The effects of aggregation and protein corona on the cellular internalization of iron oxide nanoparticles.

Engineered inorganic nanoparticles are essential components in the development of nanotechnologies. For applications in nanomedicine, particles need to be functionalized to ensure a good dispersibility in biological fluids. In many cases however, functionalization is not sufficient: the particles become either coated by a corona of serum proteins or precipitate out of the solvent. In the present paper, we show that by changing the coating of iron oxide nanoparticles from a low-molecular weight ligand (citrate ions) to small carboxylated polymers (poly(acrylic acid)), the colloidal stability of the dispersion is improved and the adsorption/internalization of iron toward living mammalian cells is profoundly affected. Citrate-coated particles are shown to destabilize in all fetal-calf-serum based physiological conditions tested, whereas the polymer coated particles exhibit an outstanding dispersibility as well as a structure devoid of protein corona. The interactions between nanoparticles and human lymphoblastoid cells are investigated by transmission electron microscopy and flow cytometry. Two types of nanoparticle/cell interactions are underlined. Iron oxides are found either adsorbed on the cellular membranes, or internalized into membrane-bound endocytosis compartments. For the precipitating citrate-coated particles, the kinetics of interactions reveal a massive and rapid adsorption of iron oxide on the cell surfaces. The quantification of the partition between adsorbed and internalized iron was performed from the cytometry data. The results highlight the importance of resilient adsorbed nanomaterials at the cytoplasmic membrane.

Structure of the tetraspanin main extracellular domain. A partially conserved fold with a structurally variable domain insertion.

The tetraspanin family of membrane glycoproteins is involved in the regulation of cellular development, proliferation, activation, and mobility. We have attempted to predict the structural features of the large extracellular domain of tetraspanins (EC2), which is very important in determining their functional specificity. The tetraspanin EC2 is composed of two subdomains: a conserved three-helix subdomain and a variable secondary structure subdomain inserted within the conserved subdomain. The occurrence of key disulphide bridges and other invariant residues leads to a conserved relative topology of both subdomains and also suggests a structural classification of tetraspanins. Using the CD81 EC2 structure as a template, the structures of two other EC2s were predicted by homology modeling and indicate a conserved shape, in which the variable subdomain is located at one side of the structure. The conserved and variable subdomains might contain sites that correspond, respectively, to common and specific interactions of tetraspanins. The tetraspanin EC2 seems to correspond to a new scheme of fold conservation/variability among proteins, namely the insertion of a structurally variable subdomain within an otherwise conserved fold.

Mapping of the detergent-exposed surface of membrane proteins and peptides by 1H solution NMR in detergent: Application to the gramicidin A ion channel.

The present work evaluates the use of intermolecular polypeptide-detergent 1H through-space connectivities to determine the bilayer exposed-surface and the bilayer topography of membrane polypeptides solubilized in non- deuterated detergents. For this purpose, the membrane peptide gramicidin A, solubilized in non-deuterated sodium dodecylsulfate as its dimeric ß6,3 helix channel conformation was used. For this peptide, a high-resolution 3D structure, as well as reasonable assumptions concerning its membrane arrangement, exist. Band-selective 2D NOESY, ROESY and 3D NOESY-NOESY experiments were used to detect detergent-polypeptide through-space correlations in the presence of an excess of the non-deuterated detergent. The observed intermolecular NOEs appear to be strongly temperature- dependent. Based on the known 3D structure of the gramicidin channel, the detergent-polypeptide through-space correlations appear to be selective for 1H located on the hydrophobic surface of gramicidin A with very few contributions from interior 1H or water-exposed 1H. It is suggested that this method can be of general use to evaluate the bilayer-exposed surface and topography of membrane peptides and small proteins.

Interaction of the wheat endosperm lipid-binding protein puroindoline-a with phospholipids.

Puroindoline-a is the main component of a new family of proteins that has been suggested to exert an antimicrobial activity in plant seeds through an interaction with lipid membranes. Here the interaction of puroindoline-a with model phospholipid membranes and micelles has been studied using intrinsic tryptophan fluorescence, fluorescence polarization of diphenyl hexatriene, and proteolysis experiments. The protein appears to interact with both zwitterionic and negative phospholipids. The interaction with phosphatidylcholine is characterized by low-affinity surface binding with very limited penetration into the hydrophobic membrane interior. On the other hand, the interaction with phosphatidylglycerol displays a high affinity and involves a partial penetration of the protein into the bilayer interior that disrupts acyl chain packing. The specificity appears to be due to the presence of a stretch of positively charged residues in the protein sequence. In all, the lipid-binding properties of puroindoline-a resemble those of cardiotoxins, another family of proteins for which a disruptive effect on the membrane structure has been involved to explain their biological function.

High-resolution mono- and multidimensional magic angle spinning 1H nuclear magnetic resonance of membrane peptides in nondeuterated lipid membranes and H2O.

High-speed (14 kHz) solid-state magic angle spinning (MAS) 1H NMR has been applied to several membrane peptides incorporated into nondeuterated dilauroyl or dimyristoylphosphatidylcholine membranes suspended in H2O. It is shown that solvent suppression methods derived from solution NMR, such as presaturation or jump-return, can be used to reduce water resonance, even at relatively high water content. In addition, regioselective excitation of 1H peptide resonances promotes an efficient suppression of lipid resonances, even in cases where these are initially two orders of magnitude more intense. As a consequence, 1H MAS spectra of the peptide low-field region are obtained without interference from water and lipid signals. These display resonances from amide and other exchangeable 1H as well as from aromatic nonexchangeable 1H. The spectral resolution depends on the specific types of resonance and membrane peptide. For small amphiphilic or hydrophobic oligopeptides, resolution of most individual amide resonance is achieved, whereas for the transmembrane peptide gramicidin A, an unresolved amide spectrum is obtained. Partial resolution of aromatic 1H occurs in all cases. Multidimensional 1H-MAS spectra of membrane peptides can also be obtained by using water suppression and regioselective excitation. For gramicidin A, F2-regioselective 2D nuclear Overhauser effect spectroscopy (NOESY) spectra are dominated by intermolecular through-space connectivities between peptide aromatic or formyl 1H and lipid 1H. These appear to be compatible with the known structure and topography of the gramicidin pore. On the other hand, for the amphiphilic peptide leucine-enkephalin, F2-regioselective NOESY spectra mostly display cross-peaks originating from though-space proximities of amide or aromatic 1H with themselves and with aliphatic 1H. F3-regioselective 3D NOESY-NOESY spectra can be used to obtain through-space correlations within aliphatic 1H. Such intrapeptide proximities should allow determination of the conformation of the peptide in membranes. It is suggested that high-speed MAS multidimensional 1H NMR of peptides in nondeuterated membranes and in H2O can be used for studies of both peptide structure and lipid-peptide interactions.

Band-selective 3D NOESY-TOCSY: measurement of through-space correlations between aliphatic protons of membrane peptides and proteins in non-deuterated detergents.

Recently the use of band-selective excitation to obtain 1H 2D NMR spectra of membrane peptides and proteins in non-deuterated detergents has been demonstrated [Seigneuret, M. and Levy, D. (1995) J. Biomol. NMR, 5, 345-352]. A limitation of the method was the inability to obtain through-space correlation between aliphatic protons. Here, a 3D F3-band-selective NOESY-TOCSY experiment is described that allows such correlations to be observed in the presence of an excess of non-deuterated detergent. Application to the measurement of proximities between aliphatic protons of the membrane peptide mastoparan X solubilized in non-deuterated n-octylglucoside is presented. With this additional experiment, it is now possible to obtain the same amount of structural constraints on membrane peptides and protein in non-deuterated detergent as in deuterated detergent and therefore to perform complete structural studies.

Ultrafast glycerophospholipid-selective transbilayer motion mediated by a protein in the endoplasmic reticulum membrane.

A relatively rapid transbilayer motion of phospholipids in the microsomal membrane seems to be required due to their asymmetric synthesis in the cytoplasmic leaflet. Marked discrepancies exist with regard to the rate and specificity of this flip-flop process. To reinvestigate this problem, we have used both spin-labeled and radioactively labeled long chain phospholipids with a new fast translocation assay. Identical results were obtained with both types of probes. Transbilayer motion of glycerophospholipids was found to be much more rapid than previously reported (half-time less than 25 s) and to occur identically for phosphatidylcholine, phosphatidylserine, and phosphatidylethanolamine. Such transport is nonvectorial and leads to a symmetric transbilayer distribution of phospholipids. In contrast, transverse diffusion of sphingomyelin was 1 order of magnitude slower. Phospholipid flip-flop appears to occur by a protein-mediated transport process displaying saturable and competitive behavior. Proteolysis, chemical modification, and competition experiments suggest that this transport process may be related to that previously described in the endoplasmic reticulum for short-chain phosphatidylcholine (Bishop, W. R., and Bell, R. M. (1985) Cell 42, 51-60). The relationship between phospholipid flip-flop and nonbilayer structures occurring in the endoplasmic reticulum was also investigated by 31P-NMR. Several conditions were found under which the 31P isotropic NMR signal previously attributed to nonbilayer structures is decreased or abolished, whereas transbilayer diffusion is unaffected, suggesting that the flip-flop process is independent of such structures. It is concluded that flip-flop in the endoplasmic reticulum is mediated by a bidirectional protein transporter with a high efficiency for glycerophospholipids and a low efficiency for sphingomyelin. In vivo, the activity of this transporter would be able to redistribute all changes in phospholipid composition due to biosynthetic processes between the two leaflets of the endoplasmic reticulum membranes within a time scale of seconds.

Alkali cation transport through liposomes by the antimicrobial fusafungine and its constitutive enniatins.

Fusafungine is a peptide antibiotic mixture composed of several enniatins and active against Gram-positive bacteria. Ionophoric properties of fusafungine have been studied in liposomes by measuring protoncation exchange by both fluorescence and 31P-nuclear magnetic resonance (NMR) and have been compared to those of its constituent enniatin peptides. Fusafungine, as well as enniatins, transport cations through a mobile carrier mechanism selective for K+ vs. Na+ and involving two antibiotic molecules. The transport efficiencies of the various enniatins appear to be related to their hydrophobicity, in agreement with a previously proposed "sandwich" transport model. The ionophoric properties of crude fusafungine may be involved in its antibiotic action and its local therapeutic properties.

A high-resolution 1H NMR approach for structure determination of membrane peptides and proteins in non-deuterated detergent: application to mastoparan X solubilized in n-octylglucoside.

Application of 1H 2D NMR methods to solubilized membrane proteins and peptides has up to now required the use of selectively deuterated detergents. The unavailability of any of the common biochemical detergents in deuterated form has therefore limited to some extent the scope of this approach. Here a 1H NMR method is described which allows structure determination of membrane peptides and small membrane proteins by 1H 2D NMR in any type of non-deuterated detergent. The approach is based on regioselective excitation of protein resonances with DANTE-Z or spin-pinging pulse trains. It is shown that regioselective excitation of the amide-aromatic region of solubilized membrane proteins and peptides leads to an almost complete suppression of the two orders of magnitude higher contribution of the protonated detergent to the 1H NMR spectrum. Consistently TOCSY, COSY and NOESY sequences incorporating such regioselective excitation in the F2 dimension yield protein 1H 2D NMR spectra of quality comparable to those obtained in deuterated detergents. Regioselective TOCSY and NOESY spectra display all through-bond and through-space correlations within amide-aromatic protons and between these protons and aliphatic and alpha-protons. Regioselective COSY spectra provide scalar coupling constants between amide and alpha-protons. Application of the method to the membrane-active peptide mastoparan X, solubilized in n-octylglucoside, yields complete sequence-specific assignments and extensive secondary structure-related spatial proximities and coupling constants.(ABSTRACT TRUNCATED AT 250 WORDS)

Localisation of methionine residues in bacteriorhodopsin by carbonyl 13C-NMR with sequence-specific assignments.

High-resolution 13C-NMR experiments have been performed on bacteriorhodopsin biosynthetically labeled with carbonyl-13C amino acids and solubilized in the detergent dodecylmaltoside. 13C-NMR spectra showing good resolution were obtained in the case of labeled amino acids moderately represented in the BR sequence. For BR labeled with [13C]carbonyl methionine, several sequence-specific assignment could be performed by co-labeling with 15N amino acids or proteolysis. These assignments were used to obtain structural data on BR. Water-exposure of methionine side chains in the protein was assessed by studying, using NMR, their oxidation by hydrogen peroxide. Local secondary structure at the level of methionine residues was monitored through the effect of 1H-2H exchange on NMR spectra. It was concluded that Met32, Met68 and Met163 are peripheral while all 6 other methionine residues are deeply embedded within hydrophobic alpha-helices. These results confirm the current model of the BR folding and secondary structure.

Detergent delipidation and solubilization strategies for high-resolution NMR of the membrane protein bacteriorhodopsin.

High-resolution NMR studies of bacteriorhodopsin require the availability of the detergent-solubilized protein with both high concentration and small rotational correlation time. A procedure is described for the optimized preparation of such samples. Bacteriorhodopsin was first delipidated by detergent treatment of purple membrane under nonsolubilizing conditions for the protein. The delipidated aggregated protein could then be solubilized into monomers at concentration close to millimolar by selected detergents. The solubilizing detergent had an important effect on the rotational correlation time of the protein as shown by measuring in each case the temperature-dependent stability of the protein, the size of the detergent-protein complex, and the detergent viscosity. Consistently, a strong influence of the detergent was also found on spectral resolution in 13C NMR spectra of solubilized bacteriorhodopsin labeled with [1-13C]phenylalanine. Best resolution was obtained using n-dodecylmaltoside as detergent, with which relatively narrow well resolved 13C NMR resonances were observed at 50 degrees C. It is suggested that high-resolution NMR studies performed with this detergent may contribute to the structural resolution of bacteriorhodopsin.

High-resolution 13C NMR study of the topography and dynamics of methionine residues in detergent-solubilized bacteriorhodopsin.

The proton transport membrane protein bacteriorhodopsin has been biosynthetically labeled with [methyl-13C]methionine and studied by high-resolution 13C NMR after solubilization in the detergent Triton X-100. The nine methionine residues of bacteriorhodopsin give rise to four well-resolved 13C resonances, two of which are shifted upfield or downfield due to nearby aromatic residues. Methionine residues located on the hydrophilic surfaces, on the hydrophobic surface, and in the interior of the protein could be discriminated by studying the effects of papain proteolysis, glycerol-induced viscosity increase, and paramagnetic broadening by spin-labels on NMR spectra. Such data were used to evaluate current models of the bacteriorhodopsin transmembrane folding and tertiary structure. T2 and NOE measurements were performed to study the local dynamics of methionine residues in bacteriorhodopsin. For the detergent-solubilized protein, hydrophilic and hydrophobic external residues undergo a relatively large extent of side chain wobbling motion while most internal residues are less mobile. In the native purple membrane and in reconstituted bacteriorhodopsin liposomes, almost all methionine residues have their wobbling motion severely restricted, indicating a large effect of the membrane environment on the protein internal dynamics.

Evidence for proton countertransport by the sarcoplasmic reticulum Ca2(+)-ATPase during calcium transport in reconstituted proteoliposomes with low ionic permeability.

To ascertain the coupling between Ca2+ and H+ fluxes during Ca2+ transport by the Ca2(+)-pumping ATPase of the sarcoplasmic reticulum, we used well characterized reconstituted proteoliposomes. The method for the functional reconstitution of the Ca2(+)-ATPase was an extension of our recently published procedure (Rigaud, J. L., Paternostre, M. T., and Bluzat, A. (1988) Biochemistry, 27, 2677-2688). The reconstituted vesicles which sustained high Ca2+ transport activities in the absence of Ca2+ precipitating anions exhibited low ionic passive permeability. Proton fluxes generated by external acid pulses have been monitored by using the fluorescence of the pH-sensitive probe pyranine trapped inside proteliposomes. When K+ was the only permeant ion, low proton-hydroxyl passive permeability was found (permeability coefficient congruent to 5 x 10(-5) cm s-1). In the presence of Cl-1 ions, a higher proton permeability was observed, presumably due to diffusion of HCl molecules. It was further demonstrated that systematic characterization of the passive permeability is essential for understanding and controlling the ATP-dependent Ca2+ accumulation in the reconstituted liposomes. The first line of evidence for Ca2(+)-H+ countertransport during operation of the Ca2(+)-ATPase came from Ca2+ uptake measurements. The ATP-dependent Ca2+ accumulation into proteoliposomes was shown to be critically dependent upon the ionic composition of the medium and the presence of ionophores. In K2SO4 medium a very low Ca2+ uptake was obtained which was only slightly affected by the presence of valinomycin. On the contrary, Ca2+ accumulation was increased 3-4-fold in the presence of the protonophore carbonyl-cyanide-p-trifluoromethoxy phenylhydrazone, indicating that a transmembrane pH gradient was built up during Ca2+ uptake that inhibited the transport activity of the pump. Accordingly, we found that Ca2+ loading capacity increased with internal buffer capacity. Finally in KCl medium, high Ca2+ accumulation was observed even in the absence of protonophore in agreement with a rapid dissipation of the pH gradient in the presence of chloride ions. Additional evidence that the Ca2+ pump of sarcoplasmic reticulum operated as a Ca2(+)-H+ countertransport was provided by measurements of ATP-dependent intraliposomal alkalinization using entrapped 8-hydroxyl-1,3,6-pyrene trisulfonate (pyranine) and accumulation of the weak acid acetate. In K2SO4 medium, transmembrane pH gradients of about 1 pH unit were generated with kinetics parallel to those of the Ca2+ uptake.(ABSTRACT TRUNCATED AT 400 WORDS)

Phospholipid vesicle solubilization and reconstitution by detergents. Symmetrical analysis of the two processes using octaethylene glycol mono-n-dodecyl ether.

The processes of liposome solubilization and reconstitution were studied by using n-dodecyl octaethylene glycol monoether (C12E8). The solubilization of large unilamellar liposomes prepared by reverse-phase evaporation was systematically investigated by turbidity, 31P nuclear magnetic resonance, and centrifugation experiments. The solubilization process is well described by the three-stage model previously proposed for other detergents, and our results further demonstrate the validity of some of the postulates related to this model. In stage I, the detergent distributes between the bilayers and the aqueous solution with a partition coefficient of 1.6 mM-1. In stage II, the detergent-saturated liposomes convert into mixed micelles, the conversion being complete by stage III where all the phospholipids are present as mixed micelles. The agreement between the three methods was excellent, and the results allowed quantitative determination of the effective detergent to phospholipid ratios at which the lamellar to micellar transformation begins and is complete, which amounted to 0.66 and 2.2 (mol/mol), respectively. Furthermore, compositional analysis determined from centrifugation experiments directly demonstrate that the properties of detergent-saturated liposomes and mixed micelles remain constant throughout most of stage II: the C12E8 to phospholipid ratios in the pelleted vesicles and in micelles are constant during stage II and similar to the ratios at which stage II was initiated and complete, respectively. On the other hand, bilayer formation upon detergent removal from mixed C12E8-phospholipid micelles by SM2 Bio-Beads is demonstrated to be the symmetrical opposite of bilayer solubilization.(ABSTRACT TRUNCATED AT 250 WORDS)

IgG anti-tetanus toxoid antibody synthesis by human bone marrow. I. Two distinct populations of marrow B cells and functional differences between marrow and peripheral blood B cells.

This investigation uses a system for inducing and detecting anti-tetanus toxoid antibody (anti-TT) synthesis to study specific antibody (Ab) synthesis by bone marrow mononuclear cells (MC). We measured the amounts of anti-TT secreted and the number of B cells secreting antibody (Ab). The ELISA plaque detects single B cells secreting specific Ab. The results show that (1) spontaneous anti-TT secretion by MC is higher than spontaneous anti-TT secretion by peripheral blood lymphocytes (PBL) using an ELISA plaque (P less than 0.01); (2) spontaneous anti-TT production by MC correlated with the serum anti-TT titers as measured by an ELISA (r = 0.75, P = 0.005); (3) two types of marrow B cells were identified--one that spontaneously secretes anti-TT and another that produces anti-TT after TT-stimulation; (4) the frequency of anti-TT-secreting B cells is higher in MC than in PBL; (5) the amount of Ab secreted per marrow B cell is not different from that secreted by a peripheral B cell; and (6) marrow B cells could be induced to produce anti-TT in vitro up to 10 months without added cytokines. These results show that bone marrow is a major repository for differentiated B cells that spontaneously produce Abs to maintain circulating Abs titers and for memory B cells that can be induced to produce specific Ab.

A systematic study of liposome and proteoliposome reconstitution involving Bio-Bead-mediated Triton X-100 removal.

Equilibrium and kinetic aspects of Triton X-100 adsorption onto hydrophobic Bio-Beads SM2 were investigated in detail using the batch procedure originally described by Holloway, P.W. (1973) Anal. Biochem. 53, 304-308. The results demonstrated the importance of the initial detergent concentration, the amount of beads, the commercial source of the detergent, the temperature and the presence of phospholipids in determining the rates of Triton X-100 adsorption onto Bio-Beads. One of the main findings was that Bio-Beads allowed the almost complete removal of Triton X-100, whatever the initial experimental conditions. It was shown that monomeric as well as micellar detergent could be adsorbed and that a key factor in determining the rate of detergent removal was the availability of the free bead surface. Rates of detergent removal were found to be linearly related to the amount of beads even for bead concentrations above those sufficient to remove all the detergent initially present. Adsorptive capacity of phospholipids onto Bio-Beads SM2 was also analyzed and found to be much smaller (2 mg lipid per g of wet beads) than that of Triton X-100 (185 mg TX 100 per g of wet beads). A more general aspect of this work was that the use of Bio-Beads SM2 provided a convenient way for varying and controlling the time course of Triton X-100 removal. The method was further extended to the formation of liposomes from phospholipid-Triton X-100 micelles and the size of the liposomes was found to be critically dependent upon the rate of detergent removal. A general procedure was described to prepare homogeneous populations of vesicles. Freeze-fracture electron microscopy and permeability studies indicated that the liposomes thus obtained were unilamellar, relatively large and impermeable. Noteworthy, this new procedure was shown to be well suited for the reconstitution of different membrane transport proteins such as bacteriorhodopsin, Ca2(+)-ATPase and H(+)-ATPase.

Decreased specific antibody synthesis in old adults: decreased potency of antigen-specific B cells with aging.

The rise in rates of infection in adults over the age of 60 is accompanied by a decreased ability of older adults to make specific immune responses after immunization with a variety of specific antigens (Ag). This investigation delineates age-related changes in Ag-specific humoral immunity, comparing adults over age 60 to young adults aged 18-40, using tetanus toxoid (TT) as an immunologic probe. A culture system which does not require TT booster immunizations of study subjects was used to induce in vitro specific antibody responses. The amount of anti-TT antibody (Ab) produced in serum and in culture was measured by a TT-specific enzyme-linked immunosorbent assay (ELISA). The numbers of anti-TT Ab-secreting B cells were measured by a TT-specific ELISA-plaque assay. The TT-specific responses of old subjects were significantly less than that seen for young control subjects in the following measures: (1) serum anti-TT Ab titers (mean +/- S.E. log 2 titer = 3.3 +/- 1.1 vs. 9.5 +/- 1.4, P less than 0.01); (2) anti-TT Ab produced by peripheral blood lymphocytes (PBL) in cultures stimulated with TT (6 +/- 2.1 ng/ml vs. 22 +/- 8.4 ng/ml, P less than 0.01); (3) numbers of anti-TT Ab secreting B cells per million cells cultured (6.7 +/- 3.4 vs. 26.6 +/- 7.6, P less than 0.001) and (4) mean ng Ab secreted per anti-TT Ab-secreting B cell (0.6 +/- 0.4 ng vs. 12.7 +/- 7.8 ng, P less than 0.01). This study shows that both decreased numbers of Ag-specific immune B cells and decreased potency on a per cell basis contribute to the impaired immune responses to immunizations in older adults.

Modulation of lymphocyte proliferation and immunoglobulin production by transferrin-gallium.

Gallium resembles iron with respect to transferrin (Tf) binding and cellular uptake via Tf receptors. We have previously shown that transferrin-gallium (Tf-Ga) complexes interfere with the cellular incorporation of iron and inhibit the proliferation of HL60 cells. Since mitogen-stimulated peripheral blood lymphocytes express Tf receptors, we examined the effect of Tf-Ga on lymphocyte proliferation and on immunoglobulin synthesis by B-lymphocytes. Tf-Ga inhibited phytohemagglutinin, pokeweed mitogen, and tetanus toxoid-stimulated lymphocyte proliferation by greater than 50%, an effect which appeared to be cytostatic rather than cytotoxic. In cocultures of T-lymphocytes or CD4+ T-lymphocytes and B-lymphocytes, Tf-Ga also inhibited pokeweed mitogen-stimulated immunoglobulin production by 84 to 100%. Tf-Ga inhibited both T-independent Epstein Barr virus-stimulated B-lymphocyte proliferation and immunoglobulin production; however, these effects appeared to be independent of each other, since immunoglobulin production was inhibited by 75% by a concentration of Tf-Ga which did not uniformly inhibit proliferation. Tf-Ga is capable of targeting Tf receptor-bearing T- and B-lymphocytes and interfering with their proliferation and function. Such effects may be of relevance to patients being treated with this metal. The potential immunosuppressive activity of gallium warrants further investigation.

Influence of cations on the blue to purple transition of bacteriorhodopsin. Comparison of Ca2+ and Hg2+ binding and their effect on the surface potential.

We have investigated the effect of Ca2+ and Hg2+ binding on various properties of the blue membrane prepared by deionization of the Halobacterium halobium purple membrane. Binding of radioactive 45Ca2+ and 203Hg2+ was monitored by a filtration technique. Five high and medium affinity sites for Ca2+ and seven low affinity sites for Hg2+ were found per bacteriorhodopsin. Competitive binding was observed only for three Ca2+ and three Hg2+. Visible absorption studies indicated that Ca2+ binding could restore the purple color of bacteriorhodopsin while Hg2+ was inefficient. Hg2- could partially reverse to blue the Ca2+-regenerated purple membrane in parallel with the displacement of three Ca2+. Effects of cation binding on the surface potential of the membrane were measured by Electron Spin Resonance spectroscopy using a cationic spin-labeled amphiphile. Cations such as La3+, Ca2+, Mg2+, or Na+ strongly increased (i.e. rendered less negative) the surface potential. An univocal correlation was found between the cation-induced variation of surface potential and the extent of regeneration of the purple color. Hg2+ induced a smaller increase in surface potential than that corresponding to the effective divalent cations. This lower effect appears to be due to binding to sites not related to those of other cations.

On the molecular mechanism of the blue to purple transition of bacteriorhodopsin. UV-difference spectroscopy and electron spin resonance studies.

Conformational changes in the bacteriorhodopsin molecule related to the blue to purple transition have been monitored using UV-difference spectrophotometry. Mn2+ binding to the deionized blue membrane, which restores the purple form, promotes the appearance of a difference spectrum that can be interpreted as arising from tryptophan perturbation. Similar difference spectra were found upon pH increase of the blue membrane suspensions. Such pH increase yields the deionized purple membrane and shows an apparent pK of 5.4. Binding of Hg2+ to the blue membrane does not induce any UV-difference spectrum or change the apparent pK of the transition. ESR studies of Mn2+ binding show that in the pink membrane several high and medium affinity binding sites have been converted to low affinity ones. In the NaBH4-reduced membrane, a medium affinity site has been converted to a low affinity site. Upon Mn2+ binding to the reduced membrane or pH increase, absorption changes were found in the visible region which showed a dependence upon bound Mn2+ as well as an apparent pK similar to those of the nonreduced membrane. It is proposed that the functional form of the membrane depends primarily on the deprotonated state of a control group and that cation binding only affects the pK of this deprotonation through changes in the membrane surface potential.