Characterization of steady state, single-turnover, and binding kinetics of the TaqI restriction endonuclease.

The TaqI restriction endonuclease recognizes and cleaves the duplex DNA sequence T decreases CGA. Steady state kinetic analysis with a small oligodeoxyribonucleotide substrate showed that the enzyme obeyed Michaelis-Menten kinetics (Km = 53 nM, kcat = 1.3 min-1 at 50 degrees C and Km = 0.5 nM, kcat = 2.9 min-1 at 60 degrees C). At 0 degree C, the enzyme was completely inactive, while at 15 degrees C, turnover produced nicked substrate as the major product in excess of enzyme indicating dissociation between nicking events. Above 37 degrees C, both strands in the duplex were cleaved prior to dissociation. In contrast to the tight, temperature-dependent binding of substrate, binding of the Mg2+ cofactor was weak (Kd = 2.5 mM) and the same at either 50 degrees C or 60 degrees C. Single-turnover experiments using oligonucleotide substrate showed that hydrolysis of duplex DNA occurred via two independent nicking events, each with a first order rate constant (kst) of 5.8 min-1 at 60 degrees C and 3.5 min-1 at 50 degrees C. The pH dependence of Km (pKa = 9) and kst (pKa = 7) suggests Lys/Arg and His, respectively, as possible amino acids influencing these constants. Moreover, although kst increased significantly with pH, kcat did not, indicating that at least two steps can be rate-controlling in the reaction pathway. Binding of protein to canonical DNA in the presence of Mg2+ at 0 degree C or in the absence of Mg2+ at 50 degrees C was weak (Kd = 2.5 microM or 5,000-fold weaker than the optimal measured Km) and equal to the binding of noncanonical DNA as judged by retention on nitrocellulose. Similar results were seen in gel retardation assays. These results suggest that both Mg2+ and high temperature are required to attain the correct protein conformation to form the tight complex seen in the steady state analysis. In the accompanying paper (Zebala, J. A., Choi, J., Trainor, G. L., and Barany, F. (1992) J. Biol. Chem. 267, 8106-8116), we report how these kinetic constants are altered using substrate analogues and propose a model of functional groups involved in TaqI endonuclease recognition.     

Continuous production of clinical dextran using two-stage reactor

Summary Clinical dextran with desired molecular weight was produced continuously in the two-stage reactor. Cells ofLeuconostoc meseteroides B512F cultivated in the first reactor were transferred to the second reactor where sucrose and primer were added for clinical dextran production. By using this two-stage reactor, the fraction of desired clinical dextran increased significantly when observed with gel permeation chromatography.     

Effect of dehydration on thirst and drinking during immersion in men.

The mechanism for reduced voluntary water intake during water immersion was studied in eight men (19-25 yr of age) immersed to the neck while sitting for 3 h at 34.5 degrees C or in air at 28 degrees C when euhydrated (Eu-H2O and Eu-air, respectively) and hypohydrated (Hypo-H2O and Hypo-air) by 3.6% body weight loss. Thirst sensations (degree of thirst, mouth dryness and taste, drinking desirability, and stomach fullness) were similar at the beginning of Hypo-air and Hypo-H2O test periods. Initial drinking of tap water (15 degrees C) was 216 +/- 30 ml/7 min (P less than 0.05) with Hypo-air, decreased to 108 +/- 28 ml/7 min (P less than 0.05) with Hypo-H2O, and was 10-50 ml/10-30 min thereafter. Intake was less than 10 ml/10-30 min in Eu-air, and there was no drinking in Eu-H2O. Within the first 10 min of immersion, compared with Hypo-air findings, the significant reduction in drinking in the Hypo-H2O experiment was associated with unchanged plasma Na+, plasma osmolality, heart rates, and mean arterial pressures; the different responses were increased cardiac output, plasma volume, and atrial natriuretic peptides and decreased plasma renin activity and arginine vasopressin. Thus the extracellular pathway, as opposed to the osmotic pathway, appears to be the major mechanism for immersion-induced suppression of drinking.     

Evidence for two independent pathways in the stimulation of steroidogenesis by luteinizing hormone involving chloride channels and cyclic AMP

The possible role of chloride channels in luteinizing hormone (LH) action on steroidogenesis in rat Leydig cells had been investigated. A chloride channel blocker, SITS (4-acetamido-4'-isothiocyanatostilbene-2,2'-disulphonic acid), inhibited LH-stimulated steroidogenesis at low (less than or equal to 1 ng/ml), but not at high (100 ng/ml) LH concentrations. In addition, dibutyryl cyclic AMP- and forskolin-stimulated steroidogenesis was unaffected by SITS. The removal of extracellular chloride potentiated steroidogenesis stimulated by submaximal but not maximal doses of LH. These results suggest that at low levels of LH, steroidogenesis depends on chloride channels whereas with high levels, cyclic AMP is the mediator of LH action.     

Cytochemical localization of glycoconjugates in rat peritoneal mast cells during degranulation

Summary Cytochemical methods for the localization of glycoconjugates including concanavalin A-horseradish peroxidase (ConA-HRP) and dialysed iron were used to study the distribution of glycoconjugates in mast cell granules during degranulation. The ConA-HRP method revealed intense staining of discharged mast cell granules. Dialysed iron staining was seen at the granule periphery, with extruded granules exhibiting more intense staining than undischarged granules.Some of the work reported herein was performed in partial fulfillment of the requirements for a Ph.D. degree.     

Biosynthesis of membrane bound Ig and secretion of Ig by chicken lymphoid cells.

The metabolic turnover of membrane proteins of chicken lymphoid cells is studied, using a double isotope labeling technique (i.e., [14C]amino acid pulse and [3H]leucine chase). Compared with other membrane proteins, the metabolic turnover of membrane bound immunoglobulins (M-Ig) is very slow. There was no difference in the turnover between M-Ig and specific antigen binding receptor immunoglobulins. Immunoglobulins appear to be a stable constituent of the lumphocyte membrane. Cellular kinetic experiments show that the rate of biosynthesis of secreted immunoglobulins (S-Ig) is nearly ten times as much as that of M-Ig, suggesting that metabolic pathway leading to M-Ig are distinct from those leading to S-Ig. The difference in 3H/14C ratios between S-Ig and M-Ig reflects the rate of biosynthesis of these immunoglobulins by two types of bursa derived lymphoid cells.     

Increased signal complexity is associated with increased mating success

The evolution of complex signals has often been explored by testing multiple functional hypotheses regarding how independent signal components provide selective benefits to offset the costs of their production. In the present study, we take a different approach by exploring the function of complexity per se. We test the hypothesis that increased vibratory signal complexity—based on both proportional and temporal patterning—provides selective benefits to courting male Schizocosa stridulans wolf spiders. In support of this hypothesis, all of our quantified metrics of vibratory signal complexity predicted the mating success of male S. stridulans. The rate of visual signalling, which is mechanistically tied to vibratory signal production, was also associated with mating success. We additionally found evidence that males can dynamically adjust the complexity of their vibratory signalling. Together, our results suggest that complexity per se may be a target of female choice.