Exploring the role of amino acid-18 of the leucine binding proteins of E. coli

Two periplasmic binding proteins of E. coli, the leucine specific-binding protein (LS) and leucine-isoleucine-valine binding protein (LIV), have high similarity in their structure and function, but show different substrate specificity. A key difference between these proteins is residue 18 in the binding pocket, a tryptophan residue in the LS and a tyrosine residue in the LIV. To examine the role of this residue in binding specificity, we used fluorescence and (19)F NMR to monitor ligand binding to three mutants: LSW18Y, LSW18F and LIVY18W. We observed leucine binding to all proteins. LS binds L-phenylalanine but the mutation from Trp to Tyr or Phe disallows this ligand and expands the binding repertoire to L-isoleucine and L-valine. The LIVY18W mutant still retains the ability to bind L-isoleucine and also binds L-phenylalanine.     

An immunodominant membrane protein (Imp) of 'Candidatus Phytoplasma mali' binds to plant actin

The phytopathogenic, cell-wall-less phytoplasmas exhibit a dual life cycle: they multiply in the phloem of their host plant and in the body of their insect vector. Their membrane proteins are in direct contact with both hosts and are supposed to play a crucial role in the phytoplasma spread within the plant as well as by the insect vector. Three types of nonhomologous but highly abundant and immunodominant membrane proteins (IDP) have been identified within the phytoplasmas: Amp, IdpA, and Imp. Although recent results indicate that Amp is involved in vector specificity interacting with insect proteins such as actin, little is known about the interaction of IDP with the plant. We could demonstrate that transiently expressed Imp of 'Candidatus Phytoplasma mali' as well as the Imp without transmembrane domain (Imp?Tm) bind with plant actins in vivo. Moreover, in vitro co-sediment and binding assays showed that Escherichia coli-expressed recombinant Imp?Tm-His binds to both G- and F-actins isolated from rabbit muscle. Transgenic plants expressing Imp- or Imp?Tm-green fluorescent protein did not exhibit any remarkable change of phenotype compared with the wild-type plant. These results indicate that Imp specifically binds to plant actin and a role of Imp-actin binding in phytoplasma motility is hypothesized.     

Multiplicity of leucine transport systems in Escherichia coli K-12

The major component of leucine uptake in Escherichia coli K-12 is a common system for l-leucine, l-isoleucine, and l-valine (LIV-I) with a Michaelis constant (K(m)) value of 0.2 muM (LIV-I system). The LIV-binding protein appears to be associated with this system. It now appears that the LIV-I transport system and LIV-binding protein also serve for the entry of l-alanine, l-threonine, and possibly l-serine. A minor component of l-leucine entry occurs by a leucine-specific system (L-system) for which a specific leucine-binding protein has been isolated. A mutant has been obtained that shows increased levels of the LIV-I transport activity and increased levels of both of the binding proteins. Another mutant has been isolated that shows only a major increase in the levels of the leucine-specific transport system and the leucine-specific binding protein. A third binding protein that binds all three branched-chain amino acids but binds isoleucine preferentially has been identified. The relationship of the binding proteins to each other and to transport activity is discussed. A second general transport system (LIV-II system) with a K(m) value of 2 muM and a relatively low V(max) can be observed in E. coli. The LIV-II system is not sensitive to osmotic shock treatment nor to growth of cells in the presence of leucine. This high K(m) system, which is specific for the branched-chain amino acids, can be observed in membrane vesicle preparations.     

Novel ZIP kinase isoform lacks leucine zipper

Zipper-interacting protein kinase (ZIP kinase) has been thought to be involved in apoptosis and the C-terminal leucine zipper motif is important for its function. Recent studies have revealed that ZIP kinase also plays a role in regulating myosin phosphorylation. Here, we found novel ZIP kinase isoform in which the C-terminal non-kinase domain containing a leucine zipper is eliminated (hZIPK-S). hZIPK-S binds to myosin phosphatase targeting subunit 1(MYPT1) similar to the long isoform (hZIPK-L). In addition, we found that hZIPK-S as well as hZIPK-L bind to myosin. These results indicate that a leucine zipper is not critical for the binding of ZIP kinase to MYPT1 and myosin. Consistently, hZIPK-S localized with stress-fibers where they co-localized with myosin. The residues 278-311, the C-terminal side of the kinase domain common to the both isoforms, is involved in the binding to MYPT1, while the myosin binding domain is within the kinase domain. These results suggest that the newly found hZIPK-S as well as the long isoform play an important role in the regulation of myosin phosphorylation.     

Dimerization of cGMP-dependent protein kinase 1alpha and the myosin-binding subunit of myosin phosphatase: role of leucine zipper domains

Nitric oxide (NO) and nitrovasodilators induce vascular smooth muscle cell relaxation in part by cGMP-dependent protein kinase (cGK)-mediated activation of myosin phosphatase, which dephosphorylates myosin light chains. We recently found that cGMP-dependent protein kinase 1alpha binds directly to the myosin-binding subunit (MBS) of myosin phosphatase via the leucine/isoleucine zipper of cGK. We have now studied the role of the leucine zipper domain of MBS in dimerization with cGK and the leucine/isoleucine zipper and leucine zipper domains of both proteins in homodimerization. Mutagenesis of the MBS leucine zipper domain disrupts cGKIalpha-MBS dimerization. Mutagenesis of the MBS leucine zipper eliminates MBS homodimerization, while similar disruption of the cGKIalpha leucine/isoleucine zipper does not prevent formation of cGK dimers. The MBS leucine zipper domain is phosphorylated by cGK, but this does not have any apparent effect on heterodimer formation between the two proteins. MBS LZ mutants that are unable to bind cGK were poor substrates for cGK. These data support the theory that the MBS leucine zipper domain is necessary and sufficient to mediate both MBS homodimerization and binding of the protein to cGK. In contrast, the leucine/isoleucine zipper of cGK is required for binding to MBS, but not for cGK homodimerization. These data support that the MBS and cGK leucine zipper domains mediate the interaction between these two proteins. The contribution of these domains to both homodimerization and their specific interaction with each other suggest that additional regulatory mechanisms involving these domains may exist.     

A structural comparison of human serum transferrin and human lactoferrin

The transferrins are a family of proteins that bind free iron in the blood and bodily fluids. Serum transferrins function to deliver iron to cells via a receptor-mediated endocytotic process as well as to remove toxic free iron from the blood and to provide an anti-bacterial, low-iron environment. Lactoferrins (found in bodily secretions such as milk) are only known to have an anti-bacterial function, via their ability to tightly bind free iron even at low pH, and have no known transport function. Though these proteins keep the level of free iron low, pathogenic bacteria are able to thrive by obtaining iron from their host via expression of outer membrane proteins that can bind to and remove iron from host proteins, including both serum transferrin and lactoferrin. Furthermore, even though human serum transferrin and lactoferrin are quite similar in sequence and structure, and coordinate iron in the same manner, they differ in their affinities for iron as well as their receptor binding properties: the human transferrin receptor only binds serum transferrin, and two distinct bacterial transport systems are used to capture iron from serum transferrin and lactoferrin. Comparison of the recently solved crystal structure of iron-free human serum transferrin to that of human lactoferrin provides insight into these differences.     

HSP90, HSP70, and GAPDH directly interact with the cytoplasmic domain of macrophage scavenger receptors.

The macrophage scavenger receptor (MSR) is a trimeric membrane protein which binds to modified low-density lipoprotein (LDL) and has been indicated in the development of atherosclerosis. It has recently been demonstrated that the N-terminal cytoplasmic domain of MSR has an important role in the efficient internalization and cell-surface expression of the receptor. This study shows that the N-terminal cytoplasmic domain in bovine was constructed using a peptide architecture technique in which the peptide chain was bundled at their C-terminus to yield a trimeric form and that this did not form an ordered structure. Furthermore, the binding proteins to the cytoplasmic domain of MSR were determined for the first time using a peptide affinity column. Sequence analyses of the specific binding proteins in bovine revealed that heat shock protein 90 (HSP90), heat shock protein 70 (HSP70), leucine aminopeptidase (LAP), adenocylhomocysteinase, and glyceraldehyde 3-phosphate dehydrogenase (GAPDH) were included. GST-pull-down assay and immunoprecipitation analyses on HSP90, HSP70, and GAPDH showed that all these proteins could bind to the cytoplasmic domain of MSR in vitro and in vivo. These proteins interact with the cytoplasmic domain directly and may have an effect on the functions of MSR such as internalization, cell-surface expression, and signal transduction.     

The Athb-1 and -2 HD-Zip domains homodimerize forming complexes of different DNA binding specificities.

The Arabidopsis Athb-1 and -2 proteins are characterized by the presence of a homeodomain (HD) with a closely linked leucine zipper motif (Zip). We have suggested that the HD-Zip motif could, via dimerization of the leucine zippers, recognize dyad-symmetric DNA sequences. Here we report an analysis of the DNA binding properties of the Athb-1 homeodomain-leucine zipper (HD-Zip-1) domain in vitro. DNA binding analysis performed using random-sequence DNA templates showed that the HD-Zip-1 domain, but not the Athb-1 HD alone, binds to DNA. The HD-Zip-1 domain recognizes a 9 bp dyad-symmetric sequence [CAAT(A/T)ATTG], as determined by selecting high-affinity binding sites from random-sequence DNA. Gel retardation assays demonstrated that the HD-Zip-1 domain binds to DNA as a dimer. Moreover, the analysis of the DNA binding activity of Athb-1 derivatives indicated that a correct spatial relationship between the HD and the Zip is essential for DNA binding. Finally, we determined that the Athb-2 HD-Zip domain recognizes a distinct 9 bp dyad-symmetric sequence [CAAT(G/C)ATTG]. A model of DNA binding by the HD-Zip proteins is proposed.     

Chromobindin A. A Ca2+ and ATP regulated chromaffin granule binding protein

A variety of studies have shown that about 20 proteins can be isolated from bovine adrenal medullary cytosol by virtue of their ability to bind to chromaffin granule membranes in the presence of Ca2+. In the present study we have examined the properties of a group of seven of these proteins. This group of proteins binds to granule membranes in the presence of Ca2+, however, the proteins are not released from the membrane by the removal of Ca2+ unless ATP is present. The proteins range from 53 to 59 kDa and they form a multisubunit complex of about 800 kDa. This complex, which we have named chromobindin A, has 13 subunits joined together in a ring, 175 A in diameter and 115 A in height. The binding of chromobindin A to membranes is stimulated by Ca2+, Sr2+, and Ba2+. The release is stimulated by a variety of nucleotides, including the nonhydrolyzable nucleotide analog adenyl-5'-yl imidodiphosphate. At present the function of chromobindin A in vivo is not clear, although the observation that Ca2+ stimulates chromobindin A binding together with observations that imply that chromobindin A binds to a protease-sensitive receptor on the granule membrane suggest that the complex is involved in exocytosis and that it may be partially responsible for the ATP dependence of this process.     

Membrane targeting by APPL1 and APPL2: dynamic scaffolds that oligomerize and bind phosphoinositides

Human adaptor protein, phosphotyrosine interaction, PH domain and leucine zipper containing 1 (APPL1) and adaptor protein, phosphotyrosine interaction, PH domain and leucine zipper containing 2 (APPL2) are homologous effectors of the small guanosine triphosphatase RAB5 that interact with a diverse set of receptors and signaling proteins and are proposed to function in endosome-mediated signaling. Herein, we investigated the membrane-targeting properties of the APPL1 and APPL2 Bin/Amphiphysin/Rvs (BAR), pleckstrin homology (PH) and phosphotyrosine binding (PTB) domains. Coimmunoprecipitation and yeast two-hybrid studies demonstrated that full-length APPL proteins formed homooligomers and heterooligomers and that the APPL minimal BAR domains were necessary and sufficient for mediating APPL-APPL interactions. When fused to a fluorescent protein and overexpressed, all three domains (minimal BAR, PH and PTB) were targeted to cell membranes. Furthermore, full-length APPL proteins bound to phosphoinositides, and the APPL isolated PH or PTB domains were sufficient for in vitro phosphoinositide binding. Live cell imaging showed that full-length APPL-yellow fluorescent protein (YFP) fusion proteins associated with cytosolic membrane structures that underwent movement, fusion and fission events. Overexpression of full-length APPL-YFP fusion proteins was sufficient to recruit endogenous RAB5 to enlarged APPL-associated membrane structures, although APPL1 was not necessary for RAB5 membrane targeting. Taken together, our findings suggest a role for APPL proteins as dynamic scaffolds that modulate RAB5-associated signaling endosomal membranes by their ability to undergo domain-mediated oligomerization, membrane targeting and phosphoinositide binding.     

Myosin VI targeting to clathrin-coated structures and dimerization is mediated by binding to Disabled-2 and PtdIns(4,5)P2

Vesicle transport is essential for the movement of proteins, lipids and other molecules between membrane compartments within the cell. The role of the class VI myosins in vesicular transport is particularly intriguing because they are the only class that has been shown to move 'backwards' towards the minus end of actin filaments. Myosin VI is found in distinct intracellular locations and implicated in processes such as endocytosis, exocytosis, maintenance of Golgi morphology and cell movement. We have shown that the carboxy-terminal tail is the key targeting region and have identified three binding sites: a WWY motif for Disabled-2 (Dab2) binding, a RRL motif for glucose-transporter binding protein (GIPC) and optineurin binding and a site that binds specifically and with high affinity (Kd = 0.3 microM) to PtdIns(4,5)P2-containing liposomes. This is the first demonstration that myosin VI binds lipid membranes. Lipid binding induces a large structural change in the myosin VI tail (31% increase in helicity) and when associated with lipid vesicles, it can dimerize. In vivo targeting and recruitment of myosin VI to clathrin-coated structures (CCSs) at the plasma membrane is mediated by Dab2 and PtdIns(4,5)P2 binding.     

The receptor-bound N-terminal ectodomain of the amyloid precursor protein is associated with membrane rafts

The soluble N-terminal ectodomain of amyloid precursor protein (sAPP), resulting from alpha-secretase-mediated proteolytic processing, has been shown to function as a growth factor for epithelial cells, including keratinocytes and thyrocytes. Extracellularly applied sAPP binds to a cell surface receptor and exhibits a patchy binding pattern reminiscent of that observed for raft proteins. Here we show that (i) the receptor-bound sAPP resides in a detergent-insoluble membrane microdomain which cofractionates in density gradients with cholesterol-rich membrane rafts and caveolae; (ii) the sAPP-binding microdomains are different from caveolae; and (iii) sAPP is capable of binding to isolated rafts and inducing tyrosine phosphorylation of some raft proteins. These observations suggest that a novel type of membrane raft is involved in sAPP signaling.     

The Protein 4.1 family: Hub proteins in animals for organizing membrane proteins

Proteins of the 4.1 family are characteristic of eumetazoan organisms. Invertebrates contain single 4.1 genes and the Drosophila model suggests that 4.1 is essential for animal life. Vertebrates have four paralogues, known as 4.1R, 4.1N, 4.1G and 4.1B, which are additionally duplicated in the ray-finned fish. Protein 4.1R was the first to be discovered: it is a major mammalian erythrocyte cytoskeletal protein, essential to the mechanochemical properties of red cell membranes because it promotes the interaction between spectrin and actin in the membrane cytoskeleton. 4.1R also binds certain phospholipids and is required for the stable cell surface accumulation of a number of erythrocyte transmembrane proteins that span multiple functional classes; these include cell adhesion molecules, transporters and a chemokine receptor. The vertebrate 4.1 proteins are expressed in most tissues, and they are required for the correct cell surface accumulation of a very wide variety of membrane proteins including G-Protein coupled receptors, voltage-gated and ligand-gated channels, as well as the classes identified in erythrocytes. Indeed, such large numbers of protein interactions have been mapped for mammalian 4.1 proteins, most especially 4.1R, that it appears that they can act as hubs for membrane protein organization. The range of critical interactions of 4.1 proteins is reflected in disease relationships that include hereditary anaemias, tumour suppression, control of heartbeat and nervous system function. The 4.1 proteins are defined by their domain structure: apart from the spectrin/actin-binding domain they have FERM and FERM-adjacent domains and a unique C-terminal domain. Both the FERM and C-terminal domains can bind transmembrane proteins, thus they have the potential to be cross-linkers for membrane proteins. The activity of the FERM domain is subject to multiple modes of regulation via binding of regulatory ligands, phosphorylation of the FERM associated domain and differential mRNA splicing. Finally, the spectrum of interactions of the 4.1 proteins overlaps with that of another membrane-cytoskeleton linker, ankyrin. Both ankyrin and 4.1 link to the actin cytoskeleton via spectrin, and we hypothesize that differential regulation of 4.1 proteins and ankyrins allows highly selective control of cell surface protein accumulation and, hence, function. This article is part of a Special Issue entitled: Reciprocal influences between cell cytoskeleton and membrane channels, receptors and transporters. Guest Editor: Jean Claude Hervé     

Atomic structures of periplasmic binding proteins and the high-affinity active transport systems in bacteria

We have determined and refined the X-ray crystal structures of six periplasmic binding proteins that serve as initial receptors for the osmotic-shock sensitive, active transport of L-arabinose, D-galactose/D-glucose, maltose, sulphate, leucine/isoleucine/valine and leucine. The tertiary structures and atomic interactions between proteins and ligands show common features that are important for understanding the function of the binding proteins. All six structures are ellipsoidal, consisting of two similar, globular domains. The ligand-binding site is located deep in the cleft between the two domains. Irrespective of the nature of the ligand (e.g. saccharide, sulphate dianion or leucine zwitterion), the specificities and affinities of the binding sites are achieved mainly through hydrogen-bonding interactions. Binding of ligands induces a large protein conformational change. Three different structures have been observed among the binding proteins: unliganded 'open cleft', liganded 'open cleft', and liganded 'closed cleft'. Here we discuss the functions of binding proteins in the light of numerous crystallographic and ligand-binding studies and propose a mechanism for the binding protein-dependent, high-affinity active transport.     

Homer and the ryanodine receptor

Homer proteins have recently been identified as novel high-affinity ligands that modulate ryanodine receptor (RyR) Ca²⁺ release channels in heart and skeletal muscle, through an EVH1 domain which binds to proline-rich regions in target proteins. Many Homer proteins can also self-associate through a coiled-coil domain that allows their multimerisation. In other tissues, especially neurons, Homer anchors proteins embedded in the surface membrane to the Ca²⁺ release channel in the endoplasmic reticulum and can anchor membrane or cytosolic proteins to the cytoskeleton. Although this anchoring aspect of Homer function has not been extensively investigated in muscle, there are consensus sequences for Homer binding in the RyR and on many of the proteins that it interacts with in the massive RyR ion channel complex. In this review we explore the potential of Homer to contribute to a variety of cell processes in muscle and neurons that also involve RyR channels.     

Identification of a membrane-binding domain within the amino-terminal region of human immunodeficiency virus type 1 Gag protein which interacts with acidic phospholipids.

Retroviral Gag proteins are targeted to the plasma membrane, where they play the central role in virion formation. Several studies have suggested that the membrane-binding signal is contained within the amino-terminal matrix sequence; however, the precise location has never been determined for the Gag protein of any retrovirus. In this report, we show that the first 31 residues of human immunodeficiency virus type 1 Gag protein can function independently as a membrane-targeting domain when fused to heterologous proteins. A bipartite membrane-targeting motif was identified, consisting of the myristylated N-terminal 14 amino acids and a highly basic region that binds acidic phospholipids. Replacement of the N-terminal membrane-targeting domain of pp60v-src with that of human immunodeficiency virus type 1 Gag elicits efficient membrane binding and a transforming phenotype. Removal of myristate or the basic region results in decreased membrane binding of Gag-Src chimeras in vitro and impaired virion formation by Pr55gag in vivo. We propose that the N-terminal Gag sequence functions as a targeting signal to direct interaction with acidic phospholipids on the cytoplasmic leaflet of the plasma membrane.     

Biochemical characterization of a truncated penta-EF-hand Ca2+ binding protein from maize

Plants possess multiple genes encoding calcium sensor proteins that are members of the penta-EF-hand (PEF) family. Characterized PEF proteins such as ALG-2 (apoptosis-linked gene 2 product) and the calpain small subunit function in diverse cellular processes in a calcium-dependent manner by interacting with their target proteins at either their N-terminal extension or Ca2+ binding domains. We have identified a previously unreported class of PEF proteins in plants that are notable because they do not possess the hydrophobic amino acid rich N-terminal extension that is typical of these PEF proteins. We demonstrate that the maize PEF protein without the N-terminal extension has the characteristics of known PEF proteins; the protein binds calcium in the 100 nM range and, as a result of calcium binding, displays an increase in hydrophobicity. Characterization of the truncated maize PEF protein provides insights into the role of the N-terminal extension in PEF protein signaling. In the context of the current model of how PEF proteins are activated by calcium binding, these results demonstrate that this distinctive class of PEF proteins could function as calcium sensor proteins in plants even in the absence of the N-terminal extension.