Purification and characterization of a chloride ion-dependent α-glucosidase from the midgut gland of Japanese scallop (Patinopecten yessoensis)

Marine glycoside hydrolases hold enormous potential due to their habitat-related characteristics such as salt tolerance, barophilicity, and cold tolerance. We purified an α-glucosidase (PYG) from the midgut gland of the Japanese scallop (Patinopecten yessoensis) and found that this enzyme has unique characteristics. The use of acarbose affinity chromatography during the purification was particularly effective, increasing the specific activity 570-fold. PYG is an interesting chloride ion-dependent enzyme. Chloride ion causes distinctive changes in its enzymatic properties, increasing its hydrolysis rate, changing the pH profile of its enzyme activity, shifting the range of its pH stability to the alkaline region, and raising its optimal temperature from 37 to 55 °C. Furthermore, chloride ion altered PYG’s substrate specificity. PYG exhibited the highest V_max/K_m value toward maltooctaose in the absence of chloride ion and toward maltotriose in the presence of chloride ion.     

Effects of pH on toxicity of As,Cr, Cu,Ni and Zn to Selenastrum capricornutum Printz

Acute toxicity tests were conducted to establish the response of Selenastrum capricornutum Printz to sublethal concentrations of As, Cr, Cu, Ni and Zn at a broad range of pH levels. Cultures were incubated for a period of seven days at pH 4 in standard algal assay media containing sublethal concentrations of metals. At this low pH, growth was depressed for all metals tested. The adjustment of pH to higher levels resulted in increased growth when cultures were treated with As, Cu, or Ni and incubated for an additional 7 days. Toxicity was least at the optimum pH range for growth of the alga.The observation that the toxicity of As, Cu, and Ni to S. capricornutum decreases markedly at pH values above 4.0 may be of ecological importance in the control of acid mine pollution. If a high percentage of algae show a similar response to decreasing toxicity with increasing pH, it clearly would be of value to adopt measures which control pH as well as the levels of metals present. It was suggested that algae with a broad pH growth range, such as S. capricornutum, could benefit from the addition of highly alkaline materials to waters where certain metals are present.     

Effect of chloride on ferrous iron oxidation by a Leptospirillum ferriphilum‐dominated chemostat culture

Biomining is the use of microorganisms to catalyze metal extraction from sulfide ores. However, the available water in some biomining environments has high chloride concentrations and therefore, chloride toxicity to ferrous oxidizing microorganisms has been investigated. Batch biooxidation of Fe²⁺ by a Leptospirillum ferriphilum‐dominated culture was completely inhibited by 12 g L^?1 chloride. In addition, the effects of chloride on oxidation kinetics in a Fe²⁺ limited chemostat were studied. Results from the chemostat modeling suggest that the chloride toxicity was attributed to affects on the Fe²⁺ oxidation system, pH homeostasis, and lowering of the proton motive force. Modeling showed a decrease in the maximum specific growth rate (µ_max) and an increase in the substrate constant (K_s) with increasing chloride concentrations, indicating an effect on the Fe²⁺ oxidation system. The model proposes a lowered maintenance activity when the media was fed with 2–3 g L^?1 chloride with a concomitant drastic decrease in the true yield (Y_true). This model helps to understand the influence of chloride on Fe²⁺ biooxidation kinetics. Biotechnol. Bioeng. 2010; 106: 422–431. © 2010 Wiley Periodicals, Inc.     

Kinetic characteristics of the sulfate self-exchange in human red blood cells and red blood cell ghosts

Summary The sulfate and the chloride self-exchange fluxes were determined by measuring the rate of the tracer efflux from radioactively labeled human red blood cells and red blood cell ghosts. The concentration dependence and the pH-dependence of the sulfate self-exchange flux were studied. In addition, the effects of some monovalent and divalent anions on the sulfate and the chloride self-exchange fluxes were investigated.The sulfate self-exchange fluxes saturate, exhibiting a concentration maximum at sulfate concentrations between 100 and 300mm (25°C). The position of the concentration maximum depends upon pH. At high sulfate concentrations a self-inhibition of the flux becomes apparent. The apparent half-saturation constant and the apparent self-inhibition constant at pH 7.2 were 30mm and 400mm respectively. Within the pH range of 6.3–8.5, both constants decreased with increasing pH. No saturation of the sulfate self-exchange flux was observed if the sulfate concentration was raised by substituting sulfate for isoosmotic amounts of a second salt (NaCl, NaNO₃, Na-acetate, Na-lactate, Na-succinate or Na₂HPO₄). Red blood cells and red blood cell ghosts display the same pattern of concentration responsiveness.The sulfate self-exchange flux exhibits a pH-maximum at about pH 6.2 (37°C). The location of the pH-maximum is little affected by variations of the sulfate concentration. The logarithmic plots (log vs. pH) revealed that the flux/pH relation can be approximated by two straight lines. The slopes of the alkaline branches of the flux/pH curves range from –0.55 to –0.86, the slopes of the branches of the curves range from 0.08 to 1.14 and were strongly affected by changes of the sulfate concentrations. The apparent pK's obtained from the alkaline and from the acidic branches of the flux/pH curves were about 7.0 and 6.0, respectively. Intact red blood cells and red blood cell ghosts display the same type of pH-dependency of the sulfate self-exchange flux.The sulfate self-exchange flux is competitively inhibited by nitrate, chloride, acetate, oxalate and phosphate. The chloride self-exchange flux is competitively inhibited by thiocyanate, nitrate, sulfate and phosphate. The inhibition constants for the various anion species increase in the given sequence.The results of our studies indicate that the sulfate self-exchange flux is mediated by a two-site transport mechanism consisting either of a mobile carrier or a two-site pore. The experiments reported in this paper do not permit distinguishing between both transport mechanisms. The similarities of the sulfate and the chloride self-exchange flux and the mutual competition between sulfate and chloride point to a common transport system for both anion species.     

Sedimentation Properties of Dextran Sulfate-Low Density Lipoprotein Complexes

The nature of interaction between dextran sulfate and the human plasma low density lipoproteins of S_f 0–10 was investigated in high density media of glycine and glucose. The soluble complex formation between the two components was manifested by sedimentation of the lipoproteins along with dextran sulfate in the glycine and glucose media of density 1.063. The addition of sodium chloride to the mixture caused dissociation of the complex: during subsequent ultracentrifugation, flotation of lipoprotein and sedimentation of dextran sulfate occurred. However, when the complex is in the acidic glycine medium (pH 4.0), the addition of sodium chloride did not induce dissociation of the complex.

Both the solubility and the size of the complex were greatly influenced by the ratio of the two components in solution. At low relative concentrations of dextran sulfate, insoluble aggregates were formed; but the aggregates disintegrated into soluble units upon increasing the dextran sulfate concentrations. From the sedimentation patterns of dextran sulfate lipoprotein mixtures at various ratios, it was possible to estimate the ratio of the two components in the complex. In the presence of excess dextran sulfate a composite biphasic Schlieren diagram was produced as a result of the unusual Johnston-Ogston effect.     

The Effects of Culture Conditions on the Secretion of Human Lysozyme by Saccharomyces cerevisiae A2-1-1A

The effects of initial glucose concentrations on the cell growth, glucose usage, and human lysozyme (HLY) secretion under the ENOl promoter were examined in the Saccharomyces cerevisiae strain A2–1–1A harboring a multicopy plasmid. By increasing the initial glucose from 2 % to 10 %, the HLY secretion increased 7 ~ 8 fold although the cell growth was not affected. By adding a mixture of mineral salts to the basal medium, the HLY secretion was increased about twice due to the continuity of the HLY expression at the stationary phase of cell growth.

The high HLY secretion (5.5 mg per liter, 47-fold higher than the original level) was achieved by the strain A2–1–1A grown in the synthetic basal medium containing 10% initial glucose, and supplemented with mineral salts containing ammonium sulfate, potassium phosphate, potassium chloride, magnesium sulfate, and iron sulfate.     

Effect of soil chloride level on cadmium concentration in sunflower kernels

Understanding soil factors related to cadmium (Cd) uptake and accumulation in plants is important for development of agronomic technologies, and breeding strategy to produce low Cd crops. The objective of the study was to examine the effect of soluble salts (chloride and sulfate) and other soil factors on the Cd concentration in sunflower (Helianthus annuus L.) kernels. Commercial nonoilseed hybrid kernels and soils were sampled from 22 farmer's production fields in North Dakota and Minnesota. The sites sampled included saline and nonsaline variants from 7 soil series. Soils were sampled at four depths. Relationships between kernel Cd level and soil physical and chemical characteristics were examined. The soil pH covered a narrow range (7.3–8.1) at these sampled sites. Regression analysis showed that there was no correlation between kernel Cd and soil pH at any depth. The kernel Cd level was highly correlated with DTPA-extractable Cd in all 4 depths, and with clay content in sub-soils. Soil chloride and sulfate concentrations varied among soil series and within soil series. The absence of a statistically significant effect of soil sulfate level on kernel Cd concentration, indicated that soil sulfate levels did not affect Cd uptake by sunflower plants. However, soil chloride levels in sub-soil were correlated with kernel Cd. The most important soil factor was DTPA-extractable Cd. When chloride was included in the multiple regression equations, R square (R²) values improved significantly. These results demonstrate that soil chloride concentration is another important factor related to Cd uptake in sunflower plants.     

FACTORS AFFECTING THE TOXICITY OF SEVERAL LICHEN ACIDS: EFFECT OF PH AND LICHEN ACID CONCENTRATION

The effect of pH 5–8 and lichen acid concentration gradients (2.7 times 10⁻² - 2.7 times 10⁻⁶ m ) on the toxicity of the following lichen acids: usnic, lecanoric, evernic, vulpinic, stictic, fumarpro-tocetraric, psoromic, and atranorin, on spores of Funaria hygrometrica was tested. Percent germination and sporeling growth were used as indicators of toxicity. None of the lichen acids were significantly toxic, for either percent germination or sporeling growth at concentrations equal to or below 2.7 times 10⁻⁵ m at pH 7.0, but many of the lichen acids which increased in toxicity at values different from pH 7 may have been toxic at lower concentrations if a different pH was used for the assay. Lichen acid toxicity showed a good correlation with pH for the parameter of spore germination, or sporeling growth, or both. Some lichen acids did not inhibit germination but were effective in retarding sporeling growth, or vice versa. This observation is discussed in relation to changing fatty acids and other lipid composition as germination occurs. Two of the three O-methylated lichen acids (evernic and psoromic) were among the most effective in inhibiting growth over all, but at lower pH values these were less effective than non-O-methylated lichen acids. Stictic, which is also an O-methylated lichen acid, was the least effective inhibitor over all the pH values for both parameters, while vulpinic was the most toxic over all the pH values. The order of relative toxicity for the lichen acids is different, depending on the pH and concentration at which they are tested and depending on the parameter measured. Thus, in an ecological sense, it is difficult to evaluate the adaptive significance of a particular compound or group of compounds without knowing what factors influence the toxicity of those compounds and how these factors vary in the organism's habitat.     

Inorganic nitrogen source for autotrophic growth of Euglena mutabilis Schmitz

The effect of inorganic nitrogen source on population growth of Euglena mutabilis, an acidophillic benthic protozoa colonizing on the sediment of acid mine drainage, was investigated. Sodium nitrate, ammonium chloride, and ammonium sulfate were tested as nitrogen sources. The population density of E. mutabilis at equilibrium density cultivated in ammonium chloride‐ and ammonium sulfate‐containing media was 9–11 times higher than that in sodium nitrate‐containing medium at the optimal salt medium concentration. The population growth of E. mutabilis in ammonium sulfate‐containing medium was rapid and reached half of the equilibrium density after ca. 228 h, which was ca. 77 h earlier than that in ammonium chloride‐containing medium. Culture medium with ammonium sulfate as the nitrogen source achieved the highest maximum population density and the fastest growth rate among the three nitrogen salts used as nitrogen sources.     

非生物胁迫因子对棘孢木霉嗜铁素及钙调磷酸酶基因表达的影响

木霉菌(Trichoderma spp.)嗜铁素具有吸收、贮存和胞内运输铁的功能,对菌体自身的生长发育有重要作用,也是重要的生防促生因子,但嗜铁素的产量会受到环境中多种胁迫因子的影响。真菌的钙调磷酸酶基因能够调控外源离子的胁迫反应,但钙调磷酸酶信号通路与嗜铁素合成之间的关系并不明确。以棘孢木霉菌(Trichoderma asperellum)T6为材料,研究了NaCl、CaCl_2及pH对棘孢木霉菌T6嗜铁素产量以及嗜铁素合成关键基因(SidA)与钙调磷酸酶催化亚基基因(CnA)表达量的影响。结果表明,高浓度NaCl和CaCl_2以及高pH均能抑制嗜铁素的产生。利用半定量PCR分析得知,CnA基因与SidA基因之间存在一定的负调控关系,该结果与钙调磷酸酶专性抑制剂环孢菌素A能够提高嗜铁素产量的结果相一致。     

Magnesium and calcium ions enhance barotolerance of streptococci

Summary Magnesium and calcium ions were found to enhance barotolerance of Streptococcus faecalis ATCC strain 9790 growing in a complex, glucose-containing medium. Enhancement was indicated both by higher growth rates and yields at 408 atm, and also by an increase in the maximum pressure permitting growth from 550 to 700 atm. The optimum concentration of either ion was ca. 50 mM, and both ions appeared to be equipotent in affecting the same processes by chemically specific interactions. Sodium, potassium, strontium, manganous, chloride, bromide or sulfate ions were all ineffective or only marginally effective in enhancing barotolerance. Mg⁺⁺ and Ca⁺⁺ also enhanced growth of compressed, ribose-degrading cultures. Pressure increased the sensitivity of streptococcal growth to low pH, and there appeared to be two distinct effects of Mg⁺⁺ and Ca⁺⁺ on barotolerance. First, the rate of exponential growth was enhanced prior to the time at which culture acidity began to limit growth. Second, growth was possible in more acid conditions under pressure when the ions were present, and enhanced yields from compressed cultures were related to this partial reversal of the potentiating effect of high pressure on acid inhibition of growth.Barotolerance of Escherichia coli or Saccharomyces cerevisiae was not enhanced by these ions; while tolerance of two types of chain-forming cocci freshly isolated from a rotting mussel was enhanced.     

Toxicity of organotins towards the marine yeastDebaryomyces hansenii

Of nine organotin compounds tested towards the marine yeastDebaryomyces hansenii, only triphenyltin chloride (Ph₃SnCl) and mono-, di-, and tributyltin chloride induced significant K⁺ release from cells which was symptomatic of viability loss. The general order of toxicity of the butylated compounds was tributyltin chloride (Bu₃SnCl) > monobutyltin chloride (BuSnCl₃) dibutyltin chloride (Bu₂SnCl₂). The overall toxicity of Ph₃SnCl was similar to BuSnCl₃. Release of K⁺ induced by butylated tin compounds or by Ph₃SnCl was strongly dependent on the external pH. Maximal toxicity occurred at pH 6.5 for Bu₃SnCl, BuSnCl₃, and Ph₃SnCl, whereas maximal toxicity of Bu₂SnCl₂ occurred at pH 5.0. Toxicity was decreased above or below these values. The toxicity of BuSnCl₃, Bu₃SnCl, and Ph₃SnCl was reduced at salinity levels approximating to sea water conditions. Prior growth ofD. hansenii in 3% (w/v) NaCl also resulted in reduced sensitivity to Bu₃SnCl as evidenced by a decreased rate and extent of K⁺ efflux. Bu₃SnCl-induced Na⁺ release from cells grown in the absence or presence of 3% (w/v) NaCl was low and similar in both cases. It appeared that the monovalent cation was important in the reduction of Bu₃SnCl toxicity since Na₂SO₄ had a similar protective effect as NaCl while CsCl completely prevented K⁺ efflux. Thus, the effects of external NaCl were related both to Na⁺ and to Cl^–. These results emphasize that cellular and environmental factors influence the toxic effects of organotins and suggests that these compounds may be more effective antimicrobial agents in some environmental niches than in others.     

Kinetics of Sulfate Reduction in a Coastal Aquifer Contaminated with Petroleum Hydrocarbons

An integrated field and laboratory study was conducted to quantify the effect of environmental determinants on the activity of sulfate reducers in a freshwater aquifer contaminated with petroleum hydrocarbons (PHC). Within the contaminated zone, PHC-supported in␣situ sulfate reduction rates varied from 11.58±3.12 to 636±53 nmol cm⁻³ d⁻¹ and a linear increase (R ²=0.98) in reduction rate was observed with increasing in situ sulfate concentrations suggesting sulfate limitation. Half-saturation concentration (K _s) for sulfate reduction coupled to PHC mineralization was determined for the first time. At two different sites within the␣aquifer, maximum sulfate reduction rate under␣non-limiting conditions (R _max) was 5,000 nmol cm⁻³ d⁻¹, whereas the retrieved K _s values were 3.5 and 7.5 mM, respectively. The K _s values are the highest ever reported from a natural environment. Furthermore, the K _s values were significantly higher than in situ sulfate concentrations confirming sulfate limited growth. On addition of lactate and formate, sulfate reduction rate increased indicating that reactivity and bioavailability of organic substrate may also have played a role in rate inhibition in certain parts of the aquifer. Experiments with sulfide amendments show statistically minor decrease in sulfate reduction rates on addition of sulfide and analogous increase in sulfide toxicity with increasing sulfide concentrations (0.5–10 mM) was not apparent.     

Characterization of the Band 3 substrate site in human red cell ghosts by NDS-TEMPO,a disulfonatostilbene spin probe: The function of protons in NDS-TEMPO and substrate-anion binding in relation to anion transport

Summary NDS-TEMPO is a specific disulfonatostilbene spin label for the Band 3 substrate site (K. F. Schnell, W. Elbe, J. Käsbauer & E. Kaufmann,Biochim. Biophys. Acta 732:266–275, 1983). The pH dependence of NDS-TEMPO binding and of chloride and sulfate binding was studied in resealed human erythrocyte ghosts. pH was varied from 6.0 to 9.0. The ESR spectra from NDS-TEMPO-labeled red cell ghosts exhibited a strong immobilization of membrane-bound NDS-TEMPO. Changes of pH had no effect upon the mobility of membrane-bound NDS-TEMPO. A mutual competition between NDS-TEMPO binding and the binding of the substrate-anions, chloride and sulfate, was observed throughout the entire pH range. The maximal number of NDS-TEMPO binding sites per cell was in the range of 9.0×10⁵ to 1.10×10⁶ and was found to be insusceptible to changes of pH. The NDS-TEMPO/substrate-site and the chloride/substratesite dissociation constants amounted to 1.25 m and to 17mm and were independent of pH from pH 6.0 to 8.0, while the sulfate/substrate-site dissociation constant displayed a strong pH dependency with a maximum of 50mm at about pH 7.0. The NDS-TEMPO inhibition constants from the chloride and the sulfate flux experiments were 0.5 m (0°C) and 1.8 m (25°C), respectively, and are in close accordance with the NDS-TEMPO/substrate-site dissociation constants. Our studies provide strong evidence for the assumption that NDS-TEMPO binds in fact to the substrate site of Band 3. They show that the strong pH dependence of the chloride and of the sulfate transport cannot result from the pH dependency of substrate-anion binding, but point to the participation of ionizable regulator sites in transport catalysis. These regulator sites seem to be positioned outside the substrate site of the Band 3 transport domain.     

Purification,Crystallization and Some Enzymatic Properties of Acid Protease of Cladosporium sp. No. 45–2

An acid protease of Cladosporium sp. No. 45–2 was purified and crystallized by precipitation with ammonium sulfate, fractional precipitation with acetone, and pH adjustment. About 600 mg of third crystallized preparation was obtained from one liter of culture broth. The purified enzyme was chromatographically homogeneous and confirmed to be monodispersive by physicochemical criteria such as uhracentrifugal and electrophoretical analysis. The enzyme was most active at pH values between 2.5 and 2.7 toward both casein and hemoglobin and was stable at pH values from 2.5 to 7.0 on twenty hour incubation at 30°C.

Millimolar concentration of sodium lauryl sulfate markedly inhibited the enzyme, wheares diisopropyl phosphorofluoridate, sulfhydryl reagents, ethylenediaminetetra acetic acid, and divalent metal ion relatively little affected the activity. The enzyme was most resistant toward S-PI among the acid proteases tested.     

Influence of mixed electrolytes on the adsorption of lysozyme,PEG, and PEGylated lysozyme on a hydrophobic interaction chromatography resin

In a recent work (Werner A and Hasse H in J Chromatogr A 2013;1315:135) the influence of mixed electrolytes on the adsorption of the macromolecules lysozyme, PEG and di‐PEGylated lysozyme on a hydrophobic resin has been studied, but only at one overall ionic strength (3000 mM). The present work, therefore, extends these studies to other ionic strengths (2400 and 2700 mM), and explores the application of a model to predict the entire data set. The adsorbent is Toyopearl PPG‐600M. The solvent is a 25 mM aqueous sodium phosphate buffer at pH 7.0. The studied salts are sodium chloride, sodium sulfate, ammonium chloride and ammonium sulfate. Pure salts as well as binary and ternary mixtures of these salts with varying ratios of the amounts of the salts are studied at 25 °C. The loading of the adsorbent increases with increasing salt concentration for all macromolecules. Synergetic effects of the mixed electrolytes are observed. © 2017 American Institute of Chemical Engineers Biotechnol. Prog., 33:1104–1115, 2017     

Interactions of calcium sulfite with soils and plants

CaSO₃ is a by-product formed by several of the processes used for scrubbing SO₂ from flue gas produced by coal-burning power generators. Using CaSO₃ to improve the calcium status of acid soils would be a beneficial alternative to disposal in landfills. CaSO₃ has biocidal properties and is used as a disinfectant and food and drink preservative. It is important to evaluate under what conditions application to soils would not harm plant growth. Laboratory experiments confirmed that two transformations of CaSO₃ occurred in soil systems: (1) decomposition to produce SO₂ gas, and (2) oxidation to calcium sulfate. Conversion to SO₂ occurred in solution and soil at low pH, and acid soils treated with CaSO₃ were initially toxic to seedling root growth. The degree of toxicity was time-dependent, with reduction in toxicity occurring as CaSO₃ oxidized to calcium sulfate. Soil reaction also influenced toxicity, and at soil pH levels above 6, little seedling toxicity was evident.     

响应面法优化褐藻胶降解菌Cobetia sp.20发酵培养基

为了提高褐藻胶降解菌株Cobetia sp.20产褐藻胶裂解酶的能力,利用响应面法优化其发酵产褐藻胶裂解酶的培养基。首先利用单因素法分别对发酵培养基中的不同碳源、碳源添加量、不同氮源、氮源添加量以及氯化钠添加量、磷酸二氢钾添加量、硫酸镁添加量和pH进行探究,研究各因素对产酶的影响。在单因素实验的基础上,通过Plackett-Burman试验确定Cobetia sp.20发酵培养基中影响产酶的主要因素。通过响应面试验建立回归方程。研究结果表明,Cobetia sp.20最优发酵培养基配方为褐藻胶15.00 g/L、硫酸铵7.50 g/L、氯化钠15.00 g/L、硫酸镁0.50 g/L、磷酸二氢钾5.30 g/L、硫酸亚铁0.01 g/L、pH值7.58。优化后酶活为142.79 U/mL,比优化前提高了26.36%。褐藻胶裂解酶活的提高,为褐藻胶裂解酶的工业化生产提供了参考。     

Effect of hydrogen sulfide on growth of sulfate reducing bacteria

A culture of sulfate reducing bacteria (SRB) growing on lactate and sulfate was incubated at different pH values in the range of 5.8-7.0. The effect of pH on growth rate was determined in this pH range; the highest growth rate was observed at pH 6.7. Hydrogen sulfide produced from sulfate reduction was found to have a direct and reversible toxicity effect on the SRB. A hydrogen sulfide Concentration of 547 mg/L (16.1 mM) completely inhibited the culture growth. Comparison between acetic acid and hydrogen sulfide inhibition is presented and the concomitant inhibition kinetics are mathematically described. (c) 1992 John Wiley & Sons, Inc.     

Anion- and pH-linked effects on the heme-iron geometry in ferrous nitrosylated monomeric myoglobins

 The cooperative effect of anions and proton concentration on the EPR spectroscopic properties of the ferrous nitrosylated derivative of monomeric Mb from loggerhead sea turtle (Caretta caretta), sperm whale (Physeter catodon), and horse (Caballus caballus) has been investigated between pH 4.5 and 9.0, at 100 K. In the absence of anions, an EPR spectrum characteristic of the hexa-coordinated species of ferrous nitrosylated Mb with an axial geometry is observed, which is unaffected by pH. On the other hand, a transition toward a species characterized by an EPR spectrum corresponding to a hexa-coordinated rhombic geometry takes place in the presence of phosphate, acetate, citrate, sulfate, and chloride. Only the hexa-coordinated form characterized by the rhombic EPR spectrum appears then to undergo a pH-dependent transition toward the penta-coordinated species. Present results show clear-cut evidence for the spectroscopic coupling of proton and anion binding sites with the Mb reactive center, indicating that an allosteric mechanism might modulate the proximal HisF8-heme-NO geometry in monomeric hemoproteins. Received: 15 December 1997 / Accepted: 15 June 1998