NMR study of the exchange rates of allosterically responsive labile protons in the heme pockets of hemoglobin A.

1H NMR spectroscopy has been used to measure the proximal histidyl labile ring proton (NH) rates of exchange with bulk solvent in the individual subunits of hemoglobin (Hb) A. These protons displayed a substantial decrease in their exchange rates in comparison with related monomeric proteins and exhibited sensitivity to the quarternary state. With the beta subunit NH, the exchange behaviour was similar to an allosterically responsive subset of protons, which have been identified using 1H-3H methods (Englander, J.J., R. Rogero, and S. W. Englander, 1983, J. Mol. Biol. 169:325-344). Assuming similar exchange mechanisms for the two subunits, the NMR data suggested a more flexible alpha than beta subunit in Hb A.     

Proton magnetic resonance study of the influence of chemical modification, mutation, quaternary state, and ligation state on dynamic stability of the heme pocket in hemoglobin as reflected in the exchange of the proximal histidyl ring labile proton

Proton nuclear magnetic resonance spectroscopy has been utilized to investigate the rates of exchange with deuterium of the proximal histidyl ring protons in a series of chemically modified and mutated forms of Hb A. Differences in rates of exchange are related to differences in the stability of the deformed or partially unfolded intermediates from which exchange with bulk solvent takes place. Each modified/mutated Hb exhibited kinetic subunit heterogeneity in the reduced ferrous state, with the alpha subunit exhibiting faster exchange than the beta subunit. Modification or mutation resulted in significant increases in the His F8 ring NH exchange rates primarily for the affected subunit and only if the modification/mutation occurs at the allosterically important alpha 1 beta 2 subunit interface. Moreover, this enhancement in exchange rate is observed primarily in that quaternary state of the modified/mutated Hb in which the modified/substituted residue makes the intersubunit contact. This confirms the importance of allosteric constraints in determining the dynamic properties of the heme pocket. Using modified or mutated Hbs that can switch between the alternate quaternary states within a given ligation state or ligate within a given quaternary state, we show that the major portion of the enhanced exchange rate in R-state oxy Hb relative to T-state deoxy Hb originates from the quaternary switch rather than from ligation. However, solely ligation effects are not negligible. The exchange rates of the His F8 ring labile protons increase dramatically upon oxidizing the iron to the ferric state, and both the subunit kinetic heterogeneity and the allosteric sensitivity to the quaternary state are essentially abolished.(ABSTRACT TRUNCATED AT 250 WORDS)     

High pressure NMR studies of hemoproteins. The effect of pressure on the tertiary and quaternary structures of human adult ferrous hemoglobin

The effect of pressure on the tertiary and quaternary structures of human oxy, carbonmonoxy, and deoxyhemoglobin was examined by high pressure NMR spectroscopy at 300 MHz. The increased pressure displaced the ring current-shifted gamma 1-methyl resonance of beta E11 valine for oxy- and carbonmonoxyhemoglobin to the upfield side, whereas that of the alpha subunit was insensitive to pressure. Such a preferential pressure-induced upfield shift for the beta E11 valine gamma 1-methyl signal was also encountered for the isolated carbonmonoxy beta chain. For deoxyhemoglobin, hyperfine shifted resonances of the heme peripheral proton groups and the proximal histidyl NH proton for the beta subunit were pressure-dependent, in contrast to the pressure-insensitive responses for these resonances of the alpha subunit. These results indicate the structural nonequivalence of the pressure-induced structural changes in the alpha and beta subunits of hemoglobin. The exchangeable proton resonances due to the intra- and intersubunit hydrogen bonds which have been used as the oxy and deoxy quaternary structural probes were not changed upon pressurization. From all of above results, it was concluded that pressure induces the tertiary structural change preferentially at the beta heme pocket of the ferrous hemoglobin derivatives with the quaternary structure retained.     

A proton nuclear magnetic resonance investigation of proximal histidyl residues in human normal and abnormal hemoglobins. A probe for the heme pocket.

Proton nuclear magnetic resonance spectroscopy at 250 MHz has been used to investigate the conformations of proximal histidyl residues of human normal adult hemoglobin, hemoglobin Kempsey [beta 99(G1) Asp leads to Asn], hemoglobin Osler [beta 145(HC2) Tyr leads to Asp], and hemoglobin McKees Rocks [beta 145(HC2) Tyr leads to Term] around neutral pH in H2O at 27 degrees C, all in the deoxy form. Two resonances that occur between 58 and 76 ppm downfield from the water proton signal have been assigned to the hyperfine shifted proximal histidyl NH-exchangeable protons of the alpha- and beta-chains of deoxyhemoglobin. These two resonances are sensitive to the quaternary state of hemoglobin, amino acid substitutions in the alpha 1 beta 2-subunit interface and in the carboxy-terminal region of the beta-chain, and the addition of organic phosphates. The experimental results show that there are differences in the heme pockets among these four hemoglobins studied. The structural and dynamic information derived from the hyperfine shifted proximal histidyl NH-exchangeable proton resonances complement that obtained from the ferrous hyperfine shifted and exchangeable proton resonances of deoxyhemoglobin over the spectral region from 5 to 20 ppm downfield from H2O. The relationship between these findings and Perutz's stereochemical mechanism for the cooperative oxygenation of hemoglobin is discussed.     

Proton magnetic resonance study of the influence of heme 2,4 substituents on the exchange rates of labile protons in the heme pocket of myoglobin.

Four exchangeable protons with large hyperfine shifts are assigned in the heme pocket of sperm whale met-cyano myoglobin reconstituted with heme possessing acetyl groups, ethyl groups, bromines, and hydrogens at the 2,4 position, using both relaxation and chemical-shift data. The four protons arise from the ring NH's of the proximal (F8), distal (E7), and FG2 histidines, and the peptide NH of His F8. The similarity of all chemical shifts to those of the native protein as well as the invariance of the relaxation rates of the distal histidyl ring NH dictate essentially the same structure for the heme cavity of both native and reconstituted proteins. The exchange rates with bulk water of the four labile proteins in each modified protein were determined by saturation-transfer and line width methods. All four labile protons were found to have the same exchange rate as in the native protein for acetyl and ethyl 2,4 substituents; the two resolved labile protons in the derivative with 2,4 bromine were also unchanged. The reconstituted protein with hydrogens at the 2,4 position exhibited slower exchange rates for three of the four protons, indicating an increased dynamic stability of the heme pocket in the absence of bulky 2,4 substituents.     

The Bohr effect of hemoglobin intermediates and the role of salt bridges in the tertiary/quaternary transitions

Understanding mechanisms in cooperative proteins requires the analysis of the intermediate ligation states. The release of hydrogen ions at the intermediate states of native and chemically modified hemoglobin, known as the Bohr effect, is an indicator of the protein tertiary/quaternary transitions, useful for testing models of cooperativity. The Bohr effects due to ligation of one subunit of a dimer and two subunits across the dimer interface are not additive. The reductions of the Bohr effect due to the chemical modification of a Bohr group of one and two alpha or beta subunits are additive. The Bohr effects of monoliganded chemically modified hemoglobins indicate the additivity of the effects of ligation and chemical modification with the possible exception of ligation and chemical modification of the alpha subunits. These observations suggest that ligation of a subunit brings about a tertiary structure change of hemoglobin in the T quaternary structure, which breaks some salt bridges, releases hydrogen ions, and is signaled across the dimer interface in such a way that ligation of a second subunit in the adjacent dimer promotes the switch from the T to the R quaternary structure. The rupture of the salt bridges per se does not drive the transition.     

Substitution of the heme binding module in hemoglobin alpha- and beta-subunits. Implication for different regulation mechanisms of the heme proximal structure between hemoglobin and myoglobin

In our previous work, we demonstrated that the replacement of the "heme binding module," a segment from F1 to G5 site, in myoglobin with that of hemoglobin alpha-subunit converted the heme proximal structure of myoglobin into the alpha-subunit type (Inaba, K., Ishimori, K. and Morishima, I. (1998) J. Mol. Biol. 283, 311-327). To further examine the structural regulation by the heme binding module in hemoglobin, we synthesized the betaalpha(HBM)-subunit, in which the heme binding module (HBM) of hemoglobin beta-subunit was replaced by that of hemoglobin alpha-subunit. Based on the gel chromatography, the betaalpha(HBM)-subunit was preferentially associated with the alpha-subunit to form a heterotetramer, alpha(2)[betaalpha(HBM)(2)], just as is native beta-subunit. Deoxy-alpha(2)[betaalpha(HBM)(2)] tetramer exhibited the hyperfine-shifted NMR resonance from the proximal histidyl N(delta)H proton and the resonance Raman band from the Fe-His vibrational mode at the same positions as native hemoglobin. Also, NMR spectra of carbonmonoxy and cyanomet alpha(2)[betaalpha(HBM)(2)] tetramer were quite similar to those of native hemoglobin. Consequently, the heme environmental structure of the betaalpha(HBM)-subunit in tetrameric alpha(2)[betaalpha(HBM)(2)] was similar to that of the beta-subunit in native tetrameric Hb A, and the structural conversion by the module substitution was not clear in the hemoglobin subunits. The contrastive structural effects of the module substitution on myoglobin and hemoglobin subunits strongly suggest different regulation mechanisms of the heme proximal structure between these two globins. Whereas the heme proximal structure of monomeric myoglobin is simply determined by the amino acid sequence of the heme binding module, that of tetrameric hemoglobin appears to be closely coupled to the subunit interactions.     

Allosteric effects of chloride ions at the intradimeric alpha1beta1 and alpha2beta2 interfaces of human hemoglobin

The structural transition induced by ligand binding in human hemoglobin encompasses quaternary structure changes at the interfaces between the two alphabeta dimers. In contrast, the interfaces between alpha and beta subunits within the same dimer (i.e., alpha1beta1 and alpha2beta2 interfaces) are structurally invariant. Previous work from this laboratory using NMR spectroscopy has identified four sites at the intradimeric alpha1beta1 and alpha2beta2 interfaces that, although structurally invariant, experience significant changes in the rates of proton exchange upon ligand binding. These sites are Hisalpha103(G10) and Hisalpha122(H5) in each alpha subunit of the hemoglobin tetramer. In the present work, we show that the proton exchange at the Hisalpha103(G10) sites is affected by the interactions of hemoglobin with chloride ions. Increasing concentrations of chloride ions at pH 6.45 and at 37 degrees C enhance the exchange rate of the Hisalpha103(G10) N(epsilon 2) proton. The enhancement is greater in deoxygenated than in ligated hemoglobin. In the framework of the local unfolding model for proton exchange, these results suggest that the structural free energy and/or the proton transfer reactions at the Hisalpha103(G10) sites depend on the concentration of chloride ions. Therefore, the ligand-induced changes at the Hisalpha103(G10) sites are modulated by the allosteric effect of chloride ions on hemoglobin.     

Studies on cobalt myoglobins and hemoglobins. Preparation of isolated chains containing cobaltous protoporphyrin IX and characterization of their equilibrium and kinetic properties of oxygenation and EPR spectra.

Human hemoglobin containing cobalt protoporphyrin IX or cobalt hemoglobin has been separated into two functionally active alpha and beta subunits using a new method of subunit separation, in which the -SH groups of the isolated subunits were successfully regenerated by treatment with dithiothreitol in the presence of catalase. Oxygen equilibria of the isolated subunit chains were examined over a wide range of temperature using Imai's polarographic method (Imai, K., Morimoto, H., Kotani, M., Watari, H., and Kuroda, M. (1970) Biochim. Biophys. Acta 200, 189-196). Kinetic properties of their reversible oxygenation were investigated by the temperature jump relaxation method at 16 degrees. Electron paramagnetic resonance characteristics of the molecules in both deoxy and oxy states were studies at 77K. The oxygen affinity of the individual regenerated chains was higher than that of the tetrameric cobalt hemoglobin and was independent of pH. The enthalpy changes of the oxygenation have been determined as -13.8 kcal/mol and -16.8 kcal/mol for the alpha and beta chains, respectively. The rates of oxygenation were similar to those reported for iron hemoglobin chains, whereas those of deoxygenation were about 10(2) times larger. The effects of metal substitution on oxygenation properties of the isolated chains were correlated with the results obtained previously on cobalt hemoglobin and cobalt myoglobin. The EPR spectrum of the oxy alpha chain showed a distinctly narrowed hyperfine structure in comparison with that of the oxy beta chain, indicating that the environment around the paramagnetic center (the bound oxygen) is different between these chains. In the deoxy form, EPR spectra of alpha and beta chains were indistinguishable. These observations suggest that one of the inequivalences between alpha and beta chains might exist near the distal histidine group.     

Degradation of the subunits of receptor-bound human choriogonadotropin by Leydig tumor cells

Biologically active, iodine-labeled derivatives of human choriogonadotropin in which all the iodine is localized either in the alpha or beta subunits have been prepared. It is found that upon binding to Leydig tumor cells these derivatives are ultimately degraded to 3'-monoiodotyrosine. A comparison of the rates of degradation of the derivatives labeled exclusively in the alpha or beta subunits show that the alpha subunit is degraded somewhat faster than the beta subunit. It was also found that NH4Cl, chloroquine and leupeptin inhibited the degradation of both subunits to the same extent. These results show that the Leydig tumor cells degrade both subunits of the receptor-bound human choriogonadotropin, and suggest that the two subunits are degraded by the same mechanism(s).     

Rhodopsin and the retinal G-protein distinguish among G-protein beta gamma subunit forms

The beta gamma subunits of G-proteins are composed of closely related beta 35 and beta 36 subunits tightly associated with diverse 6-10 kDa gamma subunits. We have developed a reconstitution assay using rhodopsin-catalyzed guanosine 5'-3-O-(thio)triphosphate (GTP gamma S) binding to resolved alpha subunit of the retinal G-protein transducin (Gt alpha) to quantitate the activity of beta gamma proteins. Rhodopsin facilitates the exchange of GTP gamma S for GDP bound to Gt alpha beta gamma with a 60-fold higher apparent affinity than for Gt alpha alone. At limiting rhodopsin, G-protein-derived beta gamma subunits catalytically enhance the rate of GTP gamma S binding to resolved Gt alpha. The isolated beta gamma subunit of retinal G-protein (beta 1, gamma 1 genes) facilitates rhodopsin-catalyzed GTP gamma S exchange on Gt alpha in a concentration-dependent manner (K0.5 = 254 +/- 21 nM). Purified human placental beta 35 gamma, composed of beta 2 gene product and gamma-placenta protein (Evans, T., Fawzi, A., Fraser, E.D., Brown, L.M., and Northup, J.K. (1987) J. Biol. Chem. 262, 176-181), substitutes for Gt beta gamma reconstitution of rhodopsin with Gt alpha. However, human placental beta 35 gamma facilitates rhodopsin-catalyzed GTP gamma S exchange on Gt alpha with a higher apparent affinity than Gt beta gamma (K0.5 = 76 +/- 54 nM). As an alternative assay for these interactions, we have examined pertussis toxin-catalyzed ADP-ribosylation of the Gt alpha subunit which is markedly enhanced in rate by beta gamma subunits. Quantitative analyses of rates of pertussis modification reveal no differences in apparent affinity between Gt beta gamma and human placental beta 35 gamma (K0.5 values of 49 +/- 29 and 70 +/- 24 nM, respectively). Thus, the Gt alpha subunit alone does not distinguish among the beta gamma subunit forms. These results clearly show a high degree of functional homology among the beta 35 and beta 36 subunits of G-proteins for interaction with Gt alpha and rhodopsin, and establish a simple functional assay for the beta gamma subunits of G-proteins. Our data also suggest a specificity of recognition of beta gamma subunit forms which is dependent both on Gt alpha and rhodopsin. These results may indicate that the recently uncovered diversity in the expression of beta gamma subunit forms may complement the diversity of G alpha subunits in providing for specific receptor recognition of G-proteins.     

Intersubunit interactions in proton-translocating adenosine triphosphatase as revealed by hydrogen-exchange kinetics

The rates of hydrogen-deuterium exchange in the peptide groups of the alpha and beta subunits and the alpha-beta subunit complex of proton-translocating adenosine triphosphatase from the thermophilic bacterium PS3 were examined. The exchange was found to be much slower in the isolated beta subunit than in the isolated alpha subunit. This has been taken as indicating that the structure of the beta subunit is tighter than that of the alpha subunit. Adenosine 5'-triphosphate (ATP) caused tightening of a relatively tight portion of the alpha subunit and of a relatively loose portion of the beta subunit. When the alpha and beta subunits are brought into contact, tightening of the alpha subunit, but not the beta subunit, occurs. The effect of ATP on the structure of the beta subunit is more pronounced in the presence of the alpha subunit than in its absence. These findings support the idea proposed previously that the alpha subunit has an allosteric site and the beta subunit a catalytic site and that the conformation of the beta subunit is controlled by the alpha subunit.     

Assessment of roles of surface histidyl residues in the molecular basis of the Bohr effect and of beta 143 histidine in the binding of 2,3-bisphosphoglycerate in human normal adult hemoglobin.

Site-directed mutagenesis has been used to construct two mutant recombinant hemoglobins (rHbs), rHb(betaH116Q) and rHb(betaH143S). Purified rHbs were used to assign the C2 proton resonances of beta116His and beta143His and to resolve the ambiguous assignments made over the past years. In the present work, we have identified the C2 proton resonances of two surface histidyl residues of the beta chain, beta116His and beta143His, in both the carbonmonoxy and deoxy forms, by comparing the proton nuclear magnetic resonance (NMR) spectra of human normal adult hemoglobin (Hb A) with those of rHbs. Current assignments plus other previous assignments complete the assignments for all 24 surface histidyl residues of human normal adult hemoglobin. The individual pK values of 24 histidyl residues of Hb A were also measured in deuterium oxide (D(2)O) in 0.1 M N-(2-hydroxyethyl)piperazine-N'-2-ethanesulfonic acid (HEPES) buffer in the presence of 0.1 M chloride at 29 degrees C by monitoring the shifts of the C2 proton resonances of the histidyl residues as a function of pH. Among those surface histidyl residues, beta146His has the biggest contribution to the alkaline Bohr effect (63% at pH 7.4), and beta143His has the biggest contribution to the acid Bohr effect (71% at pH 5.1). alpha20His, alpha112His, and beta117His have essentially no contribution; alpha50His, alpha72His, alpha89His, beta97His, and beta116His have moderate positive contributions; and beta2His and beta77His have a moderate negative contribution to the Bohr effect. The sum of the contributions from 24 surface histidyl residues accounted for 86% of the alkaline Bohr effect at pH 7.4 and about 55% of the acid Bohr effect at pH 5.1. Although beta143His is located in the binding site for 2,3-bisphosphoglycerate (2,3-BPG) according to the crystal structure of deoxy-Hb A complexed with 2, 3-BPG, beta143His is not essential for the binding of 2,3-BPG in the neutral pH range according to the proton NMR and oxygen affinity studies presented here. With the accurately measured and assigned individual pK values for all surface histidyl residues, it is now possible to evaluate the Bohr effect microscopically for novel recombinant Hbs with important functional properties, such as low oxygen affinity and high cooperativity. The present study further confirms the importance of a global electrostatic network in regulating the Bohr effect of the hemoglobin molecule.     

Ca(2+) channel inactivation heterogeneity reveals physiological unbinding of auxiliary beta subunits.

Voltage gated Ca(2+) channel (VGCC) auxiliary beta subunits increase membrane expression of the main pore-forming alpha(1) subunits and finely tune channel activation and inactivation properties. In expression studies, co-expression of beta subunits also reduced neuronal Ca(2+) channel regulation by heterotrimeric G protein. Biochemical studies suggest that VGCC beta subunits and G protein betagamma can compete for overlapping interaction sites on VGCC alpha(1) subunits, suggesting a dynamic association of these subunits with alpha(1). In this work we have analyzed the stability of the alpha(1)/beta association under physiological conditions. Regulation of the alpha(1A) Ca(2+) channel inactivation properties by beta(1b) and beta(2a) subunits had two major effects: a shift in voltage-dependent inactivation (E(in)), and an increase of the non-inactivating current (R(in)). Unexpectedly, large variations in magnitude of the effects were recorded on E(in), when beta(1b) was expressed, and R(in), when beta(2a) was expressed. These variations were not proportional to the current amplitude, and occurred at similar levels of beta subunit expression. beta(2a)-induced variations of R(in) were, however, inversely proportional to the magnitude of G protein block. These data underline the two different mechanisms used by beta(1b) and beta(2a) to regulate channel inactivation, and suggest that the VGCC beta subunit can unbind the alpha1 subunit in physiological situations.     

A study on the quaternary structure change of hemoglobin in the ligation process

In order to inquire into the molecular mechanism underlying the cooperative ligand binding to hemoglobin (Hb), conformational interaction at the interfaces between subunits are investigated on the basis of the atomic coordinates of human deoxy and human carbonmonoxy Hbs. Hypothetical intermediate structures are used, each of which is obtained from the procedure where one or more subunits in deoxy Hb are replaced by the corresponding CO-liganded subunits in carbonmonoxy Hb using the method of superimposition of two sets of atomic coordinates. When either alpha or beta subunit is substituted with the corresponding subunit in carbonmonoxy Hb, serious steric hindrances are produced between alpha 1FG4(92)Arg and beta 2C3(37)Trp or between alpha 1C6(41)Thr and beta 2FG4(97)His, all of which belong to the allosteric core affected directly by ligand binding. These steric hindrances become more serious when both alpha 1(alpha 2) and beta 2(beta 1) subunits are substituted. Therefore the change in the relative distance between iron atom and porphyrin by ligation results in strain in the C-terminal residues as an effect of the steric hindrance between the FG and C segments. However, no steric hindrance can be seen between subunits when the subunits in carbonmonoxy Hb are substituted with the corresponding subunits in deoxy Hb. The nature of the quaternary structural change from liganded to deoxy Hb seems to be different from that from deoxy to liganded Hb.     

Study of the conversion of GDP-mannose into GDP-fucose in Nereids: a biochemical marker of oocyte maturation

The high-resolution proton nuclear magnetic resonance spectra of carp hemoglobin have been compared to those of human normal adult hemoglobin. Carp deoxy and carbonmonoxy hemoglobins in the deoxy-type quaternary state exhibit two downfield exchangeable proton resonances as compared to four seen in human normal adult deoxyhemoglobin. This suggests that two of the hydrogen bonds present in human normal adult deoxyhemoglobin are absent or occur in very different environments in carp hemoglobin. One of the exchangeable proton resonances of carp hemoglobin, while present in the deoxy-type quaternary state of the carbonmonoxy and deoxy derivatives, is absent in the oxy-type quaternary state of both, in agreement with the assignments of these quaternary structures by other methods. The ring-current-shifted proton resonances (sensitive tertiary structural markers) of carp carbonmonoxyhemoglobin are substantially different from those of human normal adult hemoglobin. The aromatic proton resonance region of carp hemoglobin has fewer resonances than that of human normal adult hemoglobin, consistent with its much reduced histidine content. The hyperfine-shifted proximal histidyl NH-exchangeable proton resonances of carp hemoglobin suggest that during the transition from the oxy to the deoxy quaternary structure, there is a greater alteration in the heme pocket of one type of subunits (presumably the beta chain) than that in the other subunit. The present results suggest that there are differences in both tertiary and quaternary structures between carp and human normal adult hemoglobins which could contribute to the great differences in the functional properties between these two proteins.     

The beta subunit increases the Ca2+ sensitivity of large conductance Ca2+-activated potassium channels by retaining the gating in the bursting states

Coexpression of the beta subunit (KV,Cabeta) with the alpha subunit of mammalian large conductance Ca2+- activated K+ (BK) channels greatly increases the apparent Ca2+ sensitivity of the channel. Using single-channel analysis to investigate the mechanism for this increase, we found that the beta subunit increased open probability (Po) by increasing burst duration 20-100-fold, while having little effect on the durations of the gaps (closed intervals) between bursts or on the numbers of detected open and closed states entered during gating. The effect of the beta subunit was not equivalent to raising intracellular Ca2+ in the absence of the beta subunit, suggesting that the beta subunit does not act by increasing all the Ca2+ binding rates proportionally. The beta subunit also inhibited transitions to subconductance levels. It is the retention of the BK channel in the bursting states by the beta subunit that increases the apparent Ca2+ sensitivity of the channel. In the presence of the beta subunit, each burst of openings is greatly amplified in duration through increases in both the numbers of openings per burst and in the mean open times. Native BK channels from cultured rat skeletal muscle were found to have bursting kinetics similar to channels expressed from alpha subunits alone.     

Deletions in the large (beta) subunit of a hetero-oligomeric aminoacyl-tRNA synthetase

Glycyl-tRNA synthetase is one of two aminoacyl-tRNA synthetases in Escherichia coli that is comprised of heterologous subunits which are organized in an alpha 2 beta 2 quaternary structure. The two subunits are encoded by a single mRNA with the region for alpha (303 codons) subunit followed by that for beta (689 codons) subunit. Five COOH-terminal deletions in the beta subunit coding region have been created. Each deletion protein has been investigated for its synthesis and stability in vivo, adenylate synthesis activity in vitro, and aminoacylation activity in vivo and in vitro. This has been done in the presence of free alpha subunit and, additionally, with alpha subunit that is fused by its carboxyl terminus to the amino terminus of each of the beta subunit deletion proteins. With a fused or unfused alpha chain, over 100 amino acids can be deleted from the carboxyl terminus of the beta chain without loss of in vivo complementation of a delta glyS (deletion) strain. Further analysis shows that the alpha subunit and approximately the amino-terminal half of the beta subunit are sufficient for the adenylate synthesis activity. In particular, a deletion of 306 amino acids from the COOH terminus of the beta subunit has little effect on the Km parameter for ATP or glycine in the pyrophosphate exchange reaction. The tRNA-dependent step in aminoacylation requires additional beta subunit sequences on the COOH-terminal side of those needed for adenylate synthesis. In these respects, the functional organization of the beta chain parallels that of several aminoacyl-tRNA synthetases which have only homologous subunits. In the case of the glycine enzyme, however, the heterologous alpha subunit is required for the elucidation of activities encoded by functional determinants of the beta chain.     

Receptor- and nucleotide exchange-independent mechanisms for promoting G protein subunit dissociation

Mechanisms for heterotrimeric G protein activation that do not rely on G protein coupled receptor activation are becoming increasingly apparent. We recently identified beta gamma subunit-binding peptides that we proposed bound to a "hot spot" on beta gamma subunits, stimulating G protein dissociation without stimulating nucleotide exchange and activating G protein signaling in intact cells. AGS3, a member of the activators of G protein signaling family of proteins, also activates G protein signaling in a nucleotide exchange-independent manner, and AGS3 homologues are involved in asymmetric cell division during development. Here we demonstrate that a consensus G protein regulatory (GPR) peptide from AGS3 and related proteins is sufficient to induce G protein subunit dissociation and that both the GPR and hot spot-binding peptides promote dissociation to extents comparable with a known G protein activator, AMF. Peptides derived from adenylyl cyclase 2 and GRK2 prevented formation of the heterotrimeric complex but did not alter the rate of alpha subunit dissociation from beta gamma subunits. These data indicate that these nucleotide exchange-independent G protein activator peptides do not simply compete for alpha interactions with beta gamma subunits, but actively promote subunit dissociation. Thus, we propose two novel mechanisms for nucleotide exchange independent activation of G protein signaling, one that involves conformational changes in the alpha subunit and one that involves conformational changes in the beta gamma subunits.     

Subunit interactions involved in the assembly of pyridine nucleotide transhydrogenase in the membranes of Escherichia coli.

The pyridine nucleotide transhydrogenase (PNT) of Escherichia coli consists of two different subunits (alpha and beta) and assembles as a tetramer (alpha 2 beta 2) in the inner membrane. The pnt genes from E. coli have been cloned on a multicopy plasmid resulting in high level expression of the enzyme activity. We have studied the influence of the different segments of the polypeptide chains of the alpha and beta subunits on the assembly and function of the enzyme by constructing a series of deletion mutants for both of the subunits. Our results show that the assembly of the beta subunit is contingent upon the insertion of the alpha subunit into the membrane, while the alpha subunit can assemble independently of the beta subunit. All deletions constructed for the cytosolic portion of the alpha subunit gave no incorporation of the alpha subunit and, as a consequence, of the beta subunit, also. Of the four membrane-spanning regions of the alpha subunit, the last two were indispensable, while the deletion of the first two still allowed the association of alpha as well as of the beta subunit with the membrane. However, the enzyme was not functional. The two subunits were also loosely associated as mild detergent treatment released them from the membrane in contrast with the wild-type enzyme. Deletions within the beta subunit had little effect on the assembly of the alpha subunit, although less was incorporated. All deletions involving the cytosolic portion of the beta subunit resulted in loss of incorporation into the membrane. Of the eight membrane-spanning regions of the beta subunit, the deletion of regions 2-3, 2-4, 2-6, and 2-7 yielded significant association of both the subunits with the membrane. However, none of these mutants assembled a functional enzyme, and again the two subunits were loosely associated with the membrane. Based on the stringent requirement of the cytosolic portions of alpha and beta subunits for assembly, a model is proposed that suggests interactions between these two regions must occur prior to assembly.