Genome-scale identification of membrane-associated human mRNAs

The subcellular localization of proteins is critical to their biological roles. Moreover, whether a protein is membrane-bound, secreted, or intracellular affects the usefulness of, and the strategies for, using a protein as a diagnostic marker or a target for therapy. We employed a rapid and efficient experimental approach to classify thousands of human gene products as either "membrane-associated/secreted" (MS) or "cytosolic/nuclear" (CN). Using subcellular fractionation methods, we separated mRNAs associated with membranes from those associated with the soluble cytosolic fraction and analyzed these two pools by comparative hybridization to DNA microarrays. Analysis of 11 different human cell lines, representing lymphoid, myeloid, breast, ovarian, hepatic, colon, and prostate tissues, identified more than 5,000 previously uncharacterized MS and more than 6,400 putative CN genes at high confidence levels. The experimentally determined localizations correlated well with in silico predictions of signal peptides and transmembrane domains, but also significantly increased the number of human genes that could be cataloged as encoding either MS or CN proteins. Using gene expression data from a variety of primary human malignancies and normal tissues, we rationally identified hundreds of MS gene products that are significantly overexpressed in tumors compared to normal tissues and thus represent candidates for serum diagnostic tests or monoclonal antibody-based therapies. Finally, we used the catalog of CN gene products to generate sets of candidate markers of organ-specific tissue injury. The large-scale annotation of subcellular localization reported here will serve as a reference database and will aid in the rational design of diagnostic tests and molecular therapies for diverse diseases.     

Characterization of a G protein-coupled guanylyl cyclase-B receptor from bovine tracheal smooth muscle

A G protein-coupled natriuretic peptide-guanylyl cyclase receptor-B (NPR-B) located in plasma membranes from bovine tracheal smooth muscle shows complex kinetics and regulation. NPR-B was activated by natriuretic peptides (CNP-53 > ANP-28) at the ligand extracellular domain, stimulated by Gq-protein activators, such as mastoparan, and inhibited by Gi-sensitive chloride, interacting at the juxtamembrane domain. The kinase homology domain was evaluated by the ATP inhibition of Mn2+-activated NPR-B, which was partially reversed by mastoparan. The catalytic domain was studied by kinetics of Mn2+/Mg2+ and GTP, and the catalytic effect with GTP analogues with modifications of the /gamma phosphates and ribose moieties. Most NPR-B biochemical properties remained after detergent solubilization but the mastoparan activation and chloride inhibition of NPR-B disappeared. Our results indicate that NPR-B is a highly regulated nano-machinery with domains acting at cross-talk points with other signal transducing cascades initiated by G protein-coupled receptors and affected by intracellular ligands such as chloride, Mn2+, Mg2+, ATP, and GTP.     

Correlation of an adenine-specific conformational change with the ATP-dependent peptidase activity of Escherichia coli Lon

Escherichia coli Lon, also known as protease La, is a serine protease that is activated by ATP and other purine or pyrimidine triphosphates. In this study, we examined the catalytic efficiency of peptide cleavage as well as intrinsic and peptide-stimulated nucleotide hydrolysis in the presence of hydrolyzable nucleoside triphosphates ATP, CTP, UTP, and GTP. We observed that the k(cat) of peptide cleavage decreases with the reduction in the nucleotide binding affinity of Lon in the following order: ATP > CTP > GTP approximately UTP. Compared to those of the other hydrolyzable nucleotide triphosphates, the ATPase activity of Lon is also the most sensitive to peptide stimulation. Collectively, our kinetic as well as tryptic digestion data suggest that both nucleotide binding and hydrolysis contribute to the peptidase turnover of Lon. The kinetic data that were obtained were further put into the context of the structural organization of Lon protease by probing the conformational change in Lon bound to the different nucleotides. Both adenine-containing nucleotides and CTP protect a 67 kDa fragment of Lon from tryptic digestion. Since this 67 kDa fragment contains the ATP binding pocket (also known as the alpha/beta domain), the substrate sensor and discriminatory (SSD) domain (also known as the alpha-helical domain), and the protease domain of Lon, we propose that the binding of ATP induces a conformational change in Lon that facilitates the coupling of nucleotide hydrolysis with peptide substrate delivery to the peptidase active site.     

Single-molecule dynamics reveal an altered conformation for the autoinhibitory domain of plasma membrane Ca(2+)-ATPase bound to oxidatively modified calmodulin

We used single-molecule polarization modulation methods to investigate the activation of the plasma membrane Ca(2+)-ATPase (PMCA) by oxidized calmodulin (CaM). Oxidative modification of methionine residues of CaM to their corresponding sulfoxides is known to inhibit the ability of CaM to activate PMCA. Single-molecule polarization methods were used to measure the orientational mobility of fluorescently labeled oxidized CaM bound to PMCA. We previously identified two distinct populations of PMCA-CaM complexes characterized by high and low orientational mobilities, with the low-mobility population appearing at a subsaturating Ca(2+) concentration [Osborn, K. D., et al. (2004) Biophys. J. 87, 1892-1899]. We proposed that the high-mobility population corresponds to PMCA-CaM complexes with a dissociated (and mobile) autoinhibitory domain, whereas the low-mobility population corresponds to PMCA-CaM complexes where the autoinhibitory domain is not dissociated and therefore the enzyme is not active. In the present experiments, performed with PMCA complexed with oxidatively modified CaM at a saturating Ca(2+) concentration, we found a large population of molecules with an orientationally immobile autoinhibitory domain. In contrast, native CaM bound to PMCA was characterized almost entirely by the more orientationally mobile population at a similar Ca(2+) concentration. The addition of 1 mM ATP to complexes of oxidized CaM with PMCA reduced but did not abolish the low-mobility population. These results indicate that the decline in the ability of oxidized CaM to activate PMCA results at least in part from its reduced ability to induce conformational changes in PMCA that result in dissociation of the autoinhibitory domain after CaM binding.     

Inhibitor coordination interactions in the binuclear manganese cluster of arginase

Arginase is a manganese metalloenzyme that catalyzes the hydrolysis of L-arginine to form L-ornithine and urea. The structure and stability of the binuclear manganese cluster are critical for catalytic activity as it activates the catalytic nucleophile, metal-bridging hydroxide ion, and stabilizes the tetrahedral intermediate and its flanking states. Here, we report X-ray structures of a series of inhibitors bound to the active site of arginase, and each inhibitor exploits a different mode of coordination with the Mn(2+)(2) cluster. Specifically, we have studied the binding of fluoride ion (F(-); an uncompetitive inhibitor) and L-arginine, L-valine, dinor-N(omega)-hydroxy-L-arginine, descarboxy-nor-N(omega)-hydroxy-L-arginine, and dehydro-2(S)-amino-6-boronohexanoic acid. Some inhibitors, such as fluoride ion, dinor-N(omega)-hydroxy-L-arginine, and dehydro-2(S)-amino-6-boronohexanoic acid, cause the net addition of one ligand to the Mn(2+)(2) cluster. Other inhibitors, such as descarboxy-nor-N(omega)-hydroxy-L-arginine, simply displace the metal-bridging hydroxide ion of the native enzyme and do not cause any net change in the metal coordination polyhedra. The highest affinity inhibitors displace the metal-bridging hydroxide ion (and sometimes occupy a Mn(2+)(A) site found vacant in the native enzyme) and maintain a conserved array of hydrogen bonds with their alpha-amino and -carboxylate groups.     

Single-molecule dynamics of the calcium-dependent activation of plasma-membrane Ca2+-ATPase by calmodulin

The plasma membrane calcium-ATPase (PMCA) helps to control cytosolic calcium levels by pumping out excess Ca2+. PMCA is regulated by the Ca2+ signaling protein calmodulin (CaM), which stimulates PMCA activity by binding to an autoinhibitory domain of PMCA. We used single-molecule polarization methods to investigate the mechanism of regulation of the PMCA by CaM fluorescently labeled with tetramethylrhodamine. The orientational mobility of PMCA-CaM complexes was determined from the extent of modulation of single-molecule fluorescence upon excitation with a rotating polarization. At a high Ca2+ concentration, the distribution of modulation depths reveals that CaM bound to PMCA is orientationally mobile, as expected for a dissociated autoinhibitory domain of PMCA. In contrast, at a reduced Ca2+ concentration a population of PMCA-CaM complexes appears with significantly reduced orientational mobility. This population can be attributed to PMCA-CaM complexes in which the autoinhibitory domain is not dissociated, and thus the PMCA is inactive. The presence of these complexes demonstrates the inadequacy of a two-state model of Ca2+ pump activation and suggests a regulatory role for the low-mobility state of the complex. When ATP is present, only the high-mobility state is detected, revealing an altered interaction between the autoinhibitory and nucleotide-binding domains.     

Differential regional metabolism of glucagon in anesthetized pigs

Glucagon metabolism under basal (endogenous) conditions and during intravenous glucagon infusion was studied in anesthetized pigs by use of midregion (M), COOH-terminal (C), and NH2-terminal (N)-RIAs. Arteriovenous concentration differences revealed a negative extraction of endogenous glucagon immunoreactivity across the portal bed (-35.4 +/- 11.0, -40.3 +/- 9.6, -35.6 +/- 16.9%, M-, C-, N-RIA, respectively), reflecting net secretion of pancreatic glucagon and intestinal glicentin and oxyntomodulin, but under exogenous conditions, a net extraction occurred (11.6 +/- 3.6 and 18.6 +/- 5.7%, C- and N-RIA, respectively). Hindlimb extraction of endogenous (17.4 +/- 3.7%, C-RIA) and exogenous (29.1 +/- 4.8 and 19.8 +/- 5.1%, C- and M-RIA) glucagon was detected, indicating M and C cleavage of the molecule. Renal extraction of glucagon was detected by all assays under endogenous (19.4 +/- 6.7, 33.9 +/- 7.1, 29.5 +/- 6.7%, M-, C-, N-RIA) and exogenous conditions (46.9 +/- 4.8, 46.4 +/- 6.0, 47.0 +/- 7.7%; M-, C-, N-RIA), indicating substantial elimination of the peptide. Hepatic glucagon extraction was undetectable under basal conditions and detected only by M-RIA (10.0 +/- 3.8%) during glucagon infusion, indicating limited midregional cleavage of the molecule. The plasma half-life determined by C- and N-RIAs (2.7 +/- 0.2 and 2.3 +/- 0.2 min) were similar, but both were shorter than when determined by M-RIA (3.2 +/- 0.2 min, P < 0.02). Metabolic clearance rates were similar regardless of assay (14.4 +/- 1.1, 13.6 +/- 1.7, 17.0 +/- 1.7 ml x kg-1 x min-1, M-, C-, N-RIA). Porcine plasma degraded glucagon, but this was not significantly affected by the dipeptidyl peptidase IV (DPP IV) inhibitor valine-pyrrolidide, and in anesthetized pigs, glucagon's metabolic stability was unchanged by DPP IV inhibition. We conclude that tissue-specific metabolism of glucagon occurs, with the kidney being the main site of removal and the liver playing little, if any, role. Furthermore, valine-pyrrolidide has no effect on glucagon stability, suggesting that DPP IV is unimportant in glucagon metabolism in vivo, in contrast to its significant role in the metabolism of the other proglucagon-derived peptides and glucose-dependent insulinotropic polypeptide.     

Semantic memory and the human hippocampus

It has been unclear whether the hippocampus is uniquely important for episodic memory (memory for events that are specific to time and place) or whether the hippocampus is also important for learning and remembering facts (semantic memory). In two studies, we assessed the capacity for semantic memory in patients with bilateral damage thought to be restricted primarily to the hippocampal region who developed memory impairment at a known time. Since the onset of their memory impairment, the patients have acquired less factual knowledge than controls. The patients also exhibit temporally limited retrograde amnesia for factual information from the several years preceding the onset of memory impairment. Remote memory for factual knowledge (from 11-30 years before amnesia) is intact. The results show that the hippocampal region supports semantic memory as well as episodic memory and that its role in the acquisition and storage of semantic knowledge is time limited.     

House fly cytochrome b5 exhibits kinetically trapped hemin and selectivity in hemin binding

We report that cytochrome b(5) (cyt b(5)) from Musca domestica (house fly) is more thermally stable than all other microsomal (Mc) cytochromes b(5) that have been examined to date. It also exhibits a much higher barrier to equilibration of the two isomeric forms of the protein, which differ by a 180 degrees rotation about the alpha-gamma-meso axis of hemin (ferric heme). In fact, hemin is kinetically trapped in a nearly statistical 1.2:1 ratio of rotational forms in freshly expressed protein. The equilibrium ratio (5.5:1) is established only upon incubation at temperatures above 37 degrees C. House fly Mc cyt b(5) is only the second b-hemoprotein that has been shown to exhibit kinetically trapped hemin at room temperature or above, the first being cyt b(5) from the outer membrane of rat liver mitochondria (rat OM cyt b(5)). Finally, we show that the small excess of one orientational isomer over the other in freshly expressed protein results from selective binding of hemin by the apoprotein, a phenomenon that has not heretofore been established for any apocyt b(5).     

Diamonds in the rough: Dryland microorganisms are ecological engineers to restore degraded land and mitigate desertification

Our planet teeters on the brink of massive ecosystem collapses, and arid regions experience manifold environmental and climatic challenges that increase the magnitude of selective pressures on already stressed ecosystems. Ultimately, this leads to their aridification and desertification, that is, to simplified and barren ecosystems (with proportionally less microbial load and diversity) with altered functions and food webs and modification of microbial community network. Thus, preserving and restoring soil health in such a fragile biome could help buffer climate change's effects. We argue that microorganisms and the protection of their functional properties and networks are key to fight desertification. Specifically, we claim that it is rational, possible and certainly practical to rely on native dryland edaphic microorganisms and microbial communities as well as dryland plants and their associated microbiota to conserve and restore soil health and mitigate soil depletion in newly aridified lands. Furthermore, this will meet the objective of protecting/stabilizing (and even enhancing) soil biodiversity globally. Without urgent conservation and restoration actions that take into account microbial diversity, we will ultimately, and simply, not have anything to protect anymore.