The measurement of the intrinsic alkaline Bohr effect of various human haemoglobins by isoelectric focusing

We have used isoelectric focusing to measure the differences between the pI values of various normal and mutant human haemoglobins when completely deoxygenated and when fully liganded with CO. It was assumed that the ΔpI(deox.–ox.) values might correspond quantitatively to the intrinsic alkaline Bohr effect, as most of the anionic cofactors of the haemoglobin molecule are `stripped' off during the electrophoretic process. In haemoglobins known to exhibit a normal Bohr coefficient (ΔlogP₅₀/ΔpH) in solutions, the ΔpI(deox.–ox.) values are lower the higher their respective pI(ox.) values. This indicates that for any particular haemoglobin the ΔpI(deox.–ox.) value accounts for the difference in surface charges at the pH of its pI value. This was confirmed by measuring, by the direct-titration technique, the difference in pH of deoxy and fully liganded haemoglobin A₀ (α₂β₂) solutions in conditions approximating those of the isoelectric focusing, i.e. at 5°C and very low concentration of KCl. The variation of the ΔpH(deox.–ox.) curve as a function of pH (ox.) was similar to the isoelectric-focusing curve relating the variation of ΔpI(deox.–ox.) versus pI(ox.) in various haemoglobins with Bohr factor identical with that of haemoglobin A₀. In haemoglobin A₀ the ΔpI(deox.–ox.) value is 0.17 pH unit, which corresponds to a difference of 1.20 positive charges between the oxy and deoxy states of the tetrameric haemoglobin. This value compares favourably with the values of the intrinsic Bohr effect estimated in back-titration experiments. The ΔpI(deox.–ox.) values of mutant or chemically modified haemoglobins carrying an abnormality at the N- or C-terminus of the α-chains are decreased by 30% compared with the ΔpI value measured in haemoglobin A₀. When the C-terminus of the β-chains is altered, as in Hb Nancy (α₂β^{Tyr-145→Asp}₂), we observed a 70% decrease in the ΔpI value compared with that measured in haemoglobin A₀. These values are in close agreement with the estimated respective roles of the two major Bohr groups, Val-1α and His-146β, at the origin of the intrinsic alkaline Bohr effect [Kilmartin, Fogg, Luzzana & Rossi-Bernardi (1973) J. Biol. Chem. 248, 7039–7043; Perutz, Kilmartin, Nishikura, Fogg, Butler & Rollema (1980) J. Mol. Biol. 138, 649–670]. In other mutant haemoglobins it is demonstrated also that the ΔpI(deox.–ox.) value may be decreased or even suppressed when the substitution affects residues involved in the stability of the tetramer. These results support the interpretation proposed by Perutz, Kilmartin, Nishikura, Fogg, Butler & Rollema [(1980), J. Mol. Biol. 138, 649–670] for the mechanism of the alkaline Bohr effect, and also indicate that the transition between the two quaternary configurations is a prerequisite for the full expression of the alkaline Bohr effect.     

Fish red blood cell carbon dioxide transport in vitro: A comparative study

Red blood cell (rbc) carbon dioxide transport was examined in vitro in three teleosts (Oncorhynchus mykiss, Anguilla anguilla, Scophthalmus maximus) and an elasmobranch (Scyliorhinus canicula) using a radioisotopic assay that measures the net conversion of plasma HCO₃⁻ to CO₂. The experiments were designed to compare the intrinsic rates of rbc CO₂ excretion and the impact of haemoglobin oxygenation/deoxygenation among the species.Under conditions simulating in vivo levels of plasma HCO₃⁻ and natural haematocrits, the rate of whole blood CO₂ excretion varied between 14.0 μmol ml⁻¹ h⁻¹ (S. canicula) and 17.6 μmol ml⁻¹ h⁻¹ (O. mykiss). The rate of CO₂ excretion in separated plasma was significantly greater in the dogfish, S. canicula. The contribution of the rbc to overall whole blood CO₂ excretion was low in the dogfish (46 ± 6%) compared to the teleosts (trout, 71 ± 4%; turbot, 64 ± 5%; eel, 55 ± 3%).To eliminate the naturally occurring differences in haematocrit and plasma [HCO₃⁻] as inter-specific variables, the rates of whole blood CO₂ excretion were determined in blood that had been resuspended to constant [HCO₃⁻] (5 mmol⁻¹) and haematocrit (20%) in appropriate teleost and elasmobranch Ringer solutions. Under such normalized conditions, the rate of whole blood CO₂ excretion was significantly higher in the turbot (22.4 ± 1.3 μmol ml⁻¹ h⁻¹) in comparison to the other species (16.4–18.4 μmol ml⁻¹ h⁻¹) and thus revealed a greater intrinsic rate of rbc CO₂ excretion in the turbot.To study the contribution of Bohr protons, the rates of whole blood CO₂ excretion were assessed in blood subjected to rapid oxygenation during the initial phase of the 3 min assay period. Rapid oxygenation significantly enhanced the rate of CO₂ excretion in the teleosts but not in the elasmobranch. The extent of the increase provided by the rapid oxygenation of haemoglobin was a linear function of the extent of the Haldane effect, as quantified in each species from in vitro CO₂ dissociation (combining) curves. Under steady-state conditions, deoxygenated blood exhibited greater rates of CO₂ excretion than oxygenated blood in the teleosts but not in the elasmobranch. As a consequence of the Haldane effect, rbc intracellular pH was increased in the teleosts by deoxygenation but was unaltered in the elasmobranch.The results, by extrapolation, suggest that the rates of CO₂ excretion in vivo are influenced by the magnitude of the Haldane effect and the extent of haemoglobin oxygenation during gill transit in addition to the intrinsic rate at which the rbc converts plasma HCO₃⁻ to CO₂.     

Evaluation of the water environments in deoxygenated sickle cells by longitudinal and transverse water proton relaxation rates

The longitudinal and transverse water proton relaxation rates of oxygenated and deoxygenated erythrocytes from both normal adults and individuals with sickle cell disease were measured as a function of temperature at two different frequencies. The simplest model which fits all of the data consists of three different environments for water molecules. The majority of the water (98%) has a correlation time indistinguishable from bulk water (3 × 10^?11 sec). Secondly, there is a small amount of water (1.3–1.5%) present which has a correlation time of 2–4 × 10 ^?9 sec and is apparently independent of the erythrocyte sample studied. Presumably this water is the hydration sphere around the hemoglobin molecules and its correlation time is significantly slower than bulk water. The third environment contains approximately 0.2% of the water present and has a correlation time≥ 10^?7 sec. This third environment is considered tightly bound to the hemoglobin because the water proton correlation time is very similar to the expected rotational correlation time for the hemoglobin molecules. The value of the transverse relaxation rate, f_b(T_2b)^?1, for the tightly bound water fraction decreases in oxy ($\text{S}\text{S}$), deoxy ($\text{A}\text{A}$), and oxy ($\text{A}\text{A}$) erythrocyte samples as the temperature is increased as expected for a rotational correlation time process. In dramatic contrast,f_b (T_2b)^?1 increases almost linearly as the temperature is increased over the whole 4 ° to 37 °C temperature range in samples of deoxy ($\text{S}\text{S}$) erythrocytes. The observation suggests a continual increase in the formation of deoxyhemoglobulin S polymers rather than a sudden transition from a homogeneous solution of deoxyhemoglobin S molecules to a solid gel.     

Circular dichroism and absorption spectra of haemoglobin Bart's

Circular dichroism spectra of haemoglobin Bart's (γ₄) in the region from 240 to 600 nm were different from those of human adult haemoglobin, but closely similar to those of the β-subunit of human adult haemoglobin. The amplitude of the positive circular dichroism maximum of deoxygenated haemoglobin Bart's in the Soret region was much less than that of human adult haemoglobin. The peak molar extinction coefficient of deoxygenated haemoglobin Bart's in the Soret region was found to be lower than that of deoxygenated human adult haemoglobin. These data indicate that haemoglobin Bart's, which is composed of four identical chains and lacks co-operativity, is structurally similar to haemoglobin H (β₄).     

Possible relationship between membrane proteins and phospholipid asymmetry in the human erythrocyte membrane

After incubation of human erythrocytes at 37 °C in the absence of glucose (A) for 24 h, (B) for 4 h with 8 mM hexanol or (C) for 3 h with SH reagents, phosphatidylethanolamine becomes partly susceptible to hydrolysis by phospholipase A₂ from Naja naja. The presence of glucose during the pretreatments suppresses this effect, except in the case of SH reagents that inhibit glycolysis. After incubation with tetrathionate, up to 45% of the phosphatidylethanolamine is degraded by the enzyme, an amount considerably in excess of the 20% attacked in fresh erythrocytes.Pancreatic phospholipase A₂, an enzyme unable to hydrolyse the phospholipids of intact erythrocytes, partially degrades phosphatidylcholine and phosphatidylethanolamine of erythrocytes pretreated with hexanol or SH reagents. Reagents capable of oxidizing SH groups to disulfides (tetrathionate, $\text{o-}\text{iodosobenzoate}$ and hydroquinone) even render susceptible to pancreatic phospholipase A₂ phosphatidylserine, a phospholipid supposed to be entirely located in the inner lipid layer of the membrane. Alkylating or acylating SH reagents have no such effect. It is postulated that disulfide bond formation between membrane protein SH groups leads to an alteration in protein-phospholipid interactions and consequently induces a reorientation of phospholipids between the inner and the outer membrane lipid layer.     

Photochemical Apparatus Organization in Anacystis nidulans (Cyanophyceae) : Effect of CO(2) Concentration during Cell Growth

Anacystis nidulans cells grown under high (3%) CO₂ partial pressure have greater phycocyanin to chlorophyll ratio (Phc/Chl) relative to cells grown under low (0.2%) CO₂ tension (Eley (1971) Plant Cell Physiol 12: 311-316). Absorbance difference spectrophotometry of A. nidulans thylakoid membranes in the ultraviolet (ΔA₃₂₀) and red (ΔA₇₀₀) regions of the spectrum reveal photosystem II/photosystem I (PSII/PSI) reaction center ratio (RCII/RCI) changes that parallel those of Phc/Chl. For cells growing under 3% CO₂, the Phc/Chl ratio was 0.48 and RCII/RCI = 0.40. At 0.2% CO₂, Phc/Chl = 0.38 and RCII/RCI = 0.24. Excitation of intact cells at 620 nm sensitized RCII at a rate approximately 20 times faster than that of RCI, suggesting that Phc excitation is delivered to RCII only. In the presence of DCMU, excitation at 620 nm induced single exponential RCII photoconversion kinetics, suggesting a one-to-one structural-functional correspondance between phycobilisome and PSII complex in the thylakoid membrane. Therefore, phycobilisomes may serve as microscopic markers for the presence of PSII in the photosynthetic membrane of A. nidulans. Neither the size of individual phycobilisomes nor the Chl light-harvesting antenna of PSI changed under the two different CO₂ tensions during cell growth. Our results are compatible with the hypothesis that, at low CO₂ concentrations, the greater relative amounts of PSI present may facilitate greater rates of ATP synthesis via cyclic electron flow. The additional ATP may be required for the active uptake of CO₂ under such conditions.     

Quaternary structures and low frequency molecular vibrations of haems of deoxy and oxyhaemoglobin studied by resonance Raman scattering

The influence of quaternary structure on the low frequency molecular vibrations of the haem within deoxyhaemoglobin (deoxy Hb) and Oxyhaemoglobin (oxy Hb) was studied by resonance Raman scattering. The FeO₂ stretching frequency was essentially identical between the high affinity (R) state (Hb A) and low affinity (T) state (Hb Kansas and Hb M Milwaukee with inositol hexaphosphate). However in deoxy Hb, only one of the polarized lines showed an appreciable frequency shift upon switch of quaternary structure, i.e. 215 to 218 cm^?1 for the T state (Hb A, des-His(146β) Hb, and des-Arg(141α) Hb (pH 6.5)) and 220 to 221 cm^?1 for the R state (des-Arg(141α) Hb (pH 9.0), des-His(146β)-Arg(141α) Hb and NES des-Arg(141α) Hb). Based on the observed ⁵⁴Fe isotopic frequency shift of the corresponding Raman lines of deoxy Hb A (214 → 217 cm^?1), of deoxy NES des-Arg Hb (220 → 223 cm^?1), of the protoporphyrinato-Fe(II)-(2-methylimidazole) complex in the ferrous high spin state (207 → 211 cm^?1) and of deoxymyoglobin (220 → 222 cm^?1) (Kitagawa et al., 1979), and on substitution of perdeuterated for protonated 2-methylimidazole in the deoxygenated picket fence complex (T_pivPP)Fe²⁺ (2-MeIm) (209 → 206 cm^?1), and on the results of normal co-ordinates calculation carried out previously, we proposed that the 216 cm^?1 line of deoxy Hb is associated primarily with the FeN_ε(HisF8) stretching mode and accordingly that the FeN_ε(HisF8) bond is stretched in the T state due to a strain exerted by globin.     

The roles of nitrate,photosynthesis and protein turnover in the formation of nitrate reductase in the nit A mutant of Chlamydomonas

The appearance of nitrate reductase activity in derepressed cultures of the Nit A mutant of Chlamydomonas reinhardtii required concomitant photosynthetic CO₂ fixation and was inhibited when protein turnover was prevented. Provided leupeptin was included in the extraction buffer, a single species of nitrate reductase (molecular mass, m = 390 kDa) was extracted from Nit A cultures incubated in nitrate medium for 4 h. Cultures of the mutant incubated in nitrate-free medium contained a number of nitrate reductase species (m = 52–500 kDa). This evidence suggests that nitrate plays a role in the stabilisation of the structure of the mutant nitrate reductase. Only one species of nitrate reductase (m = 188 kDa) was extracted from wild type cultures grown with nitrate.     

Carbon assimilation variation and control in Picea rubens,Picea mariana,and their hybrids under ambient and elevated CO2

Key message

After 3 years of CO ₂ treatments, A stimulation from ambient to elevated CO ₂ was strongly related to the total dry mass change (%), supporting the sink demand A hypothesis.

Abstract

Adaptations related to gas exchange are important fitness traits in plants and have significant growth and ecological implications. Assimilation (A) and assimilation to internal CO₂ (AC _i ) response curve parameters were quantified from a red spruce (RS) (Picea rubens Sarg.)—black spruce (BS) [P. mariana (Mill.) B.S.P.] controlled-cross hybrid complex grown under ambient and elevated CO₂ conditions. Under ambient conditions, maximum A (A _max), maximum rate of carboxylation by rubisco (V _cmax), maximum rate of electron transport (J _max), and carboxylation efficiency (CE) generally increased with increasing BS content; however, under elevated CO₂ conditions, hybrid index 50 (hybrid index number is the percentage of RS, balance BS) often had greater values than the other indices. There were significant hybrid index, CO₂, and hybrid index × CO₂ effects for A _growth at 360 ppm (A ₃₆₀) and 720 ppm (A ₇₂₀). The net A stimulation (A _stim), from ambient to elevated CO₂ treatment after 3 years was 10.8, 57.8, 74.1, 69.8, and 58.7 %, for hybrid indices 0 (BS), 25, 50, 75, and 100 (RS), respectively. Why does BS have the least A _stim, hybrid index 50 the most, and RS a moderate level? There was a significant relationship between A ₃₆₀ and ambient total biomass among indices (P = 0.096), but none was found between A ₇₂₀ and elevated total biomass. However, A _stim (%) was strongly related to the change in total dry mass (%) in response to elevated CO₂ (R ² = 0.931, P = 0.008), supporting the hypothesis that sink demand drives A. Traits A _max, V _cmax and J _max were correlated to total chlorophyll concentration. Moreover, A _max V _cmax and J _max also showed a significant underlying male effect, particularly under ambient conditions consistent with the paternal inheritance of the chloroplast genome.     

Structures of deoxy and carbonmonoxy haemoglobin Kansas in the deoxy quaternary conformation.

Haemoglobin Kansas (Asn102(G4)β → Thr) is the only widely studied mutant or modified haemoglobin having four functional haems and displaying lower than normal oxygen affinity. Two forms of this mutant have been investigated by X-ray diffraction. The deoxy form, whose crystals are isomorphous with the native form, has been examined directly by the difference Fourier technique (3.4 Å). In addition to the replaced residue itself, the difference electron density map shows signs of slight movements throughout the region between α and β haem pockets. However, neither type of chain shows stereochemical evidence of a very abnormal oxygen affinity in the tetramer. The nature of the perturbation is different from that proposed in the earlier, low-resolution study of Greer (1971a). Exposure of deoxy crystals to carbon monoxide produces two new crystal forms similar but not identical to the native deoxy form. One of these structures has been solved by rotation and translation function methods and a difference map between carbonmonoxy haemoglobin Kansas in the deoxy quaternary structure and native deoxy haemoglobin has been calculated at 3.5 Å resolution. Carbon monoxide molecules are observed at three of the four haems, and two unidentified large peaks³ appear next to the sulphydryl groups of Cys93β. None of the interchain salt bridges which stabilize the deoxy quaternary state appears to be broken, but large tertiary structural changes are seen in the liganded chains. It seems that when the molecule is subjected to the lattice constraints of the deoxy crystal, the salt bridges do not break upon ligand binding, even though the pH dependence of the first Adair constant and the linearity of proton release with ligand uptake both imply that this does happen to stripped HbA in solution.     

Intermediate structure of normal human haemoglobin: methaemoglobin in the deoxy quaternary conformation

This paper describes a new method of producing a crystalline intermediate between the unligated and ligated states of haemoglobin, suitable for X-ray analysis, by the use of a lattice strengthening reagent. Acrylamide is polymerized in the liquid of crystallization after the crystal has grown, forming a stiff supporting gel between the haemoglobin molecules, but not covalent bonds with them. The structure of human haemoglobin A crystallized in the deoxy quaternary structure (T-state²) and then oxidized by air after lattice strengthening (tertiary structure made met, or r-state) was determined to 3.5 Å resolution by the difference Fourier technique. Marked changes in tertiary structure in the region of the haem pockets and the contacts between the subunits (α₁β₂) are observed. The iron is seen to move towards the plane of the porphyrin, causing a change of tilt of the haem. This appears to act as a lever setting in train stereochemical changes that loosen several hydrogen bonds within and between subunits, on which the stability of the tertiary and quaternary deoxy structures depend. The liganding water molecule itself causes a slight opening of the haem pocket in the α subunit, and a substantial one in the β subunit. The structural changes seen here in going from the tertiary deoxy to the aquomet state within the quaternary T-structure are similar, but opposite, to those seen earlier in going from aquomet to deoxy in the quaternary R-structure of BME-haemoglobin. Changes in tertiary structure associated with addition of ligand to the T-structure or the removal of ligand from the R-structure are thus seen to be complementary. Electron density maps show the α haems to undergo autoxidation more readily than the β haems, just as the β haems were reduced more easily than the α haems in BME-haemoglobin.     

Hemoglobin-water interactions in normal and sickle erythrocytes by proton magnetic resonance T1ϱ measurements

The dependence of the water proton magnetic resonance spin-lattice relaxation rate (T_1?^?1) in the rotating frame on the strength of the spin-locking (H₁) field has been investigated for packed oxy and deoxy normal and sickle erythrocytes at temperatures from 9 to 40 °C. The T_1?^?1 of oxy or deoxy normal erythrocytes shows no dependence on H₁ up to ~7 G at any temperature studied. On the other hand, T_1?^?1 decreases from about 40 s^?1 to 15 s^?1 (H₁ from 0 to ~7 G) for deoxygenated packed sickle cells at 40 °C. The magnitude of this variation of T_1?^?1 with H₁ decreases with decreasing temperature. Oxy packed sickle cells also show a dependence of T_1?^?1 on H₁ but the magnitude is <10% of that of the deoxygenated samples. These results suggest that water proton T_1?^?1 measurements are a sensitive probe of hemoglobin S polymerization and provide a novel technique for the study of slow water motions in these systems. The T_1?^?1 results are compared with low frequency T₁^?1 results of other investigators on hemoglobin S solutions. Analysis of the data suggests that water proton motions with correlation times of the order of 10^?5 s are present in the deoxygenated sickle cell samples at temperatures above 10 °C.     

Stability enhancement of an O2-tolerant NAD+-reducing [NiFe]-hydrogenase by a combination of immobilisation and chemical modification

The oxygen-tolerant, NAD⁺-reducing soluble hydrogenase (SH) from Ralstonia eutropha H16 is a promising catalyst for cofactor regeneration in enzyme-catalysed reduction processes. The technical use of the isolated enzyme, however, is limited by its relatively low stability under operational conditions such as agitation, elevated temperature or addition of co-solvents. The maximum half-life at a reaction temperature of 35 °C and pH 8.0 was only 5.3 h. In order to enhance the stability of the enzyme, it was immobilised onto the anionic resin Amberlite™ FPA54. At an immobilisation yield of 93.4% for adsorptive and 100% for covalent attachment, corresponding activities of 48.9 and 39.3%, respectively, were obtained. Covalent binding always yielded superior stabilisation. At elevated temperature and under agitation, stabilisation was further increased by modification of the covalently bound SH with methoxy-poly(ethylene) glycol (mPEG). A comparable effect was not achieved when SH modification was performed before immobilisation. In stationary aqueous solution, half-lives of up to 161 h at 25 °C and 32 h at 35 °C were obtained. In presence of the technically relevant co-solvents DMSO, DMF, 2-propanol and [EMIM][EtSO₄] half-lives of 14–29 h can now be achieved.     

Kinetics of the Oxyhydrogen Reaction in the Presence and Absence of Carbon Dioxide in Scenedesmus obliquus

The oxyhydrogen reaction in the presence and absence of CO₂ was studied in H₂-adapted Scenedesmus obliquus by monitoring the initial rates of H₂, O₂, and ¹⁴CO₂ uptake and the effect of inhibitors on these rates with gas-sensing electrodes and isotopic techniques. In the presence of 0.02 atmosphere O₂, the pH₂ was varied from 0 to 1 atmosphere. Whereas the rate of O₂ uptake increased by only 30%, the rate of H₂ uptake increased severalfold over the range of pH₂ values. At 0.1 atmosphere H₂ and 0.02 atmosphere O₂, rates for H₂ and O₂ uptake were between 15 and 25 micromoles per milligram chlorophyll per hour. As the pH₂ was changed from 0 to 1 atmosphere, the quotient H₂:O₂ changed from 0 to roughly 2. This change may reflect the competition between H₂ and the endogenous respiratory electron donors. Respiration in the presence of glucose and acetate was also competitive with H₂ uptake. KCN inhibited equally respiration (O₂ uptake in the absence of H₂) and the oxyhydrogen reaction in the presence and absence of CO₂. The uncoupler carbonyl cyanide p-trifluoromethoxyphenylhydrazone accelerated the rate of respiration and the oxyhydrogen reaction to a similar extent. It was concluded that the oxyhydrogen reaction both in the presence and absence of CO₂ has properties in common with components of respiration and photosynthesis. Participation of these two processes in the oxyhydrogen reaction would require a closely linked shuttle between mitochondrion and chloroplast.     

Structure of human deoxy cobalt haemoglobin

The structure of human adult deoxy cobalt haemoglobin has been compared to that of the native ferrous form by refinements based on X-ray data to 2.5 Å resolution. The two structures were refined in parallel by conventional methods and selected structural differences were measured by a novel difference refinement method applicable to closely related structures. The distance between the metal and the haem plane is 0.33 ± 0.08 Å in the cobalt derivative and 0.56 ± 0.03 Å in the native. The Co²⁺HisF8N_? bond length is about 0.1 to 0.2 Å longer than the Fe²⁺HisF8N_? bond length; the distance of N_? from the mean haem plane remains the same in the two structures and the substitution of cobalt for iron produces no significant change in globin structure. The free energy of co-operativity of cobalt haemoglobin is known to be about one-half of that of the native haemoglobin; the reason for this reduction is not evident from the structure of cobalt deoxyhaemoglobin.     

In vitro and in vivo analyses of the role of the carboxysomal β-type carbonic anhydrase of the cyanobacterium Synechococcus elongatus in carboxylation of ribulose-1,5-bisphosphate

The carboxylase activities of crude carboxysome preparations obtained from the wild-type Synechococcus elongatus strain PCC 7942 strain and the mutant defective in the carboxysomal carbonic anhydrase (CA) were compared. The carboxylation reaction required high concentrations of bicarbonate and was not even saturated at 50 mM bicarbonate. With the initial concentrations of 50 mM and 25 mM for bicarbonate and ribulose-1,5-bisphosphate (RuBP), respectively, the initial rate of RuBP carboxylation by the mutant carboxysome (0.22 μmol mg^?1 protein min^?1) was only 30 % of that observed for the wild-type carboxysomes (0.71 μmol mg^?1 protein min^?1), indicating the importance of the presence of CA in efficient catalysis by ribulose-1,5-bisphosphate carboxylase/oxygenase (Rubisco). While the mutant defective in the ccmLMNO genes, which lacks the carboxysome structure, could grow under aeration with 2 % (v/v) CO₂ in air, the mutant defective in ccaA as well as ccmLMNO required 5 % (v/v) CO₂ for growth, indicating that the cytoplasmically localized CcaA helped utilization of CO₂ by the cytoplasmically localized Rubisco by counteracting the action of the CO₂ hydration mechanism. The results predict that overexpression of Rubisco would hardly enhance CO₂ fixation by the cyanobacterium at CO₂ levels lower than 5 %, unless Rubisco is properly organized into carboxysomes.     

Organoelement derivatives of steroids: synthesis and structural characterization of diorganotin chloride adducts of hormones

Ten new diorganotin dichloride adducts of hormones of the type R₂SnCl₂·2L [where R = Me, Et, n-Bu, Oct and Ph; L = 4-androsten-17ß-ol-3-one (A); 5-androsten-3ß-ol-17-one (B); 4-androsten-17α- methyl-17ß-ol-3-one (C) and 3,17-dihydroxy-5- pregnene-20-one (D)] have been prepared and characterized at 297 K and 223 K. Spectroscopic measurements (IR; Raman; ¹H, ¹³C, ¹¹⁹Sn NMR) suggest the dissociation or fast ligand exchange in solution at 297 K. Hexa-coordinated adducts with bonding through carbonyl oxygen and trans-R groups in octahedral geometry are formulated at 223 K.     

Binding of VIVO2+ to the Fe binding sites of human serum transferrin. A theoretical study

The binding of V^IVO²⁺ to human serum transferrin (hTF) at the Fe^III binding sites is addressed. Geometry optimization calculations were performed for the binding of V^IVO²⁺ to the N-terminal lobe of hTF (hTF_N), and indicate that in the presence of CO₃ ^2? or HCO₃ ^?, V^IV is bound to five atoms in a distorted geometry. The structures of V^IVO–hTF_N species optimized at the semiempirical level were also used to calculate the ⁵¹V and ¹⁴N A tensors by density functional theory methods, and were compared with the reported experimental values. Globally, of all the calculated V^IVO–hTF structures, the one that yields the lowest calculated heats of formation and minimum deviations from the experimental values of the ⁵¹V and ¹⁴N A tensor components is the structure that includes CO₃ ^2? as a synergistic anion. In this structure the V=O bond length is approximately 1.6 Å, and the vanadium atom is also coordinated to the phenolate oxygen atom of Tyr188 (at approximately 1.9 Å), the aspartate oxygen atom of Asp63 (at approximately 1.9 Å), the His249 Nτ atom (at approximately 2.1 Å), and a carbonate oxygen atom (at approximately 1.8 Å). The Tyr95 phenolic ocygen atom is approximately 3.3 Å from the metal center, and thus is very weakly bound to V^IV. All of these oxygen atoms are able to establish dipolar interactions with groups of the protein.