Intrinsic proteins of the intestinal microvillus membrane. Iodonaphythylazide labeling studies

Isolated brush border membranes of the intestinal epithelial cell were labeled with a hydrophobic photoactive compound [¹²⁵I]iodonaphthylazide. High incorporation of the radioactive naphthylazide was noted for molecular weight bands of 99 000, 86 000, 65 000, 54 000 and 30 000. Minimal labeling occurred in the higher bands of 300 000, 135 000, 125 000 and 17 000. The iodonaphthylazide label was not removed by extensive papain digestion whereas chloramine T iodinated membranes released radioactivity under the same conditions. Neither enzymatic nor transport activities were inhibited by the presence of iodonaphthylazide or the irradiation process. On the basis of the presented data it is concluded that the iodonaphthylazide unspecifically labels those portions of membrane proteins which are inserted into the lipid bilayer matrix.     

Preparation and reactions of an iodinated imidoester reagent with actin and alpha-actinin

The chemical iodination of an imidoester (methyl-p-hydroxybenzimidate, Wood et al. (1975) Anal. Biochem. 68, 339) and subsequent coupling of iodinated imidoester (IIE) to protein is an indirect method of iodinating proteins that is specific for the epsilon amino group of lysine residues and maintains the positive charge on the amino group at physiological pH. Purification of the IIE from chloramine-T and free iodine by benzene extraction eliminates the need for isoelectric precipitation and produces a more time- and cost-efficient IIE preparation and purification protocol. The separation of free from protein-bound label by chromatography, using centrifugal elution, provides a separation method that is rapid and efficient, without the generation of large volumes of radioactive wastes characteristic of conventional chromatographic and dialysis methods. To optimize the parameters of labeling protein with IIE, a systematic assessment of the effects of pH, reactant concentrations, and reaction time was made using purified cardiac actin and gizzard alpha-actinin. The parameters were defined to achieve an average labeling ratio of one IIE per protein polypeptide. The data demonstrate that both proteins appear to be labeled at the same rate and define several determining factors that limit the rate and extent of IIE incorporation into protein.     

A versatile procedure for the radioiodination of proteins and labeling reagents

For tracer or analytical studies it is often useful to label proteins by direct iodination or by reacting them with an iodinated reagent. A simple iodination technique with hydrogen peroxide is described for use with either carrier-free or low-specific-activity iodine. The method introduces less oxidative damage to proteins than any other procedure tested, yet the efficiency of labeling approaches that offered by the chloramine T or Iodogen methods. The method has been applied to the facile and inexpensive preparation of the iodinated Bolton-Hunter reagent. This peroxide iodination procedure should be particularly useful for labeling proteins or peptides for structural investigations or for immunoassays.     

A versatile procedure for the radioionization of proteins and labeling reagents

For tracer or analytical studies it is often useful to label proteins by direct iodination or by reacting them with an iodinated reagent. A simple iodination technique with hydrogen peroxide is described for use with either carrier-free or low-specific-activity iodine. The method introduces less oxidative damage to proteins than any other procedure tested, yet the efficiency of labeling approaches that offered by the chloramine T or Iodogen methods. The method has been applied to the facile and inexpensive preparation of the iodinated Bolton-Hunter reagent. This peroxide iodination procedure should be particularly useful for labeling proteins or peptides for structural investigations or for immunoassays.     

Synthesis of nitrodiazirinyl derivatives of neurotoxin II fromNaja naja oxiana and their interaction with theTorpedo californica nicotinic acetylcholine receptor

Five singly modified nitrodiazirine derivatives of neurotoxin II (NT-II) fromNaja naja oxiana were obtained after NT-II reaction with N-hydroxysuccinimide ester of {2-nitro-4 [3-(trifluoromethyl)-3H-diazirin-3yl]phenoxy}acetic acid followed by Chromatographic separation of the products. To localize the label positions, each derivative was first UV-irradiated and then subjected to reduction, carboxymethylation, and trypsinolysis. Tryptic digests were separated by reversed phase-HPLC, the labeled peptides being identified by mass spectrometry. The derivatives containing the photolabel at the position Lys 25, Lys 26, Lys 44, or Lys 46 were [¹²⁵I]iodinated by the chloramine T procedure. Each iodinated derivative was found to form photoinduced cross-links with the membrane bound nicotinic acetylcholine receptor (AChR) fromTorpedo californica. The pattern of labeling the receptor'sα, β, γ, orδ subunits was dependent on the photolabel position in the NT-II molecule and differed from that obtained earlier with an analogous series ofp-azidobenzoyl derivatives of NT-II. The results obtained indicate that (i) different sides of the neurotoxin molecule are involved in the AChR binding, and (ii) fragments of the different AChR subunits are located close together at the neurotoxin-binding sites.     

THE ENZYMATIC IODINATION OF THE RED CELL MEMBRANE

An enzymatic iodination procedure utilizing lactoperoxidase (LPO), radioactive iodide, and hydrogen peroxide generated by a glucose oxidase-glucose system has been described and utilized for a study of the red cell membrane. 97% of the incorporated isotope is in the erythrocyte ghost and 3% is associated with hemoglobin. No significant labeling of the red cell membrane occurs in the absence of LPO or by the deletion of any of the other reagents. A 6 million-fold excess of chloride ions inhibits iodination by no more than 50%. Incorporation of up to 1 x 10⁶ iodide atoms into a single erythrocyte membrane results in no significant cell lysis. The incorporated label is exclusively in tyrosine residues as monoiodotyrosine. 10–15% of the trichloroacetic acid-precipitable radioactivity can be extracted with lipid solvents but is present as either labeled protein or ¹²⁵I. Sodium dodecyl sulfate-polyacrylamide gel electrophoresis of solubilized membrane proteins reveals only two labeled protein bands out of the 15 present, and the presence of 50-1 x 10⁶ iodide atoms per ghost does not alter this pattern. Component a has a molecular weight of 110,000, is carbohydrate poor, and represents 40% of the total label. Component b has an apparent molecular weight of 74,000, contains all of the demonstrable sialic acid, and accounts for 60% of the total label. Trypsinization of iodinated, intact red cells results in the disappearance of only component b, the appearance of labeled glycopeptides in the medium, and the absence of smaller, labeled peptides remaining in the membrane. Pronase treatment hydrolyzes component b in a similar fashion, but also cleaves component a to a 72,000 mol wt peptide which is retained in the membrane. A combination of protease treatment and double labeling with ¹²⁵I and ¹³¹I does not reveal the appearance of previously unexposed proteins.     

Photoaffinity labeling of the pactamycin binding site on eubacterial ribosomes

Pactamycin, an inhibitor of the initial steps of protein synthesis, has an acetophenone group in its chemical structure that makes the drug a potentially photoreactive molecule. In addition, the presence of a phenolic residue makes it easily susceptible to radioactive labeling. Through iodination, one radioactive derivative of pactamycin has been obtained with biological activities similar to the unmodified drug when tested on in vivo and cell-free systems. With the use of [125I]iodopactamycin, ribosomes of Escherichia coli have been photolabeled under conditions that preserve the activity of the particles and guarantee the specificity of the binding sites. Under these conditions, RNA is preferentially labeled when free, small ribosomal subunits are photolabeled, but proteins are the main target in the whole ribosome. This indicates that an important conformational change takes place in the binding site on association of the two subunits. The major labeled proteins are S2, S4, S18, S21, and L13. These proteins in the pactamycin binding site are probably related to the initiation step of protein synthesis.     

The simultaneous determination of the products of estrogen 2- and 4-hydroxylase action; the use of high-performance liquid chromatography with electrochemical detection

Both trace-labeled and high-specific activity ¹²⁵I-labeled derivatives of hexadecapeptide gastrin (G) were prepared by reaction with the iodinated form of the imidoester, methyl p-hydroxybenzimidate. Reaction conditions for preparation of trace-labeled iodinated imidoester gastrin (IIE-G) were: excess imidoester to G (IIE:G, 20:1), pH 9.2, and a reaction time of 24 h. Following purification by gel filtration and silica gel chromatography, an IIE-G component was isolated which appeared homogeneous on thin-layer chromatography and retained the same biological and immunological properties as unmodified G. Somewhat different conditions were necessary to prepare high specific activity iodinated imidoester gastrin (IIE¹-G). These included reducing the volume (20 μl) and pH (7.5) at which the imidoester was iodinated and adjusting the concentrations of reactants to the same molar amounts as 5 mCi of carrier-free ¹²⁵I. Sufficient amounts of IIE¹-G were obtained by reversing the ratio of G and IIE¹ and reacting with a G excess (GIIE¹, 10:1). The purified IIE¹-G had a specific activity exceeding 1500 μCi/nmol and was used to establish a specific and sensitive radioimmunoassay for gastrin.     

[125I]diiodofluorescein isothiocyanate: Its synthesis and use as a reagent for labeling proteins and cells to high specific radioactivity

We have synthesized a radioactive derivative of fluorescein isothiocyanate (PITC) by lactoperoxidase-catalyzed iodination of fluorescein amine using ¹²⁵I. The iodinated amine was purified by thin-layer chromatography and converted to the isothiocyanate by reaction with thiophosgene. The product was inferred to be the diiodo derivative of FITC by comparing its absorbance and fluorescence emission spectra with those of known standards. This reagent, [¹²⁵I]diI-FITC, shares many of the useful features of its congener, FITC. Specifically, it may be used to label under mild conditions of temperature and pH, and it is chemically stable. When erythrocytes were labeled with [¹²⁵I]diI-FITC, radioactivity was found principally in a major exposed protein of the cell surface, and very little hemoglobin was labeled. [¹²⁵I]diI-FITC may prove generally useful as a means of labeling proteins and cell surfaces to high specific radioactivity.     

N-chloroacetyl-[125I]iodotyramine: an alkylating agent with high specific activity

The preparation of iodinated N-chloroacetyltyramine and its evaluation as a specific sulfhydryl reagent are described. N-Chloroacetyltyramine was synthesized by a carbodiimide-mediated condensation of chloro- or iodoacetic acid and tyramine·HCL, and the crystalline product was iodinated in a reaction with chloramine T to yield either a 3,5-[¹²⁵I]diiodotyramine derivative, or a trace-iodinated product when carrier-free ¹²⁵I was employed. These iodinated derivatives react specifically with sulfhydryl groups, as judged by their ability to label reduced but not unreduced ribonuclease A and immunoglobulin E. Specific activities of 1 Ci/mmole in ¹²⁵I or ¹³¹I can be readily achieved with both the diiodinated and trace-iodinated (carrier-free) derivatives, and the specific activity of the former can be used directly to quantitate sulfhydryl groups in subnanomolar quantities of protein. N-Chloroacetyl ¹²⁵I-labeled tyramine prepared by trace iodination with carrier-free ¹²⁵I is more useful when very high specific activities (100–1000 mCi/μmol) are required. The utility of these reagents is discussed.     

A comparative study of the polypeptides of three iridescent viruses by N-terminal analysis,amino acid analysis,and surface labeling

Polyacrylamide gel analysis of the structural proteins of three types of iridescent viruses (2, 6, and 9) demonstrated that the purified virions had one major and more than 20 minor polypeptides. Surface labeling procedures performed on pure intact virions, using ¹²⁵I in the presence of lactoperoxidase and chloramine T (at low iodine concentrations), demonstrated that the major and two or three minor polypeptides were located on the outside. The major structural polypeptide was isolated from each virus type by preparative polyacrylamide gel electrophoresis. Amino acid analysis indicated that this protein was very similar in the three iridescent viruses. The three polypeptides had an identical N terminal (proline). While the major polypeptide of each virus has a slightly different molecular weight as determined by polyacrylamide gel electrophoresis, the similarities in iodine labeling, N terminals, and amino acids suggests a common function for this protein.     

Iodination of zeta protein by lactoperoxidase. Chloroperoxidase and chloramine T.

Normal and Rous sarcoma virus transformed chicken embryo fibroblasts cultured on petri dishes were labeled with ¹²⁵I by two enzymic methods and one chemical method. The enzymic labeling systems employed chloroperoxidase and lactoperoxidase. Hydrogen peroxide was generated by glucose oxidase and glucose. The chemical method used chloramine T as the oxidant for iodide ion. After solubilization of cells, SDS disc gel electrophoresis and gamma counting, it was found that only one cell protein was predominantly labeled in all three reactions. This protein, a major cell surface protein, has been previously identified and termed Zeta protein. Zeta protein disappears from transformed cells and is susceptible to trypsin digestion.     

Externally disposed plasma membrane proteins. I. Enzymatic iodination of mouse L cells

The enzymatic iodination technique has been utilized in a study of the externally disposed membrane proteins of the mouse L cell. Iodination of cells in suspension results in lactoperoxidase-specific iodide incorporation with no loss of cell viability under the conditions employed, less than 3% lipid labeling, and more than 90% of the labeled species identifiable as monoiodotyrosine. 90% of the incorporated label is localized to the cell surface by electron microscope autoradiography, with 5-10% in the centrosphere region and postulated to represent pinocytic vesicles. Sodium dodecylsulfate-polyacrylamide gels of solubilized L-cell proteins reveals five to six labeled peaks ranging from 50,000 to 200,000 daltons. Increased resolution by use of gradient slab gels reveals 15-20 radioactive bands. Over 60% of the label resides in approximately nine polypeptides of 80,000 to 150,000 daltons. Various controls indicate that the labeling pattern reflects endogenous membrane proteins, not serum components. The incorporated 125-I, cholesterol, and one plasma membrane enzyme marker, alkaline phosphodiesterase I, are purified in parallel when plasma membranes are isolated from intact, iodinated L cells. The labeled components present in a plasma membrane-rich fraction from iodinated cells are identical to those of the total cell, with a 10- to 20-fold enrichment in specific activity of each radioactive peak in the membrane.     

Synthesis of [3,5-125I]triiodo-l-thyronine of high specific activity

Two methods for the synthesis of [3,5-¹²⁵I]triiodo-l-thyronine of high specific activity are described. This triiodthyronine which carries the iodine label exclusively in the nonphenolic ring has not been available so far. Both methods start from [3,5-¹²⁵I]diiodo-l-thyronine which is iodinated either with iodine in potassium iodide or with iodide and chloramine T. The concentration of the iodinating agent is critical in both methods and the pH of the reaction mixture must be high enough (～11) to cause complete ionization of the phenolic group of the substrate. The triiodothyronine obtained in over 70% yield is purified by ion-exchange chromatography.     

A mechanism and an evaluation of surface specific iodination by the chloramine-T procedure.

Both internal and external proteins in vesicular stomatitis virus were labeled when intact virions were iodinated with 50 μm iodide; however, only the surface proteins were labeled when the same procedure was carried out at low iodide concentrations (below 0.5 μm). This result together with similar observations reported earlier with another enveloped virus, Rous-associated virus-61 (RAV-61), suggest that viral envelopes provide a barrier to iodination by chloramine-T at low, but not at high, iodide concentrations. By monitoring the permeability of the RAV-61 envelope to successive iodinations and to iodination in the presence of chaotropic thiocyanate ions, it was shown that the permeability of the viral envelope was not altered at the higher concentrations of iodide. Further results support the hypothesis that iodination mediated by chloramine-T inolves two different iodinating species: (a) a membrane impermeable one, possibly “iodamine-T,” which predominates at low iodide concentrations, and (b) a membrane permeable species, possibly molecular iodine, which predominates at high concentrations of iodide. These results reinforce the proposal that the chloramine-T procedure is a useful method for specifically labeling surface proteins of lipid-enveloped structures.     

Interactions between gangliosides and proteins in the exoplasmic leaflet of neuronal plasma membranes: A study performed with a tritium-labeled GM1 derivative containing a photoactivable group linked to the oligosaccharide chain

Interactions between gangliosides and proteins at the exoplasmic surface of the sphingolipid-enriched membrane domains can be studied by ganglioside photolabeling combined with cell surface biotin labeling. In the present paper, we report on the results obtained using a novel radioactive photoactivable derivative of GM1 ganglioside, carrying the photoactivable nitrophenylazide group at the external galactose.After cell photolabeling with the radioactive photoactivable derivative of GM1 and cell surface biotin labeling, sphingolipid-enriched domains were prepared from rat cerebellar neurons differentiated in culture and further purified by immunoprecipitation with streptavidin-coupled beads. Among proteins belonging to the sphingolipid-enriched domains that were biotin labeled, thus bearing an exoplasmic domain, a few were also cross-linked by the radioactive photoactivable ganglioside. In particular, two protein bands showing apparent molecular mass of 135 and 35 kDa were intensely photolabeled. The 135 kDa protein was immunologically identified as the GPI-anchored neural cell adhesion molecule TAG-1. These data suggest that hydrophilic interaction between the exoplasmic domains of the protein and the ganglioside sialooligosaccharide chain could exist. Published in 2004.     

Radioiodination of sulfhydryl-sensitive proteins.

A new procedure is described for the radioiodination of proteins with sulfhydryl groups essential for their biological activity. Aniline is iodinated with ¹²⁵I-labeled sodium iodide in the presence of chloramine-T, the product separated by solvent extraction, diazotized and coupled to protein.     

Iodination of mono- and heteroclonal immunoglobulin G with lactoperoxidase and chloramine T.

The difference in the reactivity of tyrosine and histidine residues in mono- and heteroclonal IgG protein toward enzyme catalyzed and chemical iodination has been studied. One heteroclonal and four monoclonal IgG proteins were iodinated using lactoperoxidase or chloramine T. The ratio of the degrees of substitution of the light and the heavy chains varied from IgG to IgG. One of the monoclonal IgG proteins, IgG-Dam, could only be modified in the gamma-chain. The lack of reactivity was attributed to steric hindrance and other local peculiarities. This interpretation is supported by spectrophotometric titration studies.     

Photoaffinity analogues of methotrexate as folate antagonist binding probes. 2. Transport studies, photoaffinity labeling, and identification of the membrane carrier protein for methotrexate from murine L1210 cells

A membrane-derived component of the methotrexate/one-carbon-reduced folate transport system in murine L1210 cells has been identified by using a photoaffinity analogue of methotrexate. The compound, a radioiodinated 4-azidosalicylyl derivative of the lysine analogue of methotrexate, is transported into murine L1210 cells in a temperature-dependent, sulfhydryl reagent inhibitable manner with a Kt of 506 +/- 79 nM and a Vmax of 17.9 +/- 4.2 pmol min-1 (mg of total cellular protein)-1. Uptake of the iodinated compound at 200 nM is inhibited by low amounts of methotrexate (I50 = 1.0 microM). The parent compounds of the iodinated photoprobe inhibit [3H]methotrexate uptake, with the uniodinated 4-azidosalicylyl derivative exhibiting a Ki of 66 +/- 21 nM. UV irradiation, at 4 degrees C, of a cell suspension that had been incubated with the probe results in the covalent modification of a 46K-48K protein. This can be demonstrated when the plasma membranes from the labeled cells are analyzed via sodium dodecyl sulfate-polyacrylamide gel electrophoresis and autoradiography. Labeling of this protein occurs half-maximally at a reagent concentration that correlates with the Kt for transport of the iodinated compound. Protection against labeling of this protein by increasing amounts of methotrexate parallels the concentration dependence of inhibition of photoprobe uptake by methotrexate. In addition, no labeling occurs when a cell line that has a defective methotrexate transport system is similarly treated. Evidence that, in the absence of irradiation and at 37 degrees C, the iodinated probe is actually internalized is demonstrated by the labeling of two soluble proteins (Mr 38K and 21K) derived from the cell homogenate supernatant.     

Immobilization of proteins on organic polymer beads

A new method is described for the immobilization of biologically active proteins onto several types of organic polymer beads. First, the soluble protein is modified by reaction with an excess of a hydrophobic imidoester, for example methyl 4-phenyl-butyrimidate, at ca. pH 9 and 0 degrees . Excess imidoester and side products resulting from imidoester hydrolysis are separated from the hydrophobic protein derivative by exclusion chromatography or dialysis. A suspension of polymer beads (e.g. Amberlite XAD-7) is then added to a solution of the modified protein at room temperature or below and stirred gently for 1-2 h. The polymer beads are allowed to settle, separated from the solution by decantation or filtration, washed, and resuspended in an appropriate buffer. Quantitative adsorption of protein to the polymer beads is observed under such conditions. The synthesis of seven hydrophobic imidoesters and their use for the immobilization of trypsin onto several types of porous polymer beads is described. The immobilizations of trypsin, yeast alcohol dehydrogenase, and E. coli asparaginase by this procedure with high recoveries of catalytic activity, suggests that it will be applicable to a large number of biologically active proteins.