoglycan, collagen types I, III, and IV; and (ii) monoclonal antibodies generated against sea urchin embryonic components. Most extracellular matrix components studied were found localized within the unfertilized egg in granules (0.5-2.0 micron) distinct from the cortical granules. Fertilization initiated trafficking of the extracellular matrix (ECM) components from within the egg granules to the basal lamina of the developing embryo. The various ECM components arrived within the developing basal lamina at different times, and not all components were unique to the basal lamina. Two ECM components were not found within the egg. These molecules appeared de novo at the mesenchyme blastula stage, and remained specific to the mesoderm through development. The reactivity of antibodies to vertebrate ECM antigens with components of the sea urchin embryo suggests the presence of immunologically similar ECM molecules between the phyla.     

Epithelial morphogenesis in hydra requires de novo expression of extracellular matrix components and matrix metalloproteinases

As a member of the phylum Cnidaria, the body wall of hydra is organized as an epithelium bilayer (ectoderm and endoderm) with an intervening extracellular matrix (ECM). Previous studies have established the general molecular structure of hydra ECM and indicate that it is organized as two subepithelial zones that contain basement membrane components such as laminin and a central fibrous zone that contains interstitial matrix components such as a unique type I fibrillar collagen. Because of its simple structure and high regenerative capacity, hydra has been used as a developmental model to study cell-ECM interaction during epithelial morphogenesis. The current study extends previous studies by focusing on the relationship of ECM biogenesis to epithelial morphogenesis in hydra, as monitored during head regeneration or after simple incision of the epithelium. Histological studies indicated that decapitation or incision of the body column resulted in an immediate retraction of the ECM at the wound site followed by a re-fusion of the bilayer within 1 hour. After changes in the morphology of epithelial cells at the regenerating pole, initiation of de novo biogenesis of an ECM began within hours while full reformation of the mature matrix required approximately 2 days. These processes were monitored using probes to three matrix or matrix-associated components: basement membrane-associated hydra laminin beta1 chain (HLM-beta1), interstitial matrix-associated hydra fibrillar collagen (Hcol-I) and hydra matrix metalloproteinase (HMMP). While upregulation of mRNA for both HLM-beta1 and Hcol-I occurred by 3 hours, expression of the former was restricted to the endoderm and expression of the latter was restricted to the ectoderm. Upregulation of HMMP mRNA was also associated with the endoderm and its expression paralleled that for HLM-beta1. As monitored by immunofluorescence, HLM-beta1 protein first appeared in each of the two subepithelial zones (basal lamina) at about 7 hours, while Hcol-I protein was first observed in the central fibrous zone (interstitial matrix) between 15 and 24 hours. The same temporal and spatial expression pattern for these matrix and matrix-associated components was observed during incision of the body column, thus indicating that these processes are a common feature of the epithelium in hydra. The correlation of loss of the ECM, cell shape changes and subsequent de novo biogenesis of matrix and matrix-associated components were all functionally coupled by antisense experiments in which translation of HLM-beta1 and HMMP was blocked and head regeneration was reversibly inhibited. In addition, inhibition of translation of HLM-beta1 caused an inhibition in the appearance of Hcol-I into the ECM, thus suggesting that binding of HLM-beta1 to the basal plasma membrane of ectodermal cells signaled the subsequent discharge of Hcol-I from this cell layer into the newly forming matrix. Given the early divergence of hydra, these studies point to the fundamental importance of cell-ECM interactions during epithelial morphogenesis.     

Type I collagen reduces the degradation of basal lamina proteoglycan by mammary epithelial cells

When mouse mammary epithelial cells are cultured on a plastic substratum, no basal lamina forms. When cultured on a type I collagen gel, the rate of glycosaminoglycan (GAG) synthesis is unchanged, but the rate of GAG degradation is markedly reduced and a GAG-rich, basal lamina-like structure accumulates. This effect of collagen was investigated by comparing the culture distribution, nature, and metabolic stability of the 35S-GAG-containing molecules produced by cells on plastic and collagen. During 48 h of labeling with 35SO4, cultures on collagen accumulate 1.4-fold more 35S-GAG per microgram of DNA. In these cultures, most of the extracellular 35S-GAG is immobilized with the lamina and collagen gel, whereas in cultures on plastic all extracellular 35S-GAG is soluble. On both substrata, the cells produce several heparan sulfate-rich 35S-proteoglycan fractions that are distinct by Sepharose CL-4B chromatography. The culture types contain similar amounts of each fraction, except that collagen cultures contain nearly four times more of a fraction that is found largely bound to the lamina and collagen gel. During a chase this proteoglycan fraction is stable in cultures on collagen, but is extensively degraded in cultures on plastic. Thus, collagen-induced formation of a basal lamina correlates with reduced degradation and enhanced accumulation of a specific heparan sulfate-rich proteoglycan fraction. Immobilization and stabilization of basal laminar proteoglycan(s) by interstitial collagen may be a physiological mechanism of basal lamina maintenance and assembly.     

Colocalization of TGF-beta 1 and collagen I and III, fibronectin and glycosaminoglycans during lung branching morphogenesis

The possible in vivo role of TGF-beta 1 in regulating various proteins of the extracellular matrix, including fibronectin, collagen I and III, and glycosaminoglycans, was examined by immunohistochemical methods during critical stages of lung morphogenesis in the 11- to 18-day-old mouse embryo. Sections of Bouin-fixed, paraffin-embedded whole embryos were exposed to polyclonal antibodies specific to synthetic peptides present in the precursor part of TGF-beta 1 (pro-TGF-beta 1), in the processed TGF-beta 1 (antibody CC), collagen I and III, fibronectin, followed by the PAP or ABC technique to visualize the location of the antibody. GAG were stained with Alcian Blue 8GX. Our results indicate colocalization of TGF-beta 1 expression and that of matrix proteins in the developing lung when branching morphogenesis (cleft formation) and tissue stabilization occur. The presence of TGF-beta 1 at the epithelial-mesenchymal interfaces of stalks and clefts at a time when matrix proteins can first be visualized in these areas, suggests a direct participation of the growth factor in the development of the basic architecture of the lung.     

Expression of type VIII collagen during morphogenesis of the chicken and mouse heart.

The expression of type VIII collagen is restricted, in adult mammals, to specialized extracellular matrices and to a select subset of blood vessels. We have examined the distribution of type VIII collagen in sequential stages of mouse and chicken embryos and found a temporal and spatially restricted pattern of expression during cardiogenesis. Type VIII collagen was first detected by immunocytochemistry on Day 11 in the developing mouse embryo and at stage 19 in the chicken embryo. The distribution of this protein was rapidly modulated during cardiac morphogenesis. Initially (Day 11 in the mouse embryo), type VIII collagen was associated with cardiac myoblasts. From Days 15 to 18, the immunoreactive component was progressively diminished in the myocardium; however, this collagen was observed in the subendocardial layer of the atrioventricular canal and later in the cardiac jelly (or the myocardial basement membrane, an area associated with the formation of cardiac valves). On Day 17, type VIII collagen was also detected in the subendothelium (intima) and tunica media of large vessels. Neonatal and adult hearts contained low to undetectable levels of type VIII collagen. The presence of type VIII collagen was confirmed by immunoblot analysis of heart extracts at different stages of development. A major 185-kDa component, as well as polypeptides of 68 and 15 kDa, reacted with anti-type VIII collagen IgG. Exposure of heart extracts to hyaluronidase or reducing agent eliminated immunoreactivity of the 185-kDa component but not that of the 68- and 15-kDa polypeptides. Type VIII collagen therefore appears to be associated with a hyaluronidase-sensitive component of the extracellular matrix during a temporally restricted stage of embryonic cardiogenesis. The contribution of this collagen to cardiac morphogenesis might reside, in part, in its ability to influence the differentiation of the myocardium and formation of the cardiac valves.     

Dynamics of extracellular matrix in ovarian follicles and corpora lutea of mice

Despite the mouse being an important laboratory species, little is known about changes in its extracellular matrix (ECM) during follicle and corpora lutea formation and regression. Follicle development was induced in mice (29 days of age/experimental day 0) by injections of pregnant mare’s serum gonadotrophin on days 0 and 1 and ovulation was induced by injection of human chorionic gonadotrophin on day 2. Ovaries were collected for immunohistochemistry (n=10 per group) on days 0, 2 and 5. Another group was mated and ovaries were examined on day 11 (n=7). Collagen type IV α1 and α2, laminin α1, β1 and γ1 chains, nidogens 1 and 2 and perlecan were present in the follicular basal lamina of all developmental stages. Collagen type XVIII was only found in basal lamina of primordial, primary and some preantral follicles, whereas laminin α2 was only detected in some preantral and antral follicles. The focimatrix, a specialised matrix of the membrana granulosa, contained collagen type IV α1 and α2, laminin α1, β1 and γ1 chains, nidogens 1 and 2, perlecan and collagen type XVIII. In the corpora lutea, staining was restricted to capillary sub-endothelial basal laminas containing collagen type IV α1 and α2, laminin α1, β1 and γ1 chains, nidogens 1 and 2, perlecan and collagen type XVIII. Laminins α4 and α5 were not immunolocalised to any structure in the mouse ovary. The ECM composition of the mouse ovary has similarities to, but also major differences from, other species with respect to nidogens 1 and 2 and perlecan.     

Components, structure, biogenesis and function of the Hydra extracellular matrix in regeneration, pattern formation and cell differentiation

The body wall of Hydra is organized as an epithelial bilayer (ectoderm and endoderm) with an intervening extracellular matrix (ECM), termed mesoglea by early biologists. Morphological studies have determined that Hydra ECM is composed of two basal lamina layers positioned at the base of each epithelial layer with an intervening interstitial matrix. Molecular and biochemical analyses of Hydra ECM have established that it contains components similar to those seen in more complicated vertebrate species. These components include such macromolecules as laminin, type IV collagen, and various fibrillar collagens. These components are synthesized in a complicated manner involving cross-talk between the epithelial bilayer. Any perturbation to ECM biogenesis leads to a blockage in Hydra morphogenesis. Blockage in ECM/cell interactions in the adult polyp also leads to problems in epithelial transdifferentiation processes. In terms of biophysical parameters, Hydra ECM is highly flexible; a property that facilitates continuous movements along the organism's longitudinal and radial axis. This is in contrast to the more rigid matrices often found in vertebrates. The flexible nature of Hydra ECM can in part now be explained by the unique structure of the organism's type IV collagen and fibrillar collagens. This review will focus on Hydra ECM in regard to: 1) its general structure, 2) its molecular composition, 3) the biophysical basis for the flexible nature of Hydra's ECM, 4) the relationship of the biogenesis of Hydra ECM to regeneration of body form, and 5) the functional role of Hydra ECM during pattern formation and cell differentiation.