Dynamic Coupling and Allosteric Networks in the α Subunit of Heterotrimeric G Proteins

G protein α subunits cycle between active and inactive conformations to regulate a multitude of intracellular signaling cascades. Important structural transitions occurring during this cycle have been characterized from extensive crystallographic studies. However, the link between observed conformations and the allosteric regulation of binding events at distal sites critical for signaling through G proteins remain unclear. Here we describe molecular dynamics simulations, bioinformatics analysis, and experimental mutagenesis that identifies residues involved in mediating the allosteric coupling of receptor, nucleotide, and helical domain interfaces of Gα_i. Most notably, we predict and characterize novel allosteric decoupling mutants, which display enhanced helical domain opening, increased rates of nucleotide exchange, and constitutive activity in the absence of receptor activation. Collectively, our results provide a framework for explaining how binding events and mutations can alter internal dynamic couplings critical for G protein function.     

Isolation of α and β Brain Tubulin Subunits after Alkaline Treatment of the Protein

We demonstrate here that brain purified tubulin can be dissociated into and subunits at pH > 10 and that the subunits can be separated by using the Triton X-114 phase separation system. After phase partition at pH > 10, tubulin but not tubulin behaves as a hydrophobic compound appearing in the detergent rich phase. After three extractions of the alkaline aqueous phase with Triton X-114, about 90% of the tubulin was recovered in the detergent rich phase. The hydrophobic behavior observed for tubulin after its dissociation at pH 11.5 was not due to an irreversible change of the protein, because when the detergent rich phase containing tubulin was diluted with a buffer solution at pH 7.3 and the solution allowed to partition again, -tubulin is recovered in the aqueous phase. The detergent in the aqueous phase of the and tubulin preparations can be removed up to 90% by 12 h dialysis. The and subunits of tubulin from kidney and liver behave, in this phase separation system, like those of brain tubulin.     

Mapping of the Mouse Actin Capping Protein α Subunit Genes and Pseudogenes

Capping protein (CP), a heterodimer of α and β subunits, is found in all eukaryotes. CP binds to the barbed ends of actin filamentsin vitroand controls actin assembly and cell motilityin vivo.Vertebrates have three α isoforms (α1, α2, α3) produced from different genes, whereas lower organisms have only one gene and one isoform. We isolated genomic clones corresponding to the α subunits of mouse CP and found three α1 genes, two of which are pseudogenes, and a single gene for both α2 and α3. Their chromosomal locations were identified by interspecies backcross mapping. The α1 gene (Cappa1) mapped to Chromosome 3 betweenD3Mit11andD3Mit13.The α1 pseudogenes (Cappa1-ps1andCappa1-ps2) mapped to Chromosomes 1 and 9, respectively. The α2 gene (Cappa2) mapped to Chromosome 6 nearPtn.The α3 gene (Cappa3) also mapped to Chromosome 6, approximately 68 cM distal fromCappa2nearKras2.One mouse mutation,de,maps in the vicinity of the α1 gene. No known mouse mutations map to regions near the α2 or α3 genes.     

Subunit Composition of the Zinc Proteins α- and β-Lipovitellin from Chicken

Chicken α- and β-lipovitellin are derived from parent vitellogenin proteins and contain four subunits (125, 80, 40, and 30 kDa) and two subunits (125 and 30 kDa), respectively. Metal analyses demonstrate both are zinc proteins containing 2.1 ± 0.2 mol of zinc/275 kDa per α-lipovitellin and 1.4 ± 0.2 mol of zinc/155 kDa per β-lipovitellin, respectively. The subunits of β-lipovitellin, Lv 1 (MW 125 kDa) and Lv 2 (MW 30 kDa), are separated by gel exclusion chromatography in the presence of zwittergent 3–16. Zinc elutes with Lv 1, suggesting that this subunit binds zinc in the absence of Lv 2. The subunits of α- and β-lipovitellin were separated by SDS-PAGE, digested with trypsin, and mapped by reverse-phase HPLC. The peptide maps of the 125-kDa subunits from α- and β-lipovitellin are essentially identical. Similar results are obtained for the 30-kDa subunits of both lipovitellins. The sequences of five and four peptides of the 125-kDa subunit of α- and β-Lv, respectively, and two peptides of the 30-kDa subunit of α- and β-lipovitellin were determined and match those predicted from the gene for vitellogenin II, Vtg II. Comparison of the amino acid composition of the 125- and 30-kDa subunits of α- and β-lipovitellin support the conclusion that they originate from the same gene. The sequences of peptides from the 80- and 40-kDa subunits of α-lipovitellin have not been found in the NCBI nonredundant data bank. The 27-amino acid N-terminal sequence of the 40-kDa protein is 56% similar to the last third of the Lv 1-coding region of the Vtg II gene, suggesting it may come from an analogous region of the Vtg I gene. We propose a scheme for the precursor—product relationship of Vtg I.     

Crystal Structure of the Human Pol α B Subunit in Complex with the C-terminal Domain of the Catalytic Subunit

In eukaryotic DNA replication, short RNA-DNA hybrid primers synthesized by primase-DNA polymerase α (Prim-Pol α) are needed to start DNA replication by the replicative DNA polymerases, Pol δ and Pol ϵ. The C terminus of the Pol α catalytic subunit (p180_C) in complex with the B subunit (p70) regulates the RNA priming and DNA polymerizing activities of Prim-Pol α. It tethers Pol α and primase, facilitating RNA primer handover from primase to Pol α. To understand these regulatory mechanisms and to reveal the details of human Pol α organization, we determined the crystal structure of p70 in complex with p180_C. The structured portion of p70 includes a phosphodiesterase (PDE) domain and an oligonucleotide/oligosaccharide binding (OB) domain. The N-terminal domain and the linker connecting it to the PDE domain are disordered in the reported crystal structure. The p180_C adopts an elongated asymmetric saddle shape, with a three-helix bundle in the middle and zinc-binding modules (Zn1 and Zn2) on each side. The extensive p180_C-p70 interactions involve 20 hydrogen bonds and a number of hydrophobic interactions resulting in an extended buried surface of 4080 Ų. Importantly, in the structure of the p180_C-p70 complex with full-length p70, the residues from the N-terminal to the OB domain contribute to interactions with p180_C. The comparative structural analysis revealed both the conserved features and the differences between the human and yeast Pol α complexes.     

Characterization of the Fourth α Isoform of the Na,K-ATPase

The Na,K-ATPase is a major ion transport protein found in higher eukaryotic cells. The enzyme is composed of two subunits, α and β, and tissue-specific isoforms exist for each of these, α1, α2 and α3 and β1, β2 and β3. We have proposed that an additional α isoform, α4, exists based on genomic and cDNA cloning. The mRNA for this gene is expressed in rats and humans, exclusively in the testis, however the expression of a corresponding protein has not been demonstrated. In the current study, the putative α4 isoform has been functionally characterized as a novel isoform of the Na,K-ATPase in both rat testis and in α4 isoform cDNA transfected 3T3 cells. Using an α4 isoform-specific polyclonal antibody, the protein for this novel isoform is detected for the first time in both rat testis and in transfected cell lines. Ouabain binding competition assays reveal the presence of high affinity ouabain receptors in both rat testis and in transfected cell lines that have identical K _D values. Further studies of this high affinity ouabain receptor show that it also has high affinities for both Na⁺ and K⁺. The results from these experiments definitively demonstrate the presence of a novel isoform of the Na,K-ATPase in testis. Received: 4 December 1998/Revised: 1 February 1999     

Dual Targeting to Mitochondria and Chloroplasts： Characterization of Thr-tRNA Synthetase Targeting Peptide

There is a group of proteins that are encoded by a single gene, expressed as a single precursor protein and dually targeted to both mitochondria and chloroplasts using an ambiguous targeting peptide. Sequence analysis of 43 dual targeted proteins in comparison with 385 mitochondrial proteins and 567 chloroplast proteins ofArabidopsis thaliana revealed an overall significant increase in phenylalanines, leucines, and serines and a decrease in acidic amino acids and glycine in dual targeting peptides （dTPs）. The N-terminal portion of dTPs has significantly more serines than mTPs. The number of arginines is similar to those in mTPs, but almost twice as high as those in cTPs. We have investigated targeting determinants of the dual targeting peptide of Thr-tRNA synthetase （ThrRS-dTP） studying organellar import of N- and C-terminal deletion constructs of ThrRS-dTP coupled to GFR These results show that the 23 amino acid long N-terminal portion of ThrRS-dTP is crucial but not sufficient for the organellar import. The C-terminal deletions revealed that the shortest peptide that was capable of conferring dual targeting was 60 amino acids long. We have purified the ThrRS- dTP（2-60） to homogeneity after its expression as a fusion construct with GST followed by CNBr cleavage and ion exchange chromatography. The purified ThrRS-dTP（2-60） inhibited import of pF1β into mitochondria and of pSSU into chloroplasts at μM concentrations showing that dual and organelle-specific proteins use the same organellar import pathways. Furthermore, the CD spectra of ThrRS-dTP（2-60） indicated that the peptide has the propensity for forming α-helical structure in membrane mimetic environments; however, the membrane charge was not important for the amount of induced helical structure. This is the first study in which a dual targeting peptide has been purified and investigated by biochemical and biophysical means.     

Molecular Evolution and Nucleotide Sequences of the Maize Plastid Genes for the α Subunit of Cf1 (atpA) and the Proteolipid Subunit of Cf0 (atpH)

The nucleotide sequences of the maize plastid genes for the alpha subunit of CF1 (atpA) and the proteolipid subunit of CF0 (atpH) are presented. The evolution of these genes among higher plants is characterized by a transition mutation bias of about 2:1 and by rates of synonymous and nonsynonymous substitution which are much lower than similar rates for genes from other sources. This is consistent with the notion that the plastid genome is evolving conservatively in primary sequence. Yet, the mode and tempo of sequence evolution of these and other plastid-encoded coupling factor genes are not the same. In particular, higher rates of nonsynonymous substitution in atpE (the gene for the epsilon subunit of CF1) and higher rates of synonymous substitution in atpH in the dicot vs. monocot lineages of higher plants indicate that these sequences are likely subject to different evolutionary constraints in these two lineages. The 5'- and 3'-transcribed flanking regions of atpA and atpH from maize, wheat and tobacco are conserved in size, but contain few putative regulatory elements which are conserved either in their spatial arrangement or sequence complexity. However, these regions likely contain variable numbers of "species-specific" regulatory elements. The present studies thus suggest that the plastid genome is not a passive participant in an evolutionary process governed by a more rapidly changing, readily adaptive, nuclear compartment, but that novel strategies for the coordinate expression of genes in the plastid genome may arise through rapid evolution of the flanking sequences of these genes.     

Cloning,Purification, and Polymerization of Capsicum annuum Recombinant α and β Tubulin

α and β tubulin genes were cloned from the Capsicum annuum leaves using rapid amplification of cDNA ends (RACE)-PCR. Nucleotide sequence analysis revealed that 1,353 bp Capsicum annuum α?β-tubulin (CAnm α?β-TUB) encodes a protein of 450 amino acids (aa) each. The recombinant α?β tubulin was overexpressed mainly as an inclusion body in Escherichia coli BL21 (DE3), upon induction with 0.2 mM isopropyl-β-D-thiogalactopyranoside (IPTG), and its content was as high as 50% of the total protein content. Effective fusion protein purification and refolding are described. The average yields of α and β tubulin were 2.0 and 1.3 mg/l of culture respectively. The apparent molecular weight of each tubulin was estimated to be 55 kDa by SDS-polyacrylamide gel electrophoresis (PAGE). The tubulin monomers were found to be assembly competent using a standard dimerization assay, and also retained antigenicity with anti-His/T7 antibodies. The purified tubulins were polymerized to microtubule-like structures in the presence of 2 mM guanosine 5′-triphosphate (GTP).     

Cloning of the Fatty Acid Synthetase β Subunit from Fission Yeast, Coexpression with the α Subunit, and Purification of the Intact Multifunctional Enzyme Complex

We have cloned and sequenced the fission yeast (Schizosaccharomyces pombe)fas1⁺gene, which encodes the fatty acid synthetase (FAS) β subunit, by applying a PCR technique to conserved regions in the β subunit of the α₆β₆types of FAS among different organisms. The deduced amino acid sequence of the Fas1 polypeptide, consisting of 2073 amino acids (M_r= 230,616), exhibits the 48.1% identity with the β subunit from the budding yeast (Saccharomyces cerevisiae). This subunit, with five different catalytic activities, bears four distinct domains, while the α subunit, the sequence of which was previously reported by Saitohet al.(S. Saitohet al.,1996,J. Cell Biol.134, 949–961), carries three domains. We have developed a co-expression system of the FAS α and β subunits by cotransformation of two expression vectors, containing thelsd1⁺/fas2⁺gene and thefas1⁺gene, into fission yeast cells. The isolated FAS complex showed quite high specific activity, of more than 4000 mU/mg, suggesting complete purification. Its molecular weight was determined by dynamic light scattering and ultracentrifugation analysis to be 2.1–2.4 × 10⁶, and one molecule of the FAS complex was found to contain approximately six FMN molecules. These results indicate that the FAS complex fromS. pombeforms a heterododecameric α₆β₆structure. Electron micrographs of the negatively stained molecule suggest that the complex adopts a unique barrel-shaped cage architecture.     

Crystal Structure of the α Subunit of Human Translation Initiation Factor 2B

Eukaryotic translation initiation factor 2B (eIF2B) is the heteropentameric guanine-nucleotide exchange factor specific for eukaryotic initiation factor 2 (eIF2). Under stressed conditions, guanine-nucleotide exchange is strongly inhibited by the tight binding of phosphorylated eIF2 to eIF2B. Here, we report the crystal structure of the α subunit of human eIF2B at 2.65 Å resolution. The eIF2Bα structure consists of the N-terminal α-helical domain and the C-terminal Rossmann-fold-like domain. A positively charged pocket, whose entrance is about 15-17 Å in diameter, resides at the boundary between the two domains. A sulfate ion is located at the bottom of the pocket (about 16 Å in depth). The residues comprising the sulfate-ion-binding site are strictly conserved in eIF2Bα. Since this deep, wide pocket with the sulfate-ion-binding site is not conserved in distant homologues, including 5-methylthioribose 1-phosphate isomerases, these characteristics may be distinctive of eIF2Bα. Interestingly, the yeast eIF2Bα missense mutations that reduce the eIF2B sensitivity to phosphorylated eIF2 are mapped on the other side of the pocket. One of the three human eIF2Bα missense mutations that induce the lethal brain disorder vanishing white matter or childhood ataxia with central nervous system hypomyelination is mapped inside the pocket. The β and δ subunits of eIF2B are homologous to eIF2Bα and may have tertiary structures similar to the present eIF2Bα structure. The sulfate-ion-binding residues of eIF2Bα are well conserved in eIF2Bβ/δ. The abovementioned yeast and human missense mutations of eIF2Bβ/δ were also mapped on the eIF2Bα structure, which revealed that the human mutations are clustered on the same side as the pocket, while the yeast mutations reside on the opposite side. As most of the mutated residues are exposed on the surface of the eIF2B subunit structure, these exposed residues are likely to be involved in either the subunit interactions or the interaction with eIF2.     

The Structural Motifs for Substrate Binding and Dimerization of the α Subunit of Collagen Prolyl 4-Hydroxylase

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Characterization of the Testis-specific Proteasome Subunit α4s in Mammals

The 26 S proteasome is responsible for regulated proteolysis in eukaryotic cells. It is composed of one 20 S core particle (CP) flanked by one or two 19 S regulatory particles. The CP is composed of seven different α-type subunits (α1-α7) and seven different β-type subunits, three of which are catalytic. Vertebrates encode four additional catalytic β subunits that are expressed predominantly in immune tissues and produce distinct subtypes of CPs particularly well suited for the acquired immune system. In contrast, the diversity of α subunits remains poorly understood. Recently, another α subunit, referred to as α4s, was reported. However, little is known about α4s. Here we provide a detailed characterization of α4s and the α4s-containing CP. α4s is exclusively expressed in germ cells that enter the meiotic prophase and is incorporated into the CP in place of α4. A comparison of structural models revealed that the differences in the primary sequences between α4 and α4s are located on the outer surface of the CP, suggesting that α4s interacts with specific molecules via these unique regions. α4s-containing CPs account for the majority of the CPs in mouse sperm. The catalytic β subunits in the α4s-containing CP are β1, β2, and β5, and immunosubunits are not included in the α4s-containing CP. α4s-containing CPs have a set of peptidase activities almost identical to those of α4-containing CPs. Our results provide a basis for understanding the role of α4s and male germ cell-specific proteasomes in mammals.     

Artificial Proteins with Antiviral Properties of α-Interferons

Consensus 30–36 sequence LKDRHDF of human -interferons is inserted into the C- and N-terminal sequences of the artificial protein albeferon using genetic engineering methods in order to obtain artificial proteins with antiviral activity. Albeferon, obtained by Dolgikh et al. (Protein Eng., 1996, vol. 9, pp. 195–201), already contains the IFN- 130–137 fragment and possesses antiproliferative activity comparable with that of IFN-₂. According to CD spectroscopy, both proteins have regular secondary structures similar to that of the precursor protein. They exhibit antiviral activities, and the activity of one of them is comparable with that of IFN-₂. At the same time, their cytotoxic properties are displayed only at relatively high concentrations, which substantially exceed the minimal antiviral concentrations.     

Evolution of Class-Specific Peptides Targeting a Hot Spot of the Gαs Subunit

The four classes of heterotrimeric G-protein α subunits act as molecular routers inside cells, gating signals based on a bound guanosine nucleotide (guanosine 5′-triphosphate versus guanosine 5′-diphosphate). Ligands that specifically target individual subunits provide new tools for monitoring and modulating these networks, but are challenging to design due to the high sequence homology and structural plasticity of the Gα-binding surface. Here we have created an mRNA display library of peptides based on the short Gα-modulating peptide R6A-1 and selected variants that target a convergent protein-binding surface of Gαs·guanosine 5′-diphosphate. After selection/evolution, the most Gαs-specific peptide, Gαs(s)-binding peptide (GSP), was used to design a second-generation library, resulting in several new affinity- and selectivity-matured peptides denoted as mGSPs. The two-step evolutionary walk from R6A-1 to mGSP-1 resulted in an 8000-fold inversion in binding specificity, altered seven out of nine residues in the starting peptide core, and incorporated both positive and negative design steps. The resulting mGSP-1 peptide shows remarkable selectivity and affinity, exhibiting little or no binding to nine homologous Gα subunits or human H-Ras, and even discriminates the Gαs splice variant Gαs(l). Selected peptides make specific contacts with the effector-binding region of Gα, which may explain an interesting bifunctional activity observed in GSP. Overall, our work demonstrates a design of simple, linear, highly specific peptides that target a protein-binding surface of Gαs and argues that mRNA display-based selection/evolution is a powerful route for targeting protein families with high class specificity and state specificity.     

Purification of the α Subunit of Avian Myeloblastosis Virus DNA Polymerase by Polyuridylic Acid-Sepharose

The alpha subunit of the avian myeloblastosis virus DNA polymerase could be readily purified to near homogeneity using a polyuridylic acid-Sepharose column chromatography step.