Collagen fibril biosynthesis in tendon: a review and recent insights

The development and evolution of multicellular animals relies on the ability of certain cell types to synthesise an extracellular matrix (ECM) comprising very long collagen fibrils that are arranged in very ordered 3-dimensional scaffolds. Tendon is a good example of a highly ordered ECM, in which tens of millions of collagen fibrils, each hundreds of microns long, are synthesised parallel to the tendon long axis. This review highlights recent discoveries showing that the assembly of collagen fibrils in tendon is hierarchical, and involves the formation of fairly short "collagen early fibrils" that are the fusion precursors of the very long fibrils that occur in mature tendon.     

Collagen fibril morphology in developing chick metatarsal tendon: 2. Electron microscope studies

Transverse section of embryonic chick metatarsal tendons ranging in age from 11 days to 18 days fetal were examined by electron microscopy to determine both the diameters and the lateral arrangements of the cylindrical collagen fibrils. In early developmental stages, from 11 days to 14 days fetal, sharp unimodal distributions of diameters centred near 32 or 40 nm were observed, but increasingly heterogeneous diameters were seen with increasing age. The heterogeneous diameter distributions were not uniform, but showed discrete populations of preferred diameters. The centre-to-centre distance separating the fibrils in the early developmental stages was about twice the fibril diameter and constant with age. Comparison of X-ray diffraction results with these observations indicated that the saptial relationships of the structures are preserved during the preparative procedures for electron microscopy, but that a transverse shrinkage of 25–30% had occurred relative to the wet dimension.     

Collagen involvement in branching morphogenesis of embryonic lung and salivary gland

The possibility that extracellular collagen is involved in branching morphogenesis of mouse embryo lung and salivary glands has been explored duringin vitro organ culture. Control cultures of both rudiment types contain abundant collagen in extracellular spaces between mesenchymal cells and in the epithelial-mesenchymal interface. Branching morphogenesis of lungs and salivary glands is not perturbed by the presence of β-aminopropionitrile, implying that extracellular collagen cross-linking is not required, but is perturbed by α,α′-dipyridyl orl-azetidine-2-car?ylic acid (LACA), agents reported to interfere with collagen synthesis and secretion. Analysis of the structural and biosynthetic effects of LACA revealed a severe inhibition of collagen synthesis, as monitored by hydroxyproline synthesis, and extracellular collagen accumulation. Cell and tissue integrity was not affected, but a slight inhibition of general protein synthesis, protein accumulation, and epithelial expansion was observed. The strong correlations between collagen biosynthesis, extracellular collagen presence, and branching morphogenesis are consistent with an integral role for collagen in embryonic lung and salivary gland morphogenesis.     

Extracellular compartments in tendon morphogenesis: collagen fibril, bundle, and macroaggregate formation

The formation of collagen fibrils, fibril bundles, and tissue-specific collagen macroaggregates by chick embryo tendon fibroblasts was studied using conventional and high voltage electron microscopy. During chick tendon morphogenesis, there are at least three extracellular compartments responsible for three levels of matrix organization: collagen fibrils, bundles, and collagen macroaggregates. Our observations indicate that the initial extracellular events in collagen fibrillogenesis occur within narrow cytoplasmic recesses, presumably under close cellular regulation. Collagen fibrils are formed within these deep, narrow recesses, which are continuous with the extracellular space. Where these narrow recesses fuse with the cell surface, it becomes highly convoluted with folds and processes that envelope forming fibril bundles. The bundles laterally associate and coalesce, forming aggregates within a third cell-defined extracellular compartment. Our interpretation is that this third compartment forms as cell processes retract and cytoplasm is withdrawn between bundles. These studies define a hierarchical organization within the tendon, extending from fibril assembly to fascicle formation. Correlation of different levels of extracellular compartmentalization with tissue architecture provides insight into the cellular controls involved in collagen fibril and higher order assembly and a better understanding of how collagen fibrils are collected into structural groups, positioned, and woven into functional tissue-specific collagen macroaggregates.     

Collagen fibril assembly and deposition in the developing dermis: segmental deposition in extracellular compartments

The hierarchy of extracytoplasmic compartmentalization and fibrillar organization as well as the assembly and deposition of collagen fibrils was characterized in the 15-day chick embryo dermis using transmission electron microscopy. At least two levels of extracellular compartmentalization are recognizable at this stage of dermal development. The first compartment consists of a series of narrow channels containing single or small groups (less than 5) of collagen fibrils. These channels course deep within the cell and are open to the extracellular space. The second extracellular compartment consists of fibrils grouped as small bundles in close association with the cell surface and is most often defined by a single fibroblast. A third level of fibril organization and compartmentalization is sometimes apparent at this stage of dermal development consisting of laterally associated bundles, more characteristic of the mature dermis. This compartment is associated with the fibroblast surface, but is less well defined than the fibril channels or bundle-forming compartments. Dermal collagen fibrils within bundles are discontinuous. Numerous fibrils ends are identified from serial sections and the ends gradually taper. These data indicate that the dermal fibroblast compartmentalizes the extracellular space and deposits collagen fibril segments during dermal morphogenesis. A model for the genesis of the extracellular compartments and their role in collagen fibrillogenesis and development of regularly arranged connective tissues, tendon, and cornea has been proposed. Dermal development conforms to this model and we suggest that extracytoplasmic compartmentalization of the steps in matrix assembly and segmental deposition of collagen fibrils are important mechanisms in the development of a wide variety of connective tissues.     

Collagen fibril formation in a wound healing model

Control of tissue composition and organization will be a key feature in the development of successful products through tissue engineering. However, the mechanism of collagen fibril formation, growth, and organization is not yet fully understood. In this study we have examined collagen fibril formation in a wound healing model in which the newly formed fibrils were kept distinct from preexisting tissue through use of a porous tubular biomaterial implant. Samples were examined after 4, 6, 14, and 28 days by light microscopy, in situ hybridization, and immunofluorescence microscopy. These showed a normal wound healing response, with significant collagen formation at 14 and 28 days. Individual collagen fibrils were isolated from these samples by gentle extraction in a gentamicin-containing buffer which allowed extraction of a large proportion of intact fibrils. Examination by transmission electron microscopy showed that approximately 80% of the intact fibrils showed a single polarity reversal, with both ends of each fibril comprising collagen amino-terminal domains; the remaining fibrils had no polarity reversal. All fibrils had similar diameters at both time points. Immunoelectron microscopy showed that all labeled fibrils contained both type I and III collagens. These data indicate that this wound healing model provides a system in which collagen fibril formation can be readily followed.     

Making vascular networks in the adult: branching morphogenesis without a roadmap

The vascular system is unique in that extensive branching morphogenesis may take place in the adult. Developmental neovascularization is guided by precise spatial cues but vessel formation in the adult is not genetically programmed. Here, we review different adult modes for branch patterning, acquiring artery or vein identity and allocating vascular progenitor cells. The endothelium shows a remarkable degree of self-organization into a treelike network and hemodynamic forces are important in rectifying abnormal branching. This discussion is in the context of a contemplated therapy for improving organ perfusion by creating new vascular loops properly integrated within the existing network.     

Semaphorin3a inhibits ureteric bud branching morphogenesis

Class 3 semaphorins are guidance proteins involved in axon pathfinding, vascular patterning and lung branching morphogenesis in the developing mouse embryo. Semaphorin3a (Sema3a) is expressed in renal epithelia throughout kidney development, including podocytes and ureteric bud cells. However, the role of Sema3a in ureteric bud branching is unknown. Here we demonstrate that Sema3a plays a role in patterning the ureteric bud tree in both metanephric organ cultures and Sema3a mutant mice. In vitro ureteric bud injection with Sema3a antisense morpholino resulted in increased branching, whereas recombinant SEMA3A inhibited ureteric bud branching and decreased the number of developing glomeruli. Additional studies revealed that SEMA3A effects on ureteric bud branching involve downregulation of glial cell-line derived neurotrophic factor (GDNF) signaling, competition with vascular endothelial growth factor A (VEGF-A) and decreased activity of Akt survival pathways. Deletion of Sema3a in mice is associated with increased ureteric bud branching, confirming its inhibitory role in vivo. Collectively, these data suggest that Sema3a is an endogenous antagonist of ureteric bud branching and hence, plays a role in patterning the renal collecting system as a negative regulator.     

In vitro collagen fibril assembly: thermodynamic studies

The in vitro fibril assembly of calf skin collagen was examined as a function of ionic strength and temperature. In a 0.03 M NaPi, pH 7.0, buffer, fibril assembly required a minimum critical concentration of collagen. At nearly physiological ionic strengths and temperatures, the critical concentration was less than 1 microgram/mL and required a very sensitive method for measurement. Raising the ionic strength of the buffer resulted first in higher and then lower critical concentrations. Raising the temperature led to lower critical concentrations. A van't Hoff plot of the fibril growth constant calculated from the critical concentration gave positive enthalpy changes and positive heat capacity changes which indicate that the fibril growth is driven by both hydrophobic and ionic inter-collagen interactions. Sedimentation equilibrium studies showed the collagen to be monomeric at subcritical concentrations. Differential scanning microcalorimetric studies showed only one very sharp heat absorption peak for the fibril assembly which coincided with the appearance of solution turbidity. Within experimental error, the enthalpy changes of the fibril assembly measured with the microcalorimeter were of the same magnitude as the van't Hoff enthalpy changes. These results are discussed in light of a cooperative nucleation-growth mechanism of collagen fibril assembly proposed earlier.     

NRAGE: A potential rheostat during branching morphogenesis

Branching morphogenesis is a developmental process characteristic of many organ systems. Specifically, during renal branching morphogenesis, its been postulated that the final number of nephrons formed is one key clinical factor in the development of hypertension in adulthood. As it has been established that BMPs regulate, in part, renal activity of p38 MAP kinase (p38^MAPK) and it has demonstrated that the cytoplasmic protein Neurotrophin Receptor MAGE homologue (NRAGE) augments p38^MAPK activation, it was hypothesized that a decrease in the expression of NRAGE during renal branching would result in decreased branching of the UB that correlated with changes in p38^MAPK activation. To verify this, the expression of NRAGE was reduced in ex vivo kidney explants cultures using antisense morpholino. Morpholino treated ex vivo kidney explants expression were severely stunted in branching, a trait that was rescued with the addition of exogenous GDNF. Renal explants also demonstrated a precipitous drop in p38^MAPK activation that too was reversed in the presence of recombinant GDNF. RNA profiling of NRAGE diminished ex vivo kidney explants resulted in altered expression of GDNF, Ret, BMP7 and BMPRIb mRNAs. Our results suggested that in early kidney development NRAGE might have multiple roles during renal branching morphogenesis through association with both the BMP and GDNF signaling pathways.     

Airway branching morphogenesis in three dimensional culture

Background

Lungs develop from the fetal digestive tract where epithelium invades the vascular rich stroma in a process called branching morphogenesis. In organogenesis, endothelial cells have been shown to be important for morphogenesis and the maintenance of organ structure. The aim of this study was to recapitulate human lung morphogenesis in vitro by establishing a three dimensional (3D) co-culture model where lung epithelial cells were cultured in endothelial-rich stroma.

Methods

We used a human bronchial epithelial cell line (VA10) recently developed in our laboratory. This cell line cell line maintains a predominant basal cell phenotype, expressing p63 and other basal markers such as cytokeratin-5 and -14. Here, we cultured VA10 with human umbilical vein endothelial cells (HUVECs), to mimic the close interaction between these cell types during lung development. Morphogenesis and differentiation was monitored by phase contrast microscopy, immunostainings and confocal imaging.

Results

We found that in co-culture with endothelial cells, the VA10 cells generated bronchioalveolar like structures, suggesting that lung epithelial branching is facilitated by the presence of endothelial cells. The VA10 derived epithelial structures display various complex patterns of branching and show partial alveolar type-II differentiation with pro-Surfactant-C expression. The epithelial origin of the branching VA10 colonies was confirmed by immunostaining. These bronchioalveolar-like structures were polarized with respect to integrin expression at the cell-matrix interface. The endothelial-induced branching was mediated by soluble factors. Furthermore, fibroblast growth factor receptor-2 (FGFR-2) and sprouty-2 were expressed at the growing tips of the branching structures and the branching was inhibited by the FGFR-small molecule inhibitor SU5402.

Discussion

In this study we show that a human lung epithelial cell line can be induced by endothelial cells to form branching bronchioalveolar-like structures in 3-D culture. This novel model of human airway morphogenesis can be used to study critical events in human lung development and suggests a supportive role for the endothelium in promoting branching of airway epithelium.     

Collagen fibril formation in vitro at nearly physiological temperatures

Fibril formation by collagen from piglet skin was studied at temperatures of 28–39°C. Collagen fibrils obtained in this temperature range differ in the degree of ordering. Electron microscopy shows that fibrils of minimal diameter are formed at physiological pH, ionic strength (PBS), and temperature. The greater diameter of fibrils formed at 34.5°C is due to enhanced collagen hydration. Fibril diameter at 38.5°C is increased because of cooperative unfolding of the triple helix and weaker binding between collagen molecules. The optimal temperature for fibrillogenesis appears to be 36.5°C, and such fibrils are most similar to those observed in vivo.     

Collagen type I fibril packing in vivo and in vitro

Reviewed are works concerning the mechanisms of collagen (type I) fibril packing and the influence of macromolecular structure and physicochemical parameters of the medium on the process.     

Scatter factor-dependent branching morphogenesis: structural and histological features

Branching morphogenesis is a multi-step process that controls the formation of polarised tubules starting from hollow cysts. Its execution entails a series of rate-limiting events which include reversible disruption of cell polarity, dismantling of intercellular contacts, acquisition of a motile phenotype, stimulation of cell proliferation, and final re-establishment of cell polarity for creation of the definitive structures. Branching morphogenesis takes place physiologically during development, accounting for the establishment of organs endowed with a ramified architecture such as glands, the respiratory tract and the vasculartree. In cancer, aberrant implementation of branching morphogenesis leads to deregulated proliferation, protection from apoptosis and enhanced migratory/invasive properties, which together exacerbate the aggressive features of neoplastic cells. Under both physiological and pathological conditions, branching morphogenesis is mainly accomplished by a family of growth factors known as scatter factors. In this review, we will summarise the current knowledge on the biological and functional roles of scatter factors during branching morphogenesis, with a special emphasis on the phenotypic (structural and histological) consequences of scatter factor activity in different tissues.     

A mechanism for early branching in lung morphogenesis

The lung is a highly branched fluid-filled structure, that develops by repeated dichotomous branching of a single bud off the foregut, of epithelium invaginating into mesenchyme. Incorporating the known stress response of developing lung tissues, we model the developing embryonic lung in fluid mechanical terms. We suggest that the repeated branching of the early embryonic lung can be understood as the natural physical consequence of the interactions of two or more plastic substances with surface tension between them. The model makes qualitative and quantitative predictions, as well as suggesting an explanation for such observed phenomena as the asymmetric second branching of the embryonic bronchi.     

Extracellular matrix and growth factors in branching morphogenesis

The unifying hypothesis of the NSCORT in gravitational biology postulates that the ECM and growth factors are key interrelated components of a macromolecular regulatory system. The ECM is known to be important in growth and branching morphogenesis of embryonic organs. Growth factors have been detected in the developing embryo, and often the pattern of localization is associated with areas undergoing epithelial-mesenchymal interactions. Causal relationships between these components may be of fundamental importance in control of branching morphogenesis.     

Modelling in vitro lung branching morphogenesis during development

It has been shown experimentally that lung epithelial explants have an ability to undergo branching morphogenesis without mesenchyme. However, the mechanisms of this phenomenon remain to be elucidated. In the present study, we construct a mathematical model that can reproduce the dynamics of in vitro branching morphogenesis. We show that the system is essentially governed by three variables--c(0) which is the initial fibroblast growth factor (FGF) concentration, D which is the diffusion coefficient of FGF, and beta which describes the mechanical strength of the cytoskeleton. It is confirmed by numerical simulations that this model can reproduce the experimentally obtained patterns qualitatively. Finally, we experimentally verify two predictions from the model: effects of very high FGF concentration and effects of small mechanical contributions of the cytoskeleton. The theoretical predictions match well with the experimental results.     

Collagen processing, crosslinking, and fibril bundle assembly in matrix produced by fibroblasts in long-term cultures supplemented with ascorbic acid

Human foreskin fibroblasts were cultured for up to 6 weeks in medium supplemented with ascorbic acid. During this time, the cells produced an extensive new connective tissue matrix in which the accumulated collagen (mostly type I) amounted to about 0.25 mg/10(6) cells. The matrix was highly differentiated as shown by complete processing of procollagen to collagen alpha-chains and covalent crosslinking of the collagen. Alignment of collagen fibrils occurred as the fibrils were deposited between cells, and binding of adjacent fibrils to the cell surface appeared to hold the fibrils in register. Groups of aligned fibrils were subdivided into bundles by cell-surface folds. If beta-aminopropionitrile was added to the medium, collagen crosslinking was inhibited, but not collagen synthesis or fibril bundle organization. If ascorbic acid was omitted from the culture medium, the extensive new connective tissue matrix was not produced. Our results indicate that fibroblasts in long-term cultures supplemented with ascorbic acid produce a connective tissue matrix with many in vivo-like properties including supermolecular organization of collagen.