Mechanism of the PII-activated phosphatase activity of Escherichia coli NRII (NtrB): how the different domains of NRII collaborate to act as a phosphatase

The phosphatase activity of the homodimeric NRII protein of Escherichia coli is activated by the PII protein and requires all three domains of NRII. Mutations in the N-terminal domain (L16R), central domain (A129T), C-terminal domain PII-binding site (S227R), and C-terminal domain ATP-lid (Y302N) of NRII result in diminished phosphatase activity. Here, we used heterodimers formed in vitro from purified homodimeric proteins to study the phosphatase activity. A129T, S227R, and Y302N mutant subunits and A129T/S227R, A129T/Y302N, and S227R/Y302N double-mutant subunits formed stable heterodimers and were amenable to analysis; heterodimers containing these mutant subunits in various combinations were formed and their activities assessed. Complementation of the PII-activated phosphatase activity was observed in heterodimers containing S227R and Y302N subunits and in heterodimers containing A129T and Y302N subunits, but not in heterodimers containing A129T and S227R subunits. Complementation of the PII-activated phosphatase activity was also observed in heterodimers containing A129T/S227R and Y302N subunits, but not in heterodimers containing A129T/Y302N and S227R subunits. Finally, inclusion of an S227R/Y302N subunit in a heterodimer with a subunit having wild-type phosphatase activity resulted in a dramatic decrease in phosphatase activity, while inclusion of an A129T/S227R subunit did not. These results suggest that the phosphatase activity of NRII requires the collaboration of the PII-binding site from one subunit of the dimer, the central domain from the same subunit, and the ATP-lid from the opposing subunit, in addition to the undefined N-terminal domain requirement(s).     

Investigations of the potential effects of phosphorylation of the MWFE and ESSS subunits on complex I activity and assembly

There have been several reports on the phosphorylation of various subunits of NADH-ubiquinone oxidoreductase (complex I) in mammalian mitochondria. The effects of phosphorylation on assembly or activity of these subunits have not been investigated directly. The cAMP-dependent phosphorylation of the MWFE and ESSS subunits in isolated bovine heart mitochondria has been recently reported. We have investigated the significance of potential phosphorylation of these two subunits in complex I assembly and function by mutational analysis of the phosphorylation sites. Chinese hamster mutant cell lines missing either the MWFE or the ESSS subunits were transfected and complemented with the corresponding wild type and mutant cDNAs made by site-directed mutagenesis. In MWFE the serine 55 was substituted by alanine, glutamate, glutamine, and aspartate (S55A, S55E, S55Q, and S55D, respectively). The glutamate substitutions might be expected to mimic the phosphorylated state of the protein. With the exception of the MWFE(S55A) mutant protein the assembly of complex I was completely blocked, and no activity could be detected. Various substitutions in the ESSS protein (S2A, S2E, S8A, S8E, T21A, T21E, S30A, S30E) appeared to cause lower levels of mature protein and a significantly reduced complex I activity measured polarographically. The ESSS (S2/8A) double mutant protein caused a complete failure to assemble. These mutational analyses suggest that if phosphorylation occurs in vivo, the effects on complex I activity are significant.     

Molecular and biochemical properties of the ATP-stimulated multicatalytic proteinase, ingensin, from rat liver

1. A high-molecular-mass multicatalytic proteinase, ingensin, has been purified from rat liver and biochemically characterized. Trypsinization in the presence of ATP prevented the degradation of ingensin subunits. 2. Glutaraldehyde, which copolymerizes proteins, increased the apparent molecular mass of the subunits on SDS-PAGE, indicating the occurrence of covalent crosslinking of subunits. ATP, in this case, lowered the extent of covalent crosslinking. These results suggest that ATP altered the conformation of ingensin subunits. 3. Urea-induced autodigestion experiments demonstrated that some low-molecular-weight subunits selectively disappeared without changes in the contents of other subunits. The chymotryptic activity of the proteinase was more resistant to autodigestion than its tryptic activity. Therefore, we conclude that separate subunits of the enzyme are responsible for the different peptide-hydrolyzing activities.     

Changes of the quaternary structure of microvillus aminopeptidase in the membrane

Microvillus aminopeptidase (EC 3.4.11.2) is an enzyme with a molecular weight around 300 000. Normal preparations contain three different subunits (subunit A, Mr 162 000; subunit B, Mr 123 000; subunit C, Mr 61 000). The relationship between the three subunits was studied by immunoelectrophoresis using specific antibodies against individual denatured subunits and by densitometric scanning of polyacrylamide gels after separation of the three subunits. The results suggest that microvillus aminopeptidase initially appears in the membrane as a symmetric molecule built up to two identical A subunits. These subunits are then split into equimolar amounts of subunit B and subunit C by trypsin. Subunit B cannot generate subunit C but may be further degraded. The reaction sequence described is one which occurs in vivo. Treatment of purified aminopeptidase with trypsin increases the specific activity twofold. This phenomenon does not seem to be correlated to the generation of subunit B and subunit C or to the transformation of amphiphilic form into hydrophilic form.     

Effect of the beta6 Glu replaced by Val mutation on the optical activity of hemoglobin S and of its beta subunits

The carbomonoxy derivatives of hemoglobin A and S showed a different optical activity in the Soret region of the spectrum as measured by circular dichroism. Different optical activity was also measured in the carbomonoxy derivatives of the beta subunits of hemoglobin A and S, the respective deoxy derivatives showed different circular dichroism spectra only in the presence of inositol hexaphosphate. Sedimentation velocity experiments showed that the differences in optical activity are not due to a different state of aggregation of the subunits. Modification of the tertiary structure of the beta subunits seems to be responsible for the phenomenon. Speculation based on the work of Hsu and Woody (Hsu, M.C., and Woody, R.W. (1971) J. Am. Chem. Soc. 93, 3515-3525) suggests the involvement of the beta15 tryptophan in the conformational changes produced by the beta6 Glu-Val mutation in hemoglobin S.     

The neurotoxic complex from the venom of Pseudocerastes fieldi. Contribution of the nontoxic subunit

The neurotoxic complex (Cb) from the venom of Pseudocerastes fieldi consists of an acidic non-toxic subunit (CbI) and a basic toxic one (CbII). The complex is only partially dissociated by salt-gradient chromatography; the two components are completely separable in the presence of urea. Chromatofocusing of CbI resulted in two protein peaks, both of which potentiated toxicity of CbII. CbI inhibits hemolysis induced by CbII, but not the phospholipase A2 activity of CbII. CbI reveals phospholipase A activity with non-micellar dithiolecithin, however, it shows no activity with micellar lecithin. The amino acid composition of CbI and its enzymatic activity, as well as the structural homology with A2 phospholipases of nontoxic subunits from other presynaptic neurotoxins may suggest that, a catalytic activity of the non-toxic subunits plays a role at the target site.     

RNase P: interface of the RNA and protein worlds

Ribonuclease P (RNase P) is an endonuclease involved in processing tRNA. It contains both RNA and protein subunits and occurs in all three domains of life: namely, Archaea, Bacteria and Eukarya. The RNase P RNA subunits from bacteria and some archaea are catalytically active in vitro, whereas those from eukaryotes and most archaea require protein subunits for activity. RNase P has been characterized biochemically and genetically in several systems, and detailed structural information is emerging for both RNA and protein subunits from phylogenetically diverse organisms. In vitro reconstitution of activity is providing insight into the role of proteins in the RNase P holoenzyme. Together, these findings are beginning to impart an understanding of the coevolution of the RNA and protein worlds.     

Reconstitution of ATPase activity from the isolated alpha, beta, and gamma subunits of the coupling factor, F1, of Escherichia coli.

The three major subunits (α, β and γ) of the coupling factor, F₁ ATPase, of $\text{Escherichia coli}$ were separated and purified by hydrophobic column chromatography after the enzyme was dissociated by cold inactivation. The ability to hydrolyze ATP was reconstituted by dialyzing the mixture of subunits against 0.05 M Tris-succinate, pH 6.0, containing 2 mM ATP and 2 mM MgCl₂. A mixture containing α, β and γ regained ATP hydrolyzing activity. Individual subunits alone or mixtures of any two subunits did not develop ATPase activity, except for a low but significant activity with α plus β. The reconstituted ATPase had a K_m of 0.23 mM for ATP and a molecular weight by sucrose gradient density centrifugation of about 280,000.     

The formation and activity of PP2A holoenzymes do not depend on the isoform of the catalytic subunit

The protein phosphatase 2A holoenzyme is composed of one catalytic C subunit, one regulatory/scaffolding A subunit, and one regulatory B subunit. The core enzyme consists of A and C subunits only. The A and C subunits both exist as two closely related isoforms, alpha and beta. The B subunits belong to four weakly related or unrelated families, designated B, B', B", and B"', with multiple members in each family. The existence of two A and two C subunit isoforms permits the formation of four core enzymes, AalphaCalpha, AalphaCbeta, AbetaCalpha, and AbetaCbeta, and each core enzyme could in theory give rise to multiple holoenzymes. Differences between Calpha and Cbeta in expression and subcellular localization during early embryonic development have been reported, which imply that Calpha and Cbeta have different functions. To address the question of whether these differences might be caused by enzymatic differences between Calpha and Cbeta, we purified six holoenzymes composed of AalphaCalpha or AalphaCbeta core enzyme and B subunits from the B, B', or B" families. In addition, we purified four holoenzymes composed of AbetaCalpha or AbetaCbeta and B'alpha1 or B"/PR72. The phosphatase activity of each purified form was assayed using myelin basic protein and histone H1 as substrates. We found that Calpha and Cbeta have identical phosphatase activities when associated with the same A and B subunits. Furthermore, no difference was found between Calpha and Cbeta in binding A or B subunits. These data suggest that the distinct functions of Calpha and Cbeta are not based on differences in enzymatic activity or subunit interaction. The implications for the relationship between the structure and function of Calpha and Cbeta are discussed.     

Mutations in the small subunit of cyanobacterial ribulose-bisphosphate carboxylase/oxygenase that modulate interactions with large subunits

In the cyanobacterium Anacystis nidulans (Synechococcus PCC6301), ribulose 1,5-bisphosphate carboxylase/oxygenase (Rbu-P2 carboxylase) is composed of eight large subunits and eight small subunits. There are three regions of the small subunit that contain amino acids that are conserved throughout evolution, from bacteria to higher plants. Since the function of the small subunit is not fully understood, site-directed mutagenesis was performed on highly conserved residues in the first and second conserved regions. Ser-16, Pro-19, Leu-21, and Tyr-54 were replaced by Asp-16, His-19, Glu-21, and Ser-54, respectively. Crude extracts containing the recombinant His-19 mutant enzyme indicated that there was little effect on either Rbu-P2 carboxylase activity or interactions between large and small subunits. However, the Asp-16, Glu-21, and Ser-54 mutations showed effects on Rbu-P2 carboxylase activity and the interaction between large and small subunits. The large and small subunits of the Asp-16, Glu-21, and Ser-54 enzymes were found to dissociate during nondenaturing gel electrophoresis or sucrose density gradient centrifugation. However, the dissociated small subunits remained functional and were capable of reconstituting Rbu-P2 carboxylase activity when added to large subunits. These results indicated that Ser-16, Leu-21, and Tyr-54 might play an important role in interactions between large and small subunits of the A. nidulans enzyme.     

Effects of treatment with GABA(A) receptor subunit antisense oligodeoxynucleotides on GABA-stimulated 36Cl- influx in the rat cerebral cortex

GABA(A) receptor function was studied in cerebral cortical vesicles prepared from rats after intracerebroventricular microinjections of antisense oligodeoxynucleotides (aODNs) for alpha1, gamma2, beta1, beta2 subunits. GABA(A) receptor alpha1 subunit aODNs decreased alpha1 subunit mRNA by 59+/-10%. Specific [3H]GABA binding was decreased by alpha1 or beta2 subunit aODNs (to 63+/-3% and 64+/-9%, respectively) but not changed by gamma2 subunit aODNs (94+/-5%). Specific [3H]flunitrazepam binding was increased by alpha1 or beta2 subunit aODNs (122+/-8% and 126+/-11%, respectively) and decreased by gamma2 subunit aODNs (50+/-13%). The "knockdown" of specific subunits of the GABA(A )receptor significantly influenced GABA-stimulated 36Cl- influx. Injection of alpha1 subunit aODNs decreased basal 36Cl- influx and the GABA Emax; enhanced GABA modulation by diazepam; and decreased antagonism of GABA activity by bicuculline. Injection of gamma2 subunit aODNs increased the GABA Emax; reversed the modulatory efficacy of diazepam from enhancement to inhibition of GABA-stimulation; and reduced the antagonist effect of bicuculline. Injection of beta2 subunit aODNs reduced the effect of diazepam whereas treatment with beta1 subunit aODNs had no effect on the drugs studied. Conclusions from our studies are: (1) alpha1 subunits promote, beta2 subunits maintain, and gamma2 subunits suppress GABA stimulation of 36Cl- influx; (2) alpha1 subunits suppress, whereas beta2, and gamma2 subunits promote allosteric modulation by benzodiazepines; (3) diazepam can act as an agonist or inverse agonist depending on the relative composition of the receptor subunits: and (4) the mixed competitive/non-competitive effects of bicuculline result from activity at alpha1 and gamma2 subunits and the lack of activity at beta1 and beta2 subunits.     

Modifications of 60 S ribosomal subunits induced by the ricin A chain

Incubation of 60 S ribosomal subunits with the ricin A chain reduced their stability during heat treatment. The toxin shifted the thermal denaturation curve of the subunits towards lower temperatures, in a similar way to that produced by the decrease in Mg²⁺ concentration. A brief heating (3 min at 57°C), which did not affect control subunit activity, enhanced protein synthesis inhibition of the toxin-treated subunits that released more 5 S RNA, in the form of nucleoprotein complex(es) with protein L5 and phosphoproteins P1P2 (RNP_H), than did heated control subunits [(1984) Eur. J. Biochem, 143, 303-307]. No nuclease activity tested on 60 S subunits and purified 5 S and 5.8 S RNA was found associated with the toxin. The results suggest that the toxin induced a limited conformational change of the 60 S subunit, which destabilized the interaction between RNP_H and the rest of the subunit.     

Analyses of the Involvement of PKA Regulation Mechanism in Meiotic Incompetence of Porcine Growing Oocytes

Mammalian growing oocytes (GOs) lack the ability to resume meiosis, although the molecular mechanism of this limitation is not fully understood. In the present study, we cloned cDNAs of cAMP-dependent protein-kinase (PKA) subunits from porcine oocytes and analyzed the involvement of the PKA regulation mechanism in the meiotic incompetence of GOs at the molecular level. We found a cAMP-independent high PKA activity in GOs throughout the in vitro culture using a porcine PKA assay system we established, and inhibition of the activity by injection of the antisense RNA of the PKA catalytic subunit (PKA-C) induced meiotic resumption in GOs. Then we examined the possibility that the amount of the PKA regulatory subunit (PKA-R), which can bind and inhibit PKA-C, was insufficient to suppress PKA activity in GOs because of the overexpression of two PKA-Rs, PRKAR1A and PRKAR2A. We found that neither of them affected PKA activity and induced meiotic resumption in GO although PRKAR2A could inhibit PKA activity and induce meiosis in cAMP-treated full-grown oocytes (FGOs). Finally, we analyzed the subcellular localization of PKA subunits and found that all the subunits were localized in the cytoplasm during meiotic arrest and that PKA-C and PRKAR2A, but not PRKAR1A, entered into the nucleus just before meiotic resumption in FGOs, whereas all of them remained in the cytoplasm in GOs throughout the culture period. Our findings suggest that the continuous high PKA activity is a primary cause of the meiotic incompetence of porcine GOs and that this PKA activity is not simply caused by an insufficient expression level of PKA-R, but can be attributed to more complex spatial-temporal regulation mechanisms.     

Different forms of human liver glutathione S-transferases arise from dimeric combinations of at least four immunologically and functionally distinct subunits.

Four immunologically distinct subunits were characterized in glutathione (GSH) S-transferases of human liver. Five cationic enzymes (pI 8.9, 8.5, 8.3, 8.2 and 8.0) have an apparently similar subunit composition, and are dimers of 26 500-Mr (A) and 24 500-Mr (B) subunits. A neutral enzyme, pI 6.8, is a dimer of B-type subunits. One of the anionic enzymes, pI 5.5, is also a dimer of 26 500-Mr subunits. However, the 26 500-Mr subunits of this anionic enzyme form are immunologically distinct from the A subunits of the cationic enzymes, and have been designated as A'. Immunoabsorption studies with the neutral enzyme, BB, and the antibodies raised against the cationic enzymes (AB) indicate that A and B subunits are immunologically distinct. Hybridization in vitro of the A and B subunits of the cationic enzymes (AB) results in the expected binary combinations of AA, AB and BB. Studies with the hybridized enzyme forms indicate that only the A subunits express GSH peroxidase activity. A' subunits have maximum affinity for p-nitrobenzyl chloride and p-nitrophenyl acetate, and the B subunits have highest activity towards 1-chloro-2,4-dinitrobenzene. The other anionic form, pI 4.5, present in liver is a heterodimer of 22 500-Mr (C) and B subunits. The C subunits of this enzyme are probably the same as the 22 500-Mr subunits present in human lung and placental GSH transferases. The distinct immunological nature of B and C subunits was also demonstrated by immunoaffinity and subunit-hybridization studies. The results of two-dimensional polyacrylamide-gel-electrophoretic analyses indicate that in human liver GSH transferases, three charge isomers of Mr 26 500 (A type), two charge isomers of Mr 24 500 (B type) and two charge isomers of Mr 22 500 (C type) subunits are present.     

Functional roles of four conserved charged residues in the membrane domain subunit NuoA of the proton-translocating NADH-quinone oxidoreductase from Escherichia coli

The H(+)(Na(+))-translocating NADH-quinone (Q) oxidoreductase (NDH-1) of Escherichia coli is composed of 13 different subunits (NuoA-N). Subunit NuoA (ND3, Nqo7) is one of the seven membrane domain subunits that are considered to be involved in H(+)(Na(+)) translocation. We demonstrated that in the Paracoccus denitrificans NDH-1 subunit, Nqo7 (ND3) directly interacts with peripheral subunits Nqo6 (PSST) and Nqo4 (49 kDa) by using cross-linkers (Di Bernardo, S., and Yagi, T. (2001) FEBS Lett. 508, 385-388 and Kao, M.-C., Matsuno-Yagi, A., and Yagi, T. (2004) Biochemistry 43, 3750-3755). To investigate the structural and functional roles of conserved charged amino acid residues, a nuoA knock-out mutant and site-specific mutants K46A, E51A, D79N, D79A, E81Q, E81A, and D79N/E81Q were constructed by utilizing chromosomal DNA manipulation. In terms of immunochemical and NADH dehydrogenase activity-staining analyses, all site-specific mutants are similar to the wild type, suggesting that those NuoA site-specific mutations do not significantly affect the assembly of peripheral subunits in situ. In addition, site-specific mutants showed similar deamino-NADH-K(3)Fe(CN)(6) reductase activity to the wild type. The K46A mutation scarcely inhibited deamino-NADH-Q reductase activity. In contrast, E51A, D79A, D79N, E81A, and E81Q mutation partially suppressed deamino-NADH-Q reductase activity to 30, 90, 40, 40, and 50%, respectively. The double mutant D79N/E81Q almost completely lost the energy-transducing NDH-1 activities but did not display any loss of deamino-NADH-K(3)Fe(CN)(6) reductase activity. The possible functional roles of residues Asp-79 and Glu-81 were discussed.     

The function of the small subunits of ribulose bisphosphate carboxylase-oxygenase

When ribulose bisphosphate carboxylase-oxygenase from Synechococcus (strain RRIMP N1) was precipitated under mildly acidic conditions, most of its small subunits remained in solution. The precipitated enzyme readily redissolved at neutral pH and remained as an octamer of large subunits with some small subunits still attached. Optimum pH for this separation was 5.3 and disulfide-reducing reagents were not necessary. The fraction of small subunits removed by a single precipitation increased with increasing NaCl concentration. Catalytic activity of small subunit-depleted enzyme was linearly proportional to the fraction of small subunits remaining, while the carboxylase:oxygenase activity ratio and the affinity for CO2 remained constant. When isolated small subunits were added back to depleted enzyme preparations at neutral pH, reassociation occurred with return of catalytic activity. Under the usual assay conditions at pH 7.7, the binding constant of the small subunits was estimated to be about 10(-9) M. The small subunits also bound avidly to surfaces. However, loss of small subunits from the enzyme during the course of purification was minimal. The results are consistent with a simple model in which only those large subunits which have a small subunit bound to them are catalytically competent. Thus, an essential, even if indirect, role for the small subunits in catalysis is indicated.     

Physicochemical characterization of A and B subunits of Shiga toxin and reconstitution of holotoxin from isolated subunits

The A and B subunits of Shiga toxin were isolated by high performance liquid chromatography and their physicochemical properties were examined. The A subunit of Shiga toxin purified from culture supernatant was not nicked, but it could be nicked in vitro by trypsin. The isoelectric points of the A and B subunits were determined to be 8.2 and 5.8, respectively. Amino acid compositions of the two subunits were also determined. The isolated A and B subunits were reconstituted to form active holotoxin which showed lethal activity to mice which was similar to that of native Shiga toxin.