pHi regulatory ion transporters: an update on structure, regulation and cell function

Intracellular pH (pH_i) is a major regulator of various and critical cellular functions. A close regulation of pH_i is thus mandatory to maintain normal cellular activity. To this end, all cells express ion transporters that carry across their plasma membrane H⁺ or equivalent H⁺ into and out of the cell. Besides pH_i, these ion transporters are under the regulation of neurohormonal stimuli. This review summarises the molecular identity, regulation and function of the main membrane pH-regulatory ion transporters. Received 30 December 1998; received after revision 4 February 1999; accepted 9 February 1999     

S-Nitrosylation of proteins

The transfer of a nitric oxide group to cysteine sulfhydryls on proteins, known as S-nitrosylation, is increasingly becoming recognized as a ubiquitous regulatory reaction comparable to phosphorylation. It represents a form of redox modulation in diverse tissues, including the brain. An increasing number of proteins have been found to undergo S-nitrosylation in vivo. These proteins are called S-nitrosothiols, and may play an important role in many processes ranging from signal transduction, DNA repair, host defense, and blood pressure control to ion channel regulation and neurotransmission. This review focuses on the importance of the S-nitrosylation reaction and describes some recently identified S-nitrosothiols in various fields of research.     

Integrin antagonists

Integrins are a family of cell surface glycoproteins that mediate numerous cell-cell and cell-matrix interactions and are involved in biological processes such as tissue morphogenesis, leukocyte recirculation and migration, wound healing, blood clotting and immune response. Aberrant cell adhesion has been implicated in the pathogenesis of several diseases, including a number of inflammatory disorders such as rheumatoid arthritis, inflammatory bowel disease and asthma, as well as cancer and coronary heart disease. As such integrins are seen as excellent targets for the development of therapeutic agents. This report begins with an examination of the structure of integrin molecules and their ligands and then goes on to review the current state of development of antiintegrin antagonists. Received 13 April 1999; received after revision 28 May 1999; accepted 28 May 1999     

The pleiotropic functions of aspirin: mechanisms of action

Recent studies have suggested that aspirin and aspirin-like compounds have a variety of actions in addition to their well-studied ability to inhibit cyclooxygenases. These actions include inhibition of the uncoupling of oxidative phosphorylation, decreases in adenosine triphosphate stores, increases in extracellular adenosine, downregulation of the expression and activity of inducible nitric oxide synthetase, inhibition and/or stimulation of various mitogen-activated protein kinase activities and inhibition of nuclear factor binding κB site (NF-κB) activation. Moreover, aspirin-like compounds have recently been shown to have previously unappreciated clinical and biological effects, some apparently independent of cyclooxygenase. In this review we discuss the various mechanisms of action of aspirin-like compounds and their relevance to clinical disease and therapy. Received 1 February 1999; received after revision 1 April 1999; accepted 7 May 1999     

Ventral neural tube cells differentiate into hepatocytes in the chick embryo

A population of ventral neural tube cells has recently been shown to migrate out of the hind brain neural tube via the vagus nerve and contribute to the developing gastrointestinal tract. Since liver is also innervated by the vagus nerve, we sought to determine if these cells also migrate into the liver. Ventral neural tube cells in the caudal hindbrain of chick embryos were tagged with a replication-deficient retroviral vector containing the LacZ gene on embryonic day 2. Embryos were processed for detection of labeled cells on embryonic day 5 and 11. Labeled cells were seen in the liver on both days and identified as hepatocytes. Previously, it was believed that all hepatocytes develop from the gut endoderm. Results of the present study show an additional source for the formation of liver cells. Received 25 August 1998; received after revision 5 November 1998; accepted 5 November 1998     

Polymorphism in the regulatory sequence of the human hsp70-1 gene does not affect heat shock factor binding or heat shock protein synthesis

A bi-allelic polymorphism found in the regulatory region of the human heat shock (HS) protein (HSP) hsp70-1 gene, which comprises an A-->C transversion, 3 bp upstream of the HS element (HSE), has been associated with extended HLA haplotypes. In view of the chaperoning and protective functions of Hsp70, we investigated whether this hsp70-1 bi-allelic polymorphism could modulate the stress response, which may relate to enhanced resistance or susceptibility to certain diseases. We compared the basal and HS-induced HS factor (HSF)-binding activity of the two polymorphic HSEs, hsp70-1 mRNA accumulation and HSP expression in two human Epstein Barr virus (EBV)-transformed B cell lines typed for hsp70-1 promoter alleles. Our results suggest that hsp70-1 promoter polymorphism does not influence HSF-binding activity, hsp70 mRNA accumulation or synthesis in human EBV-transformed B cell lines.     

Signalling via caveolin: involvement in the cross-talk between phosphoinositolglycans and insulin

In recent years, a number of cross-talk systems have been identified which feed into the insulin signalling cascade at the level of insulin receptor substrate (IRS) tyrosine phosphorylation, e.g., receptor and non-receptor tyrosine kinases and G-protein-coupled receptors. At the molecular level, a number of negative modulator and feedback systems somehow interacting with the beta-subunit (catecholamine-, phorbolester-, or tumor necrosis factor-alpha-induced serine/threonine phosphorylation, carboxy-terminal trimming by a thiol-dependent protease, association of inhibitory/regulatory proteins such as RAD, PC1, PED, alpha2-HS-glycoprotein) have been identified as candidate mechanisms for the impairment of insulin receptor function by elevations in the activity and/or amount of the corresponding modification enzymes/inhibitors. Both decreased responsiveness and sensitivity of the insulin receptor beta-subunit for insulin-induced tyrosine autophosphorylation have been demonstrated in several cellular and animal models of metabolic insulin resistance as well as in the adipose tissue and skeletal muscle of diabetic patients and obese Pima Indians compared to non-obese subjects. Therefore, induction of the insulin signalling cascade by bypassing the defective insulin receptor kinase may be useful for the therapy of non-insulin dependent diabetes mellitus. During the past two decades, phosphoinositolglycans (PIGs) of various origin have been demonstrated to exert potent insulin-mimetic metabolic effects upon incubation with cultured or isolated muscle and adipose cells. However, it remained to be elucidated whether these compounds actually manage to trigger insulin signalling and if so at which level of hierarchy within the signalling cascade the site of interference is located. Recent studies using isolated rat adipocytes and chemically synthesized PIG compounds point to IRS1/3 tyrosine phosphorylation by p59Lyn kinase as the site of cross-talk, the negative regulation of which by interaction with caveolin is apparently abrogated by PIG. This putative mechanism is thus compatible with the recently formulated caveolin signalling hypothesis, the supporting data for which are reviewed here. Though we have not obtained experimental evidence for the involvement of PIG in physiological insulin action, the potential cross-talk between insulin and PIG signalling, including the caveolae/detergent-insoluble glycolipid-enriched rafts as the compartments where the corresponding signalling components are concentrated, thus represent novel targets for signal transduction therapy.     

Plant mitochondrial carriers: an overview

In the two last decades, biochemical studies using mitochondrial swelling experiments or direct solute uptake in isolated mitochondria have lead to the identification of different transport systems at the level of the plant mitochondrial inner membrane. Although most of them have been found to have similar features to those identified in animal mitochondria, some differences have been observed between plant and animal transporters. More recently, molecular biology studies have revealed that most of the mitochondrial exchanges are performed by nuclear encoded proteins, which form a superfamily. Members of this family have been reported in animals, yeast as well as plants. This review attempts to give an overview of the present knowledge concerning the biochemical and molecular characterisation of plant members of the mitochondrial carrier family and, when possible, a comparison with carriers from other organisms.     

Cathepsin A/protective protein: an unusual lysosomal multifunctional protein

Cathepsin A/protective protein [3.4.16.5], carboxypeptidase A, is a lysosomal serine protease with structural homology to yeast (Saccharomyces cerevisiae) carboxypeptidase Y. Cathepsin A is a member of the alpha/beta hydrolase fold family and has been suggested to share a common ancestral relationship with other alpha/beta hydrolase fold enzymes, such as cholinesterases. Several lines of evidence indicate that cathepsin A is a multicatalytic enzyme with deamidase and esterase in addition to carboxypeptidase activities. Cathepsin A was recently identified in human platelets as deamidase. In vitro, it hydrolyzes a variety of bioactive peptide hormones including tachykinins, suggesting that extralysosomal cathepsin A plays a role in regulation of bioactive peptide functions. Recent reports emphasize the lysosomal protective function of cathepsin A rather than its protease function. The protective function of cathepsin A is distinct from its catalytic function. Human lysosomal beta-galactosidase and neuraminidase exist as a high molecular weight enzyme complex, in which there is a 54-kDa glycoprotein termed 'lysosomal protective protein'. Based on cell culture studies, protective protein was found to protect both beta-galactosidase and neuraminidase from intralysosomal proteolysis by forming a multienzyme complex and was shown to be deficient in patients with galactosialidosis, a combined deficiency of beta-galactosidase and neuraminidase. Molecular cloning and gene expression studies have disclosed that protective protein is cathepsin A. The cathepsin A precursor has the potential to restore both beta-galactosidase and neuraminidase activities in fibroblasts from patients with galactosialidosis. Cathepsin A knockout mice showed a phenotype similar to human galactosialidosis and the deficient phenotype found in the mutant mice was corrected by transplanting erythroid precursor cells overexpressing cathepsin A. Collectively, these findings demonstrate the significance of cathepsin A as a key molecule in the onset of galactosialidosis and also highlight the therapeutic potential of the cathepsin A precursor for patients with galactosialidosis.