Monoclonal antibodies against phloem P-protein from plant tissue cultures. I. Microscopy and biochemical analysis

Most research involving phloem proteins is done with phloem exudates, which are not easily obtained from many plants. We report here on the use of tissue cultures to study phloem proteins. Monoclonal antibodies against the filamentous phloem protein, P-protein, were made by injecting mice with a phloem-enriched fraction isolated from Streptanthus tortuosus callus grown on a medium that stimulates the differentiation of xylem and phloem (phloem[+] cultures). Monoclonal antibodies specific for P-protein were identified by incubating free-hand stem sections of S. tortuosus in hybridoma supernatants, then in a goat anti-mouse antibody conjugated to fluorescein isothiocyanate (FITC), and observing the FITC under an epifluorescence microscope. Antibodies specific for P-protein in stem sections were used to probe nitrocellulose blots of polyacrylamide gels separating proteins isolated from both phloem(+) and phloem(-) tissue cultures. Immunoblots were incubated overnight in hybridoma supernatants followed by a secondary antibody conjugated to alkaline phosphatase. Three monoclonal antibodies—RS21, RS22, and RS23—bound to an 89-kD band in the phloem(+) lanes but failed to bind to any proteins in the phloem(—) lanes. In leaf sections of Arabidopsis thaliana processed by freeze-substitution, a mixture of RS21 and RS22 bound to the P-protein filaments in sieve elements, but not to any proteins in adjacent cells. A control antibody specific for tubulin did not bind to the P-protein filaments.     

Antibodies against the Calcium-Binding Protein: Calsequestrin from Streptanthus tortuosus (Brassicaceae)

Plant microsomes contain a protein clearly related to a calcium-binding protein, calsequestrin, originally found in the sarcoplasmic reticulum of muscle cells, responsible for the rapid release and uptake of Ca²⁺ within the cells. The location and role of calsequestrin in plant cells is unknown. To generate monoclonal antibodies specific to plant calsequestrin, mice were immunized with a microsomal fraction from cultured cells of Streptanthus tortuosus (Brassicaceae). Two clones cross-reacted with one protein band with a molecular weight equal to that of calsequestrin (57 kilodaltons) by sodium dodecyl sulfate-polyacrylamide gel electrophoresis and immunoblotting. This band is able to bind ⁴⁵Ca²⁺ and can be recognized by a polyclonal antibody against the canine cardiac muscle calsequestrin. Rabbit skeletal muscle calsequestrin cross-reacted with the plant monoclonal antibodies. The plant monoclonal antibodies generated here are specific to calsequestrin protein.     

Epitopes of Escherichia coli ribosomal protein S13

To analyze the immunochemical structure ofEscherichia coli ribosomal protein S13 and its organizationin situ, we have generated and characterized 22 S13-specific monoclonal antibodies. We used a competitive enzyme-linked immunosorbent assay to divide them into groups based on their ability to inhibit binding of one another. The discovery of five groups with distinct binding properties suggested that a minimum of five distinct determinants on S13 are recognized by our monoclonal antibodies. The locations of the epitopes detected by these monoclonal antibodies have been mapped on S13 peptides. Three monoclonal antibodies bind a S13 C-terminal 34-residue segment. All the other 19 monoclonal antibodies bind a S13N-terminal segment of about 80 residues. The binding sites of these 19 monoclonal antibodies have been further mapped to subfragments of peptides. Two monoclonal antibodies recognized S13_1–22; three monoclonal antibodies bound to S13_1–40; the binding sites of three other antibodies have been located in S13_23–80, with epitopes possibly associated with residues 40–80. The remaining 11 monoclonal antibodies did not bind to these subfragments. These data provide molecular basis to the structure of S13 epitopes, whosein situ accessibility may reveal the S13 organization on the ribosome.     

Immunocytochemical localisation of phloem lectin from Cucurbita maxima using peroxidase and colloidal-gold labels

Antibodies were raised against lectin purified from the sieve-tube exudate of Cucurbita maxima. Immunocytochemistry, using peroxidase-labelled antibodies and Protein A-colloidal gold, was employed to determine the location of the lectin within the tissues and cells of C. maxima and other cucurbit species. The anti-lectin antibodies bound to P-protein aggregates in sieve elements and companion cells, predominantly in the extrafascicular phloem of C. maxima. This may reflect the low rate of translocation in these cells. Under the electron microscope, the lectin was shown to be a component of P-protein filaments and was also found in association with the sieve-tube reticulum which lines the plasmalemma. The anti-lectin antibodies reacted with sieve-tube proteins from other species of the genus Cucurbita but showed only limited reaction with other genera. We suggest that the lectin serves to anchor P-protein filaments and associated proteins to the parietal layer of sieve elements.Abbreviation SDS-PAGE sodium dodecyl sulphate-polyacrylamide gel electrophoresis     

ULTRASTRUCTURE OF DEVELOPING SIEVE ELEMENTS IN THLASPI ARVENSE L. I. THE IMMATURE STATE

Immature sieve elements of pennycress (Thlaspi arvense, Brassicaceae) were studied with the electron microscope in connection with studies on virus-infected plants. Immature sieve elements contained cytoplasm rich in organelles and other components: endoplasmic reticulum, dictyosomes and associated smooth and coated vesicles, mitochondria, plastids, ribosomes, microtubules, microfilaments, vacuoles, and nuclei that were sometimes lobed. Tubular P-protein (phloem protein) and one to three granular P-protein bodies also were present in the cytoplasm. Coated vesicles may be involved in formation of the granular P-protein body and in some aspect of cell wall development, for in the latter case, they were often seen united with the plasmalemma. The association of coated vesicles with the P-protein body is discussed with reference to proposed concepts of the origin and function of these vesicles.     

Epitopes ofEscherichia coli ribosomal protein S13

To analyze the immunochemical structure ofEscherichia coli ribosomal protein S13 and its organizationin situ, we have generated and characterized 22 S13-specific monoclonal antibodies. We used a competitive enzyme-linked immunosorbent assay to divide them into groups based on their ability to inhibit binding of one another. The discovery of five groups with distinct binding properties suggested that a minimum of five distinct determinants on S13 are recognized by our monoclonal antibodies. The locations of the epitopes detected by these monoclonal antibodies have been mapped on S13 peptides. Three monoclonal antibodies bind a S13 C-terminal 34-residue segment. All the other 19 monoclonal antibodies bind a S13N-terminal segment of about 80 residues. The binding sites of these 19 monoclonal antibodies have been further mapped to subfragments of peptides. Two monoclonal antibodies recognized S13_1–22; three monoclonal antibodies bound to S13_1–40; the binding sites of three other antibodies have been located in S13_23–80, with epitopes possibly associated with residues 40–80. The remaining 11 monoclonal antibodies did not bind to these subfragments. These data provide molecular basis to the structure of S13 epitopes, whosein situ accessibility may reveal the S13 organization on the ribosome.     

Microsatellites for three distantly related genera in the Brassicaceae

Microsatellites are important genetic markers both in population genetics and for delimitation of closely related species. However, to develop microsatellites for each target organism is expensive and time consuming. In this study, we have therefore developed 65 new microsatellite primers for the species Draba nivalis and tested cross-species and cross-genus transfer success of these primers for two other genera in the Brassicaceae; Cardamine and Smelowskia. Furthermore, 15 previously developed microsatellites were tested for amplification in these three genera. The microsatellite markers that amplify across these genera may be useful for other genera in the Brassicaceae as well.     

Monoclonal Antibodies to Toxoplasma Cell Membrane Surface Antigens Protect Mice from Toxoplasmosis1,2

Groups of mice were given an intraperitoneal injection of one of six monoclonal antibodies to Toxoplasma gondii, a mixture of equal amounts of five monoclonal antibodies to T. gondii, or the murine myeloma protein MOPC 21, and challenged with either a highly virulent or moderately virulent parasite strain. Two monoclonal antibodies (FMC 19 and FMC 22) conferred total protection against the moderately virulent challenge, with all mice surviving, whereas 90% of control mice died. FMC 19 and FMC 22 also conferred significant protection against the highly virulent challenge as indicated by a prolonged mean time to death (MTD) of immunized compared with control groups of mice. One monoclonal antibody (FMC 23) and the mixture of five antibodies gave significant protection against the moderately virulent challenge only. Passive immunization with dilutions of FMC 22 antibody indicated that the lowest serum titer needed to confer significant protection to mice against a moderately virulent Toxoplasma challenge was 1/640. Mice challenged with highly virulent tachyzoites that had been preincubated with FMC 22 had a significantly longer MTD than mice challenged with highly virulent tachyzoites that had been preincubated with MOPC 21 or phosphate buffered saline, pH 7.2 (PBS). Immunoprecipitation and autoradiography of radiolabeled tachyzoites confirmed that FMC 19 was directed against a 35,000 molecular weight (mol. wt.) antigen and FMC 22 was directed against a 14,000 mol. wt. fraction. The potential for use of single antigens as protective immunogens in preventing toxoplasmosis is raised.     

A multiplatform strategy for the discovery of conventional monoclonal antibodies that inhibit the voltage-gated potassium channel Kv1.3

Identifying monoclonal antibodies that block human voltage-gated ion channels (VGICs) is a challenging endeavor exacerbated by difficulties in producing recombinant ion channel proteins in amounts that support drug discovery programs. We have developed a general strategy to address this challenge by combining high-level expression of recombinant VGICs in Tetrahymena thermophila with immunization of phylogenetically diverse species and unique screening tools that allow deep-mining for antibodies that could potentially bind functionally important regions of the protein. Using this approach, we targeted human Kv1.3, a voltage-gated potassium channel widely recognized as a therapeutic target for the treatment of a variety of T-cell mediated autoimmune diseases. Recombinant Kv1.3 was used to generate and recover 69 full-length anti-Kv1.3 mAbs from immunized chickens and llamas, of which 10 were able to inhibit Kv1.3 current. Select antibodies were shown to be potent (IC₅₀<10 nM) and specific for Kv1.3 over related Kv1 family members, hERG and hNav1.5.     

Sieve-Element Characters of the Proteaceae and Elaeagnaceae: Nuclear Crystals,Phloem Proteins and Sieve-Element Plastids

The sieve-element characters of 34 species from the Proteaceae and Elaeagnaceae have been studied by transmission electron microscopy. While nondispersive protein bodies and dispersive P-protein are typical components of both families, specific forms and/or their distinctive origin accentuate some taxa. Within the Grevilloideae, subfamily of Proteaceae, a number of Australian species and genera contain protein crystals of nuclear origin arranged into rosette-like bodies, while in the other members studied from the same subfamily no nondispersive protein bodies were found. Several Australian and South African genera of the Proteoideae contain compound-spherical nondispersive protein bodies that reside in the cytoplasm from their very beginning. In the Elaeagnaceae three different P-protein bodies are present of which one is tubular and dispersing, another is nondispersive and of irregular-stellate form, and a third is globular (resembling a P-protein from Cucurbita). The great majority of the species studied from the Proteaceae contains form-Ss sieve-element plastids, Lomatia ilicifolia and Macadamia ternifolia are distinct in having form-Pcs plastids. The average diameter of stem sieve-element plastids in the family is 1.38 μm. The Elaeagnaceae (three species investigated) is a pure form-So family (average diameter: 0.8 μm). There are no specific sieve-element characters that would support any relationship between the Proteaceae and Elaeagnaceae. While affinities of the former to pre-Gondwanan parts of the Rosanae/Myrtanae are discussed, a reconsideration of the Elaeagnaceae as a possible member of the Violanae (identical features with Cucurbitaceae) is proposed.     

A novel approach to cytotaxonomic and cytogenetic studies in the genus Triturus using monoclonal antibodies to lampbrush chromosomes antigens

Monoclonal antibodies against germinal vesicle antigens from Pleurodeles oocytes crossreact with lampbrush chromosomes of various Triturus species: C36/6, A33/22 and B71/22 bind to most lateral loops, B24/3 labels the spheres, while A1/5 and B81 give a distribution of fluorescent loops which is highly reproducible and species specific. — The antigens involved were characterized by immunoblotting of electrophoretic gels of germinal vesicle proteins and the molecular weights of those that bound to monoclonal antibodies C36/6, A33/22, B24/3 and C3/1 were determined. — The possible relationship between sites immunostained by some monoclonal antibodies and given DNA sequences distributed along the chromosomes is discussed. A new approach to cytotaxonomic and cytogenetic studies through the use of monoclonal antibodies on lampbrush chromosomes is offered, which can give new insight into the molecular mechanisms of speciation and karyological evolution in European newt species.     

Monoclonal antibodies raised against post-translational domains of the electroplax sodium channel

Summary Eleven monoclonal antibodies were identified that recognized eel electroplax sodium channels. All the monoclonal antibodies specifically immunostained the mature TTX-sensitive sodium channel (M _r 265,000) on immunoblots. None of the monoclonal antibodies would precipitate the in vitro translated channel core polypeptide in solution. One monoclonal antibody, 3G4, was found to bind to an epitope involving terminal polysialic acids. Extensive digestion of the channel by the exosialidase, neuraminidase, or partial polysialic acid removal bythe endosialidase, endo-N-acetylneuraminidase, destroy the 3G4 epitope, 3G4 is, therefore, a highly selective probe for the post-translationally attached polysialic acids. Except for this monoclonal antibody, the epitopes recognized by the remaining antibodies were highly resistant to extensive N-linked deglycosylation. Thus, the monoclonal antibodies may be directed against unique post-translationally produced domains of the electroplax sodium channel, presumably sugar groups that are abundant on this protein (Miller, J.A., Agnew, W.S., Levinson, S.R. 1983.Biochemistry 22:462–470). These monoclonal antibodies should prove useful as tools to study discrete post-translational processing events in sodium channel biosynthesis.     

Epitope mapping of monoclonal antibodies toEscherichia coli ribosomal protein S3

The antigenic structure ofEscherichia coli ribosomal protein S3 has been investigated by use of monoclonal antibodies. Six S3-specific monoclonal antibodies secreted by mouse hybridomas have been identified by immunoblotting of two-dimensional ribosomal protein separation gels. By using a competitive enzyme-linked immunosorbent assay, we have divided these monoclonal antibodies into three mutual inhibition groups, members of which are directed to three distinct regions of the S3 molecule. The independence of these monoclonal antibody-defined regions was confirmed by the failure of pairs of monoclonal antibodies from two inhibition groups to block the binding of biotinylated monoclonal antibodies of the third group. To determine the regions recognized by these monoclonal antibodies, chemically cleaved S3 peptides were fractionated by gel filtration and reverse-phase high-performance liquid chromatography. The fractionated peptides were coated on plates and examined for specific interaction with monoclonal antibody by enzyme immunoassay. In this manner, two epitopes have been mapped at the ends of the S3 molecule: one, in the last 22 residues, is recognized by three monoclonal antibodies; and the second, in the first 21 residues, is defined by two monoclonal antibodies. The third S3 epitope, recognized by a single monoclonal antibody, has been localized in a central segment of about 90 residues by gel electrophoresis and immunoblotting. These epitope-mapped monoclonal antibodies are valuable probes for studying S3 structurein situ.     

Structural studies on human glutathione S-transferase pi. Family of native-specific monoclonal antibodies used to block catalysis.

The glutathione S-transferases are a family of related detoxification enzymes that have been shown to conjugate numerous electrophiles to the common cellular thiol glutathione. We have generated a panel of monoclonal antibodies against the human pi class isozyme of this enzyme, and, in this report, we characterize the binding of these antibodies to the glutathione S-transferase antigen. Of the 10 monoclonal antibodies that we have isolated, 7 are able to recognize the native form of the enzyme while the remaining 3 are only able to bind to glutathione S-transferase pi in assays that partially denature the antigen, such as an enzyme-linked immunosorbent assay or a Western blot. We synthesized seven partial protein fragments and asked whether the monoclonal antibodies could bind to these fragments in an immunoprecipitation reaction. The antibodies that can bind the native form of the enzyme all bind to the carboxyl-terminal domain of the protein. Two antibodies are able to inhibit the glutathione S-transferase-catalyzed reaction noncompetitively against glutathione. Incubation of a 10-fold molar excess of either antibody over enzyme can inhibit the reaction by 50%. We have also used the same protein fragments of glutathione S-transferase pi to show that amino acids 1-77 retain the capacity to bind glutathione in a glutathione-agarose binding assay.     

Generation and characterization of a series of monoclonal antibodies that specifically recognize [HexA(±2S)-GlcNAc]n epitopes in heparan sulfate

Five monoclonal antibodies AS17, 22, 25, 38 and 48, a single monoclonal antibody ACH55, and three monoclonal antibodies NAH33, 43, 46, that recognize acharan sulfate (IdoA2S-GlcNAc)n, acharan (IdoA-GlcNAc)n and N-acetyl-heparosan (GlcA-GlcNAc)n, respectively, were generated by immunization of mice with keyhole limpet hemocyanin-conjugated polysaccharides. Specificity tests were performed using a panel of biotinylated GAGs that included chemically modified heparins. Each antibody bound avidly to the immunized polysaccharide, but did not bind to chondroitin sulfates, keratan sulfate, chondroitin nor hyaluronic acid. AS antibodies did not bind to heparan sulfate or heparin, but bound to 6-O-desulfated, N-desulfated and re-N-acetylated heparin to varying degrees. ACH55 bound to tri-desulfated and re-N-acetylated heparin but hardly bound to other modified heparins. NAH antibodies did not bind to heparin and modified heparins but bound to heparan sulfate to varying degrees. NAH43 and NAH46 also bound to partially N-de-acetylated N-acetyl-heparosan. Immunohistochemical analysis in rat cerebella was performed with the antibodies. While NAH46 stained endothelia, where heparan sulfate is typically present, neither ACH55 nor AS25 stained endothelia. On the contrary ACH55 and AS25 stained the molecular layer of the rat cerebella. Furthermore, ACH55 specifically stained Purkinje cells. These results suggest that there is unordinary expression of IdoA2S-GlcNAc and IdoA-GlcNAc in specific parts of the nervous system. Suzuki and Yamamoto contributed equally to this study.     

CHROMOSOME NUMBERS IN UMBELLIFERAE. IV.

Chromosome numbers are reported for 167 collections representing 100 taxa of Umbelliferae. More than four-fifths of the counts apply to members of subfamilies Hydrocotyloideae (29) and. Saniculoideae (50); the remaining 21 belong to Apioideae. Chromosome numbers of plants belonging to 68 taxa are published here for the first time; chromosome numbers are verified for 23 taxa; and chromosome numbers differing from those published previously are reported in nine instances. No chromosome counts have previously been reported for 19 of the genera included. Polyploidy has been established for Azorella, Mulinum, Coaxana, Enantiophylla, and Tiozimia.     

A systematic histological study of palm fruits. VIII. Subtribe Dypsidinae (Arecaceae)

Analysis of the pericarp structure in the four genera of the palm subtribe Dypsidinae reveals tissues similar to those in other taxa within the pseudomonomerous Indo-Pacific arecoid palms, but generally in unspecialized configurations consistent with their presumed basal position within this group. Unique tissues within some members of genus Dypsis include thin-walled, tannin-filled fibers around the vascular bundles. Large-fruited members of the presumably related genera Lemurophoenix, Masoala, and Marojejya show more distinctive arrangements of protective tissues and are quite different from one another. Only Marojejya appears to be closely related to Dypsis. Lemurophoenix and Masoala, by possession of both unsheathed vascular bundles and bundles with heavy fibrous sheaths, show possible affinities with genera well-removed from Dypsis.     

Both ends of Escherichia coli ribosomal protein S13 are immunochemically accessible in situ.

To investigate the structure ofEscherichia coli ribosomal protein S13 in 30S ribosomal subunits, we have previously generated 22 S13 specific monoclonal antibodies and mapped their specific epitopes to the S13 sequence. The availability of these S13 epitopesin situ has been further examined by incubating these monoclonal antibodies with 30S ribosomal subunits and analyzing formation of monoclonal antibody-linked ribosome dimers by sucrose gradients centrifugation. We have found that none of the 22 monoclonal antibodies makes ribosome dimers individually as do typical antisera. However, one monoclonal antibody, designated AS13-MAb 2, reacts with 30S ribosomal subunits to form immunocomplexes sedimenting faster than subunit monomers. When AS13-MAb 2 is paired with any one of three monoclonal antibodies directed to the S13 C-terminal epitopes, dimer formation is observed. Other pairs of monoclonal antibodies directed to distinct S13 epitopes have been tested similarly for dimer formation. Monoclonal antibody AS13-MAb 22, directed to the N-terminal region of 22 residues, also causes subunits to form typical dimers, but only if paired with one of the three monoclonal antibodies directed to the S13 C-terminal region. The close proximity of the epitopes recognized by AS13-MAbs 2 and 22 has been established by the mutual competition between the antibodies binding to intact 30S subunits. These results corroborate our previous observation, using polyclonal antibodies, that S13 has more than one epitope exposed on 30S subunits. Our finding that sequences on both ends of the S13 molecule are immunochemically accessible provides information about the molecular organization of S13in situ.     

Preparation of Monoclonal Antibodies against NADH: Nitrate Reductase from the Red Alga Porphyra yezoensis

Twenty-two monoclonal antibodies were raised against the nativeform of nitrate reductase (NR) from Porphyra yezoensis, a marinered alga. All the antibodies were able to bind to NR from P.yezoensis, with resultant inhibition of full (NADH:NR) and/orpartial (NADH:FR, NADH:CR, FMNH₂:NR, and MV:NR) enzymatic activity.Fifteen of the antibodies recognized the denatured form of theenzyme. Size-exclusion gel nitration and immunoblotting of theproducts of the limited proteolysis of NR from P. yezoensisby trypsin or Staphylococcus aureus V8 protease revealed that2 out of the 15 subunit-recognizing antibodies bound to theFAD domain, 6 bound to the heme domain, and 7 bound to the Mo-pterindomain. The products of limited proteolysis of NR from P. yezoensisalso revealed that the sites of proteolytic cleavage that encompassedthe heme domain were inverted as compared to the analogous sitesin NRs of higher plants. Some of the monoclonal antibodies cross-reactedwith NRs from plants belonged to different phyla. From threeto five of the antibodies bound subunits of NR from multicellularred algae, but failed to bind NRs from unicellular red algae.Three or four of the antibodies crossreacted with NRs from higherplants, such as tobacco and spinach. One of the antibodies boundNRs from several types of plant, namely, members of Cryptophyta,Chromophyta, and Chlorophyta. All of the monoclonal antibodiesthat cross-reacted with NRs from plants other than the red algaewere specific for the Mo-pterin domain of NR from P. yezoensis. (Received May 10, 1994; Accepted September 7, 1994)     

OBSERVATIONS ON P-PROTEIN IN DICOTYLEDONS. SUBSTRUCTURAL AND DEVELOPMENTAL FEATURES

The structure and development of P-protein have been studied in sieve elements of hypocotyl tissue of Ecballium elaterium and Cicer arietinum, and in P-protein-producing cells of root apices of Polygonum fagopyrum. Ultrastructural investigations have led us to propose a model for the structure of P-protein tubules. A tubule appears as a Super-Double Helix (“DH1”) which consists of two 6- to 9-nm-diam strands wound round a central lumen, each strand exhibiting a varying-pitched minor double helix (“DH2”). Our observations provide additional insights into the developmental relationships between the different forms of P-protein and support the idea that spiny vesicles participate in P-protein formation. The different types of P-protein bodies found in mature sieve elements of species we have investigated may be regarded as arrays of axially oriented linked “DH1”