The reaction of tertiary amino alcohols with active esters: I. Acylation and deacylation steps

The reactions of triethanolamine and four other tertiary amino alcohols with six active ester substrates were studied in the pH range 6–10 at 30°C. The reaction products were in all cases the respective O-acyl-amino alcohols. Analysis of the effects of substituents in the leaving group as well as in the acyl moiety of the substrates showed that the ester product was formed by direct attack of the nucleophilic hydroxyl group. Comparison with reactions of tertiary amines with the same substrates supports this conclusion. The reactions of tertiary amino alcohols were also compared with those of zwitterionic quaternary amino alcohols and 3-quinuclidinol, a “rigid” tertiary amino alcohol. On the basis of these comparisons, it is proposed that one of the pathways for the predominant effect of the neutral species of tertiary amino alcohols involves intramolecular general base assistance by the tertiary amino group to the nucleophilic attack of the hydroxylic oxygen on the substrate. The contribution of this pathway to the rate of reaction is evaluated.In several systems the first product of the reaction, an O-acyl-amino alcohol, undergoes relatively rapid deacylation, the overall reaction being thus hydrolysis of active esters, catalyzed by the amino alcohol via an acylation-deacylation mechanism.     

The morphogenesis of cell hairs on Drosophila wings

We describe in this paper details of morphogenesis of wing hairs in Drosophila pupae. The ultimate objective is to relate specific protein components used in hair construction to specific components produced in the rapidly changing patterns of gene expression that are characteristic for the period of hair differentiation in wing cells (H. K. Mitchell and N. S. Petersen, 1981, Dev. Biol. 85, 233-242). Hair extrusion to essentially full size occurs quite suddenly at about 34 hr (postpupariation) and this is followed by deposition of a double-layer of cuticulin during the next 4 to 5 hr. Extreme changes in shape of cells and hairs, probably related to actin synthesis, then occur for the next 5 to 6 hr. Deposition of fibers within the hairs and on hair pedestals follows. Formation of cuticle on the cell surface begins and continues until some time in the 60-hr range. It appears that cuticle is formed only on the cell surface and not in hairs or on the top of hair pedestals. The protein synthesis patterns associated with these events are described.     

The role of mononuclear phagocytes in cardiac allograft rejection in the rat: I. Ultrastructural and cytochemical features

Mononuclear phagocytes (MNP) have been identified in rejecting rat cardiac allografts by morphological and cytochemical criteria. Their accumulation has been quantitated and their distribution within the graft recorded. Lymphocytes were the major infiltrating cell type present 3 days after transplantation, but by Day 5 and Day 7 there were 2.5 to 3 times as many MNP as lymphocytes. In the later stages (Days 6 and 7) many MNP were closely adjacent to myocardial cells and frequently possessed pseudopodia which were indenting the myocardial cell membrane. Allograft recipients given 750 rads γ-irradiation and reconstituted with thoracic duct lymphocytes rapidly rejected the graft. As many MNP were present in such grafts as in unmodified recipients. A potent antimacrophage serum did not prolong graft survival or alter the numbers of MNP within rejecting grafts. We conclude that MNP must be considered strong candidates for effector cells in allograft rejection and that satisfactory depletion techniques for MNP are not yet available.     

Automatic collector of expired 14CO2 for liquid scintillation counting

A filtration technique was employed to trap ¹⁴CO₂ continuously for liquid scintillation counting. Devices for delivering scintillator and ethanolamine solutions were combined symmetrically with two fritted-glass aspirators for altenating operation. The collector was regulated by a fraction collector timer. Trial and animal tests indicated that the described method was efficient, reliable, and more convenient for frequent collection over long periods than alternative methods. The automatic collector was used for metabolic studies of [1-¹⁴C] arachidonic acid in rats kept in metabolic cages and the results were processed by multicompartmental analysis.     

Thermal shock hemolysis in human red cells. I. The effects of temperature, time, and osmotic stress

Thermal shock is a form of hemolysis which occurs in human red cells exposed to greater than a critical level of osmotic stress of 1.4 Osm and subsequently cooled from above about 12 degrees C to below that temperature. Higher concentrations and higher cooling rates each increase the amount of hemolysis, within limits. Incubation for varying periods in hypertonic solutions and varying temperatures of incubation affect the amount of thermal shock. The effect of cooling rate on thermal shock is independent of the period of exposure to hypertonic solutions. Thermal shock is not the cause of freezing injury in human red cells, at least above -10 degrees C.     

The structural basis of anomalous kinetics of rabbit liver aryl sulfatase A

Rabbit liver aryl sulfatase A (aryl sulfate sulfohydrolase, EC 3.1.6.1) is inactivated during the hydrolysis of nitrocatechol sulfate and the rate of formation of turnover-modified aryl sulfatase A depends on the initial velocity of the enzymatic reaction. Organic solvents such as ethanol and dioxane favor the anomalous kinetic behavior. The turnover-modified enzyme can apparently be reactivated by arsenate, phosphate, pyrophosphate, and sulfate in the presence of nitrocatechol sulfate. The apparent dissociation constants of these ions in the reactivation of the enzyme are similar to their K_i values. Sulfite, which is a competitive inhibitor, does not reactivate the turnover-modified enzyme. Thus, all known activators are competitive inhibitors but not all competitive inhibitors are effective as activators. Inactivation of aryl sulfatase A during hydrolysis of ³⁵S-labeled substrate at pH values near the pH optimum (pH 5–6) is accompanied by the incorporation of radioactivity into the protein molecule and the turnover-modified enzyme is thereby covalently labeled. The stoichiometry of the incorporation of radioactivity corresponds to 2 g atom of sulfur per mole of enzyme monomer, or 1 g atom of sulfur per equivalent peptide chain. It is also shown that isolated turnover-modified rabbit liver aryl sulfatase A has lost approximately 76% of its secondary structure as compared to the native enzyme. The specific activity of the inactive enzyme is also decreased by 82%. Turnover-modified rabbit liver aryl sulfatase A is partially reactivated by sulfate ions in the presence of nitrocatechol sulfate. However, circular dichroism measurements and fluorescence spectra of the isolated “reactivated” turnover-modified enzyme indicate only a further loss of secondary structure. The specific activity of this “reactivated” enzyme is in fact decreased. The loss in secondary structure and the enzyme activity of the “reactivated” aryl sulfatase A is prevented in the presence of sulfate ions. Turnover-modified rabbit liver aryl sulfatase A behaves as a very fragile molecule.     

Prostaglandin regulation of macrophage function: Effect of endogenous and exogenous prostaglandins

The expression of macrophage antitumor activity and the production of prostaglandins (PG) by operationally defined macrophage populations differed under varying culture conditions. Culture conditions that caused increased PGE₂ production by activated macrophages resulted in an inhibition of their tumoricidal activity. In contrast, production of high levels of PGE₂ by resident and elicited macrophages was associated with an increase in antitumor activity. The activation of resident or elicited cells by lipopolysaccharide (LPS) could be blocked by indomethacin. Treatment of these macrophages with PGE₂ alone also resulted in their activation and subsequent tumor cell destruction. Activation of resident and elicited macrophages by LPS appears to be mediated by PGE₂.     

Relationships between cell-mediated immunity and the IgE antibody response: I. Lymphotoxin production to DNP-Ascaris conjugates

The purpose of this paper is to present evidence for the suitability of a lymphotoxin (LT) assay as an in vitro correlate of cell-mediated immunity (CMI) to a hapten-carrier conjugate known to stimulate a high IgE antibody response. This would be used in a study of the factors influencing the relationship(s) between CMI and IgE antibody responses to the same antigen. Antigen-induced LT was assayed on actinomycin-inhibited, chromium-51-labeled L929 fibroblasts, using supernatants obtained from spleen and lymph node cells of animals immunized with 2,4-dinitrophenyl-Ascaris conjugates. Although LT was present at all times tested, beginning at Day 10, its concentration varied with time after immunization, adjuvant used, and cell type assayed. The induction of LT was T-cell dependent and conjugate specific. LT was produced by nonadherent cells. Adherent cells from immunized animals produced L-cell cytotoxin in the absence of antigen stimulation when tested before Day 10.     

New trends in cryoenzymology: I.-Supercooled aqueous solutions.

A water in oil emulsion technique is proposed to investigate enzyme catalyzed reactions at sub-zero temperatures in the supercooled liquid state to avoid some reversible effects of the usual cosolvents on kinetics. Some results are listed: potentialities and technical problems of the procedure are discussed.     

Chicken fumarase. I. Purification and characterization.

Fumarase from chicken heart is purified 400 times from the crude muscle extract. The isolation procedure includes ammonium sulfate fractionations, Bio-Gel P-300 column chromatography and electrofocusings on pH-gradients from pH 3 to 10 and from pH 7 to 9. Chicken fumarase behaves as an homogeneous protein in sedimentation, diffusion and electrofocusing studies; the protein possesses a single amino-terminal residue: lysine. The analysis of the CD and ORD spectra suggests the presence of 60-65 p. cent of alpha-helix, 0 - 5 p. cent of beta-structure with the remaining portions of the protein in an unordered conformation. Chicken fumarase is found to be composed of 4 subunits of identical molecular weight (51.000) and devoid of disulfide bridges. Finally, the physicochemical properties of chicken fumarase are compared with those of the porcine enzyme.     

Kinetic analysis of superoxide anion production by activated and resident murine peritoneal macrophages

Using a continuous spectrophotometric assay, we have monitored the formation of superoxide anion (O₂^?) by activated and resident murine peritoneal macrophages. Macrophages elicited by injection with Corynebacterium parvum, as well as resident macrophages from untreated mice, were kept in suspension culture overnight to eliminate short-lived, contaminating neutrophils. Cytochemical analysis of the cultured macrophages disclosed that essentially all of the activated macrophages reduced nitroblue tetrazolium (NBT) dye vigorously. In contrast, only 18% of the resident macrophages demonstrated vigorous NBT reduction; the remainder of the resident macrophages reduced NBT very weakly. Kinetic analysis of macrophage O₂^? formation revealed that activated macrophages exposed to phorbol myristate acetate (PMA) produced O₂^? at a 13-fold greater maximum rate than resident macrophages. The decline in the rate of O₂^? production with time by activated macrophages was also greater than that of resident macrophages. The data indicate that the greater O₂^? production by activated macrophage populations is due to (i) the presence of an increased percentage of macrophages that respond to PMA with vigorous O₂^? production, and (ii) an increased maximum rate of O₂^? formation by these macrophages.     

Acetyl-coenzyme A carboxylase from the developing endosperm of Ricinus communis. I. Isolation and characterization

Acetyl-coenzyme A carboxylase has been purified from the plastids of developing castor oil seeds. High concentrations of the enzyme are required for stability as well as the presence of dithiothreitol, glycerol, bicarbonate, Triton X-100, and polyvinyl-pyrrolidone. It has a molecular weight of approximately 528,000 and appears to be membrane associated. Acetyl-CoA carboxylase is active over a wide pH range with an optimum at 8.0. Arrhenius plots are biphasic. The enzyme displays normal Michaelis-Menten kinetics with limiting Michaelis constants of KATP, 0.1 mM; KHCO-3, 3.0 mM; and Kacetyl-CoA, 0.05 mM. Monovalent cations, such as K+ and Cs+, exert a small activating effect on the enzyme while a divalent cation, Mn2+ or Mg2+, is essential for activity. The enzyme does not appear to be highly regulated by cellular metabolites.     

Disposition of polar and nonpolar residues on outer surfaces of transmembrane helical segments of proteins involved in proton translocation

"Helical wheel" projections of transmembrane helical segments of membrane proteins involved in proton translocation were constructed. The particular proteins studied were the uncF protein subunit of the Escherichia coli proton-ATPase, the uncE protein subunit of the E. coli proton-ATPase, and cytochrome oxidase subunit III. Clear demarcation of polar and nonpolar regions on surfaces of transmembrane helical segments was seen in the uncF protein and in uncE protein helical segment two, but not in uncE protein helical segment one. The transmembrane segment of cytochrome oxidase subunit III which includes the dicyclohexylcarbodiimide (DCCD)-reactive residue was very similar to E. coli uncE protein helical segment two. The DCCD-reactive residue in both was clearly located on a nonpolar surface.     

The combinatorial distance geometry method for the calculation of molecular conformation. I. A new approach to an old problem

A new approach to the long-standing local minimum problem of molecular energy minimization is proposed. The approach relies upon a field of computer mathematics known as combinatorial optimization, together with methods of conformational analysis derived from distance geometry. The advantages over the usual numerical techniques of optimization are, first, that the algorithms derived are globally convergent, and second, that the mathematical problems involved are well-posed and suitable for study within the modern theory of computational complexity. In this paper we introduce the approach, and describe a computer program based on it.     

Comparative study of the iron-binding properties of human transferrins: I. Complete and sequential iron saturation and desaturation of the lactotransferrin

Human lactotransferrin binds 2 Fe³⁺ tightly at two specific sites. In order to demonstrate differences between the stability of the two iron-binding sites, the removal of iron was studied in buffers in the pH range 8-3 varying the ionic strength and with or without metal chelators such as phosphate ions and EDTA.The results show that in the presence of formate and acetate buffers of ionic strength 0.1–0.4 and in a pH range of 5–3, the two Fe³⁺ from human lactotransferrin are removed stimultaneously.Addition of 4 mM EDTA to buffers of ionic strength 0.1 and in the pH range 8–3 shows that between pH 5–4.3 the iron from only one of the binding sites, called the ‘acid labile’ site, is removed.Addition of 0.2 M phosphate ions to buffers of ionic strength 0.2 and in pH range 8–3 containing 4 mM EDTA shows that Fe³⁺ from the ‘acid labile’ site may be completely removed at pH 6. Removal of Fe³⁺ from the ‘acid stable’ site is obtained at pH 4.The differential behavior of the two iron binding sites was also shown by saturation experiments in the presence of citrate/bicarbonate buffers at different pH values. In a pH range 6.2–4.8, 50% saturation was obtained, but at pH 6.35 complete saturation was achieved. When saturation of partially saturated samples of human lactotransferrin was performed with ⁵⁹Fe it was demonstrated that in the pH range 6.2–4.8 iron is bound only to the ‘acid labile’ site.     

Collagen-induced platelet aggregation and release. I effects of side-chain modifications and role of arginyl residues

To investigate the mechanisms governing collagen interaction with blood platelets, the effects of side-chain modifications on collagen-induced platelet aggregation and release of serotonin were studied. Since many chemical modifications alter the ability of collagen to form fibers that, according to current theory, may complicate interpretation of data, we eliminated this possibility by using collagen stabilized in a native-type fibrillar structure by treatment with either glutaraldehyde or ultraviolet irradiation. Acetylation, methylation, succinylation, treatment with 2,4-dinitrofluorobenzene, 2,4,6-trinitrobenzene sulfonic acid or 1,2-cyclohexanedione, and deguanidination with hypobromite were used to modify collagen side-chain reactive groups: amino, carboxyl, hydroxyl and guanidino. Both unmodified monomeric dispersed and fibrillar collagen preparations initiated platelet aggregation and release, although the kinetics and magnitude of the response were different. Monomeric collagen which had been modified by deguanidination, methylation or succinylation, failed to polymerize in physiological conditions and did not induce platelet aggregation and release. However, none of the chemical modifications of stabilized native-type collagen fibers, except treatment with hypobromite or cyclohexanedione, had an effect on collagen-induced platelet aggregation and release. Both hypobromite and cyclohexanedione modified guanidino groups of arginyl residues. Results showed that the ability of a collagen sample to induce platelet aggregation and release of serotonin is dependent on the arginine content of fibrillar collagen.These data demonstrate that manipulation of amino, carboxyl and hydroxyl groups is unimportant as long as the native-type fibrillar structure is maintained, and that arginyl residues are directly involved in collagen-platelet interaction. Moreover, the data suggest that only the arginyl residues in the Y position of the tripeptide unit Gly-X-Y of collagen are responsible.     

The identification of dimethylphenylarsine as a microbial metabolite using a simple method of chemofocusing

Candida humicola acts on benzenearsonic acid to produce dimethylphenylarsine, which was identified by mass spectroscopy following the chemofocusing of the volatile metabolite onto a mercuric chloride impregnated filter. The same technique established that trimethylarsine is the volatile metabolic product obtained from C. humicola treated with 4-NH₂-2-OHC₆H₃AsO(OH)₂ and (CH₃)₃AsO. Arsanilic acid, 4-NH₂C₆H₄AsO(OH)₂, is not metabolized to a volatile arsine.     

An ultramicro method of amino acid analysis: application to studies of protein metabolism in cultured cells.

Analysis of the quantity and specific radioactivity of amino acids derived from intra-cellular pools, aminoacyl-transfer RNA, and protein hydrolysates of cultured cells has been achieved using a radiolabeled amino group ligand, dansyl chloride. Speeific activities of ¹⁴C- or ³H-labeled amino acids are calculated after reaction with appropriately labeled dansyl chloride of known specific activity. The quantity of amino acid is determined as a function of its diluting influence on a radioactive standard. The specific activity of as little as 2 pmol of amino acid can be measured using [¹⁴C]dansyl chloride the less sensitive of the two isotopic species available. Thus, cells from a single 60-mm culture dish provide sufficient material for analysis of both intracellular and transfer RNA amino acid pools, and one can easily analyze the amino acids in hydrolysates made from individual bands in polyacrylamide gels. The method offers significant improvement in speed, sensitivity, and economy over conventional methods of amino acid analysis and, because of its double-label design, gives accurate results with a minimum of technical expertise and no major equipment other than a scintillation counter.