Pitfalls during biomechanical testing - Evaluation of different fixation methods for measuring tendons endurance properties.

The goal of the study was to find a proper technique to fix tendon grafts into an INSTRON loading machine. From 8 human cadavers, 40 grafts were collected. We removed the bone-patella tendon-bone grafts, the semitendinosus and gracilis tendons, the quadriceps tendon-bone grafts, the Achilles tendons, and the peroneus longus tendons from each lower extremity. We tested the tendon grafts with five different types of fixation devices: surgical thread (Premicron 3), general mounting clamp, wire mesh, cement fixation, and a modified clamp for an INSTRON loading machine. The mean failure load in case of surgical thread fixation was (381N ± 26N). The results with the general clamp were (527N ± 45N). The wire meshes were more promising (750N ± 21N), but did not reach the outcomes we desired. Easy slippages of the ends of the tendons from the cement encasements were observed (253N ± 18N). We then began to use Shi's clamp that could produce 977N ± 416N peak force. We combined Shi's clamp with freezing of the graft and the rupture of the tendon itself demonstrated an average force of 2198 N ± 773N. We determined that our modified frozen clamp fixed the specimens against high tensile forces.

Fibroblast growth factor-2 promotes axon branching of cortical neurons by influencing morphology and behavior of the primary growth cone.

Interstitial branching is an important mechanism for target innervation in the developing CNS. A previous study of cortical neurons in vitro showed that the terminal growth cone pauses and enlarges in regions from which interstitial axon branches later develop (Szebenyi et al., 1998). In the present study, we investigated how target-derived signals affect the morphology and behaviors of growth cones leading to development of axon branches. We used bath and local application of a target-derived growth factor, FGF-2, on embryonic pyramidal neurons from the sensorimotor cortex and used time-lapse digital imaging to monitor effects of FGF-2 on axon branching. Observations of developing neurons over periods of several days showed that bath-applied FGF-2 significantly increased growth cone size and slowed growth cone advance, leading to a threefold increase in axon branching. FGF-2 also had acute effects on growth cone morphology, promoting rapid growth of filopodia within minutes. Application of FGF-2-coated beads promoted local axon branching in close proximity to the beads. Branching was more likely to occur when the FGF-2 bead was on or near the growth cone, suggesting that distal regions of the axon are more responsive to FGF-2 than other regions of the axon shaft. Together, these results show that interstitial axon branches can be induced locally through the action of a target-derived growth factor that preferentially exerts effects on the growth cone. We suggest that, in target regions, growth factors such as FGF-2 and other branching factors may induce formation of collateral axon branches by enhancing the pausing and enlargement of primary growth cones that determine future branch points.

Regulation of kinesin: implications for neuronal development.

Rapid organelle transport is required for process growth and establishment of specialized structures during neuronal development. Furthermore, maintenance of mature neuronal architecture and function depends on the proper delivery of materials to specialized domains within axons, such as nodes of Ranvier and synaptic terminals. Kinesin is the most abundant member of the kinesin superfamily of microtubule-based motors. Kinesins are responsible for anterograde transport of an assortment of membrane-bound organelles in all cell types. Kinesin is enriched in neurons, but relatively little is known about the developmental regulation of its expression, localization, and function in nervous tissue. By examining kinesin expression in developing brain and in cultures of cortical neurons, we found that kinesin is enriched in elongating neurites, including their growing tips, the growth cones. To gain understanding of mechanisms that underlie the delivery of proteins to specific cellular subcompartments, we focused on studying modifications on kinesin that lead to its dissociation from membranes. Since kinesin is a phosphoprotein in vivo, we evaluated the correlation between kinesin phosphorylation and its membrane association and identified a number of kinases which phosphorylate kinesin and alter its function.

Common mechanisms underlying growth cone guidance and axon branching.

During development, growth cones direct growing axons into appropriate targets. However, in some cortical pathways target innervation occurs through the development of collateral branches that extend interstitially from the axon shaft. How do such branches form? Direct observations of living cortical brain slices revealed that growth cones of callosal axons pause for many hours beneath their cortical targets prior to the development of interstitial branches. High resolution imaging of dissociated living cortical neurons for many hours revealed that the growth cone demarcates sites of future axon branching by lengthy pausing behaviors and enlargement of the growth cone. After a new growth cone forms and resumes forward advance, filopodial and lamellipodial remnants of the large paused growth cone are left behind on the axon shaft from which interstitial branches later emerge. To investigate how the cytoskeleton reorganizes at axon branch points, we fluorescently labeled microtubules in living cortical neurons and imaged the behaviors of microtubules during new growth from the axon shaft and the growth cone. In both regions microtubules reorganize into a more plastic form by splaying apart and fragmenting. These shorter microtubules then invade newly developing branches with anterograde and retrograde movements. Although axon branching of dissociated cortical neurons occurs in the absence of targets, application of a target-derived growth factor, FGF-2, greatly enhances branching. Taken together, these results demonstrate that growth cone pausing is closely related to axon branching and suggest that common mechanisms underlie directed axon growth from the terminal growth cone and the axon shaft.

Release of kinesin from vesicles by hsc70 and regulation of fast axonal transport.

The nature of kinesin interactions with membrane-bound organelles and mechanisms for regulation of kinesin-based motility have both been surprisingly difficult to define. Most kinesin is recovered in supernatants with standard protocols for purification of motor proteins, but kinesin recovered on membrane-bound organelles is tightly bound. Partitioning of kinesin between vesicle and cytosolic fractions is highly sensitive to buffer composition. Addition of either N-ethylmaleimide or EDTA to homogenization buffers significantly increased the fraction of kinesin bound to organelles. Given that an antibody against kinesin light chain tandem repeats also releases kinesin from vesicles, these observations indicated that specific cytoplasmic factors may regulate kinesin release from membranes. Kinesin light tandem repeats contain DnaJ-like motifs, so the effects of hsp70 chaperones were evaluated. Hsc70 released kinesin from vesicles in an MgATP-dependent and N-ethylmaleimide-sensitive manner. Recombinant kinesin light chains inhibited kinesin release by hsc70 and stimulated the hsc70 ATPase. Hsc70 actions may provide a mechanism to regulate kinesin function by releasing kinesin from cargo in specific subcellular domains, thereby effecting delivery of axonally transported materials.

Reorganization and movement of microtubules in axonal growth cones and developing interstitial branches.

Local changes in microtubule organization and distribution are required for the axon to grow and navigate appropriately; however, little is known about how microtubules (MTs) reorganize during directed axon outgrowth. We have used time-lapse digital imaging of developing cortical neurons microinjected with fluorescently labeled tubulin to follow the movements of individual MTs in two regions of the axon where directed growth occurs: the terminal growth cone and the developing interstitial branch. In both regions, transitions from quiescent to growth states were accompanied by reorganization of MTs from looped or bundled arrays to dispersed arrays and fragmentation of long MTs into short MTs. We also found that long-term redistribution of MTs accompanied the withdrawal of some axonal processes and the growth and stabilization of others. Individual MTs moved independently in both anterograde and retrograde directions to explore developing processes. Their velocities were inversely proportional to their lengths. Our results demonstrate directly that MTs move within axonal growth cones and developing interstitial branches. Our findings also provide the first direct evidence that similar reorganization and movement of individual MTs occur in the two regions of the axon where directed outgrowth occurs. These results suggest a model whereby short exploratory MTs could direct axonal growth cones and interstitial branches toward appropriate locations.

Fibroblast growth factors as multifunctional signaling factors.

The fibroblast growth factor (FGF) family consists of at least 15 structurally related polypeptide growth factors. Their expression is controlled at the levels of transcription, mRNA stability, and translation. The bioavailability of FGFs is further modulated by posttranslational processing and regulated protein trafficking. FGFs bind to receptor tyrosine kinases (FGFRs), heparan sulfate proteoglycans (HSPG), and a cysteine-rich FGF receptor (CFR). FGFRs are required for most biological activities of FGFs. HSPGs alter FGF-FGFR interactions and CFR participates in FGF intracellular transport. FGF signaling pathways are intricate and are intertwined with insulin-like growth factor, transforming growth factor-beta, bone morphogenetic protein, and vertebrate homologs of Drosophila wingless activated pathways. FGFs are major regulators of embryonic development: They influence the formation of the primary body axis, neural axis, limbs, and other structures. The activities of FGFs depend on their coordination of fundamental cellular functions, such as survival, replication, differentiation, adhesion, and motility, through effects on gene expression and the cytoskeleton.

Interstitial branches develop from active regions of the axon demarcated by the primary growth cone during pausing behaviors.

Interstitial branches arise from the axon shaft, sometimes at great distances behind the primary growth cone. After a waiting period that can last for days after extension of the primary growth cone past the target, branches elongate toward their targets. Delayed interstitial branching is an important but little understood mechanism for target innervation in the developing CNS of vertebrates. One possible mechanism of collateral branch formation is that the axon shaft responds to target-derived signals independent of the primary growth cone. Another possibility is that the primary growth cone recognizes the target and demarcates specific regions of the axon for future branching. To address whether behaviors of the primary growth cone and development of interstitial branches are related, we performed high-resolution time-lapse imaging on dissociated sensorimotor cortical neurons that branch interstitially in vivo. Imaging of entire cortical neurons for periods of days revealed that the primary growth cone pauses in regions in which axon branches later develop. Pausing behaviors involve repeated cycles of collapse, retraction, and extension during which growth cones enlarge and reorganize. Remnants of reorganized growth cones are left behind on the axon shaft as active filopodial or lamellar protrusions, and axon branches subsequently emerge from these active regions of the axon shaft. In this study we propose a new model to account for target innervation in vivo by interstitial branching. Our model suggests that delayed interstitial branching results directly from target recognition by the primary growth cone.

Changes in the expression of fibroblast growth factor receptors mark distinct stages of chondrogenesis in vitro and during chick limb skeletal patterning.

Members of the fibroblast growth factor (FGF) family of growth factors are key regulators of limb skeletal patterning and growth. Abnormal expression of FGFs or mutations in their receptors (fgfrs) result in skeletal disorders. Here we show that changes in the expression of fgfrs are intrinsic properties of differentiating cartilage. In mesenchymal micromass cultures differentiating into cartilage, as in ovo, fgfr 1 mRNA was found predominantly in undifferentiated, proliferating mesenchyme, fgfr 2 in precartilage cell aggregates, and fgfr 3 in differentiating cartilage nodules. Thus, our data suggest that switches in the expression of fgfr 1, 2, and 3 mRNAs are associated with phases of cartilage patterning both in vitro and in ovo, and mark distinct stages in the development of the limb skeleton.

Role of FGFs in skeletal muscle and limb development.

Fibroblast growth factors (FGFs) are a family of nine proteins that bind to three distinct types of cell surface molecules: (i) FGF receptor tyrosine kinases (FGFR-1 through FGFR-4); (ii) a cysteine-rich FGF receptor (CFR); and (iii) heparan sulfate proteoglycans (HSPGs). Signaling by FGFs requires participation of at least two of these receptors: the FGFRs and HSPGs form a signaling complex. The length and sulfation pattern of the heparan sulfate chain determines both the activity of the signaling complex and, in part, the ligand specificity for FGFR-1. Thus, the heparan sulfate proteoglycans are likely to play an essential role in signaling. We have recently identified a role for FGF in limb bud development in vivo. In the chick limb bud, ectopic expression of the 18 kDa form of FGF-2 or FGF-2 fused to an artificial signal peptide at its amino terminus causes skeletal duplications. These data, and the observations that FGF-2 is localized to the subjacent mesoderm and the apical ectodermal ridge in the early developing limb, suggest that FGF-2 plays an important role in limb outgrowth. We propose that FGF-2 is an apical ectodermal ridge-derived factor that participates in limb outgrowth and patterning.

The mouse insulin-like growth factor II/cation-independent mannose 6-phosphate (IGF-II/MPR) receptor gene: molecular cloning and genomic organization.

The mammalian insulin-like growth factor II/cation-independent mannose 6-phosphate receptor (IGF-II/MPR) is a multifunctional protein that binds both IGF-II and ligands containing a mannose 6-phosphate recognition marker through distinct high-affinity sites. This receptor plays an integral part in lysosomal enzyme transport, has a potential role in growth factor maturation and clearance, and may mediate IGF-II-activated signal transduction through a G-protein-coupled mechanism. Recent studies have shown that production of IGF-II/MPR mRNA and protein begins in the mouse embryo soon after fertilization and have demonstrated that the receptor gene is on mouse chromosome 17 and is maternally imprinted. In this paper, we report the cloning and characterization of the mouse IGF-II/MPR gene. The gene is 93 kb long, is composed of 48 exons, and codes for a predicted protein of 2482 amino acids. The extracellular part of the receptor is encoded by exons 1-46, with each of 15 related repeating motifs being determined by parts of 3-5 exons. A single fibronectin type II-like element is found in exon 39. The transmembrane portion of the receptor also is encoded by exon 46, and the cytoplasmic region by exons 46-48. The positions of exon-intron splice junctions are conserved between several of the repeats in the IGF-II/MPR and the homologous extracellular region of the gene for the other known lysosomal sorting receptor, the cation-dependent mannose 6-phosphate receptor.(ABSTRACT TRUNCATED AT 250 WORDS)

Differential regulation of mannose 6-phosphate receptors and their ligands during the myogenic development of C2 cells.

The mammalian insulin-like growth factor II/cation-independent mannose 6-phosphate receptor (IGF-II/CIMPR) mediates both targeting and endocytosis of mannose 6-phosphate-containing proteins and binds insulin-like growth factor II (IGF-II). The cation-dependent mannose 6-phosphate receptor (CDMPR) lacks an IGF-II-binding site and participates only in the intracellular trafficking of lysosomal enzymes. During terminal differentiation of the myogenic C2 cell line, there is an increase in cell surface expression of the IGF-II/CIMPR in parallel with a rise in secretion of IGF-II (Tollefsen, S.E., Sadow, J.L., and Rotwein, P. (1989) Proc. Natl. Acad. Sci. U.S.A. 86, 1543-1547). In this study we show that IGF-II/CIMPR mRNA increases by more than 10-fold during the initial 48 h of C2 muscle differentiation with kinetics similar to the rise in IGF-II mRNA. Comparable levels of both mRNAs are expressed in C2 myotubes and in primary cultures of fetal muscle. By contrast, no change is observed in CDMPR transcript abundance during differentiation, and only a small, transient increase is seen in the enzymatic activities and mRNA levels of several lysosomal enzymes. The differential regulation of the two mannose 6-phosphate receptors during muscle differentiation suggests that they may serve distinct functions in development.

Insulin-like growth factors and their receptors in muscle development.

Several proteins involved in IGF action are expressed in C2 cells and their abundance was found to vary as a function of development. IGF-I and II mRNA levels rose 10 and 25-fold, respectively, during differentiation, and were accompanied by an increase in growth factor secretion. The accumulation of IGF-II in conditioned culture medium was much greater than that of IGF-I. There was also an increase in the number of IGF-I receptors and IGF-II/CIMPR on the cell surface during differentiation. The sustained rise in IGF-II/CIMPR expression appeared to be a consequence of a similar increase in its mRNA abundance. The mechanisms responsible for the transient increment in IGF-I receptor number were not assessed, although it is likely that the decline in IGF-I receptor content after 72 hours in differentiation medium was a consequence of down-regulation by the IGF-II that accumulated in the medium (35). In contrast to the 13-fold rise in IGF-II/CIMPR mRNA levels, transcript levels for the CDMPR remained constant during C2 cell development, enzymatic activities of two lysosomal enzymes did not change, and only a small increment was detected at a single time point in the expression of several lysosomal enzyme mRNAs. In addition, during C2 muscle differentiation, a novel IGF binding protein was induced. These results demonstrate modulation of several components of IGF signaling pathways in differentiating myoblasts, and argue for a local role for IGFs in muscle development.