Decision tree analysis as a supplementary tool to enhance histomorphological differentiation when distinguishing human from non-human cranial bone in both burnt and unburnt states: A feasibility study.

This feasibility study was undertaken to describe and record the histological characteristics of burnt and unburnt cranial bone fragments from human and non-human bones. Reference series of fully mineralized, transverse sections of cranial bone, from all variables and specimen states, were prepared by manual cutting and semi-automated grinding and polishing methods. A photomicrograph catalogue reflecting differences in burnt and unburnt bone from human and non-humans was recorded and qualitative analysis was performed using an established classification system based on primary bone characteristics. The histomorphology associated with human and non-human samples was, for the main part, preserved following burning at high temperature. Clearly, fibro-lamellar complex tissue subtypes, such as plexiform or laminar primary bone, were only present in non-human bones. A decision tree analysis based on histological features provided a definitive identification key for distinguishing human from non-human bone, with an accuracy of 100%. The decision tree for samples where burning was unknown was 96% accurate, and multi-step classification to taxon was possible with 100% accuracy. The results of this feasibility study strongly suggest that histology remains a viable alternative technique if fragments of cranial bone require forensic examination in both burnt and unburnt states. The decision tree analysis may provide an additional but vital tool to enhance data interpretation. Further studies are needed to assess variation in histomorphology taking into account other cranial bones, ontogeny, species and burning conditions.

Interleukin-1ß enhances cartilage-to-cartilage integration.

The failure of cartilages to fuse, particularly in the case of articular cartilage under conditions of repair is due to morphological and structural constraints of the tissue. Factors that impede integration include, non-vascularisation, low cellularity, and proteoglycan in the surrounding extracellular matrix acting as a natural barrier to cellular migration. We hypothesised that brief activation of a catabolic cascade by cytokines followed by culture under anabolic conditions would promote tissue fusion in a ring-disk model of cartilage integration. Our results show that transient exposure to 10 ng mL(-1) interleukin-1ß, followed by two weeks post-culture under anabolic conditions, enhanced cartilage-cartilage integration compared to untreated explants. Quantitative PCR analysis of catabolism-related genes ADAMTS4 and MMP13 showed both were transiently upregulated and these findings correlated with evidence of extracellular matrix remodelling. At the level of histology, we observed chondrocytes readily populated the interfacial matrix between fused explants in interleukin-1ß treated explants, whereas in control explants this region was relatively acellular in comparison. Catabolic cytokine treated explants exhibited 29-fold greater adhesive strength (0.859 MPa versus 0.028 MPa, P 〈 0.05) than untreated counterparts. Collectively, our results demonstrate that a single short catabolic pulse followed by an anabolic response is sufficient to generate mechanically robust, integrative cartilage repair.

Cartilage integration: evaluation of the reasons for failure of integration during cartilage repair. A review.

Articular cartilage is a challenging tissue to reconstruct or replace principally because of its avascular nature; large chondral lesions in the tissue do not spontaneously heal. Where lesions do penetrate the bony subchondral plate, formation of hematomas and the migration of mesenchymal stem cells provide an inferior and transient fibrocartilagenous replacement for hyaline cartilage. To circumvent the poor intrinsic reparative response of articular cartilage several surgical techniques based on tissue transplantation have emerged. One characteristic shared by intrinsic reparative processes and the new surgical therapies is an apparent lack of lateral integration of repair or graft tissue with the host cartilage that can lead to poor prognosis. Many factors have been cited as impeding cartilage:cartilage integration including; chondrocyte cell death, chondrocyte dedifferentiation, the nature of the collagenous and proteoglycan networks that constitute the extracellular matrix, the type of biomaterial scaffold employed in repair and the origin of the cells used to repopulate the defect or lesion. This review addresses the principal intrinsic and extrinsic factors that impede integration and describe how manipulation of these factors using a host of strategies can positively influence cartilage integration.

Complement activation in the human brain after traumatic head injury.

The complement cascade has been suggested to be involved in the development of secondary brain injuries following brain contusions, based on animal experiments. The aim of the present study was to examine the possible involvement of the complement cascade following traumatic head injury in the human brain. Sixteen patients were included in this study, 12-77 years of age, treated at the neurointensive care unit for traumatic brain contusions. All of these patients were operated with frontal or temporal lobe resection due to intractable intracranial hypertension. The resected tissue was analyzed with regard to components related to complement activation. The time interval between accident and operation was 2-82 h. Brain tissue from three patients operated with hippocampectomy due to epilepsy, including temporal lobe resection, were used as controls. We found increased immunoreactivity for complement components C1q, C3b, and C3d and the membrane attack complex (MAC), C5b-9, in the immediate vicinity of neurons in the penumbra area of the contusion. These findings constitute histological evidence for activation of the complement cascade in the penumbra of cortical contusions in the human brain. Using in situ hybridization, we also found C3-mRNA in the penumbra, suggesting a local synthesis of complement. Furthermore, upregulation of the endogenous complement regulator clusterin was found in some neurons in the same area. We suggest that unknown compounds in the debris from injured neurons or myelin breakdown products trigger complement activation, including formation of C5b-9. Activated complement components may stimulate accumulation of inflammatory cells and formation of brain edema, as well as having membrane destructive effects by the end product MAC, thereby being mediators in the development of secondary brain damage.

Spontaneous classical pathway activation and deficiency of membrane regulators render human neurons susceptible to complement lysis.

This study investigated the capacity of neurons and astrocytes to spontaneously activate the complement system and control activation by expressing complement regulators. Human fetal neurons spontaneously activated complement through the classical pathway in normal and immunoglobulin-deficient serum and C1q binding was noted on neurons but not on astrocytes. A strong staining for C4, C3b, iC3b neoepitope and C9 neoepitope was also found on neurons. More than 40% of human fetal neurons were lysed when exposed to normal human serum in the presence of a CD59-blocking antibody, whereas astrocytes were unaffected. Significant reduction in neuronal cell lysis was observed after the addition of soluble complement receptor 1 at 10 microg/ml. Fetal neurons were stained for CD59 and CD46 and were negative for CD55 and CD35. In contrast, fetal astrocytes were strongly stained for CD59, CD46, CD55, and were negative for CD35. This study demonstrates that human fetal neurons activate spontaneously the classical pathway of complement in an antibody-independent manner to assemble the cytolytic membrane attack complex on their membranes, whereas astrocytes are unaffected. One reason for the susceptibility of neurons to complement-mediated damage in vivo may reside in their poor capacity to control complement activation.

Increased complement biosynthesis by microglia and complement activation on neurons in Huntington's disease.

In this study complement activation and biosynthesis have been analysed in the brains of Huntington's disease (HD) (n = 9) and normal (n = 3) individuals. In HD striatum, neurons, myelin and astrocytes were strongly stained with antibodies to C1q, C4, C3, iC3b-neoepitope and C9-neoepitope. In contrast, no staining for complement components was found in the normal striatum. Marked astrogliosis and microgliosis were observed in all HD caudate and the internal capsule samples but not in normal brain. RT-PCR analysis and in-situ hybridisation were carried out to determine whether complement was synthesised locally by activated glial cells. By RT-PCR, we found that complement activators of the classical pathway C1q C chain, C1r, C4, C3, as well as the complement regulators, C1 inhibitor, clusterin, MCP, DAF, CD59, were all expressed constitutively and at much higher level in HD brains compared to normal brain. Complement anaphylatoxin receptor mRNAs (C5a receptor and C3a receptor) were strongly expressed in HD caudate. In general, we found that the level of complement mRNA in normal control brains was from 2 to 5 fold lower compared to HD striatum. Using in-situ hybridisation, we confirmed that C3 mRNA and C9 mRNA were expressed by reactive microglia in HD internal capsule. We propose that complement produced locally by reactive microglia is activated on the membranes of neurons, contributing to neuronal necrosis but also to proinflammatory activities. Complement opsonins (iC3b) and anaphylatoxins (C3a, C5a) may be involved in the recruitment and stimulation of glial cells and phagocytes bearing specific complement receptors.

Differential expression of individual complement regulators in the brain and choroid plexus.

Membrane bound regulators of complement (C) control the system at key points during activation. To determine whether C regulators were expressed in the central nervous system, temporal cortex, and choroid plexus, tissues from eight adult humans were obtained at postmortem and surgery. Tissue was taken fresh for total RNA isolation, snap freezing, or processing in paraffin wax for immunocytochemistry and in situ hybridization. Immunocytochemistry of temporal cortex using anti-CD59 stained microglia intensely; astrocytes and neurons weakly. Microglia were unequivocally stained with anti-membrane cofactor protein (MCP) whereas staining on astrocytes and neurons was weak. Decay accelerating factor (DAF) was strongly expressed by microglia but weakly by astrocytes. Neurons expressed neither DAF nor complement receptor 1 (CR1). CR1 was also absent on astrocytes and microglia. The choroid plexus epithelium revealed intense apical staining with antibodies to CD59, less strongly with anti-MCP and weakly with anti-DAF. CR1 was detected only on phagocytic Kolmer cells in the choroid plexus. Reverse transcriptase-polymerase chain reaction revealed CD59, MCP, and to a lesser degree, DAF mRNA both in the choroid plexus and temporal cortex. CR1 mRNA was detected in choroid plexus samples only. Digoxigenin-UTP-labeled riboprobes to all four membrane regulators were used for in situ hybridization. DAF, MCP, and CD59 mRNA were expressed by epithelial cells of the choroid plexus and CR1 mRNA was found only in Kolmer cells. In the temporal cortex, MCP and CD59 mRNA were expressed by glia and at low level by neurons, but DAF was not detected. Previous studies have suggested that C produced in inflamed brains in conditions such as Alzheimer's and Huntington's diseases can be specifically toxic to neurons. The demonstration herein that neurons express only very low levels of CD59 and MCP and lack both CR1 and DAF might explain their susceptibility to C damage.

Huntingtin protein colocalizes with lesions of neurodegenerative diseases: An investigation in Huntington's, Alzheimer's, and Pick's diseases.

Huntington's disease (HD) is an autosomal dominant neurodegenerative disease associated with a CAG trinucleotide repeat expansion in a large gene on chromosome 4. The gene encodes the protein huntingtin with a polyglutamine tract encoded by the CAG repeat at the N-terminus. The number of CAG repeats in HD are significantly increased (36 to 120+) compared with the normal population (8-39). The pathological mechanism associated with the expanded CAG repeat in HD is not clear but there is evidence that polyglutamine is directly neurotoxic. We have immunolocalized huntingtin with an in-house, well-characterised, polyclonal antibody in HD, Alzheimer's disease (AD), and Picks disease (PiD) brains. Control brain tissue sections were from head injured and cerebral ischaemia cases. In HD, huntingtin was immunopositive in the surviving but damaged neurons and reactive astrocytes of the caudate and putamen. However, in AD and PiD the immunostaining was largely restricted to the characteristic intracellular inclusion bodies associated with the disease process in each case. In AD, huntingtin was localized only in the intracellular neurofibrillary tangles and dystrophic neurites within the neuritic amyloid plaques but not with the amyloid. In PiD, strongly positive huntingtin immunostaining was present within cytoplasmic Pick bodies. Our findings suggest huntingtin selectively accumulates in association with abnormal intracytoplasmic and cytoskeletal filaments of neurons and glia in neurodegenerative diseases such as HD, AD, and PiD. Cells in the CNS appear sensitive to damage by the aggregated, toxic levels of huntingtin and evidence of its interaction with neurofilaments could provide information about its potential role in the aetiology of HD.

The receptor for complement anaphylatoxin C3a is expressed by myeloid cells and nonmyeloid cells in inflamed human central nervous system: analysis in multiple sclerosis and bacterial meningitis.

The complement anaphylatoxins C5a and C3a are released at the inflammatory site, where they contribute to the recruitment and activation of leukocytes and the activation of resident cells. The distribution of the receptor for C5a (C5aR) has been well studied; however, the receptor for C3a (C3aR) has only recently been cloned, and its distribution is uncharacterized. Using a specific affinity-purified anti-C3aR peptide Ab and oligonucleotides for reverse transcriptase-PCR analysis, C3aR expression was characterized in vitro on myeloid and nonmyeloid cells and in vivo in the brain. C3aR was expressed by adult astrocytes, astrocyte cell lines, monocyte lines THP1 and U937, neutrophils, and monocytes, but not by K562 or Ramos. C3aR staining was confirmed by flow cytometry, confocal imaging, and electron microscopy analysis. A 65-kDa protein was immunoprecipitated by the anti-C3aR from astrocyte and monocyte cell lysates. Our results at the protein level were confirmed at the mRNA level. Using reverse transcriptase-PCR, Southern blot, and sequencing we found that C3aR mRNA was expressed by fetal astrocytes, astrocyte cell lines, and THP1, but not by K562 or Ramos. The astrocyte C3aR cDNA was identical with the reported C3aR cDNA. C3aR expression was not detected in normal brain sections. However, a strong C3aR staining was evident in areas of inflammation in multiple sclerosis and bacterial meningitis. In meningitis, C3aR was abundantly expressed by reactive astrocytes, microglia, and infiltrating cells (macrophages and neutrophils). In multiple sclerosis, infiltrating lymphocytes did not express C3aR, but a strong staining was detected on smooth muscle cells (pericytes) surrounding blood vessels.

Identification of an astrocyte cell population from human brain that expresses perforin, a cytotoxic protein implicated in immune defense.

The brain is an immunoprivileged organ isolated from the peripheral immune system. However, it has been shown that resident cells, notably astrocytes and microglia, can express numerous innate immune molecules, providing the capacity to generate a local antipathogen system. Perforin is a cytolytic protein present in the granules of cytotoxic T lymphocytes and natural killer cells. Expression in cells other than those of the hemopoetic lineage has not been described. We report here that fetal astrocytes in culture (passages 2 to 15), astrocytoma, and adult astrocytes expressed perforin. Reverse transcriptase polymerase chain reaction followed by Southern blot was carried out using multiple specific primers and all cDNAs were cloned and sequenced. Human fetal astrocyte perforin cDNA sequence was approximately 100% identical to the reported perforin cDNA cloned from T cells. Western blot analysis using monoclonal and polyclonal antiperforin peptide antibodies revealed a protein of 65 kD in both human fetal astrocyte and rat natural killer cell lysates (n = 4). Immunostaining followed by FACS(R) and confocal and electron microscopy analysis revealed that perforin was expressed by 40-50% of glial fibrillary acidic protein positive cells present in the fetal brain culture (n = 11). Perforin was not localized to granules in astrocytes but was present throughout the cytoplasm, probably in association with the endoplasmic reticulum. Perforin was not detected in normal adult brain tissue but was present in and around areas of inflammation (white and grey matter) in multiple sclerosis and neurodegenerative brains. Perforin-positive cells were identified as reactive astrocytes. These findings demonstrate that perforin expression is not unique to lymphoid cells and suggest that perforin produced by a subpopulation of astrocytes plays a role in inflammation in the brain.

Regulation of desmosomal cell adhesion in human tumour cells by polyunsaturated fatty acids.

Desmosomes are key structures in cell-cell adhesion. In this study we examined the effect of n-6 essential fatty acids on the expression of desmoglein (Dsg), desmosomal cadherin and the formation of desmosomes in E-cadherin negative human breast, colon and lung cancer cells and melanoma cells. Electron microscopy revealed that cells cultured with gamma linolenic acid (GLA) showed increased cell-cell adhesion together with an increase in the formation of desmoglein-containing desmosomes. Western blotting studies of cellular proteins demonstrated that, following culture with fatty acids, Dsg expression was modified, with the greatest increase seen after GLA treatment. Other fatty acids increased Dsg expression, but to a lesser extent. It is concluded that GLA regulates desmosome-mediated cell-cell adhesion in human cancer cells, particularly in cells without E-cadherin.

A biochemical and immuno-electron microscopical analysis of chondroitin sulphate-rich proteoglycans in human alveolar bone.

This study used biochemical and immunohistochemical methods to characterize the chondroitin sulphate-rich proteoglycans from human alveolar bone obtained from an oral source. Proteoglycans were extracted from bone by a sequential 4 M guanidine HCl extraction process, and purified by DEAE-ion exchange chromatography. SDS-PAGE and Western blot analysis, using CS-56 monoclonal antibody, demonstrated one major proteoglycan species with a core protein of 58 kDa, glycosaminoglycan chains of 45-66 kDa and a mean molecular weight of 205 kDa. This work confirmed the biochemistry of chondroitin sulphate-rich proteoglycans from a novel source of adult human alveolar bone, and pointed towards a proteoglycan with a high glutamate, glycine, aspartate, alanine, serine and leucine content. Sections of alveolar bone were embedded in LR White resin, labelled with CS-56 antibody and examined with the light and electron microscopes. At the light microscope level, labelling was restricted to the osteocyte lacunae and canaliculi. Ultrastructural observations showed that the labelling was localized to fine filamentous material in the walls of the osteocytes and canaliculi. Sparse labelling was associated with the collagen fibres immediately subjacent to the lamina limitans, but no labelling of the mineralized matrix was observed. These findings also indicated subtle differences in the distribution of chondroitin sulphate compared with previously reported work, which may indicate species or age differences in the samples used in this study. Ultrastructural analysis confirmed and extended observations of glycosaminoglycan localization at the osteocyte cell membrane of mature human alveolar bone.

Role of complement in inflammation and injury in the nervous system.

The complement (C) system plays important roles in host defence but activation at inappropriate sites or to an excessive degree can cause host tissue damage. C has been implicated as a factor in the causation or propagation of tissue injury in numerous diseases. The brain is an immunologically isolated site, sheltered from circulating cells and proteins of the immune system; nevertheless, there is a growing body of evidence implicating C in numerous brain diseases. In this brief article we review the evidence suggesting a role for C in diseases of the central and peripheral nervous system and discuss the possible sources of C at these sites. Some brain cells synthesise C and also express specific receptors; some are exquisitely sensitive to the lytic effects of C. The evidence suggests that C synthesis and activation in the brain are important in immune defence at this site but may also play a role in brain disease.

Expression of the receptor for complement C5a (CD88) is up-regulated on reactive astrocytes, microglia, and endothelial cells in the inflamed human central nervous system.

C5a receptor (C5aR, CD88) is a receptor originally described on neutrophils and monocyte-macrophages but recently found on hepatocytes, epithelial cells, endothelial cells, and tissue mast cells. We recently reported that human fetal astrocytes expressed a functional C5aR in vitro. Here we examine C5aR expression in adult brain cultures by immunostaining with six different anti-C5aRs and show that C5aR is expressed constitutively by astrocytes, microglia, and fibroblast-like cells but not by oligodendrocytes. In fetal brain cultures we confirmed that astrocytes constitutively expressed C5aR and demonstrated that fetal microglia and fibroblast-like cells but not oligodendrocytes and neurones expressed C5aR. Incubation with inflammatory cytokines (interferon gamma, interleukin-1, and tumor necrosis factor alpha) or phorbol ester failed to induce or up-regulate C5aR expression on fetal or adult brain cells. Immunohistochemistry was performed to determine the expression and distribution of C5aR in the normal and inflamed brain. In the normal brain C5aR was minimally expressed, whereas in inflamed brains from a variety of pathologies, C5aR expression was greatly up-regulated on reactive astrocytes and microglia and to a lesser extent on endothelial cells. We propose that expression of C5aR is a marker of central nervous system inflammation, and that C5aR expression on brain cells in inflammation plays an important role in cell activation and recruitment (gliosis).

Immunocytochemically detectable metallothionein is expressed by astrocytes in the ischaemic human brain.

The metallothioneins in vitro are both effective free radical and transitional metal ion scavengers. For this reason we investigated the expression of this protein in the normal CNS and after ischaemia using a monoclonal anti-metallothionein antibody to metallothionein isoforms I and II. Using immunohistochemistry and confocal laser scanning microscopy, we found anti-GFAP and anti-metallothionein were co-localized in astrocytes at the edges of infarcts. Energy dispersive X-ray microanalysis demonstrated high levels of copper and iron in the metallothionein positive reactive astrocytes. On the basis of the in vitro properties of these proteins, the functional importance of metallothionein in reactive astrocytes could be as a free radical scavenger and metal ion chelator.

Role of complement in the aetiology of Pick's disease?

Complement in the postmortem brains of 15 cases of Pick's disease has been widely analyzed immunohistochemically and, in 2 cases, by immunoelectron microscopy. Astrocytes and the Pick bodies and cytoplasm of ballooned neurons were immunoreactive with antibodies to classical pathway components C1, C1q, C4, C2 and C3 and the terminal complex components C5, C6 and C8. In almost all cases, no immunostaining was obtained with antibodies against C9 and neoepitopes in the membrane attack complex (MAC), the complement complex responsible for cytotoxicity. However, unequivocal staining with antibodies to two soluble complement regulatory proteins, S-protein and clusterin, and to the membrane complement inhibitor CD59 was found, although three other membrane inhibitors, CR1(CD35), DAF (CD55), and MCP (CD46), were not detected. The complement immunoreactivity of astrocytes and neurons could be the result of complement biosynthesis or attack. Complement attack will be restricted by the expressed regulatory proteins. However, neurons may be the victims of attack since they show pathological change. The internalization of complement-attacked membrane, perhaps involving the genesis of Pick bodies and ballooning, may explain the intracellular immunolocalization of complement in damaged neurons. Immunoglobulins, as a possible source of complement activation, were observed in only two cases, leaving unresolved the trigger for complement activation in the other cases.

Induction of tyrosine phosphorylation and translocation of ezrin by hepatocyte growth factor/scatter factor.

Ezrin is a member of the TERM family and is a key protein in cytoplasmic membrane-cytoskeleton interactions. This study showed that hepatocyte growth factor/scatter factor (HGF/SF), a cytokine known to regulate motility, morphogenesis and growth of cells, stimulated the tyrosine phosphorylation of ezrin in a human colon epithelial cell line, HT115. After HGF/SF stimulation, ezrin translocated from the cytosol and generalised membrane to the areas of ruffled membrane as visualised by indirect immunofluorescent and immunogold electron microscopy. This effect was inhibited by genistein, a tyrosine kinase inhibitor. It is concluded that HGF/SF induces ezrin translocation by stimulation of its tyrosine phosphorylation and that this plays a key role in HGF/SF induced membrane ruffling.

Inhibition of HGF/SF-induced membrane ruffling and cell motility by transient elevation of cytosolic free Ca2+.

HGF/SF (0.5-100 ng/ml) induced rapid membrane ruffling, formation of microspikes, and increased motility of HT115 cells within 5 min of addition. These effects were not accompanied by any change in cytosolic free Ca2+ concentration. However, ATP (0.5-10 mM) induced a transient rise in cytosolic free Ca2+ concentration in HT115 cells from a resting concentration of 100 nM to a peak of 400 nM before returning to baseline within 3 min. The addition of ATP to cells treated with HGF/SF inhibited both membrane ruffling and cell movement. The effect of ATP was attributed to the transient rise in cytosolic free Ca2+ concentration, because cytosolic BAPTA, which prevented the rise in cytosolic free Ca2+ concentration, also abolished the inhibitory effect of ATP. Raising cytosolic free Ca2+ concentration with ionomycin and ADP also inhibited membrane ruffling. It was thus concluded that transiently raised cytosolic free Ca2+ concentration inhibited HGF/SF-induced membrane ruffling of HT115 cells.