Showing papers in "Biochemical Society Transactions in 2002"

Stress granules: sites of mRNA triage that regulate mRNA stability and translatability.

Abstract: Mammalian stress granules (SGs) are cytoplasmic domains into which mRNAs are sorted dynamically in response to phosphorylation of eukaryotic initiation factor (eIF) 2α, a key regulatory step in translational initiation. The activation of one or more of the eIF2α kinases leads to SG assembly by decreasing the levels of eIF2-GTP-tRNA Met , the ternary complex that is normally required for loading the initiator methionine onto the 48 S preinitiation complex to begin translation. This stress-induced scarcity of eIF2-GTP-tRNA Met allows the RNA-binding proteins TIA-1 (T-cell internal antigen-1) and TIAR (TIA-1-related protein) to bind the 48 S complex in lieu of the ternary complex, thereby promoting polysome disassembly and the concurrent routing of the mRNA into a SG. The actual formation of SGs occurs upon auto-aggregation of the prion-like C-termini of TIA-1 proteins; this aggregation is reversed in vivo by overexpression of the heat-shock protein (HSP) chaperone HSP70. Remarkably, HSP70 mRNA is excluded from SGs and is preferentially translated during stress, indicating that the RNA composition of the SG is selective. Moreover, the effects of HSP70 on TIA aggregation suggest a feedback loop whereby HSP70 synthesis is auto-regulated. Proteins that promote mRNA stability [e.g. HuR (Hu protein R)] and destabilize mRNA [i.e. tristetraprolin (TTP)] are also recruited to SGs, suggesting that SGs effect a process of mRNA triage, by promoting polysome disassembly and routing mRNAs to cytoplasmic domains enriched for HuR and TTP. This model reveals connections between the eIF2α kinase system, mRNA stability and cellular chaperone levels.

Regulation of lipid accumulation in oleaginous micro-organisms.

Abstract: A small number of eukaryotic micro-organisms, the oleaginous species, can accumulate triacylglycerols as cellular storage lipids, sometimes up to 70% of the biomass. Some of these lipids, particularly those containing high proportions of polyunsaturated fatty acids of nutritional and dietary importance, are now in commercial production; these are known as single-cell oils. The biochemistry of lipid accumulation has been investigated in yeasts and filamentous fungi and can now be described in some detail: lipid accumulation is triggered by cells exhausting nitrogen from the culture medium, but glucose continues to be assimilated. Activity of isocitrate dehydrogenase within the mitochondrion, however, now slows or even stops due to the diminution of AMP within the cells. This leads to the accumulation of citrate, which is transported into the cytosol and cleaved to acetyl-CoA by ATP:citrate lyase, an enzyme that does not occur in non-oleaginous species. This enzyme is therefore essential for lipid accumulation. The presence of this enzyme does not, however, explain why different species of oleaginous micro-organisms have different capacities for lipid accumulation. The extent of lipid accumulation is considered to be controlled by the activity of malic enzyme (ME), which acts as the sole source of NADPH for fatty acid synthase (FAS). If ME is inhibited, or genetically disabled, then lipid accumulation is very low. There is no general pool of NADPH which can otherwise be used by FAS. The stability of ME is therefore crucial and it is proposed that ME is physically attached to FAS as part of the lipogenic metabolon. ME activity correlates closely with lipid accumulation in two filamentous fungi, Mucor circinelloides and Mortierella alpina. When ME ceases to be active, lipid accumulation also stops. No other enzyme activity shows such a correlation.

Regulation of mammalian acetyl-CoA carboxylase.

Abstract: Acetyl-CoA carboxylase (ACC) plays a critical role in the regulation of fatty acid metabolism and its two isoforms, ACCα and ACCβ, appear to have distinct functions in the control of fatty acid synthesis and fatty acid oxidation, respectively. They are regulated by similar short-term mechanisms of allosteric activation by citrate, and reversible phosphorylation and inactivation, and there is clearly interaction between these mechanisms. AMP-activated protein kinase is the important physiological ACC kinase for both isoforms and yet there is a potential physiological role for cAMP-dependent protein kinase in the hormonally mediated inactivation of ACCα, and phosphorylation of ACCβ in its unique N-terminus.

The role of the physicochemical environment in determining disc cell behaviour

Abstract: The cells of the intervertebral disc exist in an unusual environment. They are embedded in a dense matrix containing a high concentration of aggrecan whose fixed negative charges regulate the extracellular ionic composition and osmolarity; both extracellular cation concentrations and osmolarity are considerably higher than those experienced by most cell types. The disc also is avascular. Oxygen levels in the centre of the nucleus, where cells may be 6-8 mm from the blood supply, are very low. Since metabolism is mainly by glycolysis, lactic acid is produced at high rates and hence the pH is acidic. Finally, the disc is subjected to mechanical forces at all times; these vary with posture and activity. In particular, because the disc is under low loads during rest and high loads during the day's activities, it loses and regains around 25% of its fluid over a diurnal cycle with consequent changes to the concentrations of extracellular matrix macromolecules and ions and hence extracellular osmolality. Here we will briefly review these factors and discuss the influence of changes in the physicochemical environment on cellular activity, in particular on the rate at which disc cells synthesize and degrade matrix macromolecules.

The latex-fruit syndrome

Abstract: Approximately 30–50% of individuals who are allergic to natural rubber latex (NRL) show an associated hypersensitivity to some plant-derived foods, especially freshly consumed fruits. This association of latex allergy and allergy to plant-derived foods is called latex-fruit syndrome. An increasing number of plant sources, such as avocado, banana, chestnut, kiwi, peach, tomato, potato and bell pepper, have been associated with this syndrome. The prevailing hypothesis is that allergen cross-reactivity is due to IgE antibodies that recognize structurally similar epitopes on different proteins that are phylogenetically closely related or represent evolutionarily conserved structures. Several types of proteins have been identified to be involved in the latex-fruit syndrome. Two of these are plant defence proteins. Class I chitinases containing an N-terminal hevein-like domain cross-react with hevein (Hev b 6.02), a major IgE-binding allergen for patients allergic to NRL. A β-1,3-glucanase was identified as an important latex allergen which shows cross-reactivity with proteins of bell pepper. Another important NRL allergen, Hev b 7, is a patatin-like protein that shows cross-reactivity with its analogous protein in potato. Furthermore, patients with allergy to plant-derived foods and associated pollinosis show a high frequency of IgE reactivity to the pan-allergen profilin, which may cause positive serum IgE determinations to NRL. Although there is much information about the plant-derived foods and some data about the allergens involved in the latex-fruit syndrome, it is not always clear whether latex sensitization precedes or follows the onset of food allergy.

The role of proteoglycans in aging, degeneration and repair of the intervertebral disc.

Abstract: The ability of the nucleus pulposus of the intervertebral disc to resist compressive loads is due to its high content of the proteoglycan aggrecan. Degeneration of the intervertebral disc is preceded and accompanied by a loss of aggrecan due to proteolysis. Biological repair of intervertebral disc degeneration should strive to restore aggrecan content to its optimal functional level. One approach to such repair is to supplement the degenerate nucleus with cells that are capable of aggrecan synthesis. Such cells can be supported in a biomolecular scaffold, but it is essential that the scaffold is compatible with high aggrecan retention if a functional tissue is to be attained.

Engineering therapeutic antibodies for improved function.

Abstract: The binding sites on human IgG1 for human Fcγ receptor (FcγR) I, FcγRIIa, FcγRIIb, FcγRIIIa and neonatal FcR have been mapped. A common set of IgG1 residues is involved in binding to all FcγRs, while FcγRII and FcγRIII utilize distinct sites outside this common set. In addition to residues which abrogated binding to the FcγR, several positions were found which improved binding only to specific FcγRs or simultaneously improved binding to one type of FcγR and reduced binding to another type. Selected IgG1 variants with improved binding to FcγRIIIa were then tested in an in vitro antibody-dependent cellular cytotoxicity (ADCC) assay and showed an enhancement in ADCC when either peripheral blood mononuclear cells or natural killer cells were used.

Mechanistic diversity and regulation of Type II fatty acid synthesis.

Abstract: Fatty acid biosynthesis is catalysed in most bacteria by a group of highly conserved proteins known as the Type II fatty acid synthase (FAS) system. The Type II system organization is distinct from its mammalian counterpart and offers several unique sites for selective inhibition by antibacterial agents. There has been remarkable progress in the understanding of the genetics, biochemistry and regulation of Type II FASs. One important advance is the discovery of the interaction between the fatty acid degradation regulator, FadR, and the fatty acid biosynthesis regulator, FabR, in the transcriptional control of unsaturated fatty acid synthesis in Escherichia coli. The availability of genomic sequences and high-resolution protein crystal structures has expanded our understanding of Type II FASs beyond the E. coli model system to a number of pathogens. The molecular diversity among the pathway enzymes is illustrated by the discovery of a new type of enoyl-reductase in Streptococcus pneumoniae [enoyl-acyl carrier protein (ACP) reductase II, FabK], the presence of two enoyl-reductases in Bacillus subtilis (enoyl-ACP reductases I and III, FabI and FabL), and the use of a new mechanism for unsaturated fatty acid formation in S. pneumoniae ( trans -2- cis -3-enoyl-ACP isomerase, FabM). The solution structure of ACP from Mycobacterium tuberculosis revealed features common to all ACPs, but its extended C-terminal domain may reflect a specific interaction with very-long-chain intermediates.

Cytochrome c maturation: a complex pathway for a simple task?

Abstract: Post-translational maturation of c-type cytochromes involves covalent attachment of haem to the apocytochrome polypeptide by two thioether bonds. In bacteria, haem attachment occurs in the periplasm, after the separate translocation of haem and the polypeptide across the cytoplasmic membrane. In Escherichia coli, delivery and attachment of the cofactor requires eight or nine specific proteins, which are believed to be organized in a membrane protein complex. After transport across the membrane, haem is attached covalently to the haem chaperone CcmE in an unusual way at a single histidine residue. However, haem binding to CcmE is transient and is succeeded by a further transfer to apocytochrome c. Both haem binding to and release from CcmE involve integral membrane proteins, CcmC and CcmF respectively, which carry a conserved tryptophan-rich motif in a periplasmic domain. Apocytochrome c polypeptides are synthesized as precursors and reach the periplasm by sec-dependent translocation. There they are prepared for haem binding by reduction of the cysteine residues in the motif Cys-Xaa-Xaa-Cys-His, which is characteristic of such proteins. This reduction is achieved in a thio-reduction pathway, whereby electrons are passed from cytoplasmic thioredoxin to the transmembrane protein DsbD, across the membrane, and on to the specific reductases CcmG/CcmH. The merging of the haem delivery and the thio-reduction pathways leads to the stereospecific insertion of haem into various type c cytochromes.

Disc morphology in health and disease.

Abstract: The morphology of the intervertebral disc is dependent on the type of components present and the manner in which they are assembled. This, in turn, will determine how the tissue carries out its primary physiological functions of load bearing and allowing movement in all directions of the otherwise rigid spine. The disc starts its life in an ordered fashion, with the outer annulus fibrosus consisting of a series of regular concentric bundles of collagen fibres around the central gelatinous nucleus pulposus. With advancing age there is increased complexity of lamellae, with more bifurcations, interdigitations and irregularity in number and size of lamellar bands, probably as a result of the disc cells' synthetic response to variations in incident loads. This change in organization itself will lead to altered load bearing, hence possibly establishing a self-perpetuating cycle of disruption to disc morphology, which, once started, may be irreversible. There are also alterations to cell organization with disease and degeneration. There may be increased cell number, with clusters of cells forming by cell proliferation, or increased cell death, whether by necrosis or apoptosis, in degenerate or deformed discs such as are found in spinal deformities; for example, scoliosis. Any change in cell number is likely to alter the nutritive requirements and concentration gradients of both nutrients and metabolites. The normally avascular disc in the healthy adult can become increasingly vascularized and innervated with degeneration and disease. This may lead to an increased supply of oxygen and nutrients to the disc, but can also introduce other cells types and molecules such as cytokines and growth factors.

Role of plasminogen activators in peritoneal adhesion formation

Abstract: Intra-abdominal adhesion formation is a major complication of serosal repair following surgery, ischaemia or infection, leading to conditions such as intestinal obstruction and infertility. It has been proposed that the persistence of fibrin, due to impaired plasminogen activator activity, results in the formation of adhesions between damaged serosal surfaces. This study aimed to assess the role of fibrinolysis in adhesion formation using mice deficient in either of the plasminogen activator proteases, tissue-type plasminogen activator (tPA) or urokinase-type plasminogen activator (uPA). We hypothesize that, following serosal injury, mice with decreased peritoneal fibrinolytic activity will be more susceptible to adhesion formation. Adhesion formation was induced in tPA- and uPA-deficient and wild-type mice following either surgical trauma to the serosa with haemorrhage and acute or chronic intraperitoneal inflammation. Adhesion formation was assessed from 1 to 4 weeks post-injury. Mice deficient in tPA were more susceptible to adhesion formation following both a surgical insult and a chronic inflammatory episode compared with uPA-deficient and wild-type mice. In addition, the time of maximal adhesion formation varied depending on the nature of the initial insult. It is proposed that the persistence of fibrin due to decreased tPA activity following surgery or chronic inflammation plays a major role in peritoneal adhesion formation.

Gene regulation of mammalian desaturases.

Abstract: Stearoyl-CoA desaturase (SCD) catalyses the synthesis of oleic acid (18:1, n -9), which is mostly esterified into triacylglycerols (TAGs) as an energy reserve. Delta-6 Desaturase (D6D) and Delta-5 desaturase (D5D) are the key enzymes for the synthesis of highly unsaturated fatty acids (HUFAs), such as arachidonic acid (20:4, n -6) and docosahexaenoic acid (22:6, n -3), that are incorporated in phospholipids (PLs) and perform essential physiological functions. Despite these different physiological roles of SCD and D6D/D5D, these desaturases share common regulatory features, including dependence of expression on insulin, suppression by HUFAs, and induction by peroxisome proliferators (PPs). A key regulator of desaturase gene expression is sterol-regulatory element binding protein-1c (SREBP-1c), which mediates transcriptional activation of the SCD and D6D genes by insulin and inhibition by HUFAs. Because HUFAs are poorly incorporated into TAGs, the primary role of SREBP-1c in liver may be monitoring and regulating fatty acid composition in PLs rather than the regulation of TAG synthesis. The induction of desaturases by PPs is enigmatic because the major effect of PPs is induction of fatty acid oxidation enzymes by activating PP-activated receptor-alpha (PPARa). To our knowledge, no other gene that is induced by both SREBP-1 and PP has been identified. It is yet to be determined whether PPARa mediates the process directly. Available data suggest that the induction of desaturases by PPs may be a compensatory response to an increased demand for unsaturated fatty acids because PPs increase fatty acid degradation and induce proliferation of peroxisomes.

Collagen polymorphisms of the intervertebral disc.

Abstract: The mechanical function and the collagen pheno-type of the disc are complex, each a hybrid of elements of ligament and cartilage. In detail, the collagen properties are unique. Collagens I and II provide the bulk of the tissue fabric interwoven in opposing radial concentration gradients. From analysis of isolated cross-linked peptides, some degree of commingling of these major fibrillar collagens occurs down to the molecular level. Collagens V, VI, IX, XI, XII and XIV all contribute to the matrix. Collagen IX is the short molecular form that lacks a non-collagenous (NC)4 domain, not the long form found in most hyaline cartilages. Protein sequence and reverse transcriptase-PCR analysis confirmed this was the result of expression from the alternative transcription start site, not proteolysis of the long form. In view of recent reports that common single nucleotide polymorphisms in COL9A2 and COL9A3 are linked to chronic sciatica associated with disc pathology, the specific interactions and role of collagen IX in disc tissue are important to define.

Formatting antibody fragments to mediate specific therapeutic functions.

Abstract: Monoclonal antibodies are increasingly being used as therapeutic agents in a wide range of indications, including oncology, inflammation and infectious disease. In most cases the basis of the therapeutic function is the high degree of specificity and affinity the antibody-based drug has for its target antigen. However, the mechanism of action (MOA), the way the drug takes advantage of this specificity to mediate a therapeutic effect, varies considerably from drug to drug. Three basic potential categories of MOAs exist: antagonists, agonists and specific delivery mechanisms to target an active function to a particular cell type. The latter functions include selective cell killing, based on Fc-mediated events, recruitment of effector cells, and drug or radioisotope delivery. The majority of these mechanisms are not necessarily optimally mediated by an IgG structure; clearly, in the case of antibody-dependent cellular cytotoxicity or complement-mediated lysis, Fc is required. However, Fab fragments (the fragment comprising one antigen-binding arm of the Y-shaped IgG molecule) can be formatted to mediate most mechanisms and have the advantage that valency and half-life can be controlled to simplify the drug and address only the mechanism required. Moreover, Fab fragments can be produced in microbial expression systems which address manufacturing issues such as scale of supply and cost of goods.

Bispecific antibodies targeting cancer cells.

Abstract: In recent years, antibody therapy has become a new treatment modality for tumour patients, although the majority of responses are only partial and not long lasting. Based on evidence that effector-cell-mediated mechanisms significantly contribute to antibody efficacy in vivo, several approaches are currently pursued to improve the interaction between Fc receptor-expressing effector cells and tumour target antigens. These approaches include application of Fc receptor-directed bispecific antibodies, which contain one specificity for a tumour-related antigen and another for a cytotoxic Fc receptor on immune effector cells. Thereby, bispecific antibodies selectively engage cytotoxic trigger molecules on killer cells, avoiding, for example, interaction with inhibitory Fc receptors. In vitro, chemically linked bispecific antibodies directed against the Fc gamma receptors Fc gamma RIII (CD16) and Fc gamma RI (CD64), and the Fc alpha receptor Fc alpha RI (CD89), were significantly more effective than conventional IgG antibodies. Recent animal studies confirmed the therapeutic potential of these constructs. However, results from clinical trials have been less promising so far and have revealed clear limitations of these molecules, such as short plasma half-lives compared with conventional antibodies. In this review, we briefly summarize the scientific background for bispecific antibodies, and describe the rationale for the generation of novel recombinant molecules. These constructs may allow us to more specifically tailor pharmacokinetic properties to the demands of clinical applications.

The role of disc cell heterogeneity in determining disc biochemistry: a speculation

Abstract: The nucleus pulposus is a key player in very early disc degeneration. In the young disc, by acting as a water-like fluid, as opposed to a solid, it resists compression and instantaneously distributes forces evenly in all directions to the inner annulus. The disc anlage notochordal cells contribute not only to how the disc develops, but also to the matrix of the young disc at a time when the nucleus is at its most fluid-like. In humans, the notochordal cells disappear early, when there is a transformation of the nucleus into a more solid cartilaginous tissue. In cell culture, the co-cultures of the notochordal cells and chondrocytic cells enhance proteoglycan synthesis by the opposite cell type due, at least partly, to soluble factors. The continued presence of notochordal cells in vivo may provide protection. In work by others, in vivo reinsertion of notochordal-rich nucleus pulposus in a damaged disc will delay annular degeneration. The notochordal cells in the nucleus may have a different phenotype from when they are in the notochord and they may go through a changing programme of expression critical to disc development and maintaining a fluid-like nucleus. Little is known about why, in many species, the notochordal cells die early during growth and only the chondrocytic cells persist. This area offers an interesting avenue of research that may lead to very early intervention in disc degeneration.

Mechanobiology of the intervertebral disc.

Abstract: Intervertebral disc degeneration has been linked in humans to extreme spinal loading regimens. However, mechanisms by which spinal force influences disc cellularity, morphology and consequently biomechanical function are unclear. To gain insight into mechanobiological interactions within the disc, we developed an in vivo murine tail-compression model. Results from this model demonstrate how deviations in spinal stress induce a cycle of altered cell function and morphology as the disc remodels to a new homoeostatic configuration.

Structure-function studies of the receptors for complement C1q.

Abstract: C1q is an essential component of the phylo-genetically ancient innate complement (C) system and is crucial to our natural ability to ward off infection and clear toxic cell debris (e.g. amyloid fibrils, apoptotic cells). Several candidate C1q receptors [C1q receptor for phagocytosis enhancement (C1qRp), complement receptor (CR) 1, calreticulin (CRT), binding protein for the globular head of C1q (gC1qbp)] have been described, and the aim of this review is to shed light on their structure-function relationships. One cell-surface molecule, C1qRp, has emerged as a defence collagen receptor for C1q, as well as mannose-binding lectin (MBL) and surfactant protein A. C1qRp (also known as the AA4 antigen in rodents) is the antigen recognized by a pro-adhesive monoclonal antibody called mNI-11 and antibodies against CD93, but recent results failed to confirm C1q binding activity. CR1 (CD35), a multifunctional receptor both in its ligand specificity and in its C regulation activities, is found on circulating monocytes and neutrophils, but the major site of expression is B-lymphocytes. As a receptor, CR1 binds to C1q, other C opsonins (C4b, C3b, iC3b) and MBL, and as such, has been involved in promoting phagocytosis. Several studies support a role for the cell surface receptor for the collagenous domains of C1q (cC1qR; also known as CRT). CRT belongs to the family of heat-shock proteins, the most abundant and ubiquitous soluble intracellular proteins. Though CRT does not have a transmembrane domain, it seems to mediate phagocytosis of the apoptotic cells through association with CD91. A 33 kDa protein interacts with the globular head of C1q and, logically, has been termed gC1qbp. This protein is located in mitochondria, suggesting that gC1 qbp is not a cell-surface receptor itself.

Cholesterol and Alzheimer's disease.

Abstract: Recent studies indicate that cholesterol plays an important part in the regulation of amyloid-β peptide (Aβ) production, with high cholesterol levels being linked to increased Aβ generation and deposition. The mechanisms underlying the role(s) of cholesterol are not fully understood at present, but from the evidence currently available, it appears that there are many different ways in which abnormalities in cholesterol metabolism can affect the development of Alzheimer’s disease (AD). Polymorphisms in genes involved in cholesterol catabolism and transport have been associated with an increased level of Aβ and are therefore potential risk factors for the disease. The best known of these genes is the apolipoprotein E gene (apoE), which encodes a protein involved in cholesterol transport. The existence of a particular allele of apoE, e4, is the major genetic risk factor known for late-onset AD. Other genes implicated include cholesterol 24-hydroxylase (Cyp46), the LDL receptor related protein (LRP), the cholesterol transporters ABCA1 and ABCA2, acyl-CoA:cholesterol acetyl transferase (ACAT), and the LDL receptor (LDLR).

Targeting anticomplement agents.

Abstract: Biological targeting is normally thought of as a process of specific direction of one molecule (the agent) to another (the target) in vivo. However, an addressive approach in which the agent is concentrated, first within the vasculature and then at a disease site containing one or more targets, may be more suitable for delivering therapeutic quantities of certain drugs. This approach has been applied to complement regulatory molecules expressed in recombinant soluble forms and attached post-translationally to highly soluble synthetic peptide derivatives comprising two addressin units, one with affinity for the membrane bilayer interior and the other for phospholipid headgroups. This combination conferred affinity for outer cell membranes in general, and areas of translocated acidic phospholipid in particular. Large increases in potency in cell-based antihaemolytic assays accompanied modification and were shown to be associated with membrane binding. Modified agents co-localized with glycosylphosphatidyl- inositol-anchored proteins in lipid rafts on cell membranes. One agent, a modified fragment of human complement receptor-1 (APT070), has been prepared on a large scale and has been shown to be an active anti-inflammatory agent when administered locally and systemically in animal models of vascular shock, rheumatoid arthritis and transplantation reperfusion injury. APT070 has been shown to be well tolerated in human subjects when given intravenously and is currently under study in rheumatoid arthritis patients to explore the therapeutic potential of localized complement inhibition in the synovial space.

The contrasting IgG-binding interactions of human and herpes simplex virus Fc receptors

Abstract: A virally encoded, high-affinity Fc receptor (FcR) is found on herpes simplex virus type 1 (HSV-1) particles and infected cells where its binding of non-immune IgG protects cells from host-mediated lysis. Whilst mutation or aglycosylation of the IgG CH2 domain reduced binding to human FcR, the interaction with HSV-1 FcR was not affected. However, the HSV-1 FcR, unlike human FcR, discriminates between human IgG1 allotypes, being sensitive to changes at positions 214 (CH1) and 356/358 (CH3), away from its proposed binding site at the CH2-CH3 interface. The biological consequences are not known but this is the first evidence of a major functional difference between IgG1 allotypes.

Elastic tissues of the intervertebral disc.

Abstract: Elastic fibres have been generally considered to play no significant role in the mechanical functioning of the intervertebral disc since earlier studies reported that the elastic fibre network was sparse and irregular. However, a recent study has reported that the network is highly organized and that the distribution and orientation of elastic fibres varies from region to region. In the annulus, elastic fibres appear densely distributed in the region between the lamellae and also in 'bridges' across the lamellae. They are also organized in the nucleus where long straight fibres are radially oriented and anchor perpendicularly or obliquely into the cartilaginous endplate. Immunohistochemistry using specific antibodies indicates that elastin is present in the network, as is fibrillin. Biochemical studies show, however, that the amino acid composition of the residue remaining after alkaline (NaOH) extraction or CNBr digestion contains a higher concentration of polar amino acids than ligamentum nuchal elastin. The composition of the residue suggests that disc elastin may cross-link strongly with some other matrix components. With such coupling, it is thought that elastic fibres could play a significant mechanical role even though overall elastin is less than 5% of the total dry weight of the disc.

Receptor component protein (RCP): a member of a multi-protein complex required for G-protein-coupled signal transduction.

Abstract: The calcitonin-gene-related peptide (CGRP) receptor component protein (RCP) is a 148-amino-acid intracellular protein that is required for G-protein-coupled signal transduction at receptors for the neuropeptide CGRP. RCP works in conjunction with two other proteins to constitute a functional CGRP receptor: calcitonin-receptor-like receptor (CRLR) and receptor-activity-modifying protein 1 (RAMP1).CRLR has the stereotypical seven-transmembrane topology of a G-protein-coupled receptor; it requires RAMP1 for trafficking to the cell surface and for ligand specificity, and requires RCP for coupling to the cellular signal transduction pathway. We have made cell lines that expressed an antisense construct of RCP and determined that CGRP-mediated signal transduction was reduced, while CGRP binding was unaffected. Furthermore, signalling at two other endogenous G-protein-coupled receptors was unaffected, suggesting that RCP was specific for a limited subset of receptors.

Sequential extracts of human bone show differing collagen synthetic rates

Abstract: Type I collagen is the major bone protein. Little is known quantitatively about human bone collagen synthesis in vivo , despite its importance for the understanding of bone formation and turnover. Our aim was to develop a method that could be used for the physiological and pathophysiological investigation of human bone collagen synthesis. We have carried out preliminary studies in patients undergoing hip replacement and in pigs to validate the use of the flooding dose method using 13 C- or 15 N-labelled proline and we have now refined our techniques to allow them to be used in a normal clinical or physiological setting. The results show that the application of a flooding dose causes bone free-proline labelling to equilibrate with that of blood in pigs and human beings, so that only 150 mg of bone will provide enough sample to prepare and measure the labelling of three fractions of bone collagen (dissolved in NaCl, acetic acid and pepsin/acetic acid) which have the same relative labelling (1.0:0.43:0.1) as measured by GC-combustion-isotope ratio MS. The rates of incorporation were substantially faster than in skeletal muscle samples taken at the same time. The results suggest that different fractions of human bone collagen turnover at markedly higher rates than had been previously considered. This approach should allow us to discover how growth and development, food, activity and drugs affect bone collagen turnover and to measure the effects on it of ageing and bone disease.

Structural biology of C1.

Abstract: The classical complement pathway is a major element of innate immunity against infection, and is also involved in immune tolerance, graft rejection and various pathologies. This pathway is triggered by C1, a multimolecular protease formed from the association of a recognition protein, C1q, and a catalytic subunit, the calcium-dependent tetramer C1s-C1r-C1r-C1s, which comprises two copies of each of the modular proteases C1r and C1s. All activators of the pathway are recognized by the C1q moiety of C1, a process that generates a conformational signal that triggers self-activation of C1r, which in turn activates C1s, the enzyme that mediates specific cleavage of C4 and C2, the C1 substrates. Early work based on biochemical and electron microscopy studies has allowed characterization of the domain structure of the C1 subcomponents and led to a low-resolution model of the complex in which the elongated C1s-C1r-C1r-C1s tetramer folds into a compact, figure-of-8-shaped conformation upon interaction with C1q. The strategy used over the past decade was based on a dissection of the C1 proteins into modular segments to characterize their function and solve their three-dimensional structure by X-ray crystallography or NMR spectroscopy. This approach allows deep insights into the structure-function relationships of C1, particularly with respect to the assembly of the C1 complex and the mechanisms underlying its activation and proteolytic activity.

Additional signals from VPAC/PAC family receptors

Abstract: The receptors for the neuropeptides vasoactive intestinal polypeptide and pituitary adenylate cyclase-activating polypeptide are strong activators of adenylate cyclase, but recent evidence suggests that they can elicit a number of additional intracellular signals. Some of these are likely to be downstream of the conventional adenylate cyclase pathway, but it is now clear that others reflect novel primary coupling events of the receptors.

Transcription factors acting on the promoter of the rat fatty acid synthase gene

Abstract: Fatty acid synthase (FAS), one of the main lipogenic enzymes, converts dietary calories into a storage form of energy. The transcription factors, stimulatory proteins 1 and 3 (Sp1 and Sp3), nuclear factor Y (NF-Y), upstream stimulatory factor (USF) and sterol regulatory element binding protein-1 (SREBP-1) have cognate binding sites on the promoter of the FAS gene. It was shown that Sp1 and NF-Y interact co-operatively at the diet-induced DNase I-hypersensitive site at position -500. Adjacent binding sites for NF-Y and Sp1 have also been found between -71 and -52, and -91 and -83. cAMP regulation is mediated via the inverted CAAT element (ICE) at -99 to -92, which binds NF-Y. The FAS insulin-responsive element 3 (FIRE3)-binding site at -71 to -52 is capable of binding NF-Y, USF and SREBP-1, and is required for the sterol response in conjunction with the co-activator NF-Y around -100. Surprisingly, both FIRE3 and ICE are also necessary for the response to retinoic acid that plays a role in development and is an essential component of the diet.