Mutations in PMR1 suppress oxidative damage in yeast cells lacking superoxide dismutase.

Mutants of Saccharomyces cerevisiae lacking a functional SOD1 gene encoding Cu/Zn superoxide dismutase (SOD) are sensitive to atmospheric levels of oxygen and are auxotrophic for lysine and methionine when grown in air. We have previously shown that these defects of SOD-deficient yeast cells can be overcome through mutations in either the BSD1 or BSD2 (bypass SOD defects) gene. In this study, the wild-type allele of BSD1 was cloned by functional complementation and was physically mapped to the left arm of chromosome VII. BSD1 is identical to PMR1, encoding a member of the P-type ATPase family that localizes to the Golgi apparatus. PMR1 is thought to function in calcium metabolism, and we provide evidence that PMR1 also participates in the homeostasis of manganese ions. Cells lacking a functional PMR1 gene accumulate elevated levels of intracellular manganese and are also extremely sensitive to manganese ion toxicity. We demonstrate that mutations in PMR1 bypass SOD deficiency through a mechanism that depends on extracellular manganese. Collectively, these findings indicate that oxidative damage in a eukaryotic cell can be prevented through alterations in manganese homeostasis.     

Self-Incorporation of coenzymes by ribozymes

RNA molecules that are assembled from the four standard nucleotides contain a limited number of chemical functional groups, a characteristic that is generally thought to restrict the potential for catalysis by ribozymes. Although polypeptides carry a wider range of functional groups, many contemporary protein-based enzymes employ coenzymes to augment their capabilities. The coenzymes possess additional chemical moieties that can participate directly in catalysis and thereby enhance catalytic function. In this work, we demonstrate a mechanism by which ribozymes can supplement their limited repertoire of functional groups through RNA-catalyzed incorporation of various coenzymes and coenzyme analogues. The group I ribozyme of Tetrahymena thermophila normally mediates a phosphoester transfer reaction that results in the covalent attachment of guanosine to the ribozyme. Here, a shortened version of the ribozyme is shown to catalyze the self-incorporation of coenzymes and coenzyme analogues, such as NAD⁺ and dephosphorylated CoA-SH. Similar ribozyme activities may have played an important role in the RNA world, when RNA enzymes are thought to have maintained a complex metabolism in the absence of proteins and would have benefited from the inclusion of additional functional groups.Correspondence to: G.F. Joyce     

Response regulators of bacterial signal transduction systems: Selective domain shuffling during evolution

Response regulators of bacterial sensory transduction systems generally consist of receiver module domains covalently linked to effector domains. The effector domains include DNA binding and/or catalytic units that are regulated by sensor kinase-catalyzed aspartyl phosphorylation within their receiver modules. Most receiver modules are associated with three distinct families of DNA binding domains, but some are associated with other types of DNA binding domains, with methylated chemotaxis protein (MCP) demethylases, or with sensor kinases. A few exist as independent entities which regulate their target systems by noncovalent interactions.In this study the molecular phylogenies of the receiver modules and effector domains of 49 fully sequenced response regulators and their homologues were determined. The three major, evolutionarily distinct, DNA binding domains found in response regulators were evaluated for their phylogenetic relatedness, and the phylogenetic trees obtained for these domains were compared with those for the receiver modules. Members of one family (family 1) of DNA binding domains are linked to large ATPase domains which usually function cooperatively in the activation of E. Coli ⁵⁴-dependent promoters or their equivalents in other bacteria. Members of a second family (family 2) always function in conjunction with the E. Coli ⁷⁰ or its equivalent in other bacteria. A third family of DNA binding domains (family 3) functions by an uncharacterized mechanism involving more than one a factor. These three domain families utilize distinct helix-turn-helix motifs for DNA binding.The phylogenetic tree of the receiver modules revealed three major and several minor clusters of these domains. The three major receiver module clusters (clusters 1, 2, and 3) generally function with the three major families of DNA binding domains (families 1, 2, and 3, respectively) to comprise three classes of response regulators (classes 1, 2, and 3), although several exceptions exist. The minor clusters of receiver modules were usually, but not always, associated with other types of effector domains. Finally, several receiver modules did not fit into a cluster. It was concluded that receiver modules usually diverged from common ancestral protein domains together with the corresponding effector domains, although domain shuffling, due to intragenic splicing and fusion, must have occurred during the evolution of some of these proteins.Multiple sequence alignments of the 49 receiver modules and their various types of effector domains, together with other homologous domains, allowed definition of regions of striking sequence similarity and degrees of conservation of specific residues. Sequence data were correlated with structure/function when such information was available. These studies should provide guides for extrapolation of results obtained with one response regulator to others as well as for the design of future structure/function analyses. Correspondence to: M.H. Saier, Jr.     

The measurement of transmembrane helices by the deconvolution of CD spectra of membrane proteins: A review

The interpretation of the CD spectra of proteins to date requires additional secondary structural information of the proteins to be analyzed, such as x-ray or nmr data. Therefore, these methods are inappropriate for a CD data base whose secondary structures are unknown, as in the case of the membrane proteins. The Convex Constraint Analysis algorithm [A. Perczel, M. Hollósi, G. Tusnády, and G. D. Fasman (1991) Protein Engineering, Vol. 4, 669–679], on the other hand, operates only on a collection of spectral data to extract the common spectral components with their spectral weights. The linear combinations of these derived “pure” CD curves can reconstruct the original data set with great accuracy. For a membrane protein data set, the five-component spectra so obtained from the deconvolution consisted of two different types of α-helices (the α-helix in the soluble domain and the α_T-helix, for the transmembrane α-helix), a β-pleated sheet, a class C-like spectrum related to β-turns, and a spectrum correlated with the unordered conformation. The deconvoluted CD spectrum for the α_T-helix was characterized by a positive red-shifted band in the range 195–200 nm (+95,000 deg cm² dmol^?l), with the intensity of the negative band at 208 nm being slightly less negative than that of the 222 nm band (?50,000 and ?60,000 deg cm² dmol^?1, respectively) in comparison with the regular α-helix, with a positive band at 190 nm and two negative bands at 208 and 222 nm with magnitudes of + 70,000, ?30,000, and ?30,000 deg cm² dmol^?1, respectively. © 1994 John Wiley & Sons, Inc.     

Chaperone SecB: Conformational changes demonstrated by circular dichroism

The chaperone SecB, which is involved in protein export inEscherichia coli, is shown by circular dichroism measurements to contain a high content of-pleated sheets. Prediction of the secondary structure of SecB is in good agreement with the observed content of-sheet. In accordance with the previous studies in which changes in conformation were assessed indirectly [Randall (1992),Science 257, 241–245], here we show that the conformation of SecB changes with the concentration of salt in the milieu and also when SecB interacts with a peptide ligand.Abbreviations ANS 1-anilino-naphthalene-8-sulfonate - CD circular dichroism - NMR nuclear magnetic resonance - CCA convex constraint analysis     

Proline 21, a residue within the α-helical domain of ΦX174 lysis protein E, is required for its function in Escherichia coli

ΦX174 lysis protein E-mediated lysis of Escherichia coli is characterized by a protein E-specific fusion of the inner and outer membrane and formation of a transmembrane tunnel structure. In order to understand the fusion process, the topology of protein E within the envelope complex of E. coli was investigated. Proteinase K protection studies showed that, during the time course of protein E-mediated lysis process, more of the fusion protein E-FXa-streptavidin gradually became accessible to the protease at the cell surface. These observations postulate a conformational change in protein E during induction of the lysis process by movement of the C-terminal end of the protein throughout the envelope complex from the inner side to the outer side spanning the entire pore and fusing the inner and outer membranes at distinct areas. The initiation mechanism for such a conformational change could be the cis–trans isomerization of proline residues within α-helical membrane-spanning segments. Conversion of proline 21, presumed to be in the membrane-embedded α-helix of protein E, to alanine, glycine, serine and valine, respectively, resulted in lysis-negative E mutant proteins. Proteinase K accessibility studies using streptavidin as a reporter fused to the P21G mutant protein showed that the C-terminal part of the fusion protein is not translocated to the outer side of the membrane, suggesting that this proline residue is essential for the correct folding of protein E within the cell wall complex of E. coli . Oligomerization of protein P21G-StrpA was not disturbed.     

Fast-activating cation channel in barley mesophyll vacuoles. Inhibition by calcium

In contrast to the vacuolar ion channels which are gated open by an increase of cytosolic Ca²⁺ the vacuolar ion currents at resting cytosolic Ca²⁺are poorly explored. Therefore, this study was performed to investigate the properties of the so-called fast-activating vacuolar (FV) current which dominates the electrical characteristics of the tonoplast at physiological free Ca²⁺ concentrations. Patch—clamp measurements were performed on whole barley ( Hordeum vulgare ) mesophyll vacuoles and on excised tonoplast patches. Single ion channels were identified, which, based on their selectivity, activation kinetics, Ca²⁺- and voltage-dependence, carry the whole-vacuole FV current. Reversal potential determinations indicated a K⁺ overs C⁻ permeability ratio of about 30. Both inward and outward whole-vacuole currents as well as the activity of single FV channels were inhibited by an increase of cytosolic Ca²⁺, with a K_d≈ 6 µM. At physiological vacuolar Ca²⁺ activities, the FV channel is an outward-rectifying potassium channel. The FV channel was activated in less than a few milliseconds both by negative and positive potential steps, having a minimal activity that is 40 mV negative of the K⁺ equilibrium potential. It is proposed that transport of K⁺ through this cation channel controls the electrical potential difference across the tonoplast.     

Hemispheric specialization for global and local processing: the effect of stimulus category.

Neuropsychological evidence indicates that the global aspect of complex visual scenes is preferentially processed by the right hemisphere, and local aspects are preferentially processed by the left hemisphere. Using letter-based hierarchical stimuli (Navon figures), we recently demonstrated, in a directed-attention task, lateralized neural activity (assessed by positron emission tomography) in the left prestriate cortex during local processing, and in the right prestriate cortex during global processing. Furthermore, temporal-parietal cortex was critically activated bilaterally in a divided-attention task that involved varying the number of target switches between local and global levels of letter-based hierarchical stimuli. Little is known about whether such stimulus categories influence such hemispheric lateralization. We now present data on brain activity, derived from positron emission tomography, in normal subjects scanned during either local or global processing of object-based hierarchical stimuli. We again observe attentional modulation of neural activity in prestriate cortex. There is now greater right-sided activation for local processing and greater left-sided activation for global processing, which is the opposite of that seen with letter-based stimuli. The results suggest that the relative differential hemispheric activations in the prestriate areas during global and local processing are modified by stimulus category.