Kenneth W. Cole

Roles of unfrozen fraction, salt concentration, and changes in cell volume in the survival of frozen human erythrocytes.

The cause of slow freezing injury and the basis of the protection by solutes like glycerol are subjects of debate. During slow freezing, cells are sequestered in unfrozen channels between ice crystals that grow by removing pure water from the channels. As a consequence, the solute concentration in the channels rises and the volume of liquid in the channels progressively decreases. The rise in solute concentration, in turn, causes the cells to progressively shrink osmotically. Until recently cryobiologists have ascribed slow freezing injury to either the rise in solute (electrolyte) concentrations in the channels or to the consequent cell shrinkage, rather than to the decrease in the of the channels. Although ordinarily reciprocally coupled, it is possible to separate the composition of the channels from their size, or more precisely from the magnitude of the unfrozen fraction, by suspending cells in NaCl/cryoprotectant solutions in which the mole ratio of the two is held constant, but the molality of the NaCl is allowed to vary below and above isotonic. When human red cells are frozen in such solutions to temperatures that produce given NaCl concentrations (ms), but varying unfrozen fractions (U), survival at low U is found to be strongly dependent on U but independent of ms. At higher values of U, survival becomes inversely dependent on both ms and U. Although cell volume during freezing is independent of the NaCl tonicity in the solution, the cells in the several solutions differ in volume both prior to the onset of freezing and after the completion of thawing. We have now examined and compared the effect of returning the thawed cells to isotonic solutions and isotonic volume or nearly so, and find that there is little change in survival after exposure to low U, but that survival after exposure to high U values exhibits substantially increased sensitivity to ms, a sensitivity that is probably a manifestation of posthypertonic hemolysis. Low values of U were in general attained by the use of solutions with low tonicities of NaCl, and as a consequence cells frozen to low U values had larger volumes prior to freezing than cells frozen to higher U values. The significance of this confounding is discussed.

Chorismate synthase of Neurospora crassa: A flavoprotein

Abstract Chorismate synthase is purified from Neurospora crassa. The final step is accomplished by preparative electrophoresis. Its purity is estimated at ≥90% on the basis of analytical polyacrylamide gel electrophoresis. The enzyme appears to be active in at least two multimeric states, with a subunit molecular weight of ~55,000. The purified enzyme preparation is absolutely dependent on the presence of a reducing system, which can readily be provided under aerobic conditions by NADPH plus FMN or under stringent anaerobic conditions by dithionite. The following evidence implicates a physiological role for FMN in N. crassa chorismate synthase activity: (a) a preferential stimulation of activity by NADPH and FMN over other pyridine and flavin nucleotides, respectively, in both impure and purified enzyme preparations; (b) an alteration of the Chromatographic pattern of the enzyme on diethylaminoethylcellulose by the addition of FMN to the elution buffer; (c) an apparent binding of FMN to the enzyme as exhibited by gel filtration in the presence of the substrate, 3-enolpyruvylshikimate 5-phosphate; (d) a requirement for preliminary incubation with FMN, in concert with the substrate, to eliminate a reaction lag (i.e., to activate the enzyme); (e) a substrate-dependent diaphorase activity exhibited by purified enzyme preparations in the presence of FMN and NADPH. The observed activation and alteration of Chromatographic behavior of chorismate synthase by FMN suggest that the flavin nucleotide influences the conformation of the enzyme. The ability to replace NADPH and FMN with dithionite suggests that FMN mediates the flow of electrons from a source of reducing power (NADPH) to some enzymic site important to the function of the enzyme. Hence, the diaphorase activity which is observed as intrinsic to chorismate synthase of N. crassa may be significant from the standpoint of catalysis or may have importance as a regulatory mechanism.

The protease problem in Neurospora: Structural modification of the arom multienzyme system during its extraction and isolation☆

Abstract The “aromatic complex” or “ arom aggregate” of Neurospora crassa catalyzes five consecutive reactions in the central pathway leading to the biosynthesis of the aromatic amino acids. Previously, this multienzyme system was shown variously to have a molecular weight of 230,000 to 300,000 and to contain up to four subunits. Recently, a protease and a corresponding specific inhibitor have been isolated from N. crassa and, as described in this report, a new method for isolating the multienzyme system has been developed. We have made the following observations: (a) Detergent (sodium dodecyl sulfate) gel electrophorograms of the “complex” isolated by two different methods are not comparable. In an earlier method, which involved more manipulations and time, the detergent gel banding patterns showed four polypeptides with molecular weights totaling about 300,000. With the new purification procedure, there are two major bands: the first with an apparent molecular weight of about 150,000 and the second with a molecular weight of 50,000. (b) When the freshly purified multienzyme system is incubated at 25 °C, four new bands appear within 30 h and a fifth is visible after 40 h. (c) The formation of these new bands is prevented for up to 40 h by the addition of phenylmethanesulfonylfluoride or a purified preparation of the specific N. crassa protease inhibitor, (d) The multienzyme system appears to remain intact, as shown by standard polyacrylamide gel electrophoresis, even after it has suffered several proteolytic clips. These results demonstrate that the purified complex is contaminated with a small but influential quantity of the inhibitable N. crassa protease and show that this protease is capable of creating an artificial subunit structure in the multienzyme system. Based on these observations, we hypothesize that the arom enzyme system is a five-component multifunctional enzyme.

Critical factors affecting the permeabilization of Drosophila embryos by alkanes

Because of waxes in the vitelline membrane, the Drosophila egg is effectively impermeable to liquid water and to aqueous solutes, and consequently it cannot be cryopreserved unless it can be permeabilized. The more successful of the few published permeabilization procedures involve the removal of the chorion mechanically or by hypochlorite solution, the removal of all surrounding water by air drying or alcohol, the exposure of eggs to pure alkanes like octane or hexane for some 30 s, the removal of the alkane and the transfer of the eggs to aqueous culture medium without their desiccation, and lastly incubation of the permeabilized embryos under mineral oil. In following these procedures we opted for a somewhat different approach to applying hypochlorite, water, alcohol, and alkane; namely, eggs were placed between two Nucleopore filters, and the fluids drawn sequentially through the filters by vacuum. Extensive initial attempts were mystifying and discouraging in that although permeabilization was good, survivals were poor, and modifications that increased the latter reduced the former. The explanation turned out to be that permeabilization and survival depended critically on the amount of carry-over alcohol that contaminated the alkane. To determine the effects of alcohol concentration in the alkane, it was essential first to effectively eliminate carry-over contamination and then re-add precise amounts of alcohol (isopropanol) to the alkane (n-hexane, heptane, or octane). When the alcohol concentration is less than or equal to 0.2%, permeabilization is poor; when it is greater than or equal to 0.5%, permeabilization is good but survival (hatching) is poor. There are strong interactions between alcohol concentration and exposure time to alkane/alcohol mixtures with respect to the fraction of embryos that become permeabilized and the percentage that survive. There are also significant but less critical effects from the type of alcohol and alkane. The best results for 12-h embryos (greater than or equal to 90% permeabilization and 70-80% hatching) were achieved with eggs exposed to 0.3 or 0.4% 1-butanol in n-heptane for 90 s. High survivals of permeabilized 12-h embryos did not require incubation under mineral oil. Permeabilized embryos are permeable to water, ethylene glycol, glycerol, and the stain rhodamine B (which was used to assess permeabilization). They are effectively impermeable to sucrose. Embryo age is important. Between 14 and 16 h the above permeabilization procedures become dramatically less effective.(ABSTRACT TRUNCATED AT 400 WORDS)

Procedure for the permeabilization and cryobiological preservation of Drosophila embryos

The authors describe the detailed protocol developed in their laboratory at Oak Ridge for the permeabilization and cryobiological preservation of embryos of Drosophila melanogaster, Oregon R strain. The protocol is supplemented by notes containing two sorts of information. One category includes references to the appropriate portions of their published papers giving the scientific rationale and experimental basis for important steps. The other category is concerned with the criticality of certain steps and the precision with which they need to be performed. As an aid to investigators, the authors list even ordinary pieces of equipment. Brand names and model numbers are given where it is either important or convenient for readers to know precisely what is used.