Photochemistry of 124 kilodalton Avena phytochrome in vitro

The photochemical properties of purified 124 kilodalton (kD) Avena cv Garry phytochrome are examined and compared with those of the proteolytically degraded 118/114 kD species. The proportion of the chromoprotein in the far red absorbing form, Pfr, following saturating red irradiation is 0.86 for 124 kD phytochrome, substantially higher than the values of 0.79 determined here and 0.75 reported in the literature for 118/114 kD preparations. The ratio of the quantum yields for Pr to Pfr phototransformation and for Pfr to Pr phototransformation (r/fr) is 1.76 for the 124 kD molecule and 0.98 for the 118/114 kD species. Based on extinction coefficients determined using the Lowry assay as a measure of protein weight, the individual phototransformation quantum yields for 124 kD phytochrome are 0.17 for Pr → Pfr (r) and 0.10 for Pfr → Pr (fr). Comparison of these quantum yields with those of the 118/114 kD species (where r = fr = ~0.11) indicates that proteolytic degradation of the 124 kD molecule to the 118/114 kD species significantly affects only r. Therefore, the lower proportion of Pfr at photoequilibrium observed for 118/114 kD preparations is explained mainly in terms of a reduced efficiency of Pr → Pfr phototransformation. The absolute Pfr absorbance spectrum for 124 kD phytochrome obtained by correcting the measured spectrum for residual Pr exhibits a maximum at 730 nm and differs from previous absolute Pfr spectra for both `120' kD and 60 kD phytochrome in that it lacks a shoulder in the red region of the spectrum.     

Site-directed monoclonal antibodies against the amino terminus of 124-kDa phytochrome from Avena sativa L.

Abstract Two monoclonal antibodies (AFRC MAC 184 and 185) have been raised in rats against a synthetic octadecapeptide corresponding to the N-terminus of Avena phytochrome. The peptide was conjugated to tuberculin purified protein derivative (PPD) for immunization and the cell lines screened by ELISA using the free peptide. Both antibodies bind to intact 124-kDa phytochrome on Western blots and in a double antibody sandwich ELISA. In the ELISA, they have an approximately four-fold higher affinity for Pr than Pfr. Conformational changes during photoconversion, therefore, involve the extreme N-terminus of the phytochrome molecule.     

The role of separate molecular domains in the structure of phytochrome from etiolated Avena sativa L.

The spectral properties of peptides generated from etiolated-Avana, 124-kDa (kilodalton) phytochrome by endogenous protease(s) have been studied to assess the role of the amino-terminal and the carboxyl-terminal domains in maintaining the proper interaction between protein and chromophore. The amino-terminal, 74-kDa chromopeptide, a degradation product of the far-red absorbing form of the pigment (Pfr), is shown to be spectrally similar to the 124-kDa, undegraded molecule. The minimum and maximum of the difference spectrum (Pr-Pfr) are 730 and 665 nm, respectively, and the spectral-change ratio is unity. Also, like undegraded, 124-kDa phytochrome, the 74-kDa peptide exhibits minimal dark reversion. These data indicate that the 55-kDa, carboxyl-terminal half of the polypeptide does not interact with the chromophore and may not have a role in the structureal integrity of the amino-terminal domain. The 64-kDa chromopeptide can be generated directly from the 74-kDa species by cleavage of 10 kDa from the amino terminus upon incubation of this species as Pr. Accompanying this conversion are changes in the spectral properties, namely, a shift in the difference spectrum minimum to 722–724 nm and a tenfold increase in the capacity for dark reversion. These data indicate that the 6–10 kDa, amino-terminal segment continues to function in its role of maintaining proper chromophore-protein interactions in the 74-kDa peptide as it does in the undegraded molecule. Conversely, removal of this segment upon proteolysis to the 63-kDa species leads to aberrant spectral properties analogous to those observed when this domain is lost from the full-length, 124-kDa molecule, resulting in the 118/114-kDa degradation products. The data also show that photoconversion of the 74-kDa chromopeptide from Pfr to Pr exposes proteolytically susceptible sites in the same way as in the 124-kDa molecule. Thus, the separated, 74-kDa amino-terminal domain undergoes a photoinducible conformational change comparable to that in the intact molecule.Abbreviations and symbols Da dalton - Pfr far-red-absorbing from of phytochrome - PMSF phenylmethylsulfonyl fluoride - Pr red-absorbing form of phytochrome - R red light - FR lar-red light - A _r/A _fr spectral change ratio - _max ^FR peak maximum (nm) of Pfr absorbance     

Proteolysis alters the spectral properties of 124 kdalton phytochrome from Avena

Native phytochrome from Avena sativa L. is homogeneous with a monomeric molecular weight of 124 kdalton; 6–10 kdalton larger than the heterogeneous 120 kdalton preparations previously considered to be undegraded (Vierstra and Quail, 1982, Proc. Natl. Acad. Sci. USA, 79: 5272–5276). The phototransformation difference spectrum (Pr-Pfr) of 124 kdalton phytochrome measured in crude extracts has a minimum in the farred region at 730 nm, the same as that observed in vivo. These spectral properties contrast with those of 120 kdalton phytochrome purified by column immunoaffinity chromatography where the difference minimum is at 724 nm. When 124 kdalton phytochrome is incubated as Pr in crude extracts, the difference minimum shifts progressively to shorter wavelengths (from 730 to 722 nm) concomitant with the proteolytic degradation of the chromoprotein to the mixture of 118 and 114 kdalton species that comprise 120 kdalton phytochrome preparations. These two effects are inhibited in concert by the serine protease inhibitor, phenylmethylsulfonylfluoride, and or maintenance of the phytochrome in the Pfr form. These results provide further evidence that 124 kdalton phytochrome is the native molecule in Avena and indicate that the peptide segments removed by proteolysis of the Pr form are important to the pigment's spectral integrity. The present data thus resolve the previously unsettled question of why the Pfr form of 120 kdalton phytochrome isolated by various procedures from Avena has been found to absorb at shorter wavelengths than that observed in vivo. Previous spectral studies with 120 kdalton phytochrome preparations are open to reexamination.Abbreviations, symbols PMSF phenylmethylsulfonylfluoride - SDS-PAGE sodium dodecyl sulfate polyacrylamide gel electrophoresis - Ig immunoglobulin - A_minimum, A_maximum phototransformation difference spectrum (Pr-Pfr) minimum and maximum - A_r/A_fr ratio spectral change ratio     

A photoreversible conformational change in 124 kDa Avena phytochrome

Tryptophan (Trp) fluorescence quenching of phytochrome has been studied using anionic, cationic and neutral quenchers, I-, Cs+ and acrylamide, respectively, in an effort to understand the molecular differences between the Pr and Pfr forms. The data have been analyzed using both Stern-Volmer and modified Stern-Volmer kinetic treatments. The anionic quencher, I-, was proven to be an ineffective quencher with Stern-Volmer constants, Ksv, of 0.60 and 0.63 M-1, respectively, for the Pr and Pfr forms of phytochrome. The cationic quencher, Cs+, showed about a 2-fold difference in the Ksv of Pr and Pfr, indicating a significant change in the fluorescent Trp environments during the Pr to Pfr phototransformation. However, only 25-37% of the fluorescent Trp residues were accessible to the cationic quencher. Most of the fluorescent Trp residues were accessible to acrylamide, but the quenching by acrylamide was indistinguishable for the Pr and Pfr forms. An additional quenching by acrylamide after a saturated quenching with Cs+ showed more than 40% increase in the Ksv of Pfr over Pr. These observations, along with the finding of two distinct components in the Trp fluorescence lifetime, indicate the existence of Trp residues in at least two different sets of environments in the phytochrome protein. The two components of the fluorescence had lifetimes of 1.1 ns (major) and 4.7 ns (minor) for Pr and 0.9 ns (major) and 4.6 ns (minor) for Pfr. Fluorescence quenching was found to be both static and dynamic as the Stern-Volmer constants for the steady-state fluorescence quenching were higher than for the dynamic fluorescence quenching. Based on the quenching results, in combination with the location of Trp residues in the primary structure, we conclude that the Pr to Pfr phototransformation involves a significant conformation change in the phytochrome molecule, preferentially in the 74 kDa chromophore-bearing domain.     

Immunoprecipitation of phytochrome from green Avena by rabbit antisera to phytochrome from etiolated Avena

Thirty-nine antiserum preparations from eight rabbits were screened for their ability to precipitate the immunochemically distinct phytochrome that is obtained from green oat (Avena sativa L.) shoots. The antisera were obtained from rabbits immunized with either proteolytically degraded, but still photoreversible, 60-kDa (kilodalton) phytochrome, or approx. 120-kDa phytochrome, both of which were purified from etiolated oat shoots. The ability of these antisera to precipitate phytochrome from green oats was independent of the size of phytochrome used for immunization. While crude antisera immunoprecipitated as much as 80% of the phytochrome isolated from green oat shoots, antibodies immunopurified from these sera with a column of highly purified, approx. 120-kDa phytochrome from etiolated oats precipitated no more than about 5–10%.Abbreviations kDa kilodalton - mU milliunit     

Cross-reactivity of monoclonal antibodies against phytochrome from Zea and Avena

The cross-reactivity of diverse monoclonal antibodies against phytochrome from Zea and Avena was tested by enzyme-linked immunosorbentassay (ELISA) and by immunoblotting. About 40 antibodies were selected by means of nondenatured phytochrome; all of them reacted with sodium dodecyl sulfate denatured homologous antigen on immunoblots. The epitopes for 14 antibodies (4 raised against Avena and 10 against Zea phytochrome) were localized in 6 regions of the phytochrome molecule by means of Western blot analysis of proteolytic fragments of known localization. Results of studies on the inhibition of antibody binding by other antibodies were largely compatible with these latter findings. Except in a few cases, inhibition occurred when antibodies were located on the same or a closely adjacent region. As demonstrated by 16 species, cross-reactivity with phytochromes from other Poaceae was high. Greater losses in cross-reactivity were observed only with antibodies recognizing an epitope in the vicinity of the carboxyl terminus of 118-kg · mol^-1 phytochrome. Cross-reactivity with phytochrome from dicotyledons was restricted to a few antibodies. However, phytochrome(s) from plants illuminated for 24 h or more could be detected. One of the antibodies that recognized phytochrome from dicotyledons was also found to recognize phytochrome or a protein of 120–125 kg·mol^-1 from several ferns, a liverwort and mosses. This antibody (Z-3B1), which was localized within a 23.5-kg·mol^-1 section of Avena phytochrome (Grimm et al., 1986, Z. Naturforsch. 41c, 993), seems to be the first antibody raised against phytochrome from a monocotyledon with such a wide range of reactivity. Even though epitopes were recognized on different phytochromes, the strength of antibody binding indicated that these epitopes are not necessarily wholly identical.Abbreviations ELISA enzyme-linked immunosorbent assay - McAb monoclonal antibody - PBS phosphate-buffered saline - Pfr (Pr) far-red-absorbing (red-absorbing) form of phytochrome - SDS-PAGE sodium dodecyl sulfate-polyacrylamide gel electrophoresis     

Structure function studies on phytochrome. Identification of light-induced conformational changes in 124-kDa Avena phytochrome in vitro

Light-mediated conformational changes in highly purified 124-kDa phytochrome preparations from etiolated oat seedlings have been identified by steric exclusion high performance liquid chromatography and limited proteolytic studies. Steric exclusion high performance liquid chromatography studies of oat and rye phytochromes show photoreversible changes in retention times, with the red absorbing form of phytochrome (Pr form) eluting later than the far red absorbing form of phytochrome produced by saturating red light illumination of Pr (Pfr form) in a variety of different mobile phase buffers. Molecular mass calibration with globular protein standards in Tris-glycol buffers provides estimates of 318-349 and 363-366 kDa for the molecular sizes of the Pr and Pfr forms, respectively. These analyses support earlier studies that phytochrome is a nonglobular homodimer of 124-kDa subunits in vitro. Limited proteolytic dissection of phytochrome in nondenaturing buffers with seven different endoproteases provides evidence for two "operational" domains within the 124-kDa subunit with molecular mass values of 69-72 and 52-55 kDa. The larger 69-72-kDa domain contains the site for the chromophore attachment as shown by gel electrophoresis derived enzyme-linked immunosorbent assay utilizing site-directed rabbit antiserum to a synthetic undecapeptide which is homologous with the chromophore binding site on oat phytochrome. This chromophore domain exhibits a compact structure, resistant to further proteolysis except near its N terminus. By contrast, the 52-55-kDa nonchromophore domain contains multiple sites for further proteolytic cleavage as revealed by rapid cleavage to smaller polypeptide fragments. Detailed kinetic analyses of the limited proteolytic cleavage of phytochrome with four endoproteases, subtilisin BPN', thermolysin, trypsin, and clostripain, has mapped specific regions within the 124-kDa subunit that participate in light-induced conformational changes. These include a 4-10-kDa region near the N terminus of the chromophore binding domain and at least two regions within the nonchromophore domain. A comprehensive peptide map of the oat phytochrome subunit is presented, which incorporates the results of these proteolytic studies with the recent, yet unpublished sequence analyses of Avena phytochrome cDNA clones which show the N-terminal localization of the chromophore binding site (Hershey, H. P., Colbert, J. T., Lissemore, J. L., Barker, R. F., and Quail, P. H. (1984) Proc. Natl. Acad. Sci. U.S.A. 81, 2332-2336).     

Production and purification of monoclonal antibodies to Pisum and Avena phytochrome

At least nine monoclonal antibodies against phytochrome from Pisum sativum L. and 20 against phytochrome from Avena sativa L. have been obtained from mouse hybridomas that were produced by fusion of spleen cells with SP 2/O-Ag14 myeloma cells. Hybridomas were selected and cloned in a single step by plating on a semisolid methylcellulose medium. Eight antibodies to Pisum and one to Avena phytochrome were immunopurified from hybridoma medium or ascitic fluid. When necessary, secreted antibodies were verified to be against phytochrome by demonstrating to be against phytochrome by demonstrating immunoadsorption of phytochrome, detected as loss of photoactivity and-or by appearance of the approx. 120,000-dalton phytochrome band upon sodium dodecyl sulfate polyacrylamide gel electrophoresis.     

Characterization by enzyme-linked immunosorbent assay of monoclonal antibodies to pisum and Avena phytochrome

Nine monoclonal antibodies to pea (Pisum sativum L.) and 16 to oat (Avena sativa L.) phytochrome are characterized by enzyme-linked immunosorbent assay against phytochrome from six different sources: pea, zucchini (Cucurbita pepo L.), lettuce (Lactuca sativa L.), oat, rye (Secale cereale L.), and barley (Hordeum vulgare L.). All antibodies were raised against phytochrome with a monomer size near 120,000 daltons. Nevertheless, none of them discriminated qualitatively between 118/114-kilodalton oat phytochrome and a photoreversible, 60-kilodalton proteolytic degradation product derived from it. In addition, none of the 23 antibodies tested discriminated substantially between phytochrome—red-absorbing form and phytochrome—far red-absorbing form. Two antibodies to pea and six to oat phytochrome also bound strongly to phytochrome from the other species, even though these two plants are evolutionarily widely divergent. Of these eight antibodies, two bound significantly to all of the six phytochrome preparations tested, indicating that these two may recognize highly conserved regions of the chromoprotein. Since the molecular function of phytochrome is unknown, these two antibodies may serve as unique probes for regions of this pigment that are important to its mode of action.     

Monoclonal antibodies to three phospholipase C isozymes from bovine brain

Murine hybridoma cell lines secreting antibodies against the three bovine isozymes of phosphoinositide-specific phospholipase C (PLC) were established: 6, 23, and 12 lines were obtained for PLC-I (150 kDa), PLC-II (145 kDa), and PLC-III (85 kDa), respectively. The antibodies were purified from ascites fluid, and their properties were studied in detail. All the antibodies cross-reacted with their corresponding PLC enzymes, but not with the other two isozymes, suggesting that the three enzymes contain very different antigenic determinants. The six antibodies elicited by bovine PLC-I also cross-reacted with human and rat enzyme, whereas three each from anti-PLC-II antibodies and anti-PLC-III antibodies did not react with the enzymes from different species. Each antibody exerts different effects on the phosphatidylinositol-hydrolyzing activity of PLC. The most inhibitory antibody for either isozyme PLC-I or PLC-II exhibits 80% inhibition, whereas no more than 20% inhibition was observed for the anti-PLC-III antibodies. Purified PLC-I frequently contains catalytically active 140- and 100-kDa forms and an inactive 41-kDa protein in addition to the intact 150-kDa form, probably due to its high sensitivity to an unidentified endogenous protease. The five anti-PLC-I antibodies which bind to the denatured 150-kDa polypeptide also recognized the 140-kDa form, whereas only three cross-reacted with the 100-kDa form, and the remaining two bound to the 41-kDa protein. Competitive binding studies with intact PLC enzymes and Western blot experiments with proteolytic digests revealed that the 6 anti-PLC-I, 23 anti-PLC-II, and 12 anti-PLC-III antibodies bind at least five, six, and seven different epitopes on PLC-I, PLC-II, and PLC-III, respectively. The fact that these monoclonal antibodies bind to different epitopes on the same enzyme allowed one to develop a highly specific and sensitive tandem radioimmunoassay for quantitating PLC-I, PLC-II, and PLC-III. The principle of the assay is that binding of an 125I-labeled antibody to the antigen immobilized by another antibody at a distinctive binding site is proportional to the amount of antigen present. By using this method, PLC-I, PLC-II, and PLC-III could be measured quantitatively in the presence of other proteins, detergents, lipids, polyanions, and metal ions, all of which greatly affect the activity of PLC enzymes.     

Monoclonal antibodies directed to phytochrome from green leaves of Avena sativa L. cross-react weakly or not at all with the phytochrome that is most abundant in etiolated shoots of the same species

Seven monoclonal antibodies (MAbs) have been prepared to phytochrome from green oat (Avena sativa L. cv. Garry) leaves. One of these MAbs (GO-1) cross-reacts with apoprotein of the phytochrome that is most abundant in etiolated oat shoots as assessed by immunoblot assay of fusion proteins expressed in Escherichia coli. The epitope for this MAb is located between amino acids 618 and 686 in the primary sequence of type 3 phytochrome (Hershey et al. 1985, Nucleic Acids Res. 13, 8543–8559), which is one of the predominant phytochromes in etiolated oats. Three other MAbs (GO-4, GO-5, GO-6) immunoprecipitate phytochrome isolated from green oat leaves, as evaluated by photoreversibility assay. GO-1, GO-4, GO-5 and GO-6 are therefore directed to phytochrome. While evidence obtained with the other three MAbs (GO-2, GO-7, GO-8) strongly indicates that they are also directed to phytochrome, this evidence is not as rigorous. Recognition of antigen by any of these seven MAbs is not significantly reduced by periodate oxidation, indicating that their epitopes probably do not include carbohydrate. All but GO-1 bind either very poorly or not at all the phytochrome that is abundant in etiolated oat shoots. These data reinforce earlier observations made with antibodies directed to phytochrome from etiolated oats, indicating (1) that the phytochromes that predominate in etiolated and green oats differ immunochemically and (2) that phytochrome preparations from green oat leaves contain very little of the phytochrome that is abundant in etiolated shoots. An hypothesis that these two immunochemically distinct phytochromes form heterodimers in vitroAbbreviations Da Dalton - DEAE diethylaminoethyl - ELISA enzyme-linked immunosorbent assay - HA hydroxyapatite - Ig immunoglobulin - MAb monoclonal antibody - SDS sodium dodecyl sulfate is supported by comparison of immunoblot data obtained with conventionally purified phytochrome from etiolated oats to that expressed as fusion protein in E. coli. This research was supported by the U.S. Department of Energy (contract DE-AC-09-81SR10925 to L.H.P.). We thank Dr. Lyle Crossland and Ms. Sue Kadwell for their assistance in the construction of the cDNA clones, and Dr. Gyorgy Bisztray for providing us with clone pCBP3712. Dr. Phillip Evans and Dr. Russell Malmberg kindly provided MAbs 4F3, 6F12 and 8C10, as well as a corresponding antigen preparation. The excellent technical assistance of Mrs. Donna Tucker and Mrs. Danielle Neal is gratefully acknowledged.     

Monoclonal antibodies to cytoplasmic domains of the acetylcholine receptor

Fourteen clonal hybridoma lines that secrete monoclonal antibodies (mabs) to the Torpedo acetylcholine receptor (AChR) have been isolated. When analyzed by an immunoreplica technique, two mabs recognized the alpha subunit, three reacted with the beta subunit, one reacted with the gamma chain, and five recognized the delta subunit. One mab failed to react with any of the subunits using this assay and two mabs recognized determinants found on both the gamma and the delta subunits. These were classified according to their reactivities with the membrane-bound Torpedo AChR. One category is comprised of mabs (including both anti-alpha mabs) that recognize extracellular epitopes. A second classification included mabs that are unable to bind the membrane-associated AChR. The third category is comprised of mabs directed against cytoplasmic epitopes of the AChR. The latter mabs, all of which recognize the gamma or delta subunits or both, bind only slightly to sealed, outside-out Torpedo vesicles. The binding is increased 10-20-fold by either alkaline extraction or treatment of the vesicles with 10 mM lithium diiodosalicylate but not by permeabilization of the vesicles with saponin. Three of the six mabs in this category react with frog muscle endplates but only if the cytoplasmic surface of the membrane is accessible.     

Production and purification of polyclonal antibodies to Pisum and Avena labile phytochrome which cross-react with phyA from Pharbitis nil

Little work was done so far with phytochrome from Pharbitis nil. Purification of phyA from this plant has been exceptionally difficult. Labile phytochrome was presented in too small amount to obtain either absorption spectra or enough protein to produce antibodies. Monoclonal antibodies mAP5, MAC 50, 52, 198 recognized Pharbitis nil labile phytochrome poorly, so it was necessary to develop independently an antiserum against labile phytochrome. The antiserum was prepared against proteolytically undegraded phytochrome obtained from etiolated Avena and Pisum seedlings using conventional methods. The antiserum to phytochrome from each of the above mentioned plants was prepared by injecting purified phytochrome into rabbits. The newly produced polyclonal antibodies to phyA from Avena and Pisum were used to characterize phytochrome from etiolated seedlings of Pharbitis nil. The cross reaction was tested by immunobloting. Both kinds of PAbs recognised phyA from Pharbitis nil, however IgG against the labile phytochrome from Pisum gave stronger reaction. The recognized peptide had the molecular weight of about 120-kDa.     

Mapping of antigenic domains on phytochrome from etiolated Avena sativa L. by immunoblot analysis of proteolytically derived peptides

Several monoclonal antibodies to phytochrome that interact with putative functionally important domains have been previously identified. The locations of some of these domains are determined here by epitope mapping experiments that utilize immunoblot analyses of proteolytically degraded phytochrome. Seven independent epitopes are identified. An epitope that is recognized by monoclonal antibody Oat-25 is confirmed to be wholly located near the N terminus of phytochrome. This domain undergoes a conformational change when phytochrome is interconverted between its red- and far-red-absorbing forms and is recognized by Oat-25 better in the red-absorbing form. A second domain that also undergoes a photointerconvertible conformation change and that contains the epitope for Oat-16 is localized near the site of chromophore attachment, which is about 36 kDa from the N terminus. A third domain, which contains the most highly conserved epitope on phytochrome that has so far been identified, is recognized by Pea-25 and is located about 85 kDa from the N terminus. Other epitopes and their approximate distances from the N terminus are those recognized by Oat-22 (36 kDa), Oat-13 (65 kDa), and Oat-8 and Oat-28 (70-75 kDa). Even though epitopes for Oat-16 and Oat-22, as well as for Oat-8 and Oat-28, are close together, competitive binding assays indicate that they are different. Immunoblot analyses also indicate that the epitope for Oat-28 is further from the N terminus of phytochrome than is that for Oat-8.     

Discrimination between the red- and far-red-absorbing forms of phytochrome from Avena sativa L. by monoclonal antibodies

A set of rat monoclonal antibodies (ARC MAC 48 to 52 and 54 to 56), raised to phytochrome from dark-grown seedlings of Avena sativa L. was tested for the ability to discriminate between the red-absorbing (Pr) and far-red-absorbing (Pfr) forms of phytochrome by indirect enzyme-linked immunosorbent assay. MAC 50 bound more strongly to Pfr and MAC 49 and 52 showed preferential binding to Pr from extracts of dark-grown Avena seedlings; MAC 50 also bound more strongly to Pfr from brushite-purified phytochrome. The remainder of the monoclonal antibodies and a rabbit polyclonal antiphytochrome preparation did not discriminate between Pr and Pfr. The results provide evidence for conformational changes in defined regions of the phytochrome apoprotein upon photoconversion.Abbreviations ELISA enzyme-linked immunosorbent assay - FR far-red light - McAb monoclonal antibody(ies) - PBS phosphate-buffered saline - Pfr far-red-absorbing form of phytochrome - Pr red-absorbing form of phytochrome - R red light - PMSF phenylmethylsulphonylfluoride     

Monoclonal antibodies against two separate alloantigenic sites of HLA-1340

Two monoclonal antibodies (MB40.2 and MB40.3) which are highly specific for HLA-B40 and HLA-B7 were made. They appear to be directed against two separate alloantigenic sites of these HLA molecules. Semiquantitative analysis of the kinetics of antibody binding show that MB40.2 recognizes a site which shows a degree of cross-reactivity with B7 and is specific to some B40 molecules. This antibody also distinguishes between different molecules typed as B40. In contrast, MB40.3 recognizes an antigenic determinant which is less variable between B7 and B40 and more closely approximates a public antigen or common antigenic site. This study suggests that the introduction of monoclonal antibodies into MHC serology not only permits but demands a quantitative analysis of these complex systems of homologous but highly polymorphic molecules.Abbreviations used in this paper MHC major histocompatibility complex - IgG immunoglobulin G - SDS-PAGE sodium dodecyl sulfate polyacrylamide gel electrophoresis - PBS phosphate-buffered saline - BSA bovine serum albumin - FCS fetal calf serum - RAM rabbit anti-mouse IgG F(ab)₂ fragments For convenience the terms HLA antigen and H-2 antigen will refer only to the ₂-microglobulin-associated, class I molecules coded for by the major histocompatibility complex of man and the mouse, respectively.     

Chromophore topography and secondary structure of 124-kilodalton Avena phytochrome probed by Zn2(+)-induced chromophore modification

The relative extent of chromophore exposure of the red-absorbing (Pr) and far-red-absorbing (Pfr) forms of 124-kDa oat phytochrome and the secondary structure of the phytochrome apoprotein have been investigated by using zinc-induced modification of the phytochrome chromophore. The absence of bleaching of Pr in the presence of a 1:1 stoichiometric ratio of zinc ions, in contrast to extensive spectral bleaching of the Pfr form, confirms previous reports of differential exposure of the Pfr chromophore relative to the Pr chromophore [Hahn et al. (1984) Plant Physiol. 74, 755-758]. The emission of orange fluorescence by zinc-chelated Pfr indicates that the Pfr chromophore has been modified from its native extended/semi-extended conformation to a cyclohelical conformation. Circular dichroism (CD) analyses of native phytochrome in 20 mM Tris buffer suggests that the Pr-to-Pfr phototransformation is accompanied by a photoreversible change in the far-UV region consistent with an increase in the alpha-helical folding of the apoprotein. The secondary structure of phytochrome in Tris buffer, as determined by CD, differs slightly from that of phytochrome in phosphate buffer, suggesting that phytochrome is a conformationally flexible molecule. Upon the addition of a 1:1 molar ratio of zinc ions to phytochrome, a dramatic change in the CD of the Pfr form is observed, while the CD spectrum of the Pf form is unaffected. Analysis of the bleached Pfr CD spectrum by the method of Chang et al. (1978) reveals that chelation with zinc ions significantly alters the secondary structure of the phytochrome molecule, specifically by increasing the beta-sheet content primarily at the expense of alpha-helical folding.(ABSTRACT TRUNCATED AT 250 WORDS)     

Binding of 124-kilodalton oat phytochrome to liposomes and chloroplasts

Binding of the radio-iodinated 124-kDa oat ( Avena sativa L. cv. Garry) phytochrome to liposomes and chloroplasts was investigated as a model system in order to understand the molecular affinity of phytochrome toward cellular organelles in plants. The binding of intact (124 kDa) phytochrome to liposomes and chloroplasts is hydrophobic in nature, as in the case of the degraded (118/114 kDa) phytochrome, but electrostatic interactions play a greater role in the intact phytochrome. The physiologically active P_fr form of the intact phytochrome showed a binding preference over the inactive P_r form with neutral liposomes and chloroplasts. However, the P_fr form of intact phytochrome exhibits smaller binding preference than the P_fr form of degraded phytochrome over their respective P_r forms (see Kim, I.-S. and Song, P.-S. 1981, Biochemistry 20: 5482–5489, for degraded phytochrome binding). These results indicate that the 6/10 kDa N-terminus segment, which is lost in the degraded phytochrome, plays an important role in determining the protein surface properties of the intact phytochrome. A competitive binding study on phytochrome also suggested that the P_fr form had a greater binding affinity for chloroplasts than the P_r form. However, the physiological activity of the P_fr form may not be explained simply by the observed difference in binding affinity between the two forms of phytochrome.     

Effect of malformin on phytochrome reactions in Vigna and Avena

The rate of destruction of the far red absorbing form of phytochrome(Pfr) in green or etiolated cuttings of Vigna radiata was slowerin the presence of malformin than in its absence. Malforminhad no effect on the accumulation of total phytochrome in thedark, or on the reaccumulation of phytochrome after destructionin red light. The amount of photoconversion of the red absorbingform of phytochrome (Pr) to Pfr or Pfr to Pr by given dosesof red or far red radiation was slightly but consistently lessin malformin-treated cuttings of V. radiata than in controls.Malformin had no effect on the rate of destruction or photoconversionof phytochrome in etiolated shoots of Avena sativa. The decreasein destruction rate of Pfr by malformin in V. radiata may contributeto the inhibition of dark abscission by malformin after lighttreatment. (Received October 3, 1979; )