Connective tissue growth factor: what's in a name?

Connective tissue growth factor (CTGF) is a member of the recently described CCN gene family which contains CTGF itself, cyr61, nov, elm1, Cop1, and WISP-3. CTGF is transcriptionally activated by several factors although its stimulation by transforming growth factor beta (TGF-beta) has attracted considerable attention. CTGF acts to promote fibroblast proliferation, migration, adhesion, and extracellular matrix formation, and its overproduction is proposed to play a major role in pathways that lead to fibrosis, especially those that are TGF-beta-dependent. This includes fibrosis of major organs, fibroproliferative diseases, and scarring. CTGF also appears to play a role in the extracellular matrix remodeling that occurs in normal physiological processes such as embryogenesis, implantation, and wound healing. However, recent advances have shown that CTGF is involved in diverse autocrine or paracrine actions in several other cell types such as vascular endothelial cells, epithelial cells, neuronal cells, vascular smooth muscle cells, and cells of supportive skeletal tissues. Moreover, in some circumstances CTGF has negative effects on cell growth in that it can be antimitotic and apoptotic. In light of these discoveries, CTGF has been implicated in a diverse variety of processes that include neovascularization, transdifferentiation, neuronal scarring, atherosclerosis, cartilage differentiation, and endochondral ossification. CTGF has thus emerged as a potential important effector molecule in both physiological and pathological processes and has provided a new target for therapeutic intervention in fibrotic diseases.

Matrix metalloproteinase-13 expression in rabbit knee joint connective tissues: influence of maturation and response to injury

The hypothesis of the present work was that expression of matrix metalloproteinase-13 (MMP-13, collagenase-3) would be induced during conditions involving important matrix remodeling such as ligament maturation, scar healing and joint instability. Therefore, MMP-13 expression in the medial collateral ligament (MCL) during the variable situations of tissue maturation and healing was assessed. MMP-13 expression in three intra-articular connective tissues of the knee (i.e. articular cartilage, menisci and synovium) following the transection of the anterior cruciate ligament of the knee was evaluated at 3 and 8 weeks post-injury. MMP-13 mRNA (semi-quantitative RT-PCR) and protein (immunohistochemistry and Western blotting) were detected in all of the tissues studied. Significantly higher MCL mRNA levels for MMP-13 were detected during the early phases of tissue maturation (i.e. 29 days in utero and 2-month-old rabbits) compared to later phases (5- and 12-month-old rabbits). This pattern of expression was recapitulated following MCL injury, with very high levels of expression in scar tissue at 3 weeks post-injury and then a decline to levels not significantly different from control values by 14 weeks. Elevated mRNA levels correlated with increased protein levels for MMP-13 in both menisci and synovium following the transection of the anterior cruciate ligament and during medial collateral ligament healing. These results indicate that MMP-13 expression is regulated by a number of variables and that high levels of expression occur in situations when connective tissue remodeling is very active.

Connective tissue formation in subcutaneous cellulose sponge implants in the rat. The effect of the size and cellulose content of the implant

Granulation tissue formation was studied in viscose cellulose sponges with different cellulose contents and sizes after subcutaneous implantation in rats. Samples were removed and studied histologically and histomorphometrically 1-16 weeks after implantation. The implants with lower cellulose content and smaller size were invaded by more cells and filled with connective tissue more rapidly than those with the higher content and larger size. In larger sponge implants the beneficial effect of the lower cellulose content was more conspicuous.

Molecular structure and tissue distribution of matrilin-3, a filament-forming extracellular matrix protein expressed during skeletal development

Matrilin-3 is a recently identified member of the superfamily of proteins containing von Willebrand factor A-like domains and is able to form hetero-oligomers with matrilin-1 (cartilage matrix protein) via a C-terminal coiled-coil domain. Full-length matrilin-3 and a fragment lacking the assembly domain were expressed in 293-EBNA cells, purified, and subjected to biochemical characterization. Recombinantly expressed full-length matrilin-3 occurs as monomers, dimers, trimers, and tetramers, as detected by electron microscopy and SDS-polyacrylamide gel electrophoresis, whereas matrilin-3, purified from fetal calf cartilage, forms homotetramers as well as hetero-oligomers of variable stoichiometry with matrilin-1. In the matrix formed by cultured chondrosarcoma cells, matrilin-3 is found in a filamentous, collagen-dependent network connecting cells and in a collagen-independent pericellular network. Affinity-purified antibodies detect matrilin-3 expression in a variety of mouse cartilaginous tissues, such as sternum, articular, and epiphyseal cartilage, and in the cartilage anlage of developing bones. It is found both inside the lacunae and in the interterritorial matrix of the resting, proliferating, hypertrophic, and calcified cartilage zones, whereas the expression is lower in the superficial articular cartilage. In trachea and in costal cartilage of adult mice, an expression was seen in the perichondrium. Furthermore, matrilin-3 is found in bone, and its expression is, therefore, not restricted to chondroblasts and chondrocytes.

Structural changes in living tissues

Tissues change in many ways in the period that they are part of a living organism. Tissues are created in fairly repeatable structural patterns, and the patterns are due to both the genes and the (mechanical) environment, but we do not know exactly what part or percentage of a particular pattern to consider the genes, or the environment, responsible for. We do not know much about the beginning of tissue construction (morphogenesis) and also the methods of tissue construction. When the tissue structure is altered to accommodate a new loading, it is not known how the decision is made for the structural reconstruction. We know that tissues grow or reconstruct themselves without ceasing to continue with their structural function, but we do not understand the processes that permit them to accomplish this. Tissues change their structures to altered mechanical environments, but we are not sure how. Tissues heal themselves and we understand little of the structural mechanics of the process. With the objective of describing the interesting unsolved mechanics problems associated with these biological processes, some aspects of the formation, growth and adaptation of living tissues are reviewed. Beyond the objective is the hope that the work will stimulate new ideas and new observations in developmental biology.

Relationship between severity of middle ear mucosal lesion and middle ear pneumatic space volume in patients with otitis media with effusion

If we assume that the state of suppression of pneumatic cells is the result of suppression of pneumatic cell growth by inflammatory stimulation in the middle ear pneumatic space, it is possible to improve the state of suppression by performing sufficient treatment during the growth period of the pneumatic cells. We indwelt a tympanic membrane ventilation tube (hereinafter referred to as tube) for treatment of otitis media with effusion (OME) in child patients aged 3-13 years and investigated the following points: i) relationship between the severity of inflammation of the lamina propria of middle ear mucosal specimens (hereinafter referred to as lamina propria) collected at the time of tube indwelling and the degree of growth of the pneumatic space; and ii) changes in the pneumatic space associated with treatment by tube indwelling, which was studied by comparing the above-described mucosal severity with the pneumatic space area of 2 years after tube indwelling, and with increase in the pneumatic space volume measured periodically after tube indwelling. The results indicated that mastoid cell growth suppression is higher in patients with a higher degree of inflammatory changes in the lamina propria. In association with treatment by tube indwelling, effusion accumulated in the pneumatic space and mucosal swelling disappeared early after the treatment, or 2 months of tube indwelling. After that, in patients with severe mucosal lesion, a long time, 1.5-2 years, was found to be required for repneumatization accompanying regrowth of the temporal bone. We confirmed that the severity of inflammation of the lamina propria is deeply involved in the growth and repneumatization of the pneumatic cells.

Schwann cell-derived Desert hedgehog controls the development of peripheral nerve sheaths

We show that Schwann cell-derived Desert hedgehog (Dhh) signals the formation of the connective tissue sheath around peripheral nerves. mRNAs for dhh and its receptor patched (ptc) are expressed in Schwann cells and perineural mesenchyme, respectively. In dhh-/- mice, epineurial collagen is reduced, while the perineurium is thin and disorganized, has patchy basal lamina, and fails to express connexin 43. Perineurial tight junctions are abnormal and allow the passage of proteins and neutrophils. In nerve fibroblasts, Dhh upregulates ptc and hedgehog-interacting protein (hip). These experiments reveal a novel developmental signaling pathway between glia and mesenchymal connective tissue and demonstrate its molecular identity in peripheral nerve. They also show that Schwann cell-derived signals can act as important regulators of nerve development.

Chimera analysis reveals that fibroblasts and endothelial cells require platelet-derived growth factor receptorbeta expression for participation in reactive connective tissue formation in adults but not during development

The hypothesis that platelet-derived growth factor (PDGF) plays an important role in repair of connective tissue has been difficult to test experimentally, in part because the disruption of any of the PDGF ligand and receptor genes is embryonic lethal. We have developed a method that circumvents the embryonic lethality of the PDGF receptor (R)beta-/- genotype and minimizes the tendency of compensatory processes to mask the phenotype of gene disruption by comparing the behavior of wild-type and PDGFRbeta-/- cells within individual chimeric mice. This quantitative chimera analysis method has revealed that during development PDGFRbeta expression is important for all muscle lineages but not for fibroblast or endothelial lineages. Here we report that fibroblasts and endothelial cells, but not leukocytes, are dependent on PDGFRbeta expression during the formation of new connective tissue in and around sponges implanted under the skin. Even the 50% reduction in PDGFRbeta gene dosage in PDGFRbeta+/- cells reduces fibroblast and endothelial cell participation by 85%. These results demonstrate that the PDGFRbeta/PDGF B-chain system plays an important direct role in driving both fibroblast and endothelial cell participation in connective tissue repair, that cell behavior can be regulated by relatively small changes in PDGFRbeta expression, and that the functions served by PDGF in wound healing are different from the roles served during development.

[Development of hoof cartilage with special considerations of its ossification]

The pre- and perinatal development of the hoof cartilage is described concerning the histological structure and surrounding vessels. Beginning in the third month of fetal development, the anlage of the hoof cartilage is still present in typical shape and location. It is built out of mesenchymal connective tissue. During further fetal development, the connective tissue cells will differentiate into two cell populations, fibroblasts and chondroblasts. Vessels, traversing the hoof cartilage, are surrounded by loose connective tissue, which will partially develop fibrocartilage. At birth, hoof cartilage consists of hyaline cartilage, which is disrupted by vessels, embedded in fibrous connective tissue and/or fibrocartilage. The development of the hoof cartilage is the base to understand its structure and the predisposing locations for its ossification.

Regulation of the spatial organization of mesenchymal connective tissue: effects of cell-associated versus released isoforms of platelet-derived growth factor

Platelet-derived growth factor (PDGF), a mitogen and chemoattractant for mesenchymal cells, occurs as cell-associated or released isoforms. To investigate their in vivo role, human keratinocytes, which normally synthesize both types of PDGF, were genetically modified to overexpress either wild-type PDGF-B (cell-associated) or the truncation mutant PDGF-B211 (released). Cells expressing the mutant isoform released 20 times more PDGF (145 ng/hour/10(7) cells) than cells expressing the wild-type isoform (6 ng/ hour/10(7) cells). When grafted as epithelial sheets onto athymic mice, modified cells formed a stratified epithelium and induced a connective tissue response that differed depending on the PDGF isoform expressed. Expression of PDGF-B211 induced a thick connective tissue with increased numbers of fibroblasts, mononuclear cells, and blood vessels evenly distributed throughout the connective tissue layer, whereas expression of PDGF-B induced a zone of fibroblasts and mononuclear cells localized to the interface of the epidermis and connective tissue, which often disrupted the continuity of the basement membrane. Immunostaining revealed that wild-type PDGF protein was deposited in the basement membrane region. These data suggest that the different binding properties of PDGF isoforms control the spatial organization of cellular events in regenerating mesenchymal tissue in vivo.

Relationship between development of intramuscular connective tissue and toughness of pork during growth of pigs

We investigated changes in structures and properties of the endomysium and perimysium during development of semitendinosus muscle in relation to the increase in toughness of pork using samples from neonates to 55-mo-old pigs. The shear force value of pork increased linearly until 6 mo of age, and the rate of increase slowed down thereafter. The secondary perimysium thickened owing to an increase in the number and thickness of perimysial sheets consisting of collagen fibers, which became thicker and wavy with the growth of the pigs. This increase in thickness of the secondary perimysium was correlated significantly with the increase in the shear force value (r = .98). The endomysial sheaths became thicker and denser in the muscle of 6-mo-old pigs. Maturation of the endomysium was accompanied by hypertrophy of muscle fibers. The amount of heat-soluble collagen decreased almost linearly, indicating that nonreducible cross-links between collagen molecules were formed throughout chronological aging. We conclude that thickening of the perimysium is closely related to an increase in the toughness of pork during growth of pigs.

The production of the Alzheimer amyloid precursor protein (APP) in extraneuronal tissue does not increase in old age

Alzheimer's disease (AD) is characterized by the cerebral deposition of beta-amyloid (A beta). A beta plaques also occur in the brains of healthy aged individuals, and A beta concentrations are increased in the cerebrospinal fluid (CSF) in old age. Based on results from an in vitro senescence model on human fibroblasts, it was proposed that the production of the beta-amyloid precursor protein (APP) was increased during aging. No information was available as to whether APP production was also augmented in aged humans. It was therefore the aim of the present study to analyze APP in connective tissue, skeletal muscle, peripheral blood mononuclear cells, and serum samples from young and aged healthy individuals. APP production was assessed by Northern and Western blotting. The expression of the different APP isoforms was studied by reverse transcription-polymerase chain reaction (RT-PCR) technique. The results demonstrate that APP messenger ribonucleic acid (mRNA) and protein concentrations were identical in blood and tissue samples from young and aged individuals and that there were no age-dependent changes in the APP isoform production pattern. Thus, our data strongly argue against the possibility of an altered production of APP during healthy aging and underline the point that in vitro aging models may not accurately reflect the in vivo situation.

Ultrastructural studies on selected elements of the extracellular matrix in the developing rat lung alveolus

As the respiratory system adapts to the extrauterine life, the extracellular matrix (ECM) plays an important structural and regulatory role during its development. Therefore the purpose of this investigation was to analyze ultrastructurally several elements of extracellular connective tissue during the process of rat lung development. Morphological observations were mainly focused on the terminal part of respiratory system. To outline different components of connective tissue network, several ultrastructural techniques were used (both histochemical and immunohistochemical). The distribution and amount of the following proteins were studied: laminin, collagen type IV, collagen fibrils (CFs), elastic fibers (EFs) and fibronectin (FN). Additionally localization of glycosaminoglycans (GAGs) was examined. The present study deals with four periods of lung development: pseudoglandular, canalicular, saccular and alveolar. In all these stages localization and amount of ECM components change rapidly. In early periods of lung development, the amount of connective tissue fibers was low, basement membranes (BMs) were incomplete, and FN was distributed nearly uniformly. Later when the process of lung alveoli formation begins, the number and thickness of both CFs and EFs rapidly increased, BMs became complete, the content and distribution of FN were irregular. In all stages of lung development GAGs were distributed in BMs and among connective tissue fibers. The results described in the present study summarize morphologically ECM changes occurring during formation of lung alveolus.

Maxillary growth following atelocollagen implantation on mucoperiosteal denudation of the palatal process in young rabbits: implications for clinical cleft palate repair

OBJECTIVE

The implantation of atelocollagen matrix on the denuded surface of palatal bone following cleft palate repair has been used because it enhances wound healing. This study was performed to determine whether the beneficial effect of atelocollagen matrix implantation on the prevention of scar tissue contraction also inhibits the scar's interference with the growth of maxillary bone.

METHOD

Fifty New Zealand White rabbits (aged 4 weeks) underwent palatal mucoperiosteal denudation, and etelocollagen matrix was implanted on the left palatal process. The opposite side was left open as a control.

RESULTS

Histopathologically, the implantation side exhibited early infiltration of mononuclear cells and fibroblasts, and better growth of connective tissue strands and epithelium. In addition, the formation of rate ridges were seen that were similar to the normal mucosa. The bone of the atelocollagen-implanted side was covered with regenerated periosteum-like layers, but that of the control side was lined by granulation tissue, suggesting the existence of continuous inflammation on the periosteal region. When the animals reached adulthood (aged 24 weeks), the areas of scars and palatal processes, palatal shelf width, molar teeth incline, and bone mineral contents were measured and compared between sides. The atelocollagen-applied scars showed less contraction, the area and width of atelocollagen-implanted palatal processes showed more satisfactory growth, and the dental arch deformity was suppressed in comparison with the control side.

CONCLUSIONS

Our results suggest that the use of atelocollagen matrix on the denuded bone surface following cleft palate repair decreases the scar's effect on maxillary growth.

Interactions of androgens and estradiol on sex accessory ducts of larval tiger salamanders, Ambystoma tigrinum

Immature tiger salamander larvae were treated with 12.5 or 25 micrograms of estradiol, testosterone, or dihydrotestosterone (DHT), or 12.5 micrograms of estradiol combined with 12.5 micrograms of either testosterone or DHT. Müllerian duct epithelium was more stimulated by combined steroid treatment than by any steroid alone. Estradiol antagonized the action of DHT in the Wolffian duct. Both of the androgens and estradiol when administered alone at the higher dose stimulated enlargement of connective tissue surrounding the ducts, but the combined 12.5 micrograms androgen/12.5 micrograms estrogen treatment was more effective even though the total steroid administered was the same. The effectiveness of DHT on müllerian cells of this species is evidence against a required aromatization of androgens to explain paradoxical steroid effects and suggests that fundamental differences may exist in steroid receptors of müllerian ducts, connective tissue, and Wolffian ducts. A possible role for the urodele duct system for assessing estrogenic activity of environmental contaminants is discussed.

Embryonic and postnatal development of the rat renal interstitium

Whilst antihypertensive, structural and functional roles have been proposed for the cells of the renomedullary interstitium in the adult kidney, little is known about its role in renal development. Rat kidneys were studied throughout development, prenatally at gestational ages E14-E21 and postnatally at 0-28 days, by light microscopy, transmission and scanning electron microscopy and following immunocytochemistry. Renomedullary interstitial cells were observed as early as embryonic day E14, forming a loose, orderly network around branches of the ureteric bud. Paralleling the development of the first nephron structures, renomedullary interstitial cells were arranged in a concentric circular manner around collecting ducts. Following tubular and vascular growth from the cortex into the medulla, this arrangement resulted in the characteristic 'rungs of a ladder' appearance of interstitial cells between tubules, blood vessels and the collecting ducts. Renomedullary interstitial cells were closely adherent to basement membranes of tubules, blood vessels and collecting ducts from early in development. Contacts were absent between renomedullary interstitial cells and tubular structures in the process of remodelling, such as the hair-pin bends of the loops of Henle. At these foci laminin, a basement membrane glycoprotein was specificially localised to intracellular epithelial sites, whereas in more developed areas, laminin was restricted to epithelial basement membranes. Associated with the more mature structures, laminin was also localised to intracellular granules of renomedullary interstitial cells. Thus, renomedullary interstitial cells are present prior to and appear to be actively associated with tubule repositioning in the medulla, establishing themselves as integral to the process of renal development.

Decreased receptivity of pathway connective tissue to sympathetic nerve ingrowth in the developing rat

Sympathetic axons can form atypical pathways to denervated orbital targets in neonatal rats but not in rats aged 30 or more days. The objective of this study was to determine if connective tissue pathways that carry sympathetic nerves lose their ability to sustain axonal sprouting during the early postnatal period. Regions of periorbital sheath known to contain large numbers of sympathetic axons that travel to distal orbital targets were excised from rats (sympathectomized 3 days previously) on postnatal days 6-7, 14-15, 30-31, and 48-49 and placed in anterior chambers of adult host rats. Tissues were removed 3, 6, or 10 days post-transplant and sympathetic ingrowth was analyzed by catecholamine histofluorescence in whole-mount or cryosectioned specimens. Connective tissue transplants from 6-15-day-old donors showed significant fiber ingrowth by 3 days in oculo, and innervation was maximal by 6 days. In contrast, sprouting into 30-49-day-old tissue was significantly slower, with most transplants lacking fibers at 3 days, and with small numbers of short fibers present at 6 days. We conclude that maturational changes occur in periorbital connective tissue pathways in the early postnatal period which make them less receptive to ingrowth by sympathetic nerves. The findings that connective tissue pathways are better substrates for sympathetic sprouting in the neonatal rat supports the view that developmental changes in these tissues are likely to contribute to the impaired reinnervation of orbital targets by contralateral neurons in juvenile and adult rats.

[Age-related development of the arrangement of connective tissue fibers in the lamina propria of the human vocal folds--scanning electron microscopic examination with digestion method]

The lamina propria of the human vocal fold consists of a superficial, intermediate, and deep layer. This stratified structure is thought to facilitate phonation. Each layer has different physical properties based on different alignment and distribution of collagen and elastic fibers. In the present study, developmental changes in vocal fold structure were studied in human fetuses, infants, and children, with special reference to the pattern of distribution of collagen and elastic fibers. Vocal fold specimens were obtained at autopsy from 5 fetuses, 7 neonates, 3 infants, 3 children at the age of 1 year, 3 children at 3 years, 3 children at 5 years, 3 children at 12 years, and 5 subjects at ages ranging from 15 to 22 years. Prior to the examination of collagen fibers, elastic fibers and cells were dissolved with 10% sodium hydroxide treatment. Prior to the examination of elastic fibers, collagen fibers and cells were dissolved by treatment with 90% formic acid. The specimens were then dehydrated, dried, ion-coated with platinum, and examined with a scanning electron microscope. In fetuses and infants, thin, coiled fibers were found distributed densely in the anterior, posterior, and deep parts of the lamina propria, while irregular thick fibers were sparsely seen in the superficial layer of the vocal fold. In children aged 1 to 3 years, the dense fibers in the deep part decreased, and the longitudinal fibers in the superficial layer increased. In children at 5 years of age, longitudinal collagen and elastic fibers were noted in all of the layers of the vocal fold. The distribution of fibers was uniform irrespective of the depth. At 12 years of age, thin, coiled fibers were noted in the superficial layer, while thin, irregular fibers were found in the deep layer. At 17 years, differentiation of the superficial and deep layers was more evident. In male subjects after adolescence the curvature of curly collagen fibers decreased, and the diameter of fibers increased. The present findings suggest that the development of the vocal fold in childhood occurs in two steps. In the first step, dense fibers in the anterior, posterior, and deep parts of the lamina propria found in fetuses and infants shift to the anterior and posterior ends of the vocal fold, between which longitudinal fibers appear. During this step only simple phonation is possible. In the second step, differentiation of the superficial and deep layers occurs, and the stratified structure of the vocal fold appears in the teens. This step is probably related to the complicated modality of phonation in this age group. In males, the development of the vocal fold is completed after changes in collagen fibers during the mutation.

Developmental expression of extracellular matrix components in intramuscular connective tissue of bovine semitendinosus muscle

We have investigated the expression patterns of extracellular matrix components in intramuscular connective tissue during the development of bovine semitendinosus muscle by means of indirect immunofluorescence techniques. Types I, III, V, and VI collagen and fibronectin were located in the endomysium and the perimysium. Type IV collagen, laminin, and heparan sulfate proteoglycans (PGs) were exclusively located in the endomysium, and dermatan sulfate PGs existed only in the perimysium. The localization of these components in the intramuscular connective tissue of semitendinosus muscle remained unchanged throughout prenatal and postnatal growth of cattle, suggesting that they are essential for forming and maintaining structures of the endomysium and perimysium in bovine semitendinosus muscle. On the other hand, decorin was undetectable in the endomysium of neonates, although other matrix components were already expressed. It was expressed slightly in the endomysium of 2-month-old calves, and clearly detectable in the endomysium of cattle more than 6 months old. Chondroitin sulfate PGs were barely detectable in the perimysium of fetuses and neonatal calves, and progressively appeared during postnatal development of the muscle. It seems likely that these PGs are closely related to the postnatal development of the endomysium and perimysium.

Lingual papillae of the growing rat as a model of vasculogenesis

BACKGROUND

Capillary sprouting is an important mechanism that initiates neovascularization. Because observation of capillary sprouting and its morphological staging can be problematic, we sought to establish a simple model of capillary growth.

METHODS

Rats were obtained at gestational days 15, 16, and 20, at birth, and at postnatal day 10. Scanning electron microscopy (SEM) of vascular casts, freeze-fractured and epithelium-exfoliated specimens, as well as transmission electron microscopy (TEM) of tissue sections were used.

RESULTS

In day 15 fetuses, the filiform papillae and their connective tissue cores had not been formed, but a simple capillary network without regional differences was present. In day 16 fetuses, mesenchymal cells started to form papillary connective tissue cores, and, inside the epithelium, ridges were found. Capillary sprouts arose from the preexisting sinusoidal capillaries by elongation and widening, invaded into connective tissue cores in day 20 fetuses, and gradually bifurcated to form capillary loops in the prospective giant conical papillae of the newborn rat. In postnatal day 10 rats, the capillary network beneath the papillae became bilayered.

CONCLUSION

Vascular formation in the lingual papillae in growing rats offers an easy model for the observation of capillary sprouting. In this model, the sprouts arise from preexisting sinusoidal capillaries and not from veins, as usually observed in other models. The mechanism of capillary growth is the elongation of (preexisting) sinusoidal capillaries into the developing connective tissue cores and toward the forming epithelial ridges.

Developmental regulation of interstitial cell density in bullfrog skeletal muscle

Denervation of skeletal muscle results in striking connective tissue remodelling in junctional areas of muscle. Since extracellular matrix molecules mediate axonal growth and synaptic differentiation, it is likely that the interstitial cells and matrix molecules that accumulate near synaptic sites after denervation influence the regrowth and regeneration of synaptic connections. The experiments presented here addressed the question of whether the junctional connective tissue in developing bullfrog skeletal muscle was also specialized in its cellular and molecular composition. Denervation responses of muscle, such as extrajunctional sensitivity to acetylcholine, often reproduce the characteristics of developing muscle during synaptogenesis. In developing muscle, the distribution of interstitial cells was nonuniform during the period of muscle fibre birth and synaptogenesis. Interstitial cells were concentrated near synaptic sites as in denervated adult muscle. Unlike denervated adult muscle, there were no junctional accumulations of fibronectin or tenascin, matrix molecules produced by interstitial cells, in developing muscles. These results demonstrate that the junctional connective tissue in developing muscle is identified by a high density of interstitial cells that may play a role in the identification and formation of synaptic sites. Further, the junctional matrix environment of developing muscle is distinct from the matrix remodelling that occurs in response to denervation, suggesting that the matrix production by interstitial cells during development is regulated differently from that after denervation of the neuromuscular junction.

Structural changes in the intramuscular connective tissue during development of bovine semitendinosus muscle

Structural changes in the intramuscular connective tissue during development of bovine semitendinosus muscle were investigated using the cell-maceration method for scanning electron microscopy, by which cellular elements were eliminated and collagen fibrils and fibres were exposed. The endomysium was discontinuous and showed various shapes and sizes in the muscle of 7-month fetuses. The perimysium consisted of collagen fibres in loose contact with each other. In the muscle of neonatal calves, the endomysium consisted of cylindrical sheaths and displayed a honeycomb structure, and the perimysium was composed of several layers of collagen fibres. Collagen fibrils in the endomysium bound ever more closely with each other, and collagen fibres in the perimysium increased in thickness, and the wavy pattern of collagen fibres became more regular with growth of cattle. We have examined the mechanical strength of the intramuscular connective tissue by our new method, 'intramuscular connective tissue (IMCT) model'. The IMCT model is composed of collagen fibrils and fibres which maintains the organization in the endomysium and perimysium in situ. The shear-force value of the model increased rapidly from the 7th fetal month to the neonatal stage, and increased linearly with postnatal ageing thereafter. Changes in the arrangement of collagen fibrils and fibres seem to closely related to an increase in the mechanical strength of the intramuscular connective tissue during development of bovine skeletal muscle.

Transient expression of collagen type XIV during muscle development and its reappearance after denervation and degeneration

In the formation of muscle pattern, the architectural arrangement is believed to be controlled by the local connective tissue cells. In this study we examined the immunohistological localization of Type XIV collagen recognized by a monoclonal antibody, MAb DBM, in embryonic chick hind limbs from stage (St.) 27 to 2 weeks post hatching. DBM staining was transiently observed in the epimysium from St. 30, in the perimysium of the dorsal region from St. 37, and in the entire perimysium from St. 39. After hatching, DBM staining was notably diminished in both epimysium and perimysium. In contrast, DBM staining and in situ hybridization signals for Type XIV collagen mRNA increased in the muscle connective tissues after denervation and around the regenerating muscle fibers. Therefore, Type XIV collagen expression appears to coincide with muscle activity and muscle regenerating conditions, and Type XIV collagen is considered to play roles in muscle development and regeneration.

Effects of different osteopromotive membrane porosities on experimental bone neogenesis in rats

Biologically inert expanded polytetrafluorethylene (e-PTFE) membranes (GORE-TEX) have earlier been shown to improve healing of different types of bone defects, to be able to restore earlier existing bone, and to produce bone neogenesis. This study was performed to investigate the influence of membrane porosity on the osteopromotive efficacy and to determine bone neogenesis times in the rat. Three different e-PTFE membrane qualities with different porosities (internodal distances < 8, 20-25 and 100 microns) and four healing periods (6, 12, 18 weeks and 6 months) were studied. Dome-shaped e-PTFE membranes (5 mm inner diameter) were placed on denuded rat calvaria and covered with the periosteum and skin. After the respective time intervals, specimens were prepared for histology, and the bone obtained within the domes was quantified by an image analysis system. The results confirmed that it is possible to produce new bone by the use of the osteopromotion technique. The rate of bone neogenesis depended on the quality of membrane used; the membranes with the smallest internodal distance were less efficient than the others in that osteogenesis was somewhat delayed. The amount of new bone achievable was essentially already obtained after 6 weeks with the two most porous membranes, whereas the least porous one lagged behind. After 12 weeks there was no difference in the amount of newly formed bone. There was an obvious time sequence, in that the newly formed bone showed an increased maturity with longer observation periods. The material with the smallest internodal distance did not integrate well with the surrounding soft tissue, leading to a lack of stabilization of the membrane and more soft tissue ingrowth from the side. It is concluded that there is a porosity range within which osteogenesis beneath the membranes is optimal, tissue integration for stability is adequate enough, and soft connective tissue ingrowth is avoided.

Effect of glutamic acid on broilers given submarginal crude protein with adequate essential amino acids using feeds high and low in potassium

Broiler males were examined for their response to feeds containing CP 1 to 2% below levels advocated by NRC (1994) and when supplemented with L-glutamic acid. Crude protein and glutamic acid treatments were imposed in starting, growing, and finishing feeds over 7 wk with K at high and low levels likely to occur in practice (0.80 vs 0.65 to 0.55%). All feeds were formulated to be isocaloric (3.20 kcal ME/g) and satisfy NRC (1994) essential amino acid (EAA) minimum requirements. Improved live weight gain occurred during the first 6 wk with supplementation of glutamic acid to the low CP feed but not when intact protein per se was used to increase CP. A similar advantage in growth was obtained from glutamic acid in response to its addition at equivalence of 1 to 2% CP as well as when dietary adjustments maintained low CP. Response to altered K could not be interpreted because of concurrent differences in glutamic acid and AMEn intakes. High glutamic acid levels did not decrease abdominal fat unless CP increased concurrently, whereas carcass back bruising and drumstick deformations were relieved by supplemental glutamic acid independent of CP. Increased weight gain from glutamic acid was only evident with drumsticks and debris that included the back when carcasses were cone-deboned. Supplemental glutamic acid is believed to improve the rate of connective tissue formation during rapid growth.