Changes in the Distribution of Fibronectin During Limb Regeneration in Newts Using Immunocytochemistry

The distribution of fibronectin in regenerating newt limbs was studied using immunocytochemistry. At appropriate intervals after the initial amputation at the elbow (10–30 days), animals were reamputated at the shoulder and processed for light microscopy. The peroxidase-antiperoxidase technique was used to localize affinity-purified antibodies to fibronectin in limb tissues. At the amputation site, fibronectin was associated with basal laminae and connective tissues adjacent to dedifferentiating limb tissues destined to form the regeneration blastema. Accumulation and growth of the blastema was accompanied by the apparent de novo synthesis of fibronectin, where it appeared randomly in the interstitium between blastemal cells. The onset of chondrogenesis was characterized by a central condensation of prechondroblasts that formed the cartilage anlagen. Fibronectin formed an amorphous network between presumptive chondroblasts. As the mature cartilage phenotype was expressed and chondrocytes became isolated in lacunae, fibronectin was greatly reduced and then disappeared. The extracellular matrix surrounding undifferentiated blastemal cells still contained fibronectin. Fibronectin was also found in high concentrations between differentiating myoblasts. A condensation of fibronectin was also observed beneath the epidermis at the distal limb tip at the onset of digit formation. These observations are consistent with the hypothesis that fibronectin may play a key role in the morphogenetic events that result in the spatial organization and subsequent differentiation of cells during pattern formation in the regenerating limb.     

Fibronectin Isoform Distribution in the Mouse II. Differential Distribution of the Alternatively Spliced EIIIB, EIIIA, and V Segments in the Adult Mouse

The alternatively spliced EIIIB, EIIIA. and V segments of fibronectin (FN) show widespread codistribution in the mouse embryo, suggesting that EIIIB+, EIIIA+, and V+ isoforms serve to facilitate morphogenesis and organogenesis (Peters, JH, and Hynes, RO, 1996, this issue). To gain further clues to functions of these segments, we have used segment-specific anti-FN antibodies to perform immunofluorescence microscopy on tissue sections obtained from mice aged 9 to 15 weeks. Staining for each of the three spliced segments, relative to that for the total FN pool, was reduced in the adult as compared with the embryo. Anti-V antibodies produced patterns which were most similar to those obtained with anti-total FN antibodies, localizing to basement membranes, connective tissues subjacent to epithelia, walls of blood vessels, and cartilage. Anti-EIIIA antibodies produced the next most widespread pattern. which included prominent staining of the walls of blood vessels of all sizes, the lung inter-stitium. and smooth muscle associated with the gastrointestinal (GI), genitourinary (GU), and respiratory tracts. Although anti-EIIIB antibodies produced the faintest and most restricted pattern of staining, EIIIB+ FN could be detected in the walls of some smaller blood vessels, smooth muscle of the GI, GU, and respiratory tracts, as well as within cartilaginous structures, and eye. There were quantitative and/or qualitative differences in the staining patterns produced by the three segment-specific antibodies in a variety of tissues, including liver, cartilage, synovium, cornea, muscle, peripheral nerve, and lymph node. These findings suggest that each of the spliced segments of the FN molecule may occupy unique physical or functional positions within the extracellular matrix of the adult mouse.     

Fibronectin Isoform Distribution in the Mouse II. Differential Distribution of the Alternatively Spliced EIIIB,EIIIA, and V Segments in the Adult Mouse

The alternatively spliced EIIIB, EIIIA. and V segments of fibronectin (FN) show widespread codistribution in the mouse embryo, suggesting that EIIIB+, EIIIA+, and V+ isoforms serve to facilitate morphogenesis and organogenesis (Peters, JH, and Hynes, RO, 1996, this issue). To gain further clues to functions of these segments, we have used segment-specific anti-FN antibodies to perform immunofluorescence microscopy on tissue sections obtained from mice aged 9 to 15 weeks. Staining for each of the three spliced segments, relative to that for the total FN pool, was reduced in the adult as compared with the embryo. Anti-V antibodies produced patterns which were most similar to those obtained with anti-total FN antibodies, localizing to basement membranes, connective tissues subjacent to epithelia, walls of blood vessels, and cartilage. Anti-EIIIA antibodies produced the next most widespread pattern. which included prominent staining of the walls of blood vessels of all sizes, the lung inter-stitium. and smooth muscle associated with the gastrointestinal (GI), genitourinary (GU), and respiratory tracts. Although anti-EIIIB antibodies produced the faintest and most restricted pattern of staining, EIIIB+ FN could be detected in the walls of some smaller blood vessels, smooth muscle of the GI, GU, and respiratory tracts, as well as within cartilaginous structures, and eye. There were quantitative and/or qualitative differences in the staining patterns produced by the three segment-specific antibodies in a variety of tissues, including liver, cartilage, synovium, cornea, muscle, peripheral nerve, and lymph node. These findings suggest that each of the spliced segments of the FN molecule may occupy unique physical or functional positions within the extracellular matrix of the adult mouse.     

Full-Length Fibronectin Drives Fibroblast Accumulation at the Surface of Collagen Microtissues during Cell-Induced Tissue Morphogenesis

Generating and maintaining gradients of cell density and extracellular matrix (ECM) components is a prerequisite for the development of functionality of healthy tissue. Therefore, gaining insights into the drivers of spatial organization of cells and the role of ECM during tissue morphogenesis is vital. In a 3D model system of tissue morphogenesis, a fibronectin-FRET sensor recently revealed the existence of two separate fibronectin populations with different conformations in microtissues, i.e. ‘compact and adsorbed to collagen’ versus ‘extended and fibrillar’ fibronectin that does not colocalize with the collagen scaffold. Here we asked how the presence of fibronectin might drive this cell-induced tissue morphogenesis, more specifically the formation of gradients in cell density and ECM composition. Microtissues were engineered in a high-throughput model system containing rectangular microarrays of 12 posts, which constrained fibroblast-populated collagen gels, remodeled by the contractile cells into trampoline-shaped microtissues. Fibronectin’s contribution during the tissue maturation process was assessed using fibronectin-knockout mouse embryonic fibroblasts (Fn^-/- MEFs) and floxed equivalents (Fn^f/f MEFs), in fibronectin-depleted growth medium with and without exogenously added plasma fibronectin (full-length, or various fragments). In the absence of full-length fibronectin, Fn^-/- MEFs remained homogenously distributed throughout the cell-contracted collagen gels. In contrast, in the presence of full-length fibronectin, both cell types produced shell-like tissues with a predominantly cell-free compacted collagen core and a peripheral surface layer rich in cells. Single cell assays then revealed that Fn^-/- MEFs applied lower total strain energy on nanopillar arrays coated with either fibronectin or vitronectin when compared to Fn^f/f MEFs, but that the presence of exogenously added plasma fibronectin rescued their contractility. While collagen decoration of single fibronectin fibers enhanced the non-persistent migration of both Fn^f/f and Fn^-/- MEFs, the migration speed was increased for Fn^-/- MEFs on plasma fibronectin fibers compared to Fn^f/f MEFs. In contrast, the average speed was the same for all cells on collagen-coated Fn fibers. A Fn-FRET sensor revealed that fibronectin on average was more extended on the microtissue surface compared to fibronectin in the core. Gradients of collagen-to-fibronectin ratios and of the fraction of collagen-adsorbed to stretched fibrillar fibronectin conformations might thereby provide critical cell migration cues. This study highlights a dominant role for fibronectin in tissue morphogenesis and the development of tissue heterogeneities.     

Site-Specific Expression of Gelatinolytic Activity during Morphogenesis of the Secondary Palate in the Mouse Embryo

Morphogenesis of the secondary palate in mammalian embryos involves two major events: first, reorientation of the two vertically oriented palatal shelves into a horizontal position above the tongue, and second, fusion of the two shelves at the midline. Genetic evidence in humans and mice indicates the involvement of matrix metalloproteinases (MMPs). As MMP expression patterns might differ from sites of activity, we used a recently developed highly sensitive in situ zymography technique to map gelatinolytic MMP activity in the developing mouse palate. At embryonic day 14.5 (E14.5), we detected strong gelatinolytic activity around the lateral epithelial folds of the nasopharyngeal cavity, which is generated as a consequence of palatal shelf elevation. Activity was concentrated in the basement membrane of the epithelial fold but extended into the adjacent mesenchyme, and increased in intensity with lateral outgrowth of the cavity at E15.5. Gelatinolytic activity at this site was not the consequence of epithelial fold formation, as it was also observed in Bmp7-deficient embryos where shelf elevation is delayed. In this case, gelatinolytic activity appeared in vertical shelves at the exact position where the epithelial fold will form during elevation. Mmp2 and Mmp14 (MT1-MMP), but not Mmp9 and Mmp13, mRNAs were expressed in the mesenchyme around the epithelial folds of the elevated palatal shelves; this was confirmed by immunostaining for MMP-2 and MT1-MMP. Weak gelatinolytic activity was also found at the midline of E14.5 palatal shelves, which increased during fusion at E15.5. Whereas MMPs have been implicated in palatal fusion before, this is the first report showing that gelatinases might contribute to tissue remodeling during early stages of palatal shelf elevation and formation of the nasopharynx.     

Definition of the Native and Denatured Type II Collagen Binding Site for Fibronectin Using a Recombinant Collagen System

Interaction of collagen with fibronectin is important for extracellular matrix assembly and regulation of cellular processes. A fibronectin-binding region in collagen was identified using unfolded fragments, but it is not clear if the native protein binds fibronectin with the same primary sequence. A recombinant bacterial collagen is utilized to characterize the sequence requirement for fibronectin binding. Chimeric collagens were generated by inserting the putative fibronectin-binding region from human collagen into the bacterial collagen sequence. Insertion of a sufficient length of human sequence conferred fibronectin affinity. The minimum sequence requirement was identified as a 6-triplet sequence near the unique collagenase cleavage site and was the same in both triple-helix and denatured states. Denaturation of the chimeric collagen increased its affinity for fibronectin, as seen for mammalian collagens. The fibronectin binding recombinant collagen did not contain hydroxyproline, indicating hydroxyproline is not essential for binding. However, its absence may account, in part, for the higher affinity of the native chimeric protein and the lower affinity of the denatured protein compared with type II collagen. Megakaryocytes cultured on chimeric collagen with fibronectin affinity showed improved adhesion and differentiation, suggesting a strategy for generating bioactive materials in biomedical applications.     

Fibronectin Isoform Distribution in the Mouse I. The Alternatively Spliced EIIIB,EIIIA, and V Segments Show Widespread Codistribution in the Developing Mouse Embryo

Fibronectins (FNs) are extracellular matrix glycoproteins that are essential for embryonic development. In order to gain clues to possible developmental roles played by the particular isoforms of FN, we used indirect immunofluorescence microscopy to examine and compare the distributions of the alternatively spliced EIIIB, EIIIA, and V segments, as well as the total pool of FNs, in serial sections from mouse embryos. Antibodies to each of these segments produced staining patterns that colocalized during gastrulation (E7.5) and during early morphogenesis of somites and notochord (E9.5). During the period of continuing organogenesis in the latter half of gestation (E10.5 to E16.5), the antibodies generally continued to produce similar staining patterns localized to epithelial basement membranes, stromal connective tissues, blood vessel walls, and muscles. However, as development proceeded, there was a gradual decline in the intensity of staining for the spliced segments relative to the total pool of FN, with a particularly noticeable decline in staining for EIIIB and EIIIA segments in certain glandular organs, including the liver. A specific reduction in expression of these latter two segments was also evident in the uterus and placenta at early timepoints in gestation. However, the most dramatic difference in the expression of the spliced segments occurred in developing hyaline cartilage, which showed a selective reduction in staining for the EIIIA segment that was evident in the axial skeletal precursors by E12.5 and complete throughout the embryo by E15.5. Our findings suggest that the alternatively spliced EIIIB, EIIIA, and V segments are included in the FN that is required for the morphogenesis of “FN dependent” structures, including somites, notochord, and the vasculature. Conversely, these segments would appear to play divergent, and sometimes exclusive, biological roles in specific tissues such as liver, cartilage, and placenta.     

Fibronectin Isoform Distribution in the Mouse I. The Alternatively Spliced EIIIB, EIIIA, and V Segments Show Widespread Codistribution in the Developing Mouse Embryo

Fibronectins (FNs) are extracellular matrix glycoproteins that are essential for embryonic development. In order to gain clues to possible developmental roles played by the particular isoforms of FN, we used indirect immunofluorescence microscopy to examine and compare the distributions of the alternatively spliced EIIIB, EIIIA, and V segments, as well as the total pool of FNs, in serial sections from mouse embryos. Antibodies to each of these segments produced staining patterns that colocalized during gastrulation (E7.5) and during early morphogenesis of somites and notochord (E9.5). During the period of continuing organogenesis in the latter half of gestation (E10.5 to E16.5), the antibodies generally continued to produce similar staining patterns localized to epithelial basement membranes, stromal connective tissues, blood vessel walls, and muscles. However, as development proceeded, there was a gradual decline in the intensity of staining for the spliced segments relative to the total pool of FN, with a particularly noticeable decline in staining for EIIIB and EIIIA segments in certain glandular organs, including the liver. A specific reduction in expression of these latter two segments was also evident in the uterus and placenta at early timepoints in gestation. However, the most dramatic difference in the expression of the spliced segments occurred in developing hyaline cartilage, which showed a selective reduction in staining for the EIIIA segment that was evident in the axial skeletal precursors by E12.5 and complete throughout the embryo by E15.5. Our findings suggest that the alternatively spliced EIIIB, EIIIA, and V segments are included in the FN that is required for the morphogenesis of “FN dependent” structures, including somites, notochord, and the vasculature. Conversely, these segments would appear to play divergent, and sometimes exclusive, biological roles in specific tissues such as liver, cartilage, and placenta.     

Limb Development and Regeneration

Experiments on developing and regenerating vertebrate limbshave led to the idea that pattern formation and growth controlare causally linked. The mechanism by which position-specificgrowth occurs is termed intercalation, and evidence is presentedthat implicates intercalation in the initiation, maintenanceand cessation of growth during limb formation. We conclude thatamong the variety of cell types present in limbs, only fibroblastshave been shown to possess the positional information necessaryfor intercalation. Hence we propose that the limb pattern isgenerated by intercalation between fibroblasts to give riseto a connective tissue scaffold, which in turn dictates thepositioning and morphogenesis of all of the differentiated celltypes of the limb. Finally, we review evidence that regenerativefailure among higher vertebrates is linked to defects in theintrinsic cellular mechanisms of growth control (intercalation)and conclude that progress towards the goal of stimulating regenerativelimb outgrowth in non-regenerating vertebrates will be contingentupon a better understanding of these intrinsic mechanisms.     

Quantitative Evaluation of Collagen Crosslinks and Corresponding Tensile Mechanical Properties in Mouse Cervical Tissue during Normal Pregnancy

The changes in the mechanical integrity of the cervix during pregnancy have implications for a successful delivery. Cervical collagens are known to remodel extensively in mice with progressing gestation leading to a soft cervix at term. During this process, mature crosslinked collagens are hypothesized to be replaced with immature less crosslinked collagens to facilitate cervical softening and ripening. To determine the mechanical role of collagen crosslinks during normal mouse cervical remodeling, tensile load-to-break tests were conducted for the following time points: nonpregnant (NP), gestation day (d) 6, 12, 15, 18 and 24 hr postpartum (PP) of the 19-day gestation period. Immature crosslinks (HLNL and DHLNL) and mature crosslinks (DPD and PYD) were measured using ultra performance liquid chromatography-electrospray ionization tandem mass spectrometry (UPLC-ESI-MS/MS). There were no significant changes in the total immature crosslink density (HLNL+DHLNL mol per collagen mol) throughout normal mouse gestation (range: 0.31–0.49). Total mature crosslink density (PYD+DPD mol per collagen mol) decreased significantly in early softening from d6 to d15 (d6: 0.17, d12: 0.097, d15: 0.026) and did not decrease with further gestation. The maturity ratio (total mature to total immature crosslinks) significantly decreased in early softening from d6 to d15 (d6: 0.2, d15: 0.074). All of the measured crosslinks correlated significantly with a measure of tissue stiffness and strength, with the exception of the immature crosslink HLNL. This data provides quantitative evidence to support the hypothesis that as mature crosslinked collagens decline, they are replaced by immature collagens to facilitate increased tissue compliance in the early softening period from d6 to d15.     

Genetic Interactions Between Shox2 and Hox Genes During the Regional Growth and Development of the Mouse Limb

The growth and development of the vertebrate limb relies on homeobox genes of the Hox and Shox families, with their independent mutation often giving dose-dependent effects. Here we investigate whether Shox2 and Hox genes function together during mouse limb development by modulating their relative dosage and examining the limb for nonadditive effects on growth. Using double mRNA fluorescence in situ hybridization (FISH) in single embryos, we first show that Shox2 and Hox genes have associated spatial expression dynamics, with Shox2 expression restricted to the proximal limb along with Hoxd9 and Hoxa11 expression, juxtaposing the distal expression of Hoxa13 and Hoxd13. By generating mice with all possible dosage combinations of mutant Shox2 alleles and HoxA/D cluster deletions, we then show that their coordinated proximal limb expression is critical to generate normally proportioned limb segments. These epistatic interactions tune limb length, where Shox2 underexpression enhances, and Shox2 overexpression suppresses, Hox-mutant phenotypes. Disruption of either Shox2 or Hox genes leads to a similar reduction in Runx2 expression in the developing humerus, suggesting their concerted action drives cartilage maturation during normal development. While we furthermore provide evidence that Hox gene function influences Shox2 expression, this regulation is limited in extent and is unlikely on its own to be a major explanation for their genetic interaction. Given the similar effect of human SHOX mutations on regional limb growth, Shox and Hox genes may generally function as genetic interaction partners during the growth and development of the proximal vertebrate limb.     

Identification of Surface Proteins from Lactobacillus casei BL23 Able to Bind Fibronectin and Collagen

Strains of lactobacilli show the capacity to attach to extracellular matrix proteins. Cell-wall fractions of Lactobacillus casei BL23 enriched in fibronectin, and collagen-binding proteins were isolated. Mass spectrometry analysis of their protein content revealed the presence of stress-related proteins (GroEL, ClpL), translational elongation factors (EF-Tu, EF-G), oligopeptide solute-binding proteins, and the glycolytic enzymes enolase and glyceraldehyde-3-phosphate dehydrogenase (GAPDH). The latter two enzymes were expressed in Escherichia coli and purified as glutathione-S-transferase (GST) fusion proteins, and their in vitro binding activity to fibronectin and collagen was confirmed. These results reinforce the idea that lactobacilli display on their surfaces a variety of moonlighting proteins that can be important in their adaptation to survive at intestinal mucosal sites and in the interaction with host cells.     

小鼠胶原诱导性关节炎模型的建立及其免疫学变化研究

目的 胶原诱导性关节炎模型（collagen induced arthritis,CIA）是研究类风湿性关节炎发病机制和治疗药物筛选的理想模型,也是目前国际上公认的关节炎模型.但是,目前鲜见Ⅱ型胶原诱导CIA模型的系统免疫学变化的报道.因此,本研究采用DBA/1小鼠诱导了CIA模型,并对其免疫学改变进行了系统研究.方法 将牛Ⅱ型胶原与完全弗氏佐剂混和并充分乳化,于DBA/1小鼠尾根部皮内注射进行初次免疫,20 d后同样方法进行再次免疫.应用千分尺测量CIA模型小鼠的左右两侧足掌厚度,并进行关节炎评分.酶联免疫吸附试验测定小鼠血清Ⅱ型胶原特异性抗体,Luminex技术和αLISA技术测定血清及培养上清中的细胞因子水平.结果CIA小鼠于造模后23 d开始,陆续出现前肢、后肢的红肿、功能障碍,发病率高达100％,且随着时间的延长其关节肿胀程度呈进行性加重,关节炎评分增高.CIA小鼠脾脏指数较正常组明显升高,且Ⅱ型胶原刺激的特异性T细胞增殖明显增强.细胞因子检测结果表明,脾细胞培养上清中IFN-γ和1L-4含量及IFN-γ/IL-4比值明显升高,TNF-α和IL-1β水平亦显著升高.此外,CIA小鼠血清中存在高水平的Ⅱ型胶原特异性抗体.结论 Ⅱ型胶原诱导CIA模型发病率高,免疫学改变以Th1细胞因子升高为主,兼有细胞免疫功能及体液免疫功能损伤.     

β1 Integrins Mediate Chondrocyte Interaction with Type I Collagen, Type II Collagen, and Fibronectin

Chondrocytes isolated from the cephalic region of sterna from 14-day-old chick embryos used β1 integrins and required either Mg²⁺ or Mn²⁺ for attachment to plates coated with type I collagen, type II collagen, and fibronectin. β1 integrin was concentrated in adhesion plaques of the chondrocytes plated on type I collagen, type II collagen, and fibronectin substrates. Chondrocytes expressed at least 3 α-subunits, including α3, α5, and putative α2. α5, but not α3, had a higher molecular weight in chondrocytes than in fibroblasts. Levels of α3 and α5 were about 25-30% of that in fibroblasts. When the chondrocytes were cultured in the presence of ascorbate in suspension, the cells aggregated into clusters. This aggregation was dependent on β1 integrin and type II collagen.     

The Adaptor Protein Paxillin Is Essential for Normal Development in the Mouse and Is a Critical Transducer of Fibronectin Signaling

The integrin family of cell adhesion receptors are important for a diverse set of biological responses during development. Although many integrins have been shown to engage a similar set of cytoplasmic effector proteins in vitro, the importance of these proteins in the biological events mediated by different integrin receptors and ligands is uncertain. We have examined the role of one of the best-characterized integrin effectors, the focal adhesion protein paxillin, by disruption of the paxillin gene in mice. Paxillin was found to be critically involved in regulating the development of mesodermally derived structures such as heart and somites. The phenotype of the paxillin(-/-) mice closely resembles that of fibronectin(-/-) mice, suggesting that paxillin is a critical transducer of signals from fibronectin receptors during early development. Paxillin was also found to play a critical role in fibronectin receptor biology ex vivo since cultured paxillin-null fibroblasts display abnormal focal adhesions, reduced cell migration, inefficient localization of focal adhesion kinase (FAK), and reduced fibronectin-induced phosphorylation of FAK, Cas, and mitogen-activated protein kinase. In addition, we found that paxillin-null fibroblasts show some defects in the cortical cytoskeleton and cell spreading on fibronectin, raising the possibility that paxillin could play a role in structures distinct from focal adhesions. Thus, paxillin and fibronectin regulate some common embryonic developmental events, possibly due to paxillin modulation of fibronectin-regulated focal adhesion dynamics and organization of the membrane cytoskeletal structures that regulate cell migration and spreading.