Biochemical and immunological properties of alkaline invertase isolated from sprouting soybean hypocotyls.

Alkaline invertase from sprouting soybean (Glycine max) hypocotyls was purified to apparent electrophoretic homogeneity by consecutive use of DEAE-cellulose, green 19 dye, and Cibacron blue 3GA dye affinity chromatography. This protocol produced about a 100-fold purification with about a 11% yield. The purified protein had a specific activity of 48 mumol of glucose produced mg-1 protein min-1 (pH 7.0) and showed a single protein band in sodium dodecyl sulfate-polyacrylamide gel electrophoresis (PAGE) (58 kDa) and in native PAGE, as indicated by both protein and activity staining. The native enzyme molecular mass was about 240 kDa, suggesting a homotetrameric structure. The purified enzyme exhibited hyperbolic saturation kinetics with a Km (sucrose) near 10 mM and the enzyme did not utilize raffinose, maltose, lactose, or cellibose as a substrate. Impure alkaline invertase preparations, which contained acid invertase activity, on contrast, showed biphasic curves versus sucrose concentration. Combining equal activities of purified alkaline invertase with acid invertase resulted in a biphasic response, but there was a transition to hyperbolic saturation kinetics when the activity ratio, alkaline: acid invertase, was increased above unity. Alkaline invertase activity was inhibited by HgCl2, pridoxal phosphate, and Tris with respective Ki values near 2 microM, 5 microM, and 4 mM. Glycoprotein staining (periodic acid-Schiff method) was negative and alkaline invertase did not bind to two immobilized lectins, concanavalin A and wheat germ agglutinin; hence, the enzyme apparently is not a glycoprotein. The purified alkaline invertase, and a purified soybean acid invertase, was used to raise rabbit polyclonal antibodies. The alkaline invertase antibody preparation was specific for alkaline invertase and cross-reacted with alkaline invertases from other plants. Neither purified soybean alkaline invertases nor the crude enzyme from several plants cross-reacted with the soybean acid invertase antibody.     

Sucrolytic Enzyme Activities in Cotyledons of the Faba Bean (Developmental Changes and Purification of Alkaline Invertase)

In terms of maximum extractable catalytic activity, sucrose synthase is the predominant sucrolytic enzyme in developing cotyledons of faba bean (Vicia faba L.). Although acid invertase activity is extremely low, there is significant activity of alkaline invertase, the majority of which is extractable only with high concentrations of NaCl. Calculations of potential activity in vivo indicate that alkaline invertase is the predominant sucrolytic enzyme from 50 days after anthesis onward. However, at almost all stages of cotyledon development analyzed, the maximum extractable catalytic activities of both enzymes is in excess of the actual rate of starch deposition. Two forms of alkaline invertase were identified in developing cotyledons. The major form has been purified to homogeneity, and antibodies have been raised against it. The native protein has a molecular mass of about 238 [plus or minus] 4.5 kD. It is apparently a homotetramer (subunit molecular mass 53.4 [plus or minus] 0.9 kD). The enzyme has a pH optimum of 7.4, an isoelectric point of 5.2, and a Km[sucrose] of 10 mM and is inhibited by Tris (50% inhibition at 5 mM) and fructose (30% inhibition at 10 mM). Bean alkaline invertase is a [beta]-fructofuranosidase with no significant activity against raffinose, stachyose, trehalose, maltose, or lactose.     

Invertases in young and mature leaves of Citrus sinensis

The sucrose catabolic enzymes acid invertase (EC 3.2.1.26) and alkaline invertase (EC 3.2.1.27) were studied in young and mature Citrus sinensis leaf tissue. In young, expanding leaves (60 % final length) soluble acid invertase activity predominated, while soluble alkaline invertase activity predominated in mature leaves. The acid and alkaline invertase activities were separated on Sephadex G-200. The acid invertase had an M_r of approximately 60 000, pH maximum of 4.5 and apparent K_m of 3.3 mM sucrose. The alkaline invertase had an M_r of approximately 200 000, pH maxima of 6.8 and an apparent K_m of 20 mM sucrose. Alkaline invertase was strongly inhibited by 10 mM Tris while acid invertase was not. Possible physiological roles for the two invertases are discussed.     

Purification and characterization of three soluble invertases from barley (Hordeum vulgare L.) leaves.

Three soluble isoforms of invertase (beta-fructofuranosidase; EC 3.2.1.26) were purified from 7-d-old primary leaves of barley (Hordeum vulgare L.). Invertase I, a monomeric protein of 64 kD, was purified to apparent homogeneity as shown by sodium dodecylsulfate-polyacrylamide gel electrophoresis. Invertases IIA and IIB, multimeric proteins with molecular masses of the 116 and 155 kD, were purified 780- and 1370-fold, respectively, but were not yet homogeneous. Extracts of epidermal strips of leaves contained only invertase IIB. The specific activity of invertase was more than 100-fold higher in the epidermis than in the mesophyll. All three isoforms were acidic invertases, with pH optima of around 5.0 and little activity in the alkaline range. Invertase I had a Km for sucrose of 8.1 mM, and invertases IIA and IIB had much lower values of 1.0 and 1.7 mM, respectively. Invertase I was more than 2-fold more resistant than the other two invertases to the inhibitors HgCl2 and pyridoxal. All three constitutive invertases were found to act also as sucrose-sucrose fructosyltransferases when supplied with high concentrations of sucrose, forming 1-kestose as principal product. However, the fructosyltransferase activity of all three enzymes was inhibited by pyridoxal in the same way as their invertase activity. This characteristic clearly differentiates them from the inducible sucrose-sucrose fructosyltransferase of barley leaves, the activity responsible for the initial steps of fructan biosynthesis, which has previously been shown to be insensitive to pyridoxal.     

Characterization of the co-purified invertase and β-glucosidase of a multifunctional extract from Aspergillus terreus

The filamentous fungus Aspergillus terreus secretes both invertase and β-glucosidase when grown under submerged fermentation containing rye flour as the carbon source. The aim of this study was to characterize the co-purified fraction, especially the invertase activity. An invertase and a β-glucosidase were co-purified by two chromatographic steps, and the isolated enzymatic fraction was 139-fold enriched in invertase activity. SDS-PAGE analysis of the co-purified enzymes suggests that the protein fraction with invertase activity was heterodimeric, with subunits of 47 and 27 kDa. Maximal invertase activity, which was determined by response surface methodology, occurred in pH and temperature ranges of 4.0–6.0 and 55–65 °C, respectively. The invertase in co-purified enzymes was stable for 1 h at pH 3.0–10.0 and maintained full activity for up to 1 h at 55 °C when diluted in water. Invertase activity was stimulated by 1 mM concentrations of Mn²⁺ (161 %), Co²⁺ (68 %) and Mg²⁺ (61 %) and was inhibited by Al³⁺, Ag⁺, Fe²⁺ and Fe³⁺. In addition to sucrose, the co-purified enzymes hydrolyzed cellobiose, inulin and raffinose, and the apparent affinities for sucrose and cellobiose were quite similar (K_M = 22 mM). However, in the presence of Mn²⁺, the apparent affinity and V_max for sucrose hydrolysis increased approximately 2- and 2.9-fold, respectively, while for cellobiose, a 2.6-fold increase in V_max was observed, but the apparent affinity decreased 5.5-fold. Thus, it is possible to propose an application of this multifunctional extract containing both invertase and β-glucosidase to degrade plant biomass, thus increasing the concentration of monosaccharides obtained from sucrose and cellobiose.     

Purification and properties of a neutral invertase from the roots of Cichorium intybus

Multiple activity peaks of neutral invertase (EC 3.2.1.26) were found in chicory roots ( Cichorium intybus L. var. foliosum cv. Flash). The main activity peak was purified by a combination of anion-exchange chromatography, hydrophobic interaction chromatography, chromatofocusing and gel filtration. This protocol produced a 77-fold purification and a specific activity of 1.6 μmol (mg protein)⁻¹ min⁻¹. The mass of the enzyme was 260 kDa as estimated by gel filtration and 65 kDa on SDS-PAGE. Optimal activity was found between pH 7 and 7.5. The purified enzyme exhibited hyperbolic saturation kinetics with a K_m between 10 and 20 mM for sucrose. No other products than glucose and fructose could be detected. Raffinose was hydrolyzed at a rate of 2.4% relative to sucrose whereas the enzyme did not hydrolyze maltose, cellobiose, trehalose, 1-kestose, 1.1-nystose or inulin. Neutral invertase activity was completely inhibited by HgCl₂ and AgNO₃ and partially inhibited by CoCl₂, and ZnSO₄ (1 mM). Pyridoxal phosphate (K_i≅ 500 μ M ), Tris (K_i≅ 1.2 m M ), glucose and fructose (K_i≅ 16 m M ) were strong inhibitors of the enzyme. Fructose and Tris behaved as competitive inhibitors. A possible role for the enzyme's activity in vivo is discussed.     

Isolation and characterization of a cDNA clone from Lolium temulentum L. encoding for a sucrose hydrolytic enzyme which shows alkaline/neutral invertase activity

A novel cDNA clone, functionally expressed in E. coli, was isolated from a L. temulentum L. cDNA library. The expressed protein hydrolysed sucrose with an apparent Km of approximately 18 mM, and produced equi-molar concentrations of glucose and fructose. Optimum activity was observed at pH 7-7.5; there was little or no activity at pH 5.5. The expressed protein did not hydrolyse raffinose, stachyose or maltose. The activity of the expressed protein was inhibited by fructose (50% at 15 mM) and TRIS (50% at 2.5 mM), but was not affected by MgCl2, CaCl2 or MnCl2. These findings suggest that this cDNA clone encodes for an alkaline/neutral invertase. Sequence analysis revealed little homology with published sequences for acid invertase, however the invertase motif (NDPN) identified in other invertases was present. Expression studies show that the gene encoding for this enzyme is not regulated by sucrose accumulation in leaf tissue.     

Properties of p-nitrophenyl phosphatase activity from porcine neutrophils

p-nitrophenyl phosphatase activity is high in porcine neutrophils and was found in plasma membrane and granule fractions isolated from sucrose density gradients after nitrogen cavitation to disrupt the cells. Very little activity was found in the cytosol. The enzyme has optimum activity at alkaline pHs with a pH optimum of 10.3. The pH profile was fairly broad with activity still remaining at physiological pH. Orthovanadate was shown to be a potent competitive inhibitor of the enzyme with a Ki of 14 microM. Phosphate also inhibited but at millimolar concentrations and the two inhibitors bind in a mutually exclusive fashion. Evidence from experiments using divalent ion chelators and zinc ions suggested that the phosphatase is a zinc metalloenzyme. Beryllium was found to be a very potent, non-competitive inhibitor of the neutrophil enzyme (Ki = 1.1 microM). Levamisole and theophylline were both shown to be uncompetitive inhibitors of the porcine phosphatase (Ki = 0.2 mM and 1.2 mM respectively). The neutrophil phosphatase was inhibited by L-homoarginine but unaffected by L-phenylalanine and L-glutamate.     

Biochemical Characterization of Soluble Acid and Alkaline Invertases from Shoots of Etiolated Pea Seedlings

Soluble invertase was purified from pea(Pisum sativum L.) by sequential procedures entailing ammonium sulfate precipitation,DEAE-Sepharose column,Con-A-and Green 19-Sepharose affinity columns,hydroxyapatite column,ultra-filtration,and Sephacryl 300 gel filtration.The purified soluble acid(SAC) and alkaline(SALK) invertases had a pH optimum of 5.3 and 7.3,respectively.The temperature optimum of two invertases was 37 ℃.The effects of various concentrations of Tris-HCl,HgCl2,and CuSO4 on the activities of the two purified enzymes were examined.Tris-HCl and HgCl2 did not affect SAC activity,whereas 10 mM Tris-HCl and 0.05 mM HgCl2 inhibited SALK activity by about 50%.SAC and SALK were inhibited by 4.8 mM and 0.6 mM CuSO4 by 50%,respectively.The enzymes display typical hyperbolic saturation kinetics for sucrose hydrolysis.The Kms of SAC and SALK were determined to be 1.8 and 38.6 mM,respectively.The molecular masses of SAC shown by sodium dodecyl sulfate-polyacrylamide gel electrophoresis and immunoblotting were 22 kDa and 45 kDa.The molecular mass of SALK was 30 kDa.Iso-electric points of the SAC and SALK were estimated to be about pH 7.0 and pH 5.7,respectively.     

Acid and Neutral Invertases in the Mesocarp of Developing Muskmelon (Cucumis melo L. cv Prince) Fruit

Acid and neutral invertases were found in the mesocarp of developing muskmelon (Cucumis melo L. cv Prince) fruit and the activities of these enzymes declined with maturation of the fruit, concomitantly with the accumulation of sucrose. Neutral invertase was only present in the soluble fraction and acid invertase was present in both the soluble and cell-wall fractions. The cell-wall fraction contained three types of acid invertase: a NaCl-released invertase; an EDTA-released invertase, and a tightly bound invertase that still remained on the cell wall after treatment with NaCl and EDTA. The soluble acid and neutral invertases could be separated from one another by chromatography on DEAE-cellulose and they exhibited clear differences in their properties, namely, in their pH optima, substrate specificity, K_m values for sucrose, and inhibition by metal ions. The EDTA-released invertase and the soluble acid invertase were similar with regard to their chromatographic behavior on DEAE-cellulose, but the NaCl-released invertase was different because it was adsorbed to a column of CM-cellulose. The soluble acid invertase and two cell-wall bound invertases had very similar characteristics with regard to optimal pH and temperature, K_m value for sucrose, and substrate specificity.     

An invertase inhibitory protein from Pteris deflexa link fronds

Plant invertases play important roles in sucrose metabolism. Cell wall invertase was reported to participate in phloem loading and unloading. Soluble invertases would be involved in hexose level regulation in mature tissues and in stored sucrose utilization within vacuoles. Invertase inhibitory proteins were described as one of the possible mechanisms for invertase activity regulation in some plant species; nevertheless, these proteins were found only in sink tissues, suggesting that this mechanism would not be relevant in the sucrose turnover of leaves. This report describes the purification of invertase from Pteris deflexa fronds and the occurrence of an invertase inhibitory protein in this fern organ, as well as its purification and invertase-inhibitor interactions. The Mr of the invertase and of its inhibitory protein were 90,000 and 18,000, respectively. SDS-PAGE in the presence of 2-mercaptoetanol gave two subunits for the enzyme (Mr=66,000 and 30,000) and only one for the inhibitor. The inhibitor protein is a glycoprotein (12% w/w of neutral sugars) that did not show agglutinating activity like some others, and also showed a high heat stability at pH 5.0. The optimum pH of invertase activity is 5.0, while invertase inhibitory protein caused maximal inhibition at the same pH value. Invertase-inhibitor complex formation occurs in an immediate manner and a protease activity was discarded. The inhibition is non-competitive (Ki=1.5 x 10(-6) M) without interactions among the binding sites. The complex is slightly dissociable and sucrose was able to partially reduce the inhibitory effect. Up to the present, invertase inhibitory proteins have been found solely in heterotrophic tissues. In this work we demonstrate that this protein is also present in an autotrophic tissue of a lower vascular plant.     

Changes in Sugar Content and Activities of Sucrose Metabolizing Enzymes in Roots and Nodules of Lentil

Activities of acid and alkaline invertases and sucrose synthase were determined in roots and nodules of lentil at various stages of development. Alkaline invertase and sucrose synthase were both involved in sucrose metabolism in the nodule cytosol, but there was only a small amount of acid invertase present. Activity of sucrose metabolizing enzymes in roots was significantly less than that observed in the nodules. Amongst sugars, sucrose was found to be the main component in the host cytosol. Lentil neutral invertase (LNI) was partially purified from nodules at 50 days after sowing (DAS). Two forms of invertase were identified, i.e., a major form of 71 kDa which was taken for enzyme characterization and a minor form of 270 kDa which was not used for further studies. The purified enzyme exhibited typical hyperbolic saturation kinetics for sucrose hydrolysis. It had a Km of 11.0 to 14.0 mM for sucrose depending upon the temperature, a pH optimum of 6.8 and an optimum temperature of 40 °C. Compared with raffinose and stachyose, sucrose was better substrate for LNI. The enzyme showed no significant hydrolysis of maltose and p-nitrophenyl--D-glucopyranoside, showing its true -fructosidase nature. LNI is completely inhibited by HgCl₂, MnCl₂ and iodoacetamide but not by CaCl₂, MgCl₂ or BaCl₂.     

An Invertase Inhibitory Protein From Pteris deflexa Link Fronds

Plant invertases play important roles in sucrose metabolism. Cell wall invertase was reported to participate in phloem loading and unloading. Soluble invertases would be involved in hexose level regulation in mature tissues and in stored sucrose utilization within vacuoles. Invertase inhibitory proteins were described as one of the possible mechanisms for invertase activity regulation in some plant species; nevertheless, these proteins were found only in sink tissues, suggesting that this mechanism would not be relevant in the sucrose turnover of leaves. This report describes the purification of invertase from Pteris deflexa fronds and the occurrence of an invertase inhibitory protein in this fern organ, as well as its purification and invertase-inhibitor interactions. The Mr of the invertase and of its inhibitory protein were 90,000 and 18,000, respectively. SDS-PAGE in the presence of 2-mercaptoetanol gave two subunits for the enzyme (Mr=66,000 and 30,000) and only one for the inhibitor. The inhibitor protein is a glycoprotein (12% w/w of neutral sugars) that did not show agglutinating activity like some others, and also showed a high heat stability at pH 5.0. The optimum pH of invertase activity is 5.0, while invertase inhibitory protein caused maximal inhibition at the same pH value. Invertase-inhibitor complex formation occurs in an immediate manner and a protease activity was discarded. The inhibition is non-competitive (Ki=1.5 × 10 ^?6 M) without interactions among the binding sites. The complex is slightly dissociable and sucrose was able to partially reduce the inhibitory effect. Up to the present, invertase inhibitory proteins have been found solely in heterotrophic tissues. In this work we demonstrate that this protein is also present in an autotrophic tissue of a lower vascular plant.     

Sucrose metabolism in lima bean seeds

Developing and germinating lima bean (Phaseolus lunatus var Cangreen) seeds were used for testing the sucrose synthase pathway, to examine the competition for uridine diphosphate (UDP) and pyrophosphate (PPi), and to identify adaptive and maintenance-type enzymes in glycolysis and gluconeogenesis. In developing seeds, sucrose breakdown was dominated by the sucrose synthase pathway; but in the seedling embryos, both the sucrose synthase pathway and acid invertase were active. UDPase activity was low and seemingly insufficient to compete for UDP during sucrose metabolism in seed development or germination. In contrast, both an acid and alkaline pyrophosphatase were active in seed development and germination. The set of adaptive enzymes identified in developing seeds were sucrose synthase, PPi-dependent phosphofructokinase, plus acid and alkaline pyrophosphatase; and, the adaptive enzymes identified in germinating seeds included the same set of enzymes plus acid invertase. The set of maintenance enzymes identified during development, in the dry seed, and during germination were UDP-glucopyrophosphorylase, neutral invertase, ATP and UTP-dependent fructokinase, glucokinase, phosphoglucomutase, ATP and UTP-dependent phosphofructokinase and sucrose-P synthase.     

Comparative enzymatic properties of avian liver and skeletal muscle D-fructose-1,6-bisphosphate 1-phosphohydrolase.

The enzymatic properties of purified preparations of chicken liver and chicken skeletal muscle fructose bisphosphatases (D-fructose-1,6-bisphosphate 1-phosphohydrolase, EC 3.1.3.11) were compared. Both enzymes have an absolute requirement for Mg2+ or Mn2+. The apparent Km for MgCl2 at pH 7.5 was 0.5 mM for the muscle enzyme and 5 mM for the liver enzyme. Fructose bisphosphate inhibited both enzymes. At pH 7.5, the inhibitor constants (Ki) were 0.18 and 1.3 mM for muscle and liver fructose bisphosphatases, respectively. The muscle enzyme was considerably more sensitive to AMP inhibition than the liver enzyme. At pH 7.5 and in the presence of 1 mM MgCl2, 50% inhibition of muscle and liver fructose bisphosphatases occurred at AMP concentrations of 7 X 10(-9) and 1 X 10(-6) M, respectively. EDTA activated both enzymes. The degree of activation was time and concentration dependent. The degree of EDTA activation of both enzymes decreased with increasing MgCl2 concentration. Ca2+ was a potent inhibitor of both liver (Ki, 1 X 10(-4) M) and muscle (Ki, 1 X 10(-5) M) fructose bisphosphatase. This inhibition was reversed by the presence of EDTA. Ca2+ appears to be a competitive inhibitor with regard to Mg2+. There is, however, a positive homeotropic interaction among Mg2+ sites of both enzymes in the presence of Ca2+.     

Proteinaceous Inhibitor Versus Fructose as Modulators of Pteris deflexa Invertase Activity

An acid invertase from the fern Pteris deflexa Link was purified and the effect of reaction products on enzyme activity was studied. Fructose and glucose were competitive and non-competitive inhibitors of the enzyme, respectively. Since proteins suppressed glucose and fructose inhibition of the enzyme, an invertase modulation by reaction products is unlikely; nevertheless, an invertase proteinaceous inhibitor previously reported could have a role in this respect. The purified enzyme was an heterodimer M r 90,000 Daltons composed of subunits of 66,000 and 30,000 Daltons. The enzyme had β -fructofuranosidase activity and hydrolyzed mainly sucrose but also raffinose and stachyose, with K m of 3.22, 10.80 and 38.50 mM, respectively. Invertase activity with an optimum pH at 5.0 was present in almost every leaf fern tissue. Pinnas (sporophyll leaflets) had the higher enzyme levels. Invertase histochemical and immunochemical localization studies showed the enzyme mainly in phloem cells. Epidermis, collenchyma and parenchyma cells also showed invertase protein.     

Proteinaceous inhibitor versus fructose as modulators of Pteris deflexa invertase activity

An acid invertase from the fern Pteris deflexa Link was purified and the effect of reaction products on enzyme activity was studied. Fructose and glucose were competitive and non-competitive inhibitors of the enzyme, respectively. Since proteins suppressed glucose and fructose inhibition of the enzyme, an invertase modulation by reaction products is unlikely; nevertheless, an invertase proteinaceous inhibitor previously reported could have a role in this respect. The purified enzyme was an heterodimer Mr 90,000 Daltons composed of subunits of 66,000 and 30,000 Daltons. The enzyme had beta-fructofuranosidase activity and hydrolyzed mainly sucrose but also raffinose and stachyose, with Km of 3.22, 10.80 and 38.50 mM, respectively. Invertase activity with an optimum pH at 5.0 was present in almost every leaf fern tissue. Pinnas (sporophyll leaflets) had the higher enzyme levels. Invertase histochemical and immunochemical localization studies showed the enzyme mainly in phloem cells. Epidermis, collenchyma and parenchyma cells also showed invertase protein.     

Purification and characterization of an alkaline invertase from shoots of etiolated rice seedlings

One alkaline invertase and two acid invertase activities were detected in the shoots of etiolated rice ( Oryza sativa ) seedlings. The alkaline invertase (AIT) was purified to homogeneity through steps of ammonium sulphate fractionation, concanavalin A-Sepharose affinity chromatography (non-retained), DEAE-Sephacel chromatography and preparative electrophoresis. The pH optimum of AIT was 7.0 and the molecular mass, determined by gel filtration, was 240 kDa. It is apparently a homotetrameric enzyme (subunit molecular mass 60 kDa). The isoelectric point was 4.4 by isoelectric focusing. The best substrate of the enzyme was sucrose, with a K _m of 2.53 mM. The enzyme also hydrolysed raffinose, but not maltose or lactose, so it is a β-D-fructofuranosidase. It gave negative glycoprotein staining. Of the hydrolysis products, fructose was a competitive inhibitor and glucose was a non-competitive inhibitor. Treatment with an alkaline phosphatase could activate AIT, whereas other proteins such as BSA, concanavalin A and urease had no effect on the enzyme activity. The enzyme activity was inhibited by Tris, thiol reagents and heavy metal ions.     

Properties of a free and a solubilized form of bound alpha,alpha-trehalase purified from honey bee thorax.

The free and bound forms of alpha,alpha-trehalase (EC 3.2.1.28) of the honey bee thorax were separated and the bound enzyme was solubilized by raising the pH to 8.0 for 10 h. Both enzymes were purified. They were homogeneous as determined by several electrophoretic criteria. It was found that the two enzymes had very similar Km's (each about 0.89 mM), Vm's (53.2 and 54.3 U/mg for free and solubilized, respectively), inhibition characteristics, specificities (both only hydrolyzed alpha,alpha-trehalose), pH maxima (each had maxima at about 3.5 and 6.5), molecular weights (65,000), isoelectric points (5.1), reactivities to sulfhydryl reagents, electrophoretic mobilities, activation energies (about 12.8 kcal/mol), and similar stabilities to heat, pH, and urea. Some significant differences between the two enzymes were, however, found: the solubilized alpha,alpha-trehalase floated at 70% saturation of ammonium sulfate while the free alpha,alpha-trehalase did not; the solubilized alpha,alpha-trehalase did not dissociate into subunits as readily as did the free one; and the solubilized alpha,alpha-trehalase was found to bind more readily to a hydrophobic grouping than the free enzyme. In addition to these comparisons, three new findings relating to thorax alpha,alpha-trehalases are reported. (1) Thorax alpha,alpha-trehalases are strongly inhibited by beta-glucosides (Ki values of about 8 x 10(-4) M); (2) under certain conditions thorax alpha,alpha-trehalases from honey bees dissociated into subunits of one-half the normal molecular weight; (3) honey bee thorax alpha,alpha-trehalases have unusual biphasic pH activity profiles.