Erratum - Analysis of extracellular superoxide dismutase and Akt in ascending aortic aneurysm with tricuspid or bicuspid aortic valve.

This correct the article published on European Journal of Histochemistry 2014;58:200-206 doi: 10.4081/ejh.2014.2383.

Analysis of extracellular superoxide dismutase and Akt in ascending aortic aneurysm with tricuspid or bicuspid aortic valve.

Ascending aortic aneurysm (AsAA) is a consequence of medial degeneration (MD), deriving from apoptotic loss of smooth muscle cells (SMC) and fragmentation of elastin and collagen fibers. Alterations of extracellular matrix structure and protein composition, typical of medial degeneration, can modulate intracellular pathways. In this study we examined the relevance of superoxide dismutase (SOD3) and Akt in AsAA pathogenesis, evaluating their tissue distribution and protein levels in ascending aortic tissues from controls (n=6), patients affected by AsAA associated to tricuspid aortic valve (TAV, n=9) or bicuspid aortic valve (BAV, n=9). The results showed a significant reduction of SOD3, phospho-Akt and Akt protein levels in AsAA tissues from patients with BAV, compared to controls, whereas the differences observed between controls and patients with TAV  were not significant. The decreased levels of SOD3 and Akt in BAV aortic tissues are associated with decreased Erk1/Erk2 phosphorylation and MMP-9 levels increase. The authors suggest a role of decreased SOD3 protein levels in the progression of AsAA with BAV and a link between ECM modifications of aortic media layer and impaired Erk1/Erk2 and Akt signaling in the late stages of the aortopathy associated with BAV.

Psychrophilic superoxide dismutase from Pseudoalteromonas haloplanktis: biochemical characterization and identification of a highly reactive cysteine residue.

A psychrophilic superoxide dismutase (SOD) has been characterized from the Antarctic eubacterium Pseudoalteromonas haloplanktis (Ph). PhSOD is a homodimeric iron-containing enzyme and displays a high specific activity, even at low temperature. The enzyme is inhibited by sodium azide and inactivated by hydrogen peroxide; it is also very sensitive to peroxynitrite, a physiological inactivator of the human mitochondrial Mn-SOD. Even though PhSOD is isolated from a cold-adapted micro-organism, its heat stability is well above the maximum growth temperature of P. haloplanktis, a feature common to other Fe- and Mn-SODs. The primary structure of PhSOD was determined by a combination of mass spectrometry and automated Edman degradation. The polypeptide chain is made of 192 amino acid residues, corresponding to a molecular mass of 21251 Da. The alignment with other Fe- and Mn-SODs showed a high amino acid identity with Fe-SOD from Vibrio cholerae (79%) and Escherichia coli (70%). A significant similarity is also shared with human mitochondrial Mn-SOD. PhSOD has the unique and highly reactive Cys57 residue, located in a variable region of the protein. The three-dimensional model of the PhSOD monomer indicates that Cys57 is included in a region, whose structural organization apparently discriminates between dimeric and tetrameric SODs. This residue forms a disulfide adduct with beta-mercaptoethanol, when this reducing agent is added in the purification procedure. The reactivity of Cys57 leads also to the formation of a disulfide bridge between two PhSOD subunits in specific denaturing conditions. The possible modification of Cys57 by physiological thiols, eventually regulating the PhSOD functioning, is discussed.

Phenylmethanesulfonyl fluoride inactivates an archaeal superoxide dismutase by chemical modification of a specific tyrosine residue. Cloning, sequencing and expression of the gene coding for Sulfolobus solfataricus superoxide dismutase.

The gene encoding the superoxide dismutase from the hyperthermophilic archaeon Sulfolobus solfataricus (SsSOD) was cloned and sequenced and its expression in Escherichia coli obtained. The chemicophysical properties of the recombinant SsSOD were identical with those of the native enzyme. The recombinant SsSOD possessed a covalent modification of Tyr41, already observed in native SsSOD [Ursby, T., Adinolfi, B.S., Al-Karadaghi, S., De Vendittis, E. & Bocchini, V. (1999) J. Mol. Biol. 286, 189--205]. HPLC analysis of SsSOD samples prepared from cells treated or not with phenylmethanesulfonyl fluoride (PhCH(2)SO(2)F), a protease inhibitor routinely added during the preparation of cell-free extracts, showed that the modification was caused by PhCH(2)SO(2)F. Refinement of the crystal model of SsSOD confirmed that a phenylmethanesulfonyl moiety was attached to the hydroxy group of Tyr41. PhCH(2)SO(2)F behaved as an irreversible inactivator of SsSOD; in fact, the specific activity of both native and recombinant enzyme decreased as the percentage of modification increased. The covalent modification caused by PhCH2SO2F reinforced the heat stability of SsSOD. These results show that Tyr41 plays an important role in the enzyme activity and the maintenance of the structural architecture of SsSOD.

The A26G replacement in the consensus sequence A-X-X-X-X-G-K-[T,S] of the guanine nucleotide binding site activates the intrinsic GTPase of the elongation factor 2 from the archaeon Sulfolobus solfataricus.

A recombinant form of the elongation factor 2 from the archaeon Sulfolobus solfataricus (SsEF-2), carrying the A26G substitution, has been produced and characterized. The amino acid replacement converted the guanine nucleotide binding consensus sequences A-X-X-X-X-G-K-[T,S] of the elongation factors EF-G or EF-2 into the corresponding G-X-X-X-X-G-K-[T,S] motif which is present in all the other GTP-binding proteins. The rate of poly(U)-directed poly(Phe) synthesis and the ribosome-dependent GTPase activity of A26GSsEF-2 were decreased compared to SsEF-2, thus indicating that the A26G replacement partially affected the function of SsEF-2 during translocation. In contrast, the A26G substitution enhanced the catalytic efficiency of the intrinsic SsEF-2 GTPase triggered by ethylene glycol [Raimo, G., Masullo, M., Scarano, G., & Bocchini, V. (1997) Biochimie 78, 832-837]. Surprisingly, A26GSsEF-2 was able to hydrolyse GTP even in the absence of ethylene glycol; furthermore, the alcohol increased the affinity for GTP without modifying the catalytic constant of A26GSsEF-2 GTPase. Compared to SsEF-2, the affinity of A26GSsEF-2 for [3H]GDP was significantly reduced. These findings suggest that A26 is a regulator of the biochemical functions of SsEF-2. The involvement of this alanine residue in the guanine nucleotide-binding pocket of EF-2 or EF-G is discussed.

Iron superoxide dismutase from the archaeon Sulfolobus solfataricus: analysis of structure and thermostability.

The crystal structure of superoxide dismutase (SOD) from the hyper thermophile Sulfolobus solfataricus has been determined at 2.3 A resolution by molecular replacement and refined to a crystallographic R-factor of 16.8 % (Rfree 19.8 %). The crystals belong to the space group C2 (a=76.3 A, b=124.3 A, c=60.3 A, beta=128.8 degrees) with two identical monomers in the asymmetric unit. The monomer has a molecular weight of 24 kDa and consists of 210 amino acid residues of which 205 are visible in the electron density map. The overall fold of the monomer of S. solfataricus SOD is similar to that of the other known Fe or Mn-SODs. S. solfataricus SOD forms a very compact tetramer of a type similar to that of SOD from the hyperthermophile Aquifex pyrophilus. Both structures show an elevated number of inter-subunit ion-pairs compared with the mesophilic SOD from Mycobacterium tuberculosis and the thermophilic SOD from Thermus thermophilus. However, in contrast to the A. pyrophilus SOD structure, the number of intra-subunit ion-pairs as well as inter- subunit hydrogen bonds is not higher than in the compared mesophilic and thermophilic SOD structures. The electron density also revealed an unexpected and unusual covalent modification of a conserved tyrosine in the active site. Its involvement in the specific activity of the enzyme is discussed.

Protein engineering on enzymes of the peptide elongation cycle in Sulfolobus solfataricus.

The present article is a review of the work done on the elongation factors EF-1 alpha, EF-2 and EF-1 beta isolated from the hyperthermophilic archaeon Sulfolobus solfataricus. The molecular, physical and biochemical properties of the intact, truncated, mutant or chimeric forms are described and compared.

Heterologous expression in Escherichia coli of the gene encoding an archaeal thermoacidophilic elongation factor 2. Properties of the recombinant protein.

The gene encoding the elongation factor 2 from the hyperthermophilic archaeon Sulfolobus solfataricus (SsEF-2) was expressed in Escherichia coli using the pT7-7 expression vector. The synthesis of the heterologous product did not increase upon addition of isopropyl-beta-thiogalactopyranoside. The amount of purified intact recombinant SsEF-2 (SsEF-2rec) was about 3 mg from 60 g of transformed wet cells. Recombinant and naturally occurring SsEF-2 showed identical electrophoretic mobility, immunological properties and the N-terminal amino acid sequence; both were lacking the initial methionine. Differently from SsEF-2, SsEF-2rec did not undergo post-translational modification of His603 into diphthamide, as indicated by its inability to be ADP-ribosylated. SsEF-2rec appeared indistinguishable from SsEF-2 in the fulfillment of its biological functions; in fact, it was fully capable to support poly(Phe) synthesis, to bind GDP and to display either the intrinsic or the ribosome-dependent GTPase. Finally, SsEF-2rec was endowed with the same heat stability as SsEF-2. Altogether these findings proved that SsEF-2rec was functionally active as SsEF-2. The used expression system could allow to produce mutated forms of SsEF-2 obtained by mutagenesis of the corresponding gene.

Protein-encoding genes in the sulfothermophilic archaea Sulfolobus and Pyrococcus.

A number of unrelated protein-encoding genes from sulfothermophilic archaea, Sulfolobus acidocaldarius, Sulfolobus solfataricus, Pyrococcus furiosus and Pyrococcus woesei, has been analyzed. In the Sulfolobus genus, the content of A + T is significantly higher than that of C + G and the base usage follows the order, A > T > G > C. In Pyrococcus, the A + T content is also higher than that of C + G, but with lower values; in the order of base usage, G precedes T. The codon usage of these sulfothermophiles has been determined; alternative start codons are frequently used in both genera; codon preferences reflect the rich A + T composition of the corresponding genomes; for both genera the codon bias is particularly evident within the different arginine triplets, where AGA and AGG are predominant. From the similarities in the codon usage, close taxonomic relationships become evident within the Sulfolobus or the Pyrococcus genus; a lower, but significant similarity is also clear between these genera. The synonymous codon usage of these sulfothermophiles shows similarities with that of Saccharomyces cerevisiae and bovine mitochondria, whereas clear divergences are observed with the halophilic archaeal genus, Halobacterium, or the eubacterium, Escherichia coli. The unrelated proteins of the considered sulfothermophiles have been analyzed for the content of hydrophobic residues; the comparison with mesophiles reveals a significant increase in the average hydrophobicity of amino acid residues. This finding could indicate a mechanism of adaptation of proteins in organisms living under extreme environments. It is noteworthy that an opposite trend, i.e. a decreased average hydrophobicity, occurs in unrelated halophilic proteins.

Archaebacterial elongation factor 1 alpha carries the catalytic site for GTP hydrolysis.

The elongation factor 1 alpha from the archaebacterium Sulfolobus solfataricus (aEF-1 alpha) possesses an intrinsic GTPase activity that is triggered by NaCl up to 5.2 M and requires the presence of at least 1 mM MgCl2 or MnCl2. Chloride salts of other monovalent cations are inefficient, whereas other sodium salts are much less efficient or not efficient at all as compared with NaCl. This aEF-1 alpha GTPase (GTPaseNa) reaches a maximum in a broad pH range and is not affected by other nucleoside triphosphates but is competitively inhibited by GDP. The turnover of GTPaseNa is rate limited by the breakdown of GTP. The Km for GTP is in the range of 2.2-9.3 microM, depending on the NaCl concentration and temperature. The highest catalytic efficiency is reached at 87 degrees C, which is the optimum temperature for growth of S. solfataricus. The energetic parameters of GTPaseNa are similar to those reported in the literature for the GTPase of Escherichia coli elongation factor Tu (EF-Tu) triggered by 2 M KCl, thus suggesting that the GTPase activity supported by either EF-Tu or aEF-1 alpha undergoes a similar mechanism of activation by salt at high concentration. A molecular mechanism for this activation is proposed.

Energetic aspects of intramolecular coupling between the nucleotide binding site and the distal switch II region of the yeast RAS2 protein.

We have studied the interaction of the yeast RAS2 protein with guanine nucleotides using energetic parameters for the dissociation of RAS.nucleotide complexes. The results indicated that a Gly-->Ser substitution at position 82 led to an altered interaction with GppNHp and, to a lesser extent, also with GDP. It was also possible to conclude that structural perturbation of Gly82 can stimulate nucleotide release by decreasing the energetic barrier for nucleotide dissociation. This, together with the observation that residues 80 and 81 are involved in the response of RAS to nucleotide exchange factors without affecting GDP binding per se, suggests a potential mechanism for exchange factor-stimulated GDP release.

Glucose phosphate isomerase (GPI) "Morcone": a new variant from Italy.

Here we report the 4th Italian case of glucose phosphate isomerase (GPI) deficiency. The propositus is a young man suffering from chronic haemolytic anaemia since birth with occasional transfusion requirement. Biochemical characterization of the defective enzyme revealed increased affinity for F-6-P, decreased affinity for G-6-P and marked thermoinstability. Electrophoretic mobility appeared normal. GPI from both parents showed similar but less pronounced biochemical alterations. The variant described here seems to be different from those previously reported. Thus, we propose the provisional name of GPI "Morcone".

Cloning and sequencing of the gene encoding thermostable elongation factor 2 in Sulfolobus solfataricus.

The gene (aEF-2) coding for the translation elongation factor 2 (aEF-2) in the thermoacidophilic archaebacterium, Sulfolobus solfataricus, has been cloned and sequenced. The deduced primary structure of aEF-2 is composed of 735 amino acids (aa), excluding the Met start residue. There are no Cys residues and the calculated M(r) is 81,699. In the coding region of aEF-2, the high A + T content greatly influences the codon usage. From the alignment of the primary structure of aEF-2 with that of the analogous factors from the three kingdoms, aa identities were derived. The greatest identity (82%) was found with EF-2 from Sulfolobus acidocaldarius; lower values were observed with other archaebacterial EF-2 (45-47%), eukaryotic EF-2 (38-40%) and with the functional eubacterial analogue EF-G (28-31%). aEF-2 possesses the consensus sequences required for a GTP-binding protein and the four regions which are supposed to be involved in the functional regulation of EF-2/EF-G. These data should have phylogenetic implications.

The SCH9 protein kinase mRNA contains a long 5' leader with a small open reading frame.

The SCH9 yeast gene, that was previously identified as a suppressor of cdc25 and ras1- ras2-ts temperature-sensitive mutants, encodes a putative protein kinase that positively regulates the progression of yeast cells through the G1 phase of the cell cycle. We have determined the structure of the SCH9 transcription unit, using primer extension and S1 mapping techniques. The corresponding mRNA included an unusually long 5' region of more than 600 nucleotides preceding the major open reading frame (ORF). While the latter corresponded to a protein of 824 amino acids, an upstream open reading frame (uORF) within the 5' leader could potentially encode a 54 amino acid peptide. To investigate the role of the AUGs within the uORF, we engineered chimaeric plasmid vectors in which SCH9 sequences including the promoter, the mRNA leader and the first 514 nucleotides of the major ORF were fused in-frame with beta-galactosidase-coding sequences. Upon introduction into yeast cells, the fusion protein was efficiently expressed. However, mutational disruption of the uORF using oligonucleotide-directed mutagenesis did not affect the level of expression of the fusion protein. This indicates that regulatory mechanisms in Saccharomyces cerevisiae prevent upstream AUGs within the SCH9 mRNA leader sequence from influencing translation from downstream initiation codons.

RAS residues that are distant from the GDP binding site play a critical role in dissociation factor-stimulated release of GDP.

We have previously shown that a conserved glycine at position 82 of the yeast RAS2 protein is involved in the conversion of RAS proteins from the GDP- to the GTP-bound form. We have now investigated the role of glycine 82 and neighbouring amino acids of the distal switch II region in the physiological mechanism of activation of RAS. We have introduced single and double amino acid substitutions at positions 80-83 of the RAS2 gene, and we have investigated the interaction of the corresponding proteins with a yeast GDP dissociation stimulator (SDC25 C-domain). Using purified RAS proteins, we have found that the SDC25-stimulated conversion of RAS from the GDP-bound inactive state to the GTP-bound active state was severely impaired by amino acid substitutions at positions 80-81. However, the rate and the extent of conversion from the GDP- to the GTP-bound form in the absence of dissociation factor was unaffected. The insensitivity of the mutated proteins to the dissociation factor in vitro was paralleled by an inhibitory effect on growth in vivo. The mutations did not significantly affect the interaction of RAS with adenylyl cyclase. These findings point to residues 80-82 as important determinants of the response of RAS to GDP dissociation factors. This suggests a molecular model for the enhancement of nucleotide release from RAS by such factors.

Role of glycine-82 as a pivot point during the transition from the inactive to the active form of the yeast Ras2 protein.

Ras proteins bind either GDP or GTP with high affinity. However, only the GTP-bound form of the yeast Ras2 protein is able to stimulate adenylyl cyclase. To identify amino acid residues that play a role in the conversion from the GDP-bound to the GTP-bound state of Ras proteins, we have searched for single amino acid substitutions that selectively affected the binding of one of the two nucleotides. We have found that the replacement of glycine-82 of the Ras2 protein by serine resulted in an increased rate of dissociation of Gpp(NH)p, a nonhydrolysable analog of GTP, while the GDP dissociation rate was not significantly modified. Glycine-82 resides in a region that is highly conserved between the yeast and human proteins. However, this residue is structurally distant from residues that participate in the binding of the nucleotide, as determined from the crystal structure of the human H-ras gene product. Therefore, the ability of the nucleotide binding site to discriminate between GDP and GTP is dependent not only on residues that are spatially close to the nucleotide, but also on distant amino acids. This is in agreement with the role of glycine-82 as a pivot point during the transition from the GDP- to the GTP-bound form of the Ras proteins.

Identification of regulatory residues of the yeast adenylyl cyclase.

We have attempted to identify amino acid residues of the yeast adenylyl cyclase that are involved in the regulation of its activity, by isolating adenylyl cyclase-linked spontaneous mutations capable of suppressing the temperature-sensitive phenotype of ras1- ras2-ts1 strains. We previously identified a mutated adenylyl cyclase in which a single point mutation, called CR14, led to the replacement of threonine 1651 with isoleucine. We have now investigated the biological effects of CR14, and of other mutations that cause the replacement of threonine 1651 by distinct amino acids. We have observed that the response of adenylyl cyclase to Ras can be either enhanced or attenuated, without significant effects on the steady-state level of the former enzyme in vivo, depending on the amino acid side chain at position 1651. Therefore, this residue identifies a regulatory region on the adenylyl cyclase molecule. We have also taken advantage of the attenuation of adenylyl cyclase function caused by the replacement of threonine 1651 with aspartic acid to isolate intragenic suppressor mutations. We have identified several point mutations, leading to single amino acid substitutions, individually capable of reactivating the attenuated adenylyl cyclase. The corresponding amino acid changes are located within a relatively small region, including residues 1331, 1345, 1348 and 1374. This region could be physiologically involved in the negative control of the carboxy-terminal catalytic domain.

Effect of propan-2-ol on enzymic and structural properties of elongation factor G.

Elongation factor G (EF-G) can support a GTPase activity in vitro even in the absence of ribosomes when propan-2-ol is present [GTPasep; De Vendittis, Masullo & Bocchini (1986) J. Biol. Chem. 261, 4445-4450]. In the present work the GTPasep activity of EF-G was further studied by investigating (i) the effect of ionic environment on GTPasep and (ii) the influence of propan-2-ol on the molecular structure of EF-G as determined by fluorescence and c.d. measurements. In the presence of 1-300 mM univalent cations (M+) alone, no detectable GTPasep activity was measured; however, in the presence of 1 mM-Mg2+ a considerable stimulation was observed at 40 mM-Li+ or 75 mM-NH4+. Among bivalent cations (M2+), 1 mM-Sr2+, 2-5 mM-Ca2+ and 1 mM-Ba2+ were the most effective, but, in the presence of 75 mM-NH4+, Mg2+ and Mn2+ became the most efficient, whereas the stimulation by other M2+ species was considerably decreased. C.d. measurements showed that the alcohol increased the mean molar residue ellipticity of EF-G at 285 nm, but not at 220 nm. As estimated from fluorescence measurements, in the presence of 20% (v/v) propan-2-ol the value of the dissociation constant of the complex formed between EF-G and 8-anilino-1-naphthalene-sulphonate decreased from 8 to 5 microM; similarly, the number of binding sites on EF-G for the fluorescent probe decreased from 13 to 6. Finally, the alcohol enhanced the quenching of the intrinsic fluorescence of EF-G caused by either acrylamide or KI. The data support the hypothesis that propan-2-ol induces moderate conformational changes of EF-G that make the catalytic centre accessible to the substrate even in the absence of ribosomes. Kinetics of GTPasep studied at different temperatures did not reveal additional structural changes of EF-G occurring with time or temperature.

Yeast mutants temperature-sensitive for growth after random mutagenesis of the chromosomal RAS2 gene and deletion of the RAS1 gene.

Saccharomyces cerevisiae strains with a disrupted RAS1 gene and with an intact RAS2 gene (ras1- RAS2 strains) grew well on both fermentable and nonfermentable carbon sources. By constructing isogenic mutants having a disrupted RAS1 locus and a randomly mutagenized chromosomal RAS2 gene, we obtained yeast strains with specific growth defects. The strain TS1 was unable to grow on nonfermentable carbon sources and galactose at 37 degrees C, while it could grow on glucose at the same temperature. The mutated RAS2 gene in TS1 cells encoded a protein with the glycines at positions 82 and 84 replaced by serine and arginine respectively. Both mutations were necessary for temperature sensitivity. We also isolated a mutant yeast that was unable to grow on nonfermentable carbon sources both at 30 and 37 degrees C, while growing on glucose at both temperatures. This phenotype was caused by a single chromosomal mutation, leading to the replacement of aspartic acid 40 of the RAS2 protein by asparagine. A ras1- yeast strain with a chromosomal RAS2 gene harbouring the three mutations together did not grow at any temperature using non-fermentable carbon sources, but it was able to grow on glucose at 30 degrees C, and not at 37 degrees C. The mutated proteins were much less effective than the wild-type RAS2 protein in the stimulation of adenylate cyclase, but were efficiently expressed in vivo. The possible roles of residues 40, 82 and 84 of the RAS2 protein in the regulation of adenylate cyclase are discussed.

Suppression of defective RAS1 and RAS2 functions in yeast by an adenylate cyclase activated by a single amino acid change.

We have constructed the yeast strain TS1, with the RAS2 gene replaced by mutant allele encoding a partially defective gene product, and with an inactive RAS1 gene. TS1 cells accumulate as unbudded cells upon temperature shift from 30 to 37 degrees C, thus showing that the RAS1 and RAS2 gene functions are important for progression through the G1 phase of the cell cycle. After the isolation of revertants able to grow at the nonpermissive temperature, we have found that a chromosomal point mutation can bypass the G1 arrest of TS1 and cdc25 cells, and the lethality of ras1 ras2 mutants. The mutation predicts the replacement of threonine by isoleucine at position 1651 of yeast adenylate cyclase. The RAS-independent, as well as the RAS-dependent adenylate cyclase activity, is increased by the mutation. Like the wild-type enzyme, the RAS-dependent activity of the mutant adenylate cyclase is turned on by the GTP-bound form of the RAS2 protein. The amino acid sequence surrounding the threonine 1651 shows similarity with protein kinase substrates. Possible implications for the function of adenylate cyclase are discussed.