Behavior of aldehyde moieties involved in the activation of suppressor cells by sodium periodate

The treatment of mouse spleen cells with periodate at the optimal mitogenic concentration (1 mM) induces the activation of suppressor cells of the in vitro antibody response and leads to the formation of aldehydes on the carbohydrate termini of the surface sialoglycoconjugates. These aldehyde moieties are found on the C8 (N-AN 8) and the C7 (N-AN 7) derivatives of sialic acid. Immediate borohydride reduction prevents the activation of the suppressor cells. Data from this work show that borohydride reduction must be performed within the first 6 hr to prevent the generation of suppressor cells; 18 hr after the initial periodate oxidation, borohydride treatment did not reverse the in vitro suppressive activity of periodate-treated cells. The kinetics of the disappearance of aldehydes from the cell surface were studied by using [3H]borohydride labeling and chromatographic analysis of sialic acid derivatives. About 70 to 80% of the aldehyde moieties were found to be present 6 hr after periodate oxidation. After 18 hr, 50 to 70% of the aldehyde had disappeared from the lymphocyte membrane. Oxidized sialyl residues disappear completely after 60 hr of culture. This period corresponds to the de novo synthesis of sialic acid residues on the surface of periodate-activated cells. The two classes of oxidized sialyl-glycoconjugates were found to behave in different ways. In effect, our data showed that the aldehydes remaining at 18 hr are mainly located on the gangliosides, whereas the aldehyde moieties located on high m.w. glycoproteins disappear from the cell surface between 9 and 18 hr. This would suggest that the remaining aldehydes located on gangliosides are not directly involved in the expression of suppressive activity.     

Inhibition by sodium periodate of the in vitro antibody response of mouse spleen cells and its reversal by borohydride or aldehyde blocking reagents

Mild oxidation of mouse spleen cells by sodium periodate induces blastogenesis with enhancement of thymidine incorporation. Concomitantly, the specific in vitro response of these cells to sheep red blood cells and trinitrophenyl-polyacrylamide and the nonspecific polyclonal B-cell response to lipopolysaccharide are markedly inhibited. Exposure of these cells to sodium borohydride and hydroxylamine following periodate treatment reduces blastogenesis and prevents periodate-induced suppression. Data suggest that the integrity of aldehyde moieties generated by periodate oxidation is necessary for blastogenesis and induction of suppressor cells in mouse spleen cell culture.     

Diphtheria toxin entry into cells is facilitated by low pH

At neutral pH, NH4Cl and chloroquine protected cells against diphtheria toxin. A brief exposure of the cells to low pH (4.5-5.5) at 37 degrees completely abolished this protection. When, to cells preincubated with diphtheria toxin and NH4Cl, neutralizing amounts of anti-diphtheria toxin were added before the pH was lowered, the toxic effect was considerably reduced, but it was not completely abolished. A much stronger toxic effect was seen when antibodies were added immediately after incubation at low pH. Upon a short incubation with diphtheria toxin at low pH, the rate of protein synthesis in the cells decreased much faster than when the normal pH was maintained. The data suggest that, at low pH, diphtheria toxin (or its A fragment) penetrates directly through the surface membrane of the cell. The possibility is discussed that, when the medium has a neutral pH, the entry of diphtheria toxin involves adsorptive endocytosis and reduction of the pH in the vesicles possibly by fusion with lysosomes. Low pH did not facilitate the entry of the closely related toxins abrin, ricin, and modeccin.     

Characterization of operating parameters for XMuLV inactivation by low pH treatment

To ensure the viral safety of protein therapeutics made in mammalian cells, purification processes include dedicated viral clearance steps to remove or inactivate adventitious and endogenous viruses. One such dedicated step is low pH treatment, a robust and effective method commonly used in monoclonal antibody production to inactivate enveloped viruses. To characterize the operating space for low pH viral inactivation, we performed a statistically designed experiment evaluating the effect of pH, temperature, hold duration, acid type, and buffer concentration on inactivation of the retrovirus model, XMuLV. An additional single factor experiment was performed to study the effect of protein concentration. These data were used to generate predictive models of inactivation at each time point studied, which can be used to identify conditions for robust and effective XMuLV inactivation. At pH 3.6, XMuLV inactivation was rapid, robust, and relatively unaffected by the other factors studied, providing support for this as a generic viral inactivation condition for products that can tolerate this low pH. At pH 3.7 and 3.8, other factors besides pH affected XMuLV inactivation. By understanding the impact of each factor on inactivation, the factors can be manipulated within the operating space to ensure effective inactivation while achieving desired product quality goals. © 2015 American Institute of Chemical Engineers Biotechnol. Prog., 32:89–97, 2016     

Ouabain-induced enhancement of rat mast cells response. Modulation by protein phosphorylation and intracellular pH

The digitalic glicoside ouabain induces potentiation of rat mast cell histamine release in response to several stimuli, which is mediated by Na+/Ca2+ exchanger. In this work, we studied the effect of ouabain on cytosolic calcium, intracellular pH and histamine release with Ca2+ ionophore A23187 in conditions designed to maximize ouabain-induced potentiation of rat mast cells response. The effect of protein kinase C (PKC), cAMP and phosphatase inhibition was also tested. Ouabain induced an enhancement in histamine release, cytosolic calcium and intracellular pH. The adenylate cyclase activator forskolin reduced the effect of ouabain on histamine release and intracellular pH, but enhanced the effect on cytosolic calcium. PKC activator PMA enhanced the effect of ouabain on histamine release and cytosolic calcium, without affecting intracellular pH. A PKC inhibitor, GF-109203X, reduced ouabain-induced enhancement of histamine release and intracellular pH, but increased the enhancement on cytosolic calcium. Finally, inhibition of protein phosphatases 1 and 2A with okadaic acid, increased the effect of ouabain on histamine release and intracellular pH, but reduced cytosolic calcium in presence of ouabain. This result suggest that ouabain-induced potentiation of rat mast cell histamine release with A23187 is modulated by kinases, and this modulation may be carried out by changes in intracellular alkalinization. However, the mechanism underlying cellular alkalinization remains to be elucidated.     

Different organizational states of fodrin in cultured MDCK cells are induced by treatment with low pH, calmodulin antagonist TFP, and tumor promoter PMA.

We have investigated the molecular mechanisms underlying dynamic organization of the fodrin network by treating the epithelial MDCK cells with various agents affecting intracellular pH, intracellular calcium ion concentration, intracellular calmodulin, and protein kinase C (PKC) activity. Elevation of intracellular calcium level by A23187 or treatment with trifluoperazine (TFP), a calmodulin inhibitor, did not have any drastic effect on the fodrin distribution as judged by immunofluorescence microscopy. A long-term incubation with phorbol-12-myristate-13-acetate (PMA), a protein kinase C activator, in contrast, released fodrin from the lateral walls of the MDCK cells, leading to a diffuse cytoplasmic distribution. TFP, along with PMA, accelerated destabilization of the fodrin skeleton. Treatment with TFP alone rapidly released the cells from the substratum, which, however, could be prevented by PMA. We have previously shown that lowering of intracellular pH (< 6.5) leads to a removal of fodrin from its basolateral residence (Eskelinen et al., 1992) and that this translocation is reversed upon returning normal pH. We now show that the rebuilding of the membrane skeleton can be prevented if TFP is added to the acidified cells. Moreover, in TFP-treated acidified cells, fodrin shows a clusterlike organization similar to that observed in resting lymphocytes. We also noticed that interconversions between these different organizational states of fodrin are independent of the intracellular calcium concentration. Thus manipulation of the intracellular pH and treatment with TFP and PMA reveals different organizational states of the fodrin skeleton. This suggests that fodrin may participate in PMA-, TFP- and pH-sensitive signal transduction pathways.     

Activation of vesicular stomatitis virus fusion with cells by pretreatment at low pH

Fusion of vesicular stomatitis virus (VSV) with Vero cells was measured after exposure of the virus to low pH under a variety of experimental conditions. The method of relief of fluorescence self-quenching of the probe octadecylrhodamine was used to monitor fusion. Incubation of the virus at pH 5.5 prior to binding to cells led to significant enhancement of fusion at the plasma membrane, whereas fusion via the endocytic pathway was inhibited. Fusion of pH 5.5-pretreated VSV showed a similar pH threshold for fusion as nontreated virus, and it was blocked by antibody to VSV G protein. Activation of VSV by pretreatment at low pH was only slightly dependent on temperature. In contrast, when VSV was first bound to target cells and subsequently exposed at 4 degrees C to the low pH, activation of the fusion process did not occur. The pH 5.5-mediated activation of VSV could be reversed by returning the pH to neutral in the absence of target membranes. The low pH pretreatment also led to aggregation of virus; large aggregates could be pelleted by low speed centrifugation and only the effects of the supernatant, which consist of single virions and/or microaggregates, were considered. The data were analyzed in the framework of an allosteric model according to which viral spike glycoproteins undergo a pH-dependent conformational transition to an active (fusion-competent) state. Based on that analysis we conclude that the conformational transition to the active state is rate-limiting for fusion and that the viral spike glycoproteins are fusion-competent only in their protonated form.     

Passive enhancement of mouse tumor allografts by alloantibodies is Fc-dependent.

Enhancement of growth of a B10.D2 fibrosarcoma in B6AF1 recipients could be induced by administration of B6AF1 anti-B10.D2 lymphocyte serum. The role of the Fc part in this phenomenon was studied by treatment of the B6AF1 recipients with F(ab')2 fragments of enhancing alloantibodies. A highly purified F(ab')2 preparation was used to exclude any effects of undigested IgG. Administration of F(ab')2 did not lead to enhancement of the tumor allografts, not even when given in a dose that was 22 times the molar amount of the lowest enhancing dose of undigested IgG. We therefore conclude that passive enhancement of mouse tumor allografts by alloantibodies is Fc dependent.     

Subtype-specific, bi-component inhibition of SK channels by low internal pH

The effects of low intracellular pH (pH(i) 6.4) on cloned small-conductance Ca2+-activated K+ channel currents of all three subtypes (SK1, SK2, and SK3) were investigated in HEK293 cells using the patch-clamp technique. In 400 nM internal Ca2+ [Ca2+]i, all subtypes were inhibited by pH(i) 6.4 in the order of sensitivity: SK1>SK3>SK2. The inhibition increased with the transmembrane voltage. In saturating internal Ca2+, the inhibition was abolished for SK1-3 channels at negative potentials, indicating a [Ca2+]i-dependent mode of inhibition. Application of 50 microM 1-ethyl-2-benzimidazolone was able to potentiate SK3 current to the same extent as at neutral pH(i). We conclude that SK1-3 all are inhibited by low pH(i). We suggest two components of inhibition: a [Ca2+]i-dependent component, likely involving the SK beta-subunits calmodulin, and a voltage-dependent component, consistent with a pore-blocking effect. This pH(i)-dependent inhibition can be reversed pharmacologically.     

Virus reduction in an intravenous immunoglobulin by solvent/detergent treatment, ion-exchange chromatography and terminal low pH incubation

Virus reduction by several steps in the manufacturing process for the intravenous immunoglobulin Vigam^®, has been investigated. The solvent/detergent step based on treatment with 0.3% tri-n-butyl phosphate and 1% polysorbate 80 at 37 °C, was confirmed to be effective for a range of enveloped viruses. Virus infectivity was undetectable i.e. >6 log inactivation within 30 min of the standard 6 h process. This was consistent over the range of conditions tested i.e. solvent/detergent and protein concentration, temperature and pH. The ion-exchange chromatography step in the process was also able to remove some viruses. Virus spiked followed by blank column runs confirmed the effectiveness of the sanitisation step for ensuring there was no virus cross contamination between column runs. The terminal low pH incubation step was also able to inactivate enveloped viruses, as well as some non-enveloped viruses. The combination of these three steps ensures a high margin of virus safety for this product.