The effects of T cells and their products on in vitro healing of epitenon cell microwounds.

The purpose of the present investigation was to study the activity and behaviour of rat epitenon cells cultured in the presence of activated helper/inducer T lymphocytes and T-cell-derived cytokines interleukin-1 (IL-1), IL-2, transforming growth factor-beta (TGF-beta) and interferon-gamma (IFN-gamma). We measured the speed of healing of microwounded monolayers of epitenon cells as well as intercellular adhesion, cell proliferation and fibronectin production. The speed of monolayer healing was increased in the presence of activated CD4+ T lymphocytes and cytokines: TGF-beta > IL-2 > IL-1 > IFN-gamma. TGF-beta and IL-2 were also found to promote cell-cell adhesion; other cytokines had a minor effect. IL-2, IL-1 and IFN-gamma promoted [3H]thymidine incorporation in epitenon cells whereas TGF-beta had an inhibitory effect. Fibronectin production was studied with immunofluorescence staining methods. Activated CD4+ T lymphocytes and TGF-beta stimulated the deposition of fibronectin whereas other cytokines did not have a significant effect. Our results suggest that activated T lymphocytes and T-cell-derived cytokines, especially IL-2 and TGF-beta play a crucial role in the regulation of epitenon cell proliferation, adhesion and extracellular matrix production during in vitro microwound healing. As epitenon cells are the main cell type participating in tendon repair, factors regulating their activity may find application in clinical practice.     

The cell specific temporal expression of nitric oxide synthase isoforms during Achilles tendon healing

OBJECTIVE AND DESIGN: We have previously shown that nitric oxide synthase (NOS) activity is upregulated following tendon injury, and that this activity is important to Achilles tendon healing. The aim of this study was to identify the cellular distribution of nitric oxide synthase isoforms during tendon healing. MATERIAL OR SUBJECTS: Surgical division of the right Achilles tendon was performed in eighty-five male Sprague-Dawley rats. Healing Achilles tendons were harvested at 4, 7, 14 and 21 days following the surgery. The un-injured left Achilles tendons were used as controls. Using RNase protection assays, in situ hybridization and immunohistochemistry, mRNA and protein of NOS isoforms were evaluated. RESULTS: Minimal NOS expression was found in un-injured tendon. A cell specific temporal pattern for the mRNA and protein for all three NOS isoforms was found following injury to the Achilles tendon. iNOS was maximal on day 4 in macrophages and fibroblasts. eNOS was maximal on day 4 in endothelial cells and fibroblasts. bNOS expression gradually increased up to day 21 and was found only in fibroblasts. CONCLUSIONS: These results suggest that all three nitric oxide synthase isoforms are expressed by fibroblasts in a coordinated temporal sequence during tendon healing. The sequential pattern of NOS expression in healing fibroblasts suggests that each NOS isoform may play a different role in the healing process and provides opportunities to modify tendon healing in the clinical setting.     

Nonsteroidal anti-inflammatory drug reduces neutrophil and macrophage accumulation but does not improve tendon regeneration

Whether nonsteroidal anti-inflammatory drugs have a beneficial effect on tendon regeneration is still a matter of debate. Given that inflammatory cells are thought to induce nonspecific damage following an injury, we tested the hypothesis that a 3-day treatment with diclofenac would protect tendons from inflammatory cell injury and would promote healing. Neutrophil and ED1(+) macrophage concentrations were determined in the paratenon and the core of the rat Achilles tendon following collagenase-induced injury. Hydroxyproline content, edema, and mechanical properties were also evaluated at 1, 3, 7, 14, and 28 days post-trauma. Collagenase injections induced a 70% decrease in the ultimate rupture point at Day 3. Diclofenac treatments (1 mg/kg bid) selectively decreased the accumulation of neutrophils and ED1(+) macrophages by 59% and 35%, respectively, in the paratenon, where blood vessels are numerous, but did not reduce the accumulation of neutrophils and ED1(+) macrophages in the core of the tendon. Edema was significantly reduced on Day 3 but persisted during the remodeling phase in the diclofenac-treated group only. The inhibition of leukocyte accumulation by diclofenac did not translate into a reduction of tissue damage or a promotion of tissue healing, because the mechanical properties of injured Achilles tendons were identical in placebo and diclofenac-treated groups. These results indicate that diclofenac reduced both edema and the accumulation of inflammatory cells within the paratenon but provided no biochemical or functional benefits for the Achilles tendon.     

Synovial biology and T cells in rheumatoid arthritis.

Events that occur in rheumatoid arthritis synovial tissues are responsible for the signs and symptoms of joint inflammation and for the eventual destruction of articular and periarticular structures that lead to joint dysfunction and disability. The three most abundant cell populations in RA synovium are synovial macrophages (type A synoviocytes), synovial fibroblasts (type B synoviocytes) and infiltrating T lymphocytes. Other important cell populations include B lymphocytes, dendritic cells, plasma cells, mast cells and osteoclasts. Our current understanding of rheumatoid arthritis is moving beyond previous concepts that view this disease as the consequence of a specific and focused humoral or cellular autoimmune response to a single autoantigen. Rather, a new view of rheumatoid arthritis is emerging, which seeks to understand this disease as the product of pathologic cell-cell interactions occurring within a unique and defined environment, the synovium. T lymphocytes in rheumatoid arthritis synovium interact closely with dendritic cells, the most potent antigen-presenting cell population in the immune system. T cells also interact with monocytes and macrophages and cytokine-activated T cells may be, especially, suited to trigger production of the important cytokine TNFalpha by synovial macrophages. Recent evidence also suggests a potent bidirectional interaction between synovial T cells and synovial fibroblasts, which can lead to activation of both cell types. An important role for synovial B lymphocytes has been emphasized recently, both by experimental data and by results of clinical interventions. B cells in synovium can interact with fibroblasts as well as with other cells of the immune system and their potential role as antigen-presenting cells in the joint is as yet underexplored. Rheumatoid arthritis synovium may be one of the most striking examples of pathologic, organ-specific interactions between immune system cells and resident tissue cell populations. This view of rheumatoid arthritis also leads to the prediction that novel approaches to treatment will more logically target the intercellular communication systems that maintain such interactions, rather than attempt to ablate a single cell population.     

Tubulin polymerization‐promoting protein family member 3, Tppp3, is a specific marker of the differentiating tendon sheath and synovial joints

Tppp3, a member of the Tubulin polymerization‐promoting protein family, is an intrinsically unstructured protein that induces tubulin polymerization. We show that Tppp3 is a distinct marker in the developing musculoskeletal system. In tendons, Tppp3 is expressed in cells at the circumference of the developing tendons, likely the progenitors of connective tissues that surround tendons: the tendon sheath, epitenon, and paratenon. These tissues form an elastic sleeve around tendons and provide lubrication to minimize friction between tendons and surrounding tissues. Tppp3 is the first molecular marker of the tendon sheath, opening the door for direct examination of these tissues. Tppp3 is also expressed in forming synovial joints. The onset of Tppp3 expression in joints coincides with cavitation, representing a molecular marker that can be used to indicate this stage in joint transition in joint differentiation. In late embryonic stages, Tppp3 expression highlights other demarcation lines that surround differentiating tissues in the forelimb. Developmental Dynamics 238:685–692, 2009. © 2009 Wiley‐Liss, Inc.     

B lymphocyte function in patients with rheumatoid arthritis: impact of regulatory T lymphocytes and macrophages--modulation by antirheumatic drugs

The present work analyses B lymphocyte functions in vitro in patients with rheumatoid arthritis (RA). The impact of gold salts and penicillamine on human B lymphocyte function in vitro is discussed. Synovial fluid monocytes/macrophages increased both the polyclonally induced and the antigen-induced blood lymphocyte proliferation and increased the numbers of immunoglobulin-secreting blood B lymphocytes generated by pokeweed mitogen (PWM), a T cell-dependent polyclonal activator. The lymphostimulatory factor(s) interleukin-1, which can be produced by monocytes/macrophages, was found in most cell-free synovial fluid specimens, but only in a few paired serum samples. Thus, in vivo activated synovial monocytes/macrophages may modulate lymphocyte functions. Compared to blood, synovial fluid T lymphocytes comprised fewer T4+ (helper/inducer) cells and more T8+ (suppressor/cytotoxic) cells. Synovial fluid lymphocytes proliferated poorly when stimulated polyclonally. However, the proliferative responses to microbial antigens as well as the lectin-induced lymphokine production equaled those of blood lymphocytes. In about half of RA patients, T4+ cells from synovial fluid increased the PWM-induced immunoglobulin secretion by autologous blood B lymphocytes to higher levels as compared to similar experiments with blood T4+ cells. Synovial fluid T8+ cells suppressed PWM-induced immunoglobulin production of autologous mononuclear cells to the same degree as seen with blood T8+ cells. A large proportion of synovial fluid T subsets expressed Ia antigens, probably due to in vivo activation. Thus, synovial T helper/inducer and T suppressor/cytotoxic cells may modulate the functional activities of synovial B lymphocytes. Among mononuclear cells isolated from synovial fluid and synovial tissue, considerable numbers of B lymphocytes spontaneously secreting IgG were found; fewer B cells secreted IgM and IgA. Rheumatoid factor activity was noted in about 7% of the IgG-producing cells. Synovial fluid mononuclear cells did not produce immunoglobulins in cultures stimulated with PWM, unless synovial T cells were removed and replaced with autologous blood T cells. Under these conditions synovial fluid B lymphocytes were induced by PWM to considerable IgG synthesis; fewer cells secreted IgM and IgA. About 8-9% of the induced IgM- and IgG-synthesizing cells displayed rheumatoid factor activity. Aurothiomalate markedly inhibited PWM-induced immunoglobulin production by normal lymphocytes cultured in vitro, probably by affecting monocyte/macrophage-lymphocyte interactions. The drug also had a direct inhibitory action on B lymphocytes, whereas T cells were resistant.(ABSTRACT TRUNCATED AT 400 WORDS)     

The role of T cells in rheumatoid arthritis

In rheumatoid arthritis (RA), T cells infiltrate into the synovial membrane where they initiate and maintain activation of macrophages and synovial fibroblasts, transforming them into tissue-destructive effector cells. The diversity of the disease process and the formation of complex lymphoid microstructures indicate that multiple T cell activation pathways are involved. This model is supported by the association of distinct disease patterns with different variants and combinations of HLA class II molecules. T cell pathology in RA, however, is not limited to the joint. Affected patients have major abnormalities in the T cell pool, with a marked contraction in T cell receptor diversity and an outgrowth of large clonal populations. Clonally expanded CD4+ T cells lose expression of the CD28 molecule and gain expression of perforin and granzyme. Consequently, the functional profile of expanded CD4(+)CD28null T cells is fundamentally changed and is shifted towards tissue-injurious capabilities. CD4(+)CD28null T cells are particularly important in patients with extra-articular manifestations of RA, where they may have a direct role in vascular injury. Understanding the mechanisms underlying the loss of T cell diversity and the emergence of pro-inflammatory CD4(+)CD28null T cell clonotypes may have implications for other autoimmune syndromes.     

Tissue engineering of flexor tendons: optimization of tenocyte proliferation using growth factor supplementation

A significant problem in flexor tendon repair is the lack of suitable graft material for reconstruction. The ex vivo production of flexor tendon graft constructs requires the expansion of primary cells. Growth factors, such as platelet-derived growth factor-BB (PDGF-BB), insulin-like growth factor-1 (IGF-1), and basic fibroblast growth factor (bFGF), are known to promote tendon healing and tendon cell proliferation. The purpose of these experiments was to optimize tenocyte proliferation in 3 tendon cell populations using growth factor supplementation. Cells of the synovial sheath, epitenon, and endotenon were isolated from rabbit flexor digitorum profundus tendons and maintained in culture. Cell cultures were supplemented with IGF-1, PDGF-BB, and bFGF alone and in combination. The conditions used for individual growth factor supplementation were IGF-1 (10, 50, and 100 ng/mL), PDGF-BB (1, 10, and 50 ng/mL), and bFGF (0.5, 1, and 5 ng/mL). The conditions used for combinations of growth factors were IGF-1 + PDGF-BB (50 + 10 and 100 + 50 ng/mL, respectively) and IGF-1 + PDGF-BB+ bFGF (50 + 10 + 1; 50 + 10 + 5; 100 + 50 + 1; and 100 + 50 + 5 ng/mL, respectively). For all 3 tendon cell populations, proliferation at 72 h was greater in the presence of individual growth factors as compared to controls. With PDGF-BB (50 ng/mL) supplementation, mean absorbance values increased 97% (0.57 to 1.13) in S cells, 37% (0.51 to 0.70) in E cells, and 33% (0.33 to 0.44) in T cells ( p < 0.001). In addition, a synergistic effect was observed. The combination of growth factors resulted in greater proliferation as compared to maximal doses of individual growth factors. In cultures supplemented with IGF-1 (100 ng/mL) +PDGF-BB (50 ng/mL), mean absorbance increased 114% (0.57 to 1.22) in S cells, 63% (0.51 to 0.831) in E cells, and 47% (0.33 to 0.48) in T cells ( p < 0.001). IGF-1 (100 ng/mL) + PDGF-BB (50 ng/mL) + bFGF (5 ng/mL) resulted in the greatest amount of cell proliferation for all 3 tendon cell populations. The mean absorbances increased 251% in S cells, 98% in E cells, and 106% in T cells ( p < 0.001). In summary, IGF-1, PDGF-BB, and bFGF can be used in combination to maximize tenocyte proliferation. Synergism among growth factors may provide a means to facilitate tendon engineering.     

无滑膜肌腱滑膜化的组织工程学研究

我们将兔趾腱鞘内滑膜组织进行体外培养,经原代培养和传代培养,制成滑膜细胞悬液,再把兔腱鞘外无滑膜肌腱段放入滑膜细胞悬液中混全培养。经光镜、扫描电镜和免疫组织化学检测。结果显示,滑膜细胞爬行并覆盖了无滑膜肌腱段的表面,使无滑膜肌腱形成了有滑膜肌腱。     

Decreasing inflammatory response of injured patellar tendons results in increased collagen fibril diameters

Tissue inflammation is essential in the healing process, but its effect on the quality of the healing tissue is not clear. This study determines the effect of decreasing early inflammation during wound healing in genetic deficient mice on collagen fibril diameter. Two strains of mice were used: three C3H/HeJ mice and three C3H/HeN mice for each of two time points (7 and 14 days postinjury). C3H/HeJ mice have a genetic deficiency in the production of tumor necrosis factor by macrophages and other cytokines in response to endotoxin, and C3H/HeN mice have no genetic deficiency. The right patellar tendon of both mouse strains was transversely transected, whereas the left patellar tendon was left intact for control. After 7 and 14 days, both right and left patellar tendons were harvested, and tendon samples were examined with transmission electron microscopy. We found that at 7 days, transected tendons of C3H/HeJ mice exhibited on average 1.6 times larger collagen fibril diameters than transected C3H/HeN tendons, whereas at 14 days, collagen fibril diameters of the C3H/HeJ mice were 1.3 times that of C3H/HeN mice. Also, at both 7 days and 14 days, collagen fibrils in C3H/HeJ mice appeared more organized than C3H/HeN mice. In addition, control tendons in both mouse strains showed no significant differences in collagen fibril diameter and organization. Therefore, these results suggest that decreasing the inflammatory response in the early stages of tendon wound healing enhances the quality of the healing tendon through increased collagen fiber diameter and better organization.     

Immunohistochemical analysis of synovial membranes from inflammatory and non-inflammatory arthritides: scarcity of CD5 positive B cells and IL2 receptor bearing T cells.

Rheumatoid Arthritis (RA) synovial membranes were examined by single and dual immunohistological techniques with a number of monoclonal antibodies against lymphocyte and macrophage related antigens. CD4 positive T lymphocytes frequently expressed MHC Class II antigens and were found in sublining collections in close association with activated macrophages as well as B lymphocytes. CD8 positive T cells surrounded these collections as well as being scattered throughout the membrane and also frequently expressed MHC Class II antigens. IL2 receptor (IL2r) expression on T cells and CD5 expression on B cells were rarely seen in these synovial membranes. Similar immunohistological architecture was found in synovial membranes from patients with psoriatic arthritis (PA) and Reiter's Syndrome (RS). Normal synovium contained few T cells, with few cells expressing MHC Class II antigens. Synovium from osteoarthritis (OA) patients also demonstrated similar immunohistological changes to those found in inflammatory arthritides, suggesting that there are only quantitative rather than qualitative differences between the synovial membrane immunohistological architecture from patients with inflammatory and noninflammatory arthritides.     

Expression of CD40 and CD40 ligand among cell populations within rheumatoid synovial compartment

Augmented and prolonged expression of CD40 ligand (CD40L) was recently reported in lymphoid cells from human lupus patients, suggesting that CD40/CD40L pathway was involved in the pathogenesis of systemic autoimmune diseases. This study was thus designed to study the expression of CD40 and CD40L among cell populations within inflammatory joints of patients with rheumatoid arthritis (RA). The result showed that most B cells and monocytes in synovial fluids (SF) expressed CD40. Cultured synovial fibroblasts also stained positive for CD40. Regarding CD40L, we found that T cells as well as B cells could express CD40L. Compared with normal controls, RA patients had higher levels of CD40L+ T cells (8.71 +/- 17.69% vs 1.74 +/- 2.30%, P > 0.05) and CD40L+ B cells (7.71 +/- 7.64% vs 1.12 +/- 1.59% P < 0.05). After in vitro stimulation, T cells from RA patients had higher and longer CD40L expression than T cells from normal peripheral blood. For investigating the effect of CD40 expressed on synovial fibroblasts on TNF-alpha production in joint compartment, we used anti-CD40 antibody to bind CD40 on fibroblasts for one hour and then co-cultured with synovial fluid mononuclear cells. We found that the levels of TNF-alpha decreased in the presence of anti-CD40 antibody. We concluded that there was an intrinsic hyperexpression of CD40L on lymphoid cells within rheumatoid joints, and synovial fibroblasts could contribute to articular inflammation through surface CD40 molecule.     

Biocompatibility of NDGA-polymerized collagen fibers. II. Attachment, proliferation, and migration of tendon fibroblasts in vitro

The material properties of collagen fibers polymerized with nordihydroguaiaretic acid (NDGA) are equivalent to native tendon, suggesting that NDGA crosslinking may provide a viable approach to stabilizing collagenous materials for use in repairing ruptured, lacerated, or surgically transected fibrous tissues, such as tendons and ligaments (Koob & Hernandez, Biomaterials, in press). The present study evaluated the biocompatibility of these fibers with cultured bovine tendon fibroblasts. Fibroblast attachment, migration, and proliferation on NDGA-crosslinked materials were compared to those on prepolymerized type I tendon collagen constructs as well as on tissue-culture-treated plastic. Fibroblast attachment on NDGA-crosslinked collagen fibrils was equivalent to attachment on plates coated with collagen alone. Over a period of 8 days in culture, attached fibroblasts proliferated on NDGA-crosslinked collagen at a rate identical to that of fibroblasts attached to native collagen. In order for the biomaterial effectively to bridge gaps in fibrous tissues, fibroblasts must be able to migrate and replicate on the bridging fiber. Control and crosslinked fibers were inserted in calf tendon explants, with a portion of the fiber extending out of the sectioned end of the tendon. Explants were cultured for 9 weeks, and the number of cells was measured at weekly intervals. Cells appeared on the fibers after 1 week of culture. By 2 weeks, cells had colonized the entire fiber. The number of cells continued to increase throughout the 9 weeks in culture, forming a layer several cells thick. Histologic analysis indicated that the fibroblasts populating the fibers appeared to originate in the epitenon. There was no difference in the rate of fibroblast migration and replication, nor in the ultimate number of colonizing cells, between control collagen fibers and NDGA-crosslinked fibers. NDGA-crosslinked fibers may provide a means of bridging gaps in ruptured, lacerated, or surgically transected tendons by providing a mechanically competent scaffold on which tendon fibroblasts can migrate, attach, and proliferate.     

Some cellular aspects of chronic inflammation in joint disease

We have examined the nature of some mononuclear cells from inflamed synovial membranes of patients with rheumatoid arthritis. It was found that cells which remained in the supernatant medium after overnight culture of trypsinized tissue contained a variable number of lymphocytes which were shown to be T cells by rosetting and mitogen response. This suggests a source of T cell lymphokines with an effect on macrophages and thus a role in the maintenance of inflammation.Another role for mononuclear cells is suggested by the cytotoxicity of blood mononuclear cells directed against cultured synovial cells. this was found to occur in an autologous system using fibroblasts from rheumatoid synovium, but was not specific for rheumatoid arthritis. Stimulatory factors from rheumatoid joint effusion macrophages for blood lymphocytes were sought, but although blast transformation occurred, the results were equivocal.In this communication we set out to examine the nature of lymphoid cells in the synovial membrane and the role which they may play in the pathogenesis of chronic inflammation. We also briefly consider cell-mediated mechanisms of tissue injury. Since an active role of lymphoid cells pre-supposes the presence of an agent or agents which serve to stimulate them, we also report some recent attempts to find evidence for this.One of the striking histological features of the inflamed synovial tissue in rheumatoid arthritis, but also in some other forms of chronic arthritis, is the presence of lymphocytes and plasma cells. Immunofluorescent studies and organ culture studies have shown the presence and synthesis of immunoglobulins, predominantly the domain of plasma cells. The production of immunoglobulins, formation of complexes and activation of complement is a major factor in pathogenesis, but lymphocytes may also have a direct role through the production of lymphokines. Until recently these substances have been attributed to T lymphocytes, but Rocklin et al. [1] have recently shown that B cells may also be involved in certain experimental circumstances. The availability of synovectomy specimens from patients with rheumatoid arthritis has enabled us to examine the nature of lymphoid cells from synovial membranes. (This part of the work is reported fully elsewhere [2].)     

Functional and Phenotypical Characterization of Activated T Cells from Intra-articular Sites in Inflammatory Joint Diseases

The presence of activated T lymphocytes bearing interleukin 2 (IL-2) receptors and HLA class II (Ia) antigens accompanied by impaired T cell functions such as a decreased mitogenic responsiveness are characteristic findings, especially in intra-articular sites in chronic inflammatory joint diseases. The objective of the present study was to further characterize these in vivo activated T cells by the investigation of IL-2 production and a possible T cell receptor modulation. IL-2 receptors were found to be expressed primarily in the CD4+ subset. The Ia+ subset expressing both DR and DQ antigens showed a weaker mitogen-induced response as compared to the Ia- fraction. A decreased mitogen-induced IL-2 production and a lower response to anti-CD3 monoclonal antibodies was observed with synovial T lymphocytes as compared to peripheral blood T cells. The density of the CD3 molecule, known to be closely associated with the T cell receptor, was significantly lower in intra-articular sites, while other T cell-specific surface molecules were expressed to a similar extent in both compartments. The decreased synovial T cell mitogenesis was not restored by the addition of lymphokines (IL-1 and IL-2) or blood monocytes, nor by removing CD8+ T cells. These data present further evidence for a significant T cell activation in intra-articular sites in chronic inflammatory joint diseases. The decreased expression of the CD3 glycoprotein suggests a modulation by so far unidentified antigen(s), which could also be responsible for the weak T cell response elicited by polyclonal mitogens.     

关节滑液对兔前交叉韧带重建后腱骨愈合生物力学和组织学的影响*

背景：目前前交叉韧带重建后关节滑液对移植物强度以及腱骨愈合的影响尚无定论。 目的：观察兔前交叉韧带重建后腱骨愈合过程中,关节滑液对移植肌腱生物力学及组织学的影响。 方法：取新西兰大白兔下肢半腱肌腱,以同侧肢体半腱肌腱重建前交叉韧带模拟关节滑液影响模型,并同时取对侧肢体半腱肌行股骨髁上“U”形肌腱埋植避免关节滑液的影响。重建4周,取股骨-韧带-胫骨复合体,行生物力学测定和组织学观察。 结果与结论：重建后4周,生物力学测定时发现“U”字形埋植肌腱断裂时平均载荷明显大于前交叉韧带重建后处于关节内的肌腱(P < 0.01)。组织学观察发现,骨隧道内坏死的腱组织已被纤维组织、新生骨组织替代,腱骨交界面形成Sharpey纤维连接和纤维软骨,优于关节内肌腱;“U”字形埋植肌腱腱骨交界面成骨细胞数目明显多于前交叉韧带重建肌腱(P < 0.01)。结果证实“U”字形埋植肌腱的生物力学及腱骨愈合均优于处于关节内肌腱,提示关节滑液对前交叉韧带重建后韧带的强度以及腱骨愈合有不利影响。