Defining the Role of the Streptococcus agalactiae Sht-Family Proteins in Zinc Acquisition and Complement Evasion.

Streptococcus agalactiae is not only part of the human intestinal and urogenital microbiota but is also a leading cause of septicemia and meningitis in neonates. Its ability to cause disease depends upon the acquisition of nutrients from its environment, including the transition metal ion zinc. The primary zinc acquisition system of the pathogen is the Adc/Lmb ABC permease, which is essential for viability in zinc-restricted environments. Here, we show that in addition to the AdcCB transporter and the three zinc-binding proteins, Lmb, AdcA, and AdcAII, S. agalactiae zinc homeostasis also involves two streptococcal histidine triad (Sht) proteins. Sht and ShtII are required for zinc uptake via the Lmb and AdcAII proteins with apparent overlapping functionality and specificity. Both Sht-family proteins possess five-histidine triad motifs with similar hierarchies of importance for Zn homeostasis. Independent of its contribution to zinc homeostasis, Sht has previously been reported to bind factor H leading to predictions of a contribution to complement evasion. Here, we investigated ShtII to ascertain whether it had similar properties. Analysis of recombinant Sht and ShtII reveals that both proteins have similar affinities for factor H binding. However, neither protein aided in resistance to complement in human blood. These findings challenge prior inferences regarding the in vivo role of the Sht proteins in resisting complement-mediated clearance.IMPORTANCE This study examined the role of the two streptococcal histidine triad (Sht) proteins of Streptococcus agalactiae in zinc homeostasis and complement resistance. We showed that Sht and ShtII facilitate zinc homeostasis in conjunction with the metal-binding proteins Lmb and AdcAII. Here, we show that the Sht-family proteins are functionally redundant with overlapping roles in zinc uptake. Further, this work reveals that although the Sht-family proteins bind to factor H in vitro this did not influence survival in human blood.

Absolute concentrations of mRNA for type I and type VI collagen in the canine meniscus in normal and ACL-deficient knee joints obtained by RNase protection assay.

Relatively little is known about the cellular and molecular responses of the knee joint meniscus to joint injury, despite the functional importance of the tissue. We investigated how meniscus cells respond to joint injury in the early stages of post-traumatic osteoarthritis by characterizing the changes in matrix gene expression in menisci at 3 and 12 weeks post-surgery in dogs in which the anterior cruciate ligament (ACL) in one joint was transected and the other unoperated joint served as a control. Changes in the total RNA and DNA concentrations of the menisci were determined. Absolute concentrations of the mRNA of the COL1A1 gene of type 1 collagen, the major fibrillar collagen of the meniscus, and the COL6A3 gene of type VI collagen, a major repair molecule, were determined by quantitative ribonuclease (RNase) protection assay. The concentration of total RNA in medial and lateral menisci increased from 40 to 60 microg RNA/g wet wt in unoperated, control joints to 200-350 microg RNA/g wet wt in ACL-deficient joints. No significant changes were detected in the concentration of DNA (900-1200 microg DNA/g wet wt). Low concentrations of COL1A1 (2-3 pmol mRNA/g DNA) and COL6A3 (0.3-0.6 pmol mRNA/g DNA) mRNA transcripts were measured in normal menisci. ACL-deficiency induced a 20-38 fold increase in COL1A1 and COL6A3 mRNA concentration at 3 weeks, and an 11-19 fold increase at 12 weeks post-surgery. In general, the increase in COL1A1 and COL6A3 mRNA concentrations was greater in medial menisci than in lateral menisci. These results demonstrate that the menisci initiate a vigorous biosynthetic response to transection of the ACL.

Cell, matrix changes and alpha-smooth muscle actin expression in repair of the canine meniscus.

Processes in the repair of a crevice in the knee joint meniscus were investigated in 10 dogs. Two 2-mm cylindrical plugs from each medial meniscus were removed, rendered acellular by freezing and thawing, and then reinserted into the meniscus. Dogs were euthanized at intervals of 3-52 weeks after surgery. The crevice between the plug and meniscus at 3 weeks after surgery was filled with a tissue containing alpha-smooth muscle actin-positive cells. One year after surgery, the plug had remodeled and was populated with spindle-shaped and fibrochondrocyte-like cells. The plug had an appearance intermediate between that of hyaline and fibrocartilage at this time, with a seamless integration in sites between the remodeled plug and the surrounding meniscus. alpha-smooth muscle actin-positive cells were concentrated at the interface of the remodeled plug and adjacent meniscus and at the surface of the plug. Therefore, remodeling of both the plug and meniscal tissue and the participation of alpha-smooth muscle actin-positive cells appear essential for integration of the plug into the adjacent meniscal tissue. Cells in the superficial zone of the meniscus seem to be active in the repair process. A change in both the phenotype of the cells and the quality of the matrix toward a more hyaline state appears to be an integral part of the remodeling process in the meniscus.

Matrix protein mRNA levels in canine meniscus cells in vitro.

The resident cells of the meniscus synthesize a fibrocartilaginous extracellular matrix in vivo composed predominantly of type I collagen fibers. To increase our understanding of matrix biosynthesis by meniscus cells in vitro, we examined matrix protein mRNA levels in cultured meniscus cells isolated from skeletally mature dogs. The mRNA levels of five matrix protein genes (COL1A1, COL2A1, aggrecan, COL6A1, and fibronectin) were measured in meniscus cells by Northern blotting and compared with those of patellar tendon fibroblasts and femoral articular cartilage chondrocytes. In freshly isolated cells (Day 0 cells), COL1A1, COL2A1, and aggrecan mRNA levels were low or undetectable in both meniscus cells and tendon fibroblasts. In intact meniscus tissue, COL1A1 mRNA levels were also low or undetectable. COL2A1 and aggrecan mRNA transcripts were readily observed, however, in Day 0 articular chondrocytes. The levels of expression of COL6A1 and fibronectin mRNA transcripts in Day 0 meniscus cells were intermediate between higher articular chondrocyte levels and lower tendon fibroblast levels. After 1 week in monolayer culture (Day 7 cells), meniscus cells expressed readily detectable levels of COL1A1 mRNA transcripts, similar to that observed for cultured tendon fibroblasts. COL1A1 mRNA transcripts were either not detected or detected at very low levels in monolayer cultures of articular chondrocytes. COL2A1 and aggrecan mRNA transcripts were readily detected in cultured articular chondrocytes but not in meniscus cells or in tendon fibroblasts. All three types of cells continued to express COL6A1 and fibronectin mRNA transcripts after 1 week in culture. These results demonstrate that the patterns of expression of COL1A1 and COL2A1 mRNA transcripts by meniscus cells are similar to those of tendon fibroblasts and dissimilar to those of articular chondrocytes both in freshly isolated cells and in monolayer cultured cells. This mRNA expression pattern supports the idea that monolayer culture of meniscus cells results in the expression of a predominantly fibroblastic phenotype.

Attachment of articular cartilage chondrocytes to the tissue form of type VI collagen.

Type VI collagen is composed of a short triple helix rich in RGD sequences with globular domains at each extremity of the helix. Disulfide-bonded tetramers of the monomeric molecule associate non-covalently to form networks of microfibrils in connective tissues, including cartilage. The disulfide-bonded tetramer can be extracted with 6 M guanidine HCl and purified without pepsin digestion and is referred to here as the tissue form of type VI collagen. Type VI collagen in mature articular cartilage appears to be concentrated pericellularly. We undertook a systematic investigation using solid phase assays to establish the nature of the attachment of bovine articular cartilage chondrocytes to the intact, tissue form of bovine type VI collagen. The tissue form of type VI collagen was extracted from bovine meniscus cartilage with 6 M guanidine HCl and purified by polyethylene glycol precipitation. When equal molar quantities were coated on microwells, the tissue form of type VI collagen attached more cells than the pepsin-digested form of the molecule that lacked the globular domains. The attachment to the intact, tissue form was dose-dependent and saturable and was not inhibited by heparin or type II collagen. A linear GRGDSP peptide failed to inhibit attachment of the chondrocytes to the intact, tissue or pepsin-digested forms of type VI collagen, but totally inhibited the interaction when the intact molecule was reduced and alkylated. In contrast, a cyclic C*GRGDSPC* peptide inhibited attachment to the tissue form of type VI collagen, but not to fibronectin. The attachment had a metal ion dependence that could be satisfied by MnCl2, slightly less by MgCl2, but not at all by CaCl2. A direct interaction between the tissue form of type VI collagen and a chondrocyte cell surface receptor or receptors is a structural feature of the pericellular matrix in cartilage.

Thrombospondin 1 binds to the surface of bovine articular chondrocytes by a linear RGD-dependent mechanism.

Thrombospondin 1 is present in articular cartilage and is synthesized by chondrocytes. Adult bovine articular chondrocytes in serum-free medium were evaluated in a solid-phase assay for their ability to attach to thrombospondin 1 isolated from human platelets. The chondrocytes attached to the thrombospondin 1 by a mechanism that was inhibited by a synthetic linear GRGDSP but not a GRGESP peptide. The cells, however, did not spread on thrombospondin 1, but did spread on fibronectin and Pep-Tite 2000, a synthetic RGD-containing peptide. Preincubation of thrombospondin 1 with EDTA irreversibly inhibited its capacity to attach to chondrocytes. We conclude that thrombospondin 1 binds to chondrocytes by its RGD sequence.

Role of heparan sulfate in the terminal differentiation of growth plate chondrocytes.

Recent studies have demonstrated that basic fibroblast growth factor (bFGF) plays a key role in the terminal differentiation of growth plate chondrocytes during endochondral ossification. In this paper we examined the potential role of heparan sulfate in the regulation of the action of basic fibroblast growth factor (bFGF) in the terminal differentiation of rat growth plate chondrocytes. As rat growth plate chondrocytes differentiate in vitro, the percentage of heparitinase-sensitive material decreases. Treatment of growth plate chondrocytes with sodium chlorate, a reversible inhibitor of glycosaminoglycan sulfation, resulted in terminal differentiation of growth plate chondrocytes even in the presence of bFGF at concentrations that normally repress their differentiation. Chlorate treatment in the presence of bFGF resulted in an increase in alkaline phosphatase activity and a decrease in cellular proliferation, both characteristics of the differentiated state. Chlorate treatment also reduced the binding of bFGF to growth plate chondrocytes and this effect could be reversed in a dose-dependent manner by the simultaneous addition of sodium sulfate. The reduced binding was a function of a reduced number of receptors and not a reduced affinity for the receptor. Pretreatment of the growth plate chondrocytes with heparitinase significantly reduced the binding of bFGF to both low- and high-affinity receptors, while pretreatment with chondroitinase ABC had no effect. Finally, addition of exogenous heparin restored bFGF binding to chlorate-treated chondrocytes in a concentration-dependent manner. These results provide evidence that a cell surface heparan sulfate is involved in the binding of bFGF to high-affinity receptors and that a downregulation of this glycosaminoglycan is part of the pathway that leads to terminal differentiation of growth plate chondrocytes.

Comparison of collagen synthesis in the peripheral and central region of the canine meniscus.

A comparison of collagen synthesis in the peripheral and central regions of the normal medial meniscus, the normal lateral meniscus, and the medial meniscus, three months after reconstruction of the anterior cruciate ligament (ACL), was performed in a canine model. Triangular-shaped explants were labeled in vitro with tritiated proline to compare collagen synthesis. Regional cellularity was also quantified. In the normal medial and lateral meniscus, cellularity was similar. Total collagen synthesis, as assessed by collagenase digestible material, was significantly elevated in the peripheral one-third of the medial meniscus versus the central region (paired t-test, p = 0.026). However, in the medial meniscus after ACL reconstruction, cellularity and total collagen synthesis were significantly higher in the peripheral one-third versus the contiguous central region. They were also elevated relative to the peripheral and central region of the normal medial and lateral meniscus (ANOVA, p < 0.05; Student-Neuman-Kuel test, p < 0.05). Thus, in the normal medial meniscus, the peripheral one-third may have an increased healing potential based on its increased ability to synthesize collagen. Furthermore, after ACL reconstruction, only the peripheral, and not the central, region of the canine meniscus responds to the altered mechanical and synovial environment by significantly increasing cellularity and collagen synthesis.

Basic fibroblast growth factor binds to heparan sulfate in the extracellular matrix of rat growth plate chondrocytes.

Recent studies have demonstrated that basic fibroblast growth factor (bFGF) plays a key role in the terminal differentiation of growth plate chondrocytes during endochondral ossification. We therefore examined the binding of [125I]bFGF to an extract of extracellular matrix (ECM) of rat growth plate. Using a solid phase binding assay, binding of [125I]bFGF to ECM was demonstrated to be specific and saturable at 0.5-1 microgram/ml of bFGF. Scatchard analysis demonstrated the presence of a single class of binding sites with an apparent Kd of 14 nM. The binding of [125I]bFGF to rat growth plate ECM was inhibited by the addition of heparin, heparan sulfate, and dermatan sulfate. The binding was reversible as these glycosaminoglycans were also effective at displacement of bound [125I]bFGF from rat growth plate ECM. Chondroitin 4- or 6-sulfate had no effect on either binding or displacement when added at the same concentrations. Preincubation of the rat growth plate ECM with heparinase or heparitinase resulted in a reduction of the binding of [125I]bFGF to the ECM. Furthermore, these enzymes were able to significantly displace bound growth factor. In contrast, chondroitinase ABC or AC failed to displace bound [125I]bFGF from the ECM. Similar results were obtained when matrix derived from rat growth plate tissue was used for the binding studies. The results demonstrate that bFGF binds to a heparan sulfate in matrix produced by rat growth plate chondrocytes and matrix extracted from rat growth plate and suggest that this glycosaminoglycan may serve as a storage depot for this growth factor during endochondral ossification.

Meniscal transplantation using fresh and cryopreserved allografts. An experimental study in goats.

A comparative study of three subgroups of meniscal transplants was undertaken in the goat model: Group 1 (autograft) involved removal and immediate reimplantation of the meniscus; Group 2, fresh meniscal allografts; and Group 3, cryopreserved (30 days) meniscal allografts. Six months after surgery, tissues were evaluated for gross degenerative changes, proteoglycan concentration (as assessed by uronic acid), water content, vascularity, histology, and cell viability. The contralateral knee served as control for all comparisons. There was no statistical difference in the amount of arthritis present and all transplants demonstrated an essentially normal peripheral vascularity compared to controls. Sections revealed reduced numbers of cells in the central portions of the transplanted menisci and these viable cells demonstrated different behavior in multiplication in tissue culture compared to contralateral controls. Grossly and microscopically, the implanted menisci differed little from the controls. The measurement of proteoglycan concentration and water content of the transplanted meniscal cartilage suggest alterations that may affect the long-term mechanical properties. The autograft specimens showed the water content was very slightly increased (3% to 6%), while the proteoglycan concentration was increased (42% in terms of uronic acid). In contrast, the water content of the fresh allograft group and the cryopreserved group was increased 12% to 24%. Proteoglycan concentration in these groups was decreased up to 56% in portions of some menisci compared to controls. Fresh and cryopreserved meniscal allografts showed peripheral healing, revascularization, cellularity, and incorporation, and grossly appeared good at 6 months in the goat model. The biochemical changes in the extracellular matrix at 6 months raises questions on the long-term function of these transplanted menisci.

Interaction of intact type VI collagen with hyaluronan.

The capacity of non-pepsinyzed type VI collagen to bind to hyaluronan was investigated. Type VI collagen was extracted from bovine meniscal cartilage with 6 M GuHCl and purified by extraction of PEG precipitates and dissociative Sephacryl S-500 HR chromatography. Type VI collagen, detected with a monoclonal antibody, bound in 0.5 M NaCl to hyaluronan-coated micro-wells, the degree of binding being higher at 37 degrees C than 23 degrees C and 4 degrees C. Incubation of type VI collagen in competitive inhibition assays with testicular hyaluronidase digests of hyaluronan in liquid phase, reduced binding of the protein to hyaluronan-coated microwells to background levels. Thus, non-pepsinyzed type VI collagen binds to hyaluronan in vitro.

Thrombospondin in ligament, meniscus and intervertebral disc.

The presence of thrombospondin in extracts of ligament, meniscus and human nucleus pulposus was demonstrated by Western blot analysis using an anti-human thrombospondin antibody. Metabolic labeling of ligament fibroblast and meniscal fibrochondrocyte cultures followed by immunoprecipitation with anti-human thrombospondin revealed a single band corresponding to the molecular weight of thrombospondin when analyzed by SDS-PAGE and fluorography under reduced and non-reduced conditions. Thrombospondin, therefore, is a matrix constituent of ligament, knee joint meniscus and the nucleus pulposus and is synthesized by ligament fibroblasts and meniscal fibrochondrocytes in vitro.

A quantitative microwell assay for chondrocyte cell adhesion.

An assay for measuring the quantity of live articular chondrocytes attached to a substratum in microwell plates was established by measuring the absorbance of the blue formazan product generated from the dye 3-(4,5-dimethylthiazol-2-yl)-2,5-dypenyl tetrazolium bromide (MTT). Blue formazan production was optimal at an MTT concentration of 1 mg/ml (100 microliters per microwell) and an incubation period of 3 h. The absorbance of the dye was linearly related to the quantity of cells added per microwell. The number of live chondrocytes attached to adhesive proteins can be quantitated using this technique.

Meniscal replacement using a cryopreserved allograft. An experimental study in the dog.

The medial menisci of 14 adult dogs were replaced using a cryopreserved meniscal allograft. The morphology and metabolic activity of the transplanted allografts were then evaluated using routine histology, a vascular-injection (Spalteholz) technique, and autoroentgenography (Na2(35)SO4 incorporation) at various intervals, from two weeks to six months postoperatively. After transplantation, the allografts retained their normal gross appearance and healed to the capsular tissues of the host by fibrovascular scar tissue. Histologically, the grafts demonstrated a decrease in the number of metabolically active cells after transplantation but had a normal cellular distribution and Na2(35)SO4 uptake by three months. The allografts appeared to function normally after transplantation. Although some degenerative changes were noted in the tibial articular cartilage not covered by the meniscus, the cartilage beneath the allograft appeared normal.

The ultrastructure and biochemistry of meniscal cartilage.

The meniscus is characterized at the light microscopic and ultrastructural levels by thick collagen fibers that are predominantly circumferential in orientation. The extracellular matrix of the meniscus is composed mainly of collagen, with smaller quantities of proteoglycans, matrix glycoproteins, and elastin. The collagen is predominantly Type I, with smaller quantities of Types II, III, and V. The proteoglycans are mainly large, aggregating proteoglycans with chondroitin sulfate as their dominant glycosaminoglycan. A small proportion of small dermatan sulfate proteoglycans is probably present. The matrix glycoproteins include the link proteins, the 116-k protein, and a group of adhesive or potentially adhesive proteins that includes Type VI collagen (here classified as a glycoprotein with a collagenous domain), fibronectin, and thrombospondin. The fibrochondrocytes of the meniscus appear to have considerable potential to respond to growth and other modulating factors in the repair or regeneration of the tissue.

Cigarette smoke degrades hyaluronic acid.

Cigarette smoke has been implicated in the pathogenesis of a variety of diseases that affect connective tissues. The effect of the gas phase of cigarette smoke on hyaluronic acid was investigated in vitro. The smoke markedly reduced the chain length of purified hyaluronic acid as assessed by both viscometry and gel chromatography. The hyaluronate exposed to smoke, nevertheless, could aggregate proteoglycans, although the viscosity of the aggregates was lower than in those formed with the unexposed material. The degradation of the hyaluronate was a rapid phenomenon and was inhibited by dimethylsulfoxide, a known scavenger of hydroxyl radicals. We conclude that free radicals in the gas phase of cigarette smoke degrade hyaluronic acid in vitro.

Cartilage content of an immature dog.

The near total mineral-free and elastin-free cartilage content of a three-month-old mongrel dog was 0.73% of the dry body weight. Extraarticular (costal, tracheobronchial, thyroid, cricoid, nasal septum) cartilage constituted 0.44%; articular, 0.06; intervertebral disc, 0.10; elastic, 0.12 and meniscal fibrocartilage, 0.01%. Articular tissue accounted for only 7.25% of the total cartilage uronic acid. This is the first estimate of the amount and distribution of cartilage in a vertebrate species.