Suppression of nodule development of one side of a split-root system of soybeans caused by prior inoculation of the other side

There was reason from bacterial and algal systems to expect that pretreatments with a paraquat analog might confer tolerance against a subsequent paraquat treatment. Thus, a series of compounds were tested for protective activity against bipyridinium herbicides. These included other bipyridinium compounds and derivatives, as well as compounds having similar or more positive redox potentials than paraquat and compounds known to increase or maintain high superoxide dismutase activity levels in plants.

Only treatments with benzyl viologen, a benzyl analog of paraquat, protected Spirodela oligorrhiza (Kurz) Hegelm. colonies from otherwise damaging levels of diquat.

NADP photoreduction by isolated thylakoids was inhibited by the same concentrations of paraquat, diquat, and benzyl viologen given separately. Thus, the benzyl viologen-mediated tolerance against the bipyridinium herbicides is probably not due to a direct interaction at the thylakoid level.

Superoxide dismutase activity was about 50% higher in broken plastids of benzyl viologen-treated plants compared to controls, which may partly explain the observed tolerance.

     

Modulation of surface-associated urokinase: binding, interiorization, delivery to lysosomes, and degradation in human keratinocytes.

Receptor-mediated endocytosis of urokinase-type plasminogen activator (u-PA) was characterized with the human keratinocyte cell line NCTC, by both biochemical and ultrastructural methods. Binding to specific cell surface receptors at low temperature occurs with both catalytically active and inhibited u-PA. At 37 degrees C a single cohort of bound u-PA molecules is rapidly reduced at the surface level by both membrane dissociation and intracellular accumulation of the ligand, with no difference between active and inhibited u-PA. After a short lag period, both intact u-PA and u-PA degradation products are released into the culture medium. In the continued presence of native and inhibited u-PA at 37 degrees C the cumulative ligand uptake largely exceeds the total cellular capacity of binding sites measured at low temperature, consistent with receptor recycling. Catalytically inhibited u-PA shows a reduced interiorization rate, consistent with a requirement of an intact catalytic site which becomes evident in the presence of multiple cycles of endo-exocytosis. In the presence of a molar excess of anti-plasminogen activator inhibitor-type 1 (PAI-1) antibodies the interiorization rate is similar to that observed with catalytically inhibited u-PA, suggesting that PAI-1 molecules can modulate the intracellular accumulation of u-PA in this cell line. Parallel electron microscopy studies of a u-PA-colloidal gold complex have shown that membrane-associated u-PA molecules are concentrated in clusters before invagination of the underlying membrane to form endosomes which then fuse with lysosomes, where at least a part of u-PA degradation is likely to occur. Also, ultrastructural studies have confirmed the decrease in intracellular u-PA accumulation after inhibition of u-PA catalytic site. We conclude that cell surface-associated u-PA modulation in human keratinocytes involves ligand binding, uptake, and degradation, mediated by the classic receptor system for u-PA A chain, which can be modulated by membrane-associated PAI-1 molecules.     

Membrane-bound polyribosomes in HeLa cells: association of polyadenylic acid with membranes

Polyadenylic acid of membrane-bound polyribosomes is shown to be associated with rapidly sedimenting membrane structures. Most of this poly(A) remains attached to membranes after extensive degradation of polyribosomal messenger RNA with pancreatic ribonuclease. Previously, it was shown that exposure to EDTA removes up to 40% of the membrane-associated mRNA. In our experiments, 57% of the membrane-associated poly(A) still sediments with membrane structures after treatment with pancreatic ribonuclease followed by the addition of EDTA. This indicates that the association of about 60% of the membrane-bound poly(A) is EDTA-resistant, while the remainder is labile after removal of magnesium ions. Reconstruction experiments suggest that poly(A) from detergent-treated, membrane-derived polyribosomes is not trapped by other membrane structures. The poly(A)-containing RNA fragment that remains associated with the membranes after pancreatic ribonuclease treatment is shown to be a single peak at about 7 S, or about the size of cellular poly(A). Thus, the attachment site is almost pure poly(A). The poly(A)-containing, membrane-bound mRNA appears to be of a larger average size than total cellular poly(A)-containing RNA, as judged by its greater sedimentation value.     

Structural characterization of the membrane-associated regulatory subunit of type I cAMP-dependent protein kinase by mass spectrometry: identification of Ser81 as the in vivo phosphorylation site of RIalpha.

The mechanism by which the type Ialpha regulatory subunit (RIalpha) of cAMP-dependent protein kinase is localized to cell membranes is unknown. To determine if structural modification of RIalpha is important for membrane association, both beef skeletal muscle cytosolic RI and beef heart membrane-associated RI were characterized by electrospray ionization mass spectrometry. Total sequence coverage was 98% for both the membrane-associated and cytosolic forms of RI after digestion with AspN protease or trypsin. Sequence data indicated that membrane-associated and cytosolic forms of RI were the same RIalpha gene product. A single RIalpha phosphorylation site was identified at Ser81 located near the autoinhibitory domain of both membrane-associated and cytosolic RIalpha. Because both R subunit preparations were 30-40% phosphorylated, this post-translational modification could not be responsible for the membrane compartmentation of the majority of RIalpha. Mass spectrometry also indicated that membrane-associated RIalpha had a higher extent of disulfide bond formation in the amino-terminal dimerization domain. No other structural differences between cytosolic and membrane-associated RIalpha were detected. Consistent with these data, masses of the intact proteins were identical by LCQ mass spectrometry. Lack of detectable structural differences between membrane-associated and cytosolic RIalpha strongly suggests an interaction between RIalpha and anchoring proteins or membrane lipids as more likely mechanisms for explaining RIalpha membrane association in the heart.     

Biological activity of human immunodeficiency virus type 1 Vif requires membrane targeting by C-terminal basic domains.

Human immunodeficiency virus type 1 (HIV-1) encodes a Vif protein which is important for virus replication and infectivity. Vif is a cytoplasmic protein which exists in both membrane-associated and soluble forms. The membrane-associated form is an extrinsic membrane protein which is tightly associated with the cytoplasmic side of membranes. We have analyzed the mechanism of membrane targeting of Vif and its role in HIV-1 replication. Mutagenesis studies demonstrate that C-terminal basic domains are required for membrane association. Vif mutations which disrupt membrane association also inhibit HIV-1 replication, indicating that membrane localization of Vif is likely to be required for its biological activity in vivo. Membrane binding of Vif is almost completely abolished by trypsin treatment of membranes. These results demonstrate that membrane localization of Vif requires C-terminal basic domains and interaction with a membrane-associated protein(s). This interaction may serve to direct Vif to a specific cellular site, since immunofluorescence staining and plasma membrane fractionation studies show that Vif is localized predominantly to an internal cytoplasmic compartment rather than to the plasma membrane. The mechanism of membrane targeting of Vif is different in some respects from that of other extrinsic membrane proteins, such as Ras, Src, and MARCKS, which utilize a basic domain together with a lipid modification for membrane targeting. Membrane targeting of Vif is likely to play an important role in HIV-1 replication and thus may be a therapeutic target.     

Generation of ligand-receptor alliances by "SEA" module-mediated cleavage of membrane-associated mucin proteins

A mechanism is described whereby one and the same gene can encode both a receptor protein as well as its specific ligand. Generation of this receptor-ligand partnership is effected by proteolytic cleavage within a specific module located in a membrane resident protein. It is postulated here that the "SEA" module, found in a number of heavily O-linked glycosylated membrane-associated proteins, serves as a site for proteolytic cleavage. The subunits generated by proteolytic cleavage of the SEA module reassociate, and can subsequently elicit a signaling cascade. We hypothesize that all membrane resident proteins containing such a "SEA" module will undergo cleavage, thereby generating a receptor-ligand alliance. This requires that the protein subunits resulting from the proteolytic cleavage reassociate with each other in a highly specific fashion. The same SEA module that serves as the site for proteolytic cleavage, probably also contains the binding sites for reassociation of the resultant two subunits. More than one type of module can function as a site for proteolytic cleavage; this can occur not only in one-pass membrane proteins but also in 7-transmembrane proteins and other membrane-associated proteins. The proposal presented here is likely to have significant practical consequences. It could well lead to the rational design and identification of molecules that, by binding to one of the cleaved partners, will act either as agonists or antagonists, alter signal transduction and, hence, cellular behavior.     

Identification of a phosphoinositide binding motif that mediates activation of mammalian and yeast phospholipase D isoenzymes.

Phosphoinositides are both substrates for second messenger-generating enzymes and spatially localized membrane signals that mediate vital steps in signal transduction, cytoskeletal regulation and membrane trafficking. Phosphatidylcholine-specific phospholipase D (PLD) activity is stimulated by phosphoinositides, but the mechanism and physiological requirement for such stimulation to promote PLD-dependent cellular processes is not known. To address these issues, we have identified a site at which phosphoinositides interact with PLD and have assessed the role of this region in PLD function. This interacting motif contains critical basic amino acid residues that are required for stimulation of PLD activity by phosphoinositides. Although PLD alleles mutated at this site fail to bind to phosphoinositides in vitro, they are membrane-associated and properly localized within the cell but are inactive against cellular lipid substrates. Analogous mutations of this site in yeast PLD, Spo14p, result in enzymes that localize normally, but with catalytic activity that has dramatically reduced responsiveness to phosphoinositides. The level of responsiveness to phosphoinositides in vitro correlated with the ability of PLD to function in vivo. Taken together, these results provide the first evidence that phosphoinositide regulation of PLD activity observed in vitro is physiologically important in cellular processes in vivo including membrane trafficking and secretion.     

Radiolytic studies of trimethylamine dehydrogenase. Spectral deconvolution of the neutral and anionic flavin semiquinone, and determination of rate constants for electron transfer in the one-electron reduced enzyme

Trimethylamine dehydrogenase from the pseudomonad Methylophilus methylotrophus has been examined using the technique of pulse radiolysis to rapidly introduce a single reducing equivalent into the enzyme. Using enzyme that has had its iron-sulfur center rendered redox-inert by prior reaction with ferricenium hexafluorophosphate, we determined the spectral change associated with formation of both the anionic and neutral forms that were generated at high and low pH, respectively, of the unique 6-cysteinyl-FMN of the enzyme. With native enzyme, electron transfer was observed within the radiolytically generated one-electron reduced enzyme but only at low pH (6.0). The kinetics and thermodynamics of this electron transfer in one-electron reduced enzyme may be compared with that studied previously in the two-electron reduced enzyme. In contrast to previous studies with two-electron reduced enzyme in which a pK(a) of approximately 8 was determined for the flavin semiquinone, in the one-electron reduced enzyme the semiquinone was not substantially protonated even at pH 6. 0. These results indicate that reduction of the iron-sulfur center of the enzyme significantly decreases the pK(a) of the flavin semiquinone of the active site. This provides further evidence, in conjunction with the strong magnetic interaction known to exist between the centers in the two-electron reduced enzyme, that the two redox-active centers in trimethylamine dehydrogenase are in intimate contact with one another in the active site of the enzyme.     

Neuronal mechanisms contributing to long-term sensitization in Aplysia

1.) Cellular processes that contribute to the acquisition and expression of long-term sensitization have been examined in Aplysia. The tail-siphon withdrawal reflex was studied because the neural circuit for this reflex has been well characterized. Furthermore, the sensory neurons of this neural circuit exhibit cellular changes that accompany short-term sensitization. 2.) Repeated application of noxious stimuli to the animal produces a long-lasting enhancement of reflex withdrawal of the siphon when the animal is tested with a weak stimulus to the tail. These findings confirm the existence of long-term sensitization in Aplysia, first described by Pinkser et al. (1973). 3.) Biophysical correlates of long-term sensitization were examined in the first central relay of the tail-siphon reflex circuit, the sensory neurons that innervate the animal's tail. The net outward membrane currents of these cells reduced after 24 hours as a consequence of long-term sensitization training. 4.) The intracellular signal for the induction of these changes in membrane currents was examined by intracellular injection of cAMP into individual sensory neurons. This procedure mimics at least some of the effects of sensitization training at the single-cell level. cAMP induced a long-term reduction of membrane K+ currents 24 hours after the cells were injected with cAMP. The membrane currents reduced by cAMP were similar to those reduced by long-term sensitization training. 5.) Preliminary experiments indicate that neurotransmitters and agents that induce an evaluation of cAMP in the sensory neurons also alter the incorporation of labeled amino acids into specific proteins in the sensory neurons.(ABSTRACT TRUNCATED AT 250 WORDS)     

Anomalies of viologens in bases and water

The use of viologens as oxidation-reduction indicators in the biochemical field has greatly increased recently.

In the presence of organic and inorganic bases the viologens undergo an auto-reduction which casts doubts on their general reliability as oxidation-reduction indicators.

The inorganic bases act on the viologens only at high concentrations of the latter; however, some nitrogen bases, like pyrrolidine and piperidine, cause the blue coloration even at the low concentrations used in biochemical work.

KOH, NaOH and Na₂CO₃ (not NaHCO₃) gave the characteristic blue coloration of the reduced form when added to aqueous solutions of the viologens. Piperidine, pyrrolidine and pyridine affect the viologens in a similar manner.

Benzyl viologen was reacted with NaOH, NaOCH₃ and pyrrolidine and the products of each reaction were isolated.

On the basis of these results a mechanism is proposed for this disproportionation.

Although reduced viologens do not follow Beer's law in water, we have found that they do follow it in certain organic solvents.

The conclusions show that reductions of both benzyl and methyl viologen carried out at high pH values or in the presence of a nitrogen base may be partially or totally the result of the interaction of the base with the viologen.     

Recruitment of a specific amoeboid myosin I isoform to the plasma membrane in chemotactic Dictyostelium cells

The Dictyostelium class I myosins, MyoA, -B, -C, and -D, participate in plasma membrane-based cellular processes such as pseudopod extension and macropinocytosis. Given the existence of a high affinity membrane-binding site in the C-terminal tail domain of these motor proteins and their localized site of action at the cortical membrane-cytoskeleton, it was of interest to determine whether each myosin I was directly associated with the plasma membrane. The membrane association of a myosin I heavy chain kinase that regulates the activity of one of the class I myosins, MyoD was also examined. Cellular fractionation experiments revealed that the majority of the Dicyostelium MyoA, -B, -C and -D heavy chains and the kinase are cytosolic. However, a small, but significant, fraction (appr. 7. -15%) of each myosin I and the kinase was associated with the plasma membrane. The level of plasma membrane-associated MyoB, but neither that of MyoC nor MyoD, increases up to 2-fold in highly motile, streaming cells. These results indicate that Dictyostelium specifically recruits myoB to the plasma membrane during directed cell migration, consistent with its known role in pseudopod formation.     

Role of MinD-membrane association in Min protein interactions

Division site placement in Escherichia coli involves interactions of the MinD protein with MinC and MinE and with other MinD molecules to form membrane-associated polymeric structures. In this work, as part of a study of these interactions, we established that heterologous membrane-associated proteins such as MinD can be targeted to the yeast nuclear membrane, dependent only on the presence of a membrane-binding domain and a nuclear targeting sequence. Targeting to the nuclear membrane was equally effective using the intrinsic MinD membrane-targeting domain or the completely unrelated membrane-targeting domain of cytochrome b(5). The chimeric proteins differing in their membrane-targeting sequences were then used to establish the roles of membrane association and specificity of the membrane anchor in MinD interactions, using the yeast two-hybrid system. The chimeric proteins were also used to show that the membrane association of MinD and MinE in E. coli cells had no specificity for the membrane anchor, whereas formation of MinDE polar zones and MinE rings required the presence of the native MinD membrane-targeting sequence.     

Requirements for induction of T cell tolerance to DNFB: efficiency of membrane-associated DNFB.

Tolerance to contact sensitization with DNFB, a T cell-dependent phenomenon, was induced in mice by preparations of DNFB coupled to mouse RBC or spleen cells. Such tolerance is dose related, wanes with time, and can be transferred to normal animals with lymphoid cells (presumably containing suppressors). Tolerance to DNFB-RBC can be produced by whole DNFB-RBC, by ghosts of these cells, by sonicates of the ghosts, and by detergent-treated DNFB-RBC ghosts. Tolerance cannot be produced by larger amounts of DNFB-RBC components not associated with membrane. The ability of various DNP compounds to stimulate DNA synthesis in DNFB-sensitized cells also correlates with their ability to bind to protein components; i.e., DNFB is a far more efficient stimulator than DNBSO, whereas DNPlysine does not stimulate at all. Thus, the ability to sensitize or to tolerize with DNFB congeners is related to their ability to couple to proteins. It appears that the active induction of T cell tolerance requires that tolerogen be coupled to cell membranes. Since both T cell sensitization and tolerance to DNFB are best produced by DNFB-membrane, the actual occurrence of one state or the other must depend on the molecular method of "presentation" of DNFB-membrane.     

The Fragments of the Photosynthetic Electron Transfer Chain in Model Systems

In this paper the recent research from our laboratory is reviewed. Short fragments of the photochemical electron transfer chain of photosynthesis were reproduced in aqueous detergent solutions or in organic solvents. The function of photosystem I is reproduced in a ternary system of chlorophylls, electron donors (dienols, sulfhydryl compounds, hydrazine, etc.), and electron acceptors (viologens, nicotinamide-adenine dinucleotide [NAD], flavines, etc.). Chlorophyll-photosensitized reduction of viologens in some cases is activated by oxygen at the expense of active reductants formed during the photosensitized oxidation of an initial electron donor (thiourea). Chlorophyll-photosensitized oxidoreduction of cytochromes is activated by flavines, viologens, vitamin K derivatives, and some other redox systems (cofactors of cyclic photophosphorylation). The primary mechanism of the reactions studied depends on the reversible chlorophyll photooxidoreduction. In binary systems, chlorophyll (monomeric or aggregated) and electron donor or electron acceptor, reversible photoreduction or photooxidation is observed. Irreversible bacteriochlorophyll oxidation leads to the formation of chlorophyll and protochlorophyll analogues; irreversible protochlorophyll photoreduction results in chlorophyll-like pigment appearance. The photodisaggregation of chlorophyll was observed. The models of photosystem II studied were the photochemical oxygen evolution in aqueous solutions of electron acceptors (ferric compounds, quinone), photosensitized in the near UV part of the spectrum by inorganic semiconductors (tungsten, titanium, and zinc oxides). All reactions described are based on electron (hydrogen) transfer photosensitized by pigment system.     

Evidence of transferrin binding sites on the surface of Leishmania promastigotes.

A glycoprotein of 78,000 molecular mass (78 kDa), associated with the membrane of Leishmania infantum promastigotes, was identified and immunopurified by monoclonal antibody (mAb) LD9 produced against isolated membrane preparations. mAb LD9 was subsequently found to bind to human transferrin, also of 78 kDa. Binding of LD9 to transferrin was completely abolished when the mAb was preabsorbed by Leishmania membranes, thereby indicating that the 78-kDa Leishmania membrane-associated glycoprotein and transferrin have common antigenic epitope(s). The 78-kDa Leishmania membrane-associated protein was released in soluble nonaggregated form by mild treatment with acetic acid saline. Anti-transferrin polyclonal antibodies, recognized both the membrane-associated and the soluble form of the 78-kDa glycoprotein. The 78-kDa soluble form was characterized further as an iron-containing protein. The above data combined with iron uptake by promastigotes as demonstrated by the Prussian blue reaction indicate that the 78-kDa Leishmania membrane-associated glycoprotein is transferrin. The binding of 125I-human transferrin to Leishmania-purified membrane preparations was then investigated. The results indicate the presence of a high affinity saturable binding site (Kd = 2.2 10(-8) M) that is specific for transferrin. We suggest that the 78-kDa glycoprotein recognized by mAb LD9 is transferrin that binds to the surface of Leishmania promastigotes via a transferrin receptor.     

Bacillus subtilis ResA is a thiol-disulfide oxidoreductase involved in cytochrome c synthesis

Covalent attachment of heme to apocytochromes c in bacteria occurs on the outside of the cytoplasmic membrane and requires two reduced cysteinyls at the heme binding site. A constructed ResA-deficient Bacillus subtilis strain was found to lack c-type cytochromes. Cytochrome c synthesis was restored in the mutant by: (i) in trans expression of resA; (ii) deficiency in BdbD, a thiol-disulfide oxidoreductase that catalyzes formation of an intramolecular disulfide bond in apocytochrome c after transfer of the polypeptide across the cytoplasmic membrane; or (iii) by addition of the reductant dithiothreitol to the growth medium. In vivo studies of ResA showed that it is membrane-associated with its thioredoxin-like domain on the outside of the cytoplasmic membrane. Analysis of a soluble form of the protein revealed two redox reactive cysteine residues with a midpoint potential of about -340 mV at pH 7. We conclude that ResA, probably together with another thiol-disulfide oxidoreductase, CcdA, is required for the reduction of the cysteinyls in the heme binding site of apocytochrome c.     

Direct association of messenger RNA with microsomal membranes in human diploid fibroblasts

Messenger RNA (mRNA) of membrane-bound polysomes in a membrane fraction of WI-38 cells remains associated with the microsomal membranes even after ribosomes and their nascent polypeptide chains are removed by using puromycin in a high salt buffer or by disassembling the ribosomes in a medium of high ionic strength lacking magnesium. mRNA either was specifically labeled in the presence of actinomycin D, or it was recognized by virtue of its affinity for oligo-dT. Poly A segments in bound mRNAs have an electrophoretic mobility in acrylamide gels which is characteristic of cytoplasmic mRNAs and corresponds to 150-200 adenyl residues. Extensive RNase treatment did not lead to release of the poly A segments of membrane-associated mRNA molecules either from an intact membrane fraction or from a membrane fraction previously stripped of ribosomes. On the other hand, RNase treatment led to the release and digestion of the nonpoly A segments of the mRNA molecules, indicating that the site of attachment of mRNA to the ER membranes is located near or at the 3' end of the molecule which contains the poly A. A direct association of mRNAs and endoplasmic reticulum membranes is considered in a modelto explain the assembly of bound polysomes and protein synthesis in a membrane-associated apparatus.     

The use of amphipathic maleimides to study membrane-associated proteins

A series of amphiphilic polymethylenecarboxymaleimides has been synthesized for use as sulfhydryl reagents applicable to membrane proteins. Physical properties of the compounds which are relevant to their proposed mode of action have been determined. By comparing rates of reaction in aqueous and aprotic solvents, the compounds have been shown to react exclusively with the thiolate ion. The effects of the reagents on three membrane-associated proteins are reported, and in two cases a comparative study has been made of the effects on the proteins in the absence of membranes. A mechanism is proposed whereby the reagents are anchored at the lipid/water interface by the negatively charged carboxyl group, thus siting the reactive maleimide in a plane whose depth is defined by the length of the reagent. Supporting evidence for this model is provided by the inability of the reagents to traverse membranes, and variation of their inhibitory potency with chain length when the proteins are embedded in the membrane, but not when extracted into solution. As examples of general use of the reagents to probe sulfhydryl groups in membrane proteins, the reagents have been used to (a) determine the depths in the membrane at which two populations of sulfhydryl groups occur in the mitochondrial phosphate transporter; (b) locate a single sulfhydryl associated with the active site ofD--hydroxybutyrate dehydrogenase in the inner mitochondrial membrane; (c) examine sulfhydryl groups in theD-3-glyceraldehyde phosphate dehydrogenase associated with the human red blood cell membrane.     

The handling of Listeria monocytogenes by macrophages: the search for an immunogenic molecule in antigen presentation

The activation of T lymphocytes for immunity to the intracellular pathogen Listeria monocytogenes requires that Ia-positive macrophages ingest the bacteria. The subsequent handling of Listeria by macrophages was examined in this report and related to antigen presentation to T cells. Macrophages pulsed with radiolabeled Listeria, besides releasing acid-soluble radioactivity--an indication of extensive catabolism of the Listeria-derived proteins--were also found to release acid-insoluble peptides. The rate of release of the peptides was not markedly affected by treatment with chloroquine, ammonia, or monensin and was independent of the state of activation and the level of Ia expression of the macrophage. The peptides were not associated with fragments of membranes and were represented by several molecular species. Listeria-derived peptides were also found associated with the macrophage plasma membrane. The membrane-associated peptides behaved like integral membrane proteins and could be released by proteases or detergents. Their expression was independent of the dose of Listeria and the level of Ia expression of the macrophage, and their presence could not be inhibited by protease inhibitors or chloroquine. The Listeria peptides released by the macrophages were very weakly immunogenic in a T cell proliferation assay. Purified plasma membranes from Listeria-pulsed macrophages, which contained membrane-associated Listeria peptides, were not immunogenic by themselves but could be reprocessed by additional macrophages to subsequently stimulate T cells. Trypsin treatment of Listeria-pulsed macrophages did not cause a significant reduction in their ability to stimulate T cells. No association was found between Ia molecules and either the membrane-associated or the released peptides with the use of several technical approaches. Hence, after internalization of Listeria, potentially immunogenic material can be found at the cell surface as well as in the culture fluid. The release of soluble peptides is a clear indication that proteins can be recycled after their internalization in vesicles.     

Organic free radicals and proteins in biochemical injury: electron- or hydrogen-transfer reactions?

The reactions of organic free radicals, acting as either reductants or oxidants, have been studied by pulse radiolysis in neutral aqueous solution at room temperature. Manyhydroxyl-substituted aliphatic carbon-centred radicals and one-electron adducts have been shown to be good one-electron reductants, while several oxygen-, sulphur- and nitrogen- (but not carbon-) centred free radicals have been shown to be good one-electron oxidants. Several carbon-centred radicals can be reduced rapidly by hydrogen transfer, from undissociated thiol compounds which can thus act as catalysts facilitating the overall reduction of a carbon-centred radical by an electron-donating molecule. Kinetic considerations influenced by the one-electron redox potentials of the radical-molecule couples involved, determine whether a particular reaction predominates. In this paper examples of such reactions, involving a water-soluble derivative of vitamin E (Trolox C) and the coenzyme NADH, are described, together with studies showing (a) that even in complex multi-solute systems some organic peroxy radicals can inactiviate alcohol dehydrogenase under conditions where the superoxide radical does not, and (b) the superoxide radical can be damaging if urate is also present, and this damage can be reduced by the presence of superoxide dismutase.