A fluorescent residualizing label for studies on protein uptake and catabolism in vivo and in vitro.

Residualizing labels are tracers which remain in lysosomes after uptake and catabolism of the carrier protein and have been especially useful for studies on the sites of plasma protein degradation. Thus far these labels have contained radioactive reporters such as 3H or 125I. In the present paper we describe a fluorescent residualizing label, NN-dilactitol-N'-fluoresceinylethylenediamine (DLF). Modification of asialofetuin (ASF) or rat serum albumin (RSA) with DLF affected neither their normal kinetics of clearance from the rat circulation nor their normal tissue sites of uptake and degradation. After injection of DLF-ASF, fluorescent degradation products were recovered nearly quantitatively in liver and retained with a half-life of about 2 days. Fluorescent degradation products from DLF-RSA were recovered in skin and muscle, and were localized in fibroblasts by fluorescence microscopy. These results confirm previous studies with radioactive residualizing labels in which fibroblasts in peripheral tissues were identified as primary sites of albumin degradation. Fluorescent catabolites also accumulated in fibroblasts incubated with DLF-RSA in vitro, and residualized with a half-life of about 2 days. Overall, the data establish that DLF functions efficiently as a fluorescent residualizing label both in vivo and in vitro. The advantages of fluorescent, compared with radioactive, residualizing labels should make them valuable tools for studies on protein uptake and catabolism in biological systems.     

Matrix-assisted laser desorption/ionization time-of-flight mass spectrometry for identifying the composition of labeled proteins

Labeled proteins are extensively used in molecular biology and environmental science. The determination of the composition and label ratio is very important for monitoring the efficiency of their separation and purification. In this paper a novel method based on matrix-assisted laser desorption/ionization (MALDI) time-of-flight mass spectrometry was developed for this purpose. The results obtained for three commercial labeled proteins showed that they are mixtures of different conjugates. In some cases, the label ratio obtained by UV spectrometry and MALDI mass spectrometry was strikingly different. For fluorescent labels such as fluorescein isothiocyanate, MALDI mass spectrometry determines the number of covalently bound labels, whereas UV absorption yields both bound and adsorbed labels. For biotinylated proteins, label ratios obtained by the 4-hydroxyazabenzene-2'-carboxylic acid (HABA)-avidin method were found to be much smaller those determined by MALDI mass spectrometry. The HABA-avidin method may therefore not be suitable for the determination of biotin label ratios.     

High-resolution probing of local conformational changes in proteins by the use of multiple labeling: unfolding and self-assembly of human carbonic anhydrase II monitored by spin, fluorescent, and chemical reactivity probes

Two different spin labels, N-(1-oxyl-2,2,5,5-tetramethyl-3-pyrrolidinyl)iodoacetamide (IPSL) and (1-oxyl-2,2,5,5-tetramethylpyrroline-3-methyl) methanethiosulfonate (MTSSL), and two different fluorescent labels 5-((((2-iodoacetyl)amino)-ethyl)amino)naphtalene-1-sulfonic acid (IAEDANS) and 6-bromoacetyl-2-dimetylaminonaphtalene (BADAN), were attached to the introduced C79 in human carbonic anhydrase (HCA II) to probe local structural changes upon unfolding and aggregation. HCA II unfolds in a multi-step manner with an intermediate state populated between the native and unfolded states. The spin label IPSL and the fluorescent label IAEDANS reported on a substantial change in mobility and polarity at both unfolding transitions at a distance of 7.4-11.2 A from the backbone of position 79. The shorter and less flexible labels BADAN and MTSSL revealed less pronounced spectroscopic changes in the native-to-intermediate transition, 6.6-9.0 A from the backbone. At intermediate guanidine (Gu)-HCl concentrations the occurrence of soluble but irreversibly aggregated oligomeric protein was identified from refolding experiments. At approximately 1 M Gu-HCl the aggregation was found to be essentially complete. The size and structure of the aggregates could be varied by changing the protein concentration. EPR measurements and line-shape simulations together with fluorescence lifetime and anisotropy measurements provided a picture of the self-assembled protein as a disordered protein structure with a representation of both compact as well as dynamic and polar environments at the site of the molecular labels. This suggests that a partially folded intermediate of HCA II self-assembles by both local unfolding and intermolecular docking of the intermediates vicinal to position 79. The aggregates were determined to be 40-90 A in diameter depending on the experimental conditions and spectroscopic technique used.     

Properties of spin and fluorescent labels at a receptor-ligand interface.

Site-directed labeling was used to obtain local information on the binding interface in a receptor-ligand complex. As a model we have chosen the specific association of the extracellular part of tissue factor (sTF) and factor VIIa (FVIIa), the primary initiator of the blood coagulation cascade. Different spectroscopic labels were covalently attached to an engineered cysteine in position 140 in sTF, a position normally occupied by a Phe residue previously characterized as an important contributor to the sTF:FVIIa interaction. Two spin labels, IPSL [N-(1-oxyl-2,2,5, 5-tetramethyl-3-pyrrolidinyl)iodoacetamide] and MTSSL [(1-oxyl-2,2,5, 5-tetramethylpyrroline-3-methyl)methanethiosulfonate], and two fluorescent labels, IAEDANS [5-((((2-iodoacetyl)amino) ethyl)amino)naphthalene-1-sulfonic acid] and BADAN [6-bromoacetyl-2-dimethylaminonaphthalene], were used. Spectral data from electron paramagnetic resonance (EPR) and fluorescence spectroscopy showed a substantial change in the local environment of all labels when the sTF:FVIIa complex was formed. However, the interaction was probed differently by each label and these differences in spectral appearance could be attributed to differences in label properties such as size, polarity, and/or flexibility. Accordingly, molecular modeling data suggest that the most favorable orientations are unique for each label. Furthermore, line-shape simulations of EPR spectra and calculations based on fluorescence depolarization measurements provided additional details of the local environment of the labels, thereby confirming a tight protein-protein interaction between FVIIa and sTF when the complex is formed. The tightness of this local interaction is similar to that seen in the interior of globular proteins.     

A universally applicable process for preparing stoichiometrically 1:1 labelled functional proteins

A universally applicable labelling and purification process was established to prepare biologically active proteins with a stoichiometric 1:1 ratio of attached dye-label. The dye-label is linked to a specific DNA sequence, which acts as a barcode-like tag for affinity purification. The DNA-dye tag is covalently bound to the target protein, which is present in excess to assure the binding of not more than one dye per molecule. Affinity purification occurs at magnetic beads that are functionalized with oligonucleotides that are complementary to the DNA-tag of the labelled proteins but for one or two mismatches. Washing removes all unbound, unlabelled molecules. The labelled protein is subsequently released by the addition of a fully complementary oligonucleotide. This process allows a gentle purification of a protein fraction that has exactly one label attached to each molecule under conditions that preserve protein structure.     

Determination of the relative positions of amino acids by partial specific cleavages of end-labeled proteins

We have developed a new method for obtaining information about protein sequences that uses an approach analogous to that used to determine DNA sequences. In essence, three steps are involved. First, a detectable label is attached exclusively to the amino terminus of a polypeptide. Next, the labeled chain is subjected to partial specific cleavage in a way that produces roughly equimolar amounts of fragments of different sizes. Cleavages for methionine, tryptophan, arginine, aspartyl-proline bonds, and asparaginyl-glycine bonds have been employed. Lastly, the labeled fragments are separated according to size by sodium dodecyl sulfate-polyacrylamide gel electrophoresis. The distribution of target amino acids along the polypeptide chain can be deduced from the specific pattern of labeled bands by reading the "ladder" in the same way that DNA sequencing gels are read. Although the method can be conducted with a radioactive label, we have chosen to use a fluorescent label. We have applied the method successfully to the three subunit chains of two different fibrinogens.     

Identifying regions of membrane proteins in contact with phospholipid head groups: covalent attachment of a new class of aldehyde lipid labels to cytochrome c oxidase

A series of amine-specific reagents based on the benzaldehyde reactive group have been synthesized, characterized, and used to study beef heart cytochrome c oxidase reconstituted in phospholipid bilayers. The series contained three classes of reagents: lipid-soluble phosphodiesters having a single hydrocarbon chain, phospholipid analogues, and a water-soluble benzaldehyde. All reagents were either radiolabeled or spin-labeled or both. The Schiff bases formed by these benzaldehydes with amines were found to be reversible until the addition of the reducing agent sodium cyanoborohydride, whereas attachment of lipid-derived aliphatic aldehydes was not readily reversible in the absence of the reducing agent. The benzaldehyde group provides a convenient method of controlling and delaying permanent attachment to integral membrane proteins until after the reconstitution steps. This ensures that the lipid analogues are located properly to identify amine groups at the lipid-protein interface rather than reacting indiscriminately with amines of the hydrophilic domains of the protein. The benzaldehyde lipid labels attach to cytochrome c oxidase with high efficiency. Typically, 20% of the amount of lipid label present was covalently attached to the protein, and the number of moles of label incorporated per mole of protein ranged from 1 to 6, depending on the molar ratios of label, lipid, and protein. The efficiency of labeling by the water-soluble benzaldehyde was much less than that observed for any of the lipid labels because of dilution effects, but equivalent levels of incorporation were achieved by increasing the label concentration. Electron spin resonance spectra of a nitroxide-containing phospholipid analogue covalently attached to reconstituted cytochrome c oxidase exhibited a large motion-restricted component, which is characteristic of spin-labeled lipids in contact with the hydrophobic surfaces of membrane proteins. The line shape and splittings were similar for covalently attached label and label free to diffuse and contact the protein molecules in the bilayer, providing independent evidence that the coupling occurs at the protein-lipid interface. The distribution of the benzaldehyde reagents attached to the polypeptide components of cytochrome c oxidase was examined by sodium dodecyl sulfate-polyacrylamide gel electrophoresis. The labeling pattern observed for the lipid analogues was not affected by the presence of the nitroxide moiety on the acyl chains but was dependent on the molar ratio of labeling reagent to protein.(ABSTRACT TRUNCATED AT 400 WORDS)     

Cellular trafficking and photochemical internalization of cell penetrating peptide linked cargo proteins: a dual fluorescent labeling study

Initial cellular uptake of cell penetrating peptide (CPP) linked macromolecules is usually endosomal, with passage from endosome to cytosol a major limitation to efficient delivery. To gain a better understanding of the passage of the CPP-linked proteins, we studied the uptake and localization of CPP-linked proteins that contained two different forms of fluorescent markers, GFP protein and chemically conjugated tetramethylrhodamine, in living cells. Rhodamine labeled TAT-GFP was internalized in multiple cell lines including HEK293, N18-RE-105, hippocampal slices, and human neural progenitor cells and showed predominantly endosomal localization of both fluorescent markers. Cytosolic localization of some rhodamine label was detected to suggest that some of the GFP label had exited from the endosome. However, quantification of the distribution of the rhodamine and GFP label indicated that the protein location was primarily endosomal and that the distribution of TAT-GFP was not significantly different than that of an exclusively endosomal localized exogenous protein (tetanus toxin fragment C - TTC). As a result, photochemical internalization (PCI) was evaluated and caused a significant quantitative redistribution of cellular fluorescence of rhodamine and GFP labels to demonstrate increased cytosolic delivery of GFP. While rhodamine-labeled TAT-GFP showed cytosolic delivery with exposure to specific wavelengths of fluorescent illumination, a similarly labeled GFP fusion protein containing the membrane binding domain of TTC did not mediate PCI in N18-RE-105 cells.     

A non-radioactive automated method for DNA sequence determination

A method and instrument for automated DNA sequencing without radioactivity have been developed. In spite of the success with radioactive labels there are drawbacks attached to the technique, such as hazards in the handling, storage and disposal of radioactive materials, and the considerable cost of the radiolabelled nucleoside triphosphates. In addition, there is deterioration of sample quality with time. A sulphydryl containing M13 sequencing primer has been synthesised and subsequently conjugated with tetramethylrhodamine iodoacetamide. The fluorescent primer is used to generate a nested set of fluorescent DNA fragments. The fluorescent bands are excited by a laser and detected in the gel (detection limit about 0.1 fmol per band) during electrophoresis, and sequence data from the four tracks are transferred directly into a computer. Standard gels, 200 mm wide with 20 sample slots have also been used. The device contains no moving parts. At present 250-300 bases can be read in 6 h. The system is capable of single base resolution at a fragment length of at least 400 bases.     

Dynamic spin label study of the barstar-barnase complex

The dynamic spin label method was used to study protein-protein interactions in the model complex of the enzyme barnase (Bn) with its inhibitor barstar. The C40A mutant of barstar (Bs) containing a single cysteine residue was modified with two different spin labels varying in length and structure of a flexible linker. Each spin label was selectively bound to the Cys82 residue, located near the Bn-Bs contact site. The formation of the stable protein complex between Bn and spin labeled Bs was accompanied by a substantial restriction of spin label mobility, indicated by remarkable changes in the registered EPR spectra. Order parameter, S, as an estimate of rapid reorientation of spin label relative to protein molecule, was sharply increasing approaching 1. However, the rotational correlation time tau for spin-labeled Bs and its complex with Bn in solution corresponded precisely to their molecular weights. These data indicate that both Bs and its complex with Bn are rigid protein entities. Spin labels attached to Bs in close proximity to an interface of interaction with Bn, regardless of its structure, undergo significant restriction of mobility by the environment of the contact site of the two proteins. The results show that this approach can be used to investigate fusion proteins containing Bn or Bs.     

Extrinsic signals for monitoring the association reaction of proteins as introduced by fluorescent and non-fluorescent labels.

Two known dansyl labels (I, II) and 5-[2-(iodoacetamido)ethylamino]-1-naphthalene-sulfonic acid (III) and three new azo-dyes (IV - VI) were covalently attached to alpha-chymotrypsin and to basic pancreatic trypsin inhibitor by four different reactive groups. In order to protect the contact region of the proteins the complex of the two proteins was labeled. Advantage was taken of the fact that a group which is buried in the complex reacts about (see article) times slower than a group which is always exposed (K = dissociation equilibrium constant, [C] = concentration of the complex). The complex was dissociated at pH 3 and the labeled proteins were isolated by column chromatography. They were fully active. The dansyl label was immobilized when introduced by dansyl chloride but highly mobile when attached via the longer imidoester group (II). Changes of absorption and of fluorescence which occur when differently labeled reaction partners recombine were studied. Changes in absorption (up to 18%) were mainly due to interactions of the label of one protein with the other protein. Fluorescence changes of up to 480% could be obtained. They were interpreted in terms of a F?rster type energy transfer between donor and acceptor labels and changes of absorption and quantum yield due to interactions of the labels with the proteins. The kinetic constants of complex formation are not seriously altered by the labels (B?sterling, B & Engel, J. (1976) this J. 357, 1297-1307, succeeding). It is concluded that the labeling technique may be of general value for kinetic and equilibrium studies of protein associations.     

150 Getting a grip on alpha-synuclein amyloid oligomers

Misfolding and aggregation of proteins into nanometer-scale fibrillar assemblies is a hallmark of many neurodegenerative diseases. Aggregation of the human alpha-synuclein protein is implicated in the etiology of Parkinson’s disease. A particularly relevant question is the role of early oligomeric aggregates of alpha-synuclein in modulating the dynamics of protein aggregation, and in the interactions with essential cellular components. However, very little is known about the molecular details of these aggregate species. For large protein aggregates, such as alpha-synuclein oligomers, it is very difficult to determine the number of monomers that form an oligomer using conventional techniques. We have developed a method that uses sub-stoichiometric labeling, that is, only a fraction of the monomers contains a fluorescent label, in combination with single-molecule photobleaching to determine the number of monomers per oligomer (Zijlstra et al., 2012). The number of bleaching steps gives the number of fluorescent labels per oligomer. Knowing the exact label density, that is, the fraction of labeled monomers at the start of the aggregation, we can correlate the number of fluorescent labels per oligomer to the total number of monomers. Using this method, we can determine the composition, probe the distribution in the number of monomers per oligomer, and investigate the influence of the fluorescent label on the aggregation process. For wild-type alpha-synuclein, we find no distribution in the number of monomers per oligomer and find a single, well-defined oligomeric species consisting of ～30 monomers per oligomer. On the other hand, for oligomers formed in the presence of dopamine, we find a distinctly bimodal distribution suggesting the existence of two populations of oligomeric species.     

A label-free optical technique for detecting small molecule interactions

A novel approach for the label-free detection of molecular interactions is presented in which a colorimetric resonant grating is used as a surface binding platform. The grating, when illuminated with white light, is designed to reflect only a single wavelength. When molecules are attached to the surface, the reflected wavelength (color) is shifted due to the change of the optical path of light that is coupled into the grating. By linking receptor molecules to the grating surface, complementary binding molecules can be detected without the use of any kind of fluorescent probe or radioactive label. The detection technique is capable of detecting the addition and removal of small molecules as they interact with receptor molecules on the sensor surface or enzymes in the solution surrounding the sensor. Two assays are presented to exemplify the detection of small molecule interactions with the biosensor. First, an avidin receptor layer is used to detect 244 Da biotin binding. Second, a protease assay is performed in which a 136 Da p-nitroanilide (pNA) moeity is cleaved from an immobilized substrate. Because the sensor structure can be embedded in the plastic surfaces of microtiter plates or the glass surfaces of microarray slides, it is expected that this technology will be most useful in applications where large numbers of biomolecular interactions are measured in parallel, particularly when molecular labels will alter or inhibit the functionality of the molecules under study. Screening of pharmaceutical compound libraries with protein targets, and microarray screening of protein-protein interactions for proteomics are examples of applications that require the sensitivity and throughput afforded by this approach.     

Quantitative detection of cell surface protein expression by time-resolved fluorimetry.

A method is introduced for quantitative detection of cell surface protein expression. The method is based on immunocytochemistry, the use of long decay time europium(III) chelate and platinum(II) porphyrin labels, and detection of photoluminescence emission from adhered cells by time-resolved fluorimetry. After immunocytochemistry, the assay wells are evaporated to dryness and measured in the dry state. This protocol allows repeated and postponed analysis and microscopy imaging. In order to investigate the performance of the method, we chose expression of intercellular adhesion molecule-1 (ICAM-1) of endothelial cell line EAhy926 as a research target. The expression of ICAM-1 on the cells was enhanced by introduction of a cytokine, tumour necrosis factor-alpha (TNFalpha). The method gave signal:background ratios (S:B) of 20 and 9 for europium and platinum labels, respectively, whereas prompt fluorescent FITC label gave a S:B of 3. Screening window coefficients (=Z'-factor) were >0.5 for all the three labels, thus indicating a score for an excellent screening assay. In conclusion, the method appears to be an appropriate choice for protein expression analysis, both in high-throughput screening applications, and for detailed sample investigation by fluorescent microscopy imaging.     

Probing triplex formation by EPR spectroscopy using a newly synthesized spin label for oligonucleotides

Spin labels have been extensively used to study the dynamics of oligonucleotides. Spin labels that are more rigidly attached to a base in an oligonucleotide experience much larger changes in their range of motion than those that are loosely tethered. Thus, their electron paramagnetic resonance spectra show larger changes in response to differences in the mobility of the oligonucleotides to which they are attached. An example of this is 5-(2,2,5,5-tetramethyl-3-ethynylpyrrolidine-1-oxyl)-uridine (1). How ever, the synthesis of this modified DNA base is quite involved and, here, we report the synthesis of a new spin-labeled DNA base, 5-(2,2,6,6-tetramethyl-4-ethynylpiperidyl-3-ene-1-oxyl)-uridine (2). This spin label is readily prepared in half the number of steps required for 1, and yet behaves in a spectroscopically analogous manner to 1 in oligonucleotides. Finally, it is shown here that both spin labels 1 and 2 can be used to detect the formation of both double-stranded and triplex DNA.     

The binding of radioactive label from labelled phenacetin and related compounds to rat tissues in vivo and to nucleic acids and bovine plasma albumin in vitro

1. acetyl-(3)H- and ethyl-(14)C-labelled derivatives of phenacetin and related compounds are described. 2. Radioactive label from the ethyl-(14)C-labelled derivatives of 4-nitrophenetole, 4-phenetidine and phenacetin binds in vitro to various extents to bovine plasma albumin, salmon sperm DNA and yeast RNA; the extent of binding is increased in the presence of a rat liver microsomal hydroxylating system and further increased when the microsomal enymes are induced by prior treatment of rats with 3-methylcholanthrene. 3. The ratios of the bound radioactive labels in vitro from [ethyl-(14)C]phenacetin, N-acetoxy[ethyl-(14)C]phenacetin, [acetyl-(3)H]phenacetin and [diacetyl-(3)H]N-acetoxyphenacetin per g-atom of DNA P, RNA P and per mol of protein in the absence of the microsomal system are approximately 1:60:11:863, 1:68:41:1835 and 1:88:713:2399 respectively. 4. Radioactive label from labelled phenacetin binds in vitro to all tissues examined, including the spleen, intestines, kidney and bladder; about 80% of the radioactivity bound to the liver is concentrated in the RNA and proteins. 5. Comparison of the relative extents of binding of radioactive label derived from equimolar amounts of labelled phenacetin, ethanol or acetate shows that the incorporation of labelled C(2) units into tissues and biological macromolecules in vivo and in vitro may account for only a part of the total bound radioactive label derived from phenacetin and not at all from the incorporation of radioactive acetate into nucleic acids. 6. Some implications of these findings are discussed.     

Calcium and lanthanide binding in the sarcoplasmic reticulum ATPase

The interactions of calcium and lathanides with the sarcoplasmic reticulum ATPase, and their respective ability to activate the enzyme, were studied by direct measurements of binding with radioactive tracers, functional effects on the ATPase partial reactions, changes in the quantum yield of tryptophanyl residues and a covalently bound fluorescein label (fluorescein 5-isothiocyanate, FITC), and energy transfer between bound lanthanide and fluorescent labels. We find that: (a) Lanthanides displace calcium from specific ATPase sites with diphasic kinetics that are consistent with sequential exchange. (b) Lanthanides in excess of the calcium stoichiometry are mostly bound to sarcoplasmic reticulum lipids and non-ATPase proteins. (c) Both calcium and lanthanides activate the ATPase and allow formation of the phosphorylated intermediate by utilization of ATP; however, hydrolytic cleavage of the intermediate formed in the presence of lanthanides occurs at a slower rate than the intermediate formed in the presence of calcium. (d) In contrast to a calcium-dependent change in the quantum yield of both the tryptophanyl residues (transmembrane region) and the FITC label (extramembranous region), lanthanides induce only a change in the quantum yield of the FITC label. (e) Measurements of energy transfer between bound lanthanide and fluorescent labels detect lanthanide bound midway between the catalytic site in the globular region of the ATPase outside the membrane, and the transmembrane calcium binding domain which is involved in enzyme activation (Clarke, D. M., Loo, T. W., Inesi, G., and MacLennan, D. H. (1989a) Nature 339, 476-478). It is apparent that cation bound in this midway location controls exchange of calcium bound in the transmembrane region. The possibility that the midway location may provide a domain for binding of a second calcium is discussed.     

Kinetics of an individual transmembrane helix during bacteriorhodopsin folding

The kinetics of an individual helix of bacteriorhodopsin have been monitored during folding of the protein into lipid bilayer vesicles. A fluorescence probe was introduced at individual sites throughout helix D of bacteriorhodopsin and the changes in the fluorescence of the label were time-resolved. Partially denatured, labelled bacteriorhodopsin in SDS was folded directly into phosphatidylcholine lipid vesicles. Stopped-flow mixing of the reactants allowed the folding kinetics to be monitored with millisecond time resolution by time-resolving changes in the label fluorescence, intrinsic protein fluorescence as well as in the absorption of the retinal chromophore. Monitoring specific positions on helix D showed that two kinetic phases were altered compared to those determined by monitoring the average protein behaviour. These two phases, of 6.7 s(-1) and 0.33 s(-1), were previously assigned to formation of a key apoprotein intermediate during bacteriorhodopsin folding. The faster 6.7s(-1) phase was missing when time-resolving fluorescence changes of labels attached to the middle of helix D. The amplitude of the 0.33 s(-1) phase increased along the helix, as single labels were attached in turn from the cytoplasmic to the extracellular side. An interpretation of these results is that the 6.7 s(-1) phase involves partitioning of helix D within the lipid headgroups of the bilayer vesicle, while the 0.33 s(-1) phase could reflect transmembrane insertion of this helix. In addition, a single site on helix G was monitored during folding. The results indicate that, unlike helix D, the insertion of helix G cannot be differentiated from the average protein behaviour. The data show that, while folding of bacteriorhodopsin from SDS into lipids is a co-operative process, it is nevertheless possible to obtain information on specific regions of a membrane protein during folding in vitro.     

Transverse motion of chlorophyll derivatives in phospholipid bilayers

Chlorophyll derivatives were synthesized with spin labels attached to the porphyrin ring. These labels were incorporated into egg phosphatidylcholine vesicles in order to estimate the transbilayer motion (flip-flop) of this class of photosynthetic pigments. Using the ascorbate reduction method, the upper limit to the spin label half-life is tau 1/2 approximately 4 min at 0 degrees C. The flip-flop rate is rapid compared to that of a phospholipid spin label under the same conditions. The presence or absence of magnesium in the center of the porphyrin ring had no measurable effect on the flip-flop rate.     

Selective labeling of membrane protein sulfhydryl groups with methanethiosulfonate spin label

Electron paramagnetic resonance was used to characterize the first use of a thiol-specific spin label in membranes. Procedures for use of the spin-label, 1-oxyl-2,2,5,5-tetramethyl-Δ³-pyrroline-3-methyl (methanethiosulfonate MTS) covalently attached to membrane proteins in human erythrocyte membranes are reported. The major findings are: (1) MTS was found to be thiol-specific in membranes as it is for soluble proteins; (2) MTS labels ghost proteins in as few as 30 min at room temperature, providing a distinct advantage when sensitive or fragile membranes are to be used; (3) the distribution of the spin label suggests that the major cytoskeletal protein, spectrin, and the major transmembrane protein (Band 3) incorporate the highest percentage of spin label. This procedure expands the tools with which the researcher can investigate the physical state of membrane proteins and its alteration upon interaction of membrane perturbants or in pathological conditions.