Immunocytochemical localization of proteins in differentiating tissues of Pisum sativum

Although there may be documented morphological changes during development, it is obvious that important changes in protein content occur in a vascular plant during the several stages of differentiation. In the absence of the latter information, an approach has been established for the localization of antigenic proteins in developing tissues of Pisum sativum. Monoclonal antibodies were raised to proteins extracted from pea internode tissue, and employed for the localization of three proteins in tissue sections. One of the proteins has two polypeptide subunits with molecular weights of 25,000 and 40,000 daltons, and the antibody binds to both of them. The three monoclonal antibodies produce different patterns of cellular localization in the tissue sections, as visualized by indirect immunocytochemical labeling. In another series of analyses, quantitative and qualitative differences in the protein contents of apical shoot tissue and mature internode shoot tissue have been found. These studies were based on the use of Western blots with both polyclonal (rabbit) antibodies and monoclonal (mouse) antibodies.     

Localization of a nuclear protein during development in the pea seedling

The subcellular localization of a nuclear antigenic protein has been accomplished through the application of immunogold methodology for immunocytochemistry. Protein extracted from internode tissue of pea seedlings was used for the production of a monoclonal antibody that was applied to tissue sections for electron microscopy. As second antibody, goat anti-mouse IgG conjugated with colloidal gold served as label. The 30 kDa nuclear protein was localized in internode tissue only in the chromatin of differentiating and mature companion cells and parenchyma cells of the phloem. By contrast, virtually all of the meristematic, undifferentiated, cells in the apical dome exhibited nuclear labeling. In young, differentiating internode tissue immediately behind the apex nuclear labeling was found in all cell types except pith parenchyma. The changing localization of this 30 kDa protein with the progression of cell differentiation suggests the possibility that this protein may, in some way, be related to regulatory events of development.     

Monoclonal antibodies to epitopes on different regions of the 200 000 dalton neurofilament protein. Probes for the geometry of the filament

Neurofilaments in mammalian nervous tissues have three subunit proteins. These subunit proteins have apparent molecular masses of 200 (NF200), 150 (NF150) and 68 (NF68) kD. Biochemical assembly studies have indicated that the NF68 protein forms the core of the filament and that the other two proteins are associated proteins. Electron microscopy immunolocalization studies have been performed previously on isolated filaments and on filaments from neurons in culture, and have confirmed the localization of NF68 as a core filament protein and NF200 as a peripheral protein. We have raised two monoclonal antibodies to the NF200 components. Using immunogold labelled protein A, we have been able to localize these antibodies to tissue sections of adult cerebellum at the EM level. With this method, we have found that one of the monoclonal antibodies (NF2) shows a linear arrangement of gold particles directly on the filament, whereas the second monoclonal antibody (NF111) reacts with the filaments to give a periodic arrangement of gold particles. By immunoblotting against chymotryptic fragments of the NF200 protein, we have found that the mAB-NF111 reacts solely with a 160 kD piece, whereas the other monoclonal antibody reacts with both the 160 kD piece and the 40 kD piece. The latter piece was shown to be associated to the filament by binding studies with iodinated NF68. Thus the EM localization studies and the biochemical studies indicate that the two monoclonal antibodies react with different parts of the NF200 molecule, one binding to a part of the molecule which is located closer to the filament, and one to a more peripheral part of the molecule.     

Monoclonal antibodies to epitopes on different regions of the 200 00 dalton neurofilament protein : Probes for the geometry of the filament

Neurofilaments in mammalian nervous tissues have three subunit proteins. These subunit proteins have apparent molecular masses of 200 (NF200), 150 (NF150) and 68 (NF68) kD. Biochemical assembly studies have indicated that the NF68 protein forms the core of the filament and that the other two proteins are associated proteins. Electron microscopy immunolocalization studies have been performed previously on isolated filaments and on filaments from neurons in culture, and have confirmed the localization of NF68 as a core filament protein and NF200 as a peripheral protein. We have raised two monoclonal antibodies to the NF200 components. Using immunogold labelled protein A, we have been able to localize these antibodies to tissue sections of adult cerebellum at the EM level. With this method, we have found that one of the monoclonal antibodies (NF2) shows a linear arrangement of gold particles directly on the filament, whereas the second monoclonal antibody (NF111) reacts with the filaments to give a periodic arrangement of gold particles. By immunoblotting against chymotryptic fragments of the NF200 protein, we have found that the mAB-NF111 reacts solely with a 160 kD piece, whereas the other monoclonal antibody reacts with both the 160 kD piece and the 40 kD piece. The latter piece was shown to be associated to the filament by binding studies with iodinated NF68. Thus the EM localization studies and the biochemical studies indicate that the two monoclonal antibodies react with different parts of the NF200 molecule, one binding to a part of the molecule which is located closer to the filament, and one to a more peripheral part of the molecule.     

Localization and partial characterization of the extracellular proteins centrifuged from pea internodes

The proteins removed from the extracellular space of dark-grown pea ( Pisum sativum L. cv. Alaska) internode sections by centrifugation were studied. A large number of proteins were resolved by sodium dodecyl sulfate polyacrylamide gel electrophoresis. These proteins ranged in size from 10 to 150 kdalton and their removal from the cell wall was greatly facilitated by the presence of salts of divalent and trivalent cations in the infiltration medium. Pulse-labelling experiments with [³⁵S)-methionine showed that many of the proteins extracted from the cell wall incorporated radioactivity and that treatment with indoleacetic acid (IAA) altered the pattern of radiolabel incorporation. One of the proteins centrifuged from pea internode sections possessed per-oxidase (EC 1.11.1.7) activity. The activity of this peroxidase increased less in auxin-treated internode segments than in untreated controls. Antibodies were raised to the total protein fraction extracted by centrifugation and used to localize antigens on protein blots. Most of the proteins centrifuged from pea internode sections were stained by a dye coupled to the cell wall antiserum. Light microscopic immunohistochemical studies showed that the proteins centrifuged from dark-grown pea internodes were localized almost exclusively in the cell wall and intercellular spaces of pea internode tissue. Light microscopic immunohistochemistry also showed that antibodies to extracted proteins penetrate into the apoplast of abraded pea internode segments and split pea stems. These antibodies did not influence growth of IAA-treated or control tissue.     

Characterizing proteins and their interactions in cells and tissues using the in situ proximity ligation assay

The activity of proteins is typically regulated by secondary modifications and by interactions with other partners, resulting in the formation of protein complexes whose functions depend on the participating proteins. Accordingly, it is of central importance to monitor the presence of interaction complexes as well as their localization, thus providing information about the types of cells where the proteins are located and in what sub-cellular compartment these interactions occur. Several methods for visualizing protein interactions in situ have been developed during the last decade. These methods in most cases involve genetic constructs, and they have been successfully used in assays of living cell maintained in tissue culture, but they cannot easily be implemented in studies of clinical specimens. For such samples, affinity reagents like antibodies can be used to target the interacting proteins. In this review we will describe the in situ proximity ligation assays (in situ PLA), a method that is suitable for visualizing protein interactions in both tissue sections and in vitro cell lines, and we discuss research tasks when this or other method may be selected.     

The identification and partial characterization of merosin--a new specific protein of the basement membranes of certain tissues

A tissue-specific basement membrane-associated protein has been identified by the use of monoclonal antibodies prepared against a protein fraction of human placenta. In frozen sections of human tissues the monoclonal antibodies decorated basement membranes of Schwann cells, striated muscle, and trophoblast. In antibody-affinity chromatography of limited pepsin digests of human placenta, a 65-kDa polypeptide was bound by the monoclonal antibodies. Polyclonal antisera and new monoclonal antibodies were raised against the isolated 65-kDa polypeptide, and they stained human tissues identically to the original monoclonal antibodies. An 80-kDa polypeptide was detected by these antibodies in placental extracts prepared without proteolysis. The 65-kDa and 80-kDa polypeptides were immunologically distinct from laminin, type IV collagen, fibronectin and major serum proteins. These polypeptides are presumably derived from a novel basement membrane-associated protein which we named merosin. Several cDNA clones were isolated which code for a protein specifically recognized by polyclonal antibodies to the 65-kDa fragment. In developing mouse tissues, merosin was first detected at the newborn stage. The restricted tissue distribution and the late development appearance of merosin suggest that the protein has a tissue-specific function in highly differentiated cells.     

Immunochemical Analysis of the Temporal and Tissue-Specific Expression of an Avena sativa Plasma Membrane Determinant

An immunoglobulin Mk monoclonal (F8IVE9) antibody raised against oat (Avena sativa cv Garry) root homogenate has been produced and characterized. The predominant target bound by this antibody is a 62-kilodalton protein (p62) that is expressed in both oat root and oat shoot cells. Treatment of the oat antigen with periodate, or with recombinant N-glycanase, affects the F8IVE9 binding to the antigen, suggesting that the specific epitope for this monoclonal antibody involves a carbohydrate determinant. Levels of p62 present in cells of the oat root increase approximately twofold as the root tissue matures during the first 11 days postgermination. In contrast, levels of expression in shoot tissue remain relatively constant during the same period. The p62 antigen has been shown to be expressed at the plasma membrane by immunohistochemical means, by immunofluorescent labeling of protoplasts, and by enzyme-linked immunosorbent assay analysis of purified plasma membrane. The F8IVE9 antigenic target appears to be uniformly distributed through root tissue but is differentially expressed in specific sections of the shoot. F8IVE9 antibody also binds to antigens expressed in a number of other species, including clover, corn, pea, broccoli, mustard, and bean, and has been shown to bind to Samanea protoplast plasma membranes. This monoclonal antibody may prove to be useful for a variety of investigations, including an analysis of the specific patterns of cellular differentiation that occur during early morphogenesis, and the characterization of plasma membrane-associated elements in plants.     

Cellular Localization and Expression of Template-Activating Factor I in Different Cell Types

Template-activating factors I (TAF-I) α and β have been identified as chromatin remodeling factors from human HeLa cells. TAF-Iβ corresponds to the protein encoded by thesetgene, which was found in an acute undifferentiated leukemia as a fusion version with thecangene via chromosomal translocation. To determine the localization of TAF-I, we raised both polyclonal and monoclonal antibodies against TAF-I. The proteins that react to the antibodies are present not only in human cells but also in mouse, frog, insect, and yeast cells. The mouse TAF-I homologue is ubiquitous in a variety of tissue cells, including liver, kidney, spleen, lung, heart, and brain. It is of interest that the amounts of TAF-Iα and β vary among hemopoietic cells and some specific cell types do not contain TAF-Iα. The level of the TAF-I proteins does not change significantly during the cell cycle progression in either HeLa cells synchronized with an excess concentration of thymidine or NIH 3T3 cells released from the serum-depleted state. TAF-I is predominantly located in nuclei, while TAF-I that is devoid of its acidic region, the region which is essential for the TAF-I activity, shows both nuclear and cytoplasmic localization. The localization of TAF-I in conjunction with the regulation of its activity is discussed.     

Localization of mitochondrial DNA encoded cytochrome <Emphasis Type="Italic">c</Emphasis> oxidase subunits I and II in rat pancreatic zymogen granules and pituitary growth hormone granules

Cytochrome c oxidase (COX) complex is an integral part of the electron transport chain. Three subunits of this complex (COX I, COX II and COX III) are encoded by mitochondrial (mit-) DNA. High-resolution immunogold electron microscopy has been used to study the subcellular localization of COX I and COX II in rat tissue sections, embedded in LR Gold resin, using monoclonal antibodies for these proteins. Immunofluorescence labeling of BS-C-1 monkey kidney cells with these antibodies showed characteristic mitochondrial labeling. In immunogold labeling studies, the COX I and COX II antibodies showed strong and specific mitochondrial labeling in the liver, kidney, heart and pancreas. However, in rat pancreatic acinar tissue, in addition to mitochondrial labeling, strong and specific labeling was also observed in the zymogen granules (ZGs). In the anterior pituitary, strong labeling with these antibodies was seen in the growth hormone secretory granules. In contrast to these compartments, the COX I or COX II antibodies showed only minimal labeling (five- to tenfold lower) of the cytoplasm, endoplasmic reticulum and the nucleus. Strong labeling with the COX I or COX II antibodies was also observed in highly purified ZGs from bovine pancreas. The observed labeling, in all cases, was completely abolished upon omission of the primary antibodies. These results provide evidence that, similar to a number of other recently studied mit-proteins, COX I and COX II are also present outside the mitochondria. The presence of mit-DNA encoded COX I and COX II in extramitochondrial compartments, provides strong evidence that proteins can exit, or are exported, from the mitochondria. Although the mechanisms responsible for protein exit/export remain to be elucidated, these results raise fundamental questions concerning the roles of mitochondria and mitochondrial proteins in diverse cellular processes in different compartments.     

Localization of cell wall polysaccharides in nonarticulated laticifers ofAsclepias speciosa Torr.

Summary Asclepias speciosa Torr, has latex-containing cells known as nonarticulated laticifers. In stem sections of this species, we have analyzed the cell walls of nonarticulated laticifers and surrounding cells with various stains, lectins, and monoclonal antibodies. These analyses revealed that laticifer walls are rich in (1→4) β-D-glucans and pectin polymers. Immunolocalization of pectic epitopes with the antihomogalacturonan antibodies JIM5 and JIM7 produced distinct labeling patterns. JIM7 labeled all cells including laticifers, while JIM5 only labeled mature epidermal cells and xylem elements. Two antibodies, LM5 and LM6, which recognize rhamnogalacturonan I epitopes distinctly labeled laticifer walls. LM6, which binds to a (l→5) α-arabinan epitope, labeled laticifer walls more intensely than walls of other cells. LM5, which recognizes a (1→4) β-D-galac-tan epitope, did not label laticifer segments at the shoot apex but labeled more mature portions of laticifers. Also the LM5 antibody did not label cells at the shoot apical meristem, but as cells grew and matured the LM5 epitope was expressed in all cells. LM2, a monoclonal antibody that binds to β-D-glucuronic acid residues in arabinogalactan proteins, did not label laticifers but specifically labeled sieve tubes. Sieve tubes were also specifically labeled byRicinus communis agglutinin, a lectin that binds to terminal β-D-galactosyl residues. Taken together, the analyses conducted showed that laticifer walls have distinctive cytochemical properties and that these properties change along the length of laticifers. In addition, this study revealed differences in the expression of pectin and arabinogalactan protein epitopes during shoot development or among different cell types.     

Reactivity of a panel of neurofilament antibodies on phosphorylated and dephosphorylated neurofilaments

The work of the Sternbergers and their colleagues has shown that monoclonal antibodies reactive with neurofilament subunit proteins may be sensitive to the state of phosphorylation of these proteins. We therefore examined the ability of our previously described panel of monoclonal and polyclonal neurofilament antibodies to bind to normal and to enzymatically dephosphorylated neurofilament subunits. All the monospecific antibodies, both mono- and polyclonal, which we had previously documented as reactive with neurofilament H protein proved to bind only to the phosphorylated form of this protein, and H antibody staining of neurofilamentous profiles in frozen sections could be abolished by appropriate pretreatment of sections with alkaline phosphatase. In contrast, all monospecific antibodies, both mono- and polyclonal, reactive with native M and L proved to bind with apparently undiminished affinity following enzymatic dephosphorylation of the appropriate antigen, either in frozen sections or on Western blots. The class of monoclonal antibodies which react with both H and M were variable in their response to dephosphorylated neurofilaments; some completely lost their reactivity whilst others were partially or wholly unaffected. We stained frozen sections of nervous tissues from various mammalian species with the panel of antibodies, and observed filamentous staining of the perikarya and dendrites of a variety of different types of neuron with all antibodies, both mono- and polyclonal, directed against L and M. Antibodies with strong reactivity for phosphorylated H always failed to stain neurofilamentous dendritic and perikaryal profiles. We further describe the isolation and characterization of a new monoclonal antibody, which recognizes both phosphorylated and enzymatically dephosphorylated forms of H.(ABSTRACT TRUNCATED AT 250 WORDS)     

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.     

Reduction of High Background Staining by Heating Unfixed Mouse Skeletal Muscle Tissue Sections Allows for Detection of Thermostable Antigens With Murine Monoclonal Antibodies

Antigen detection with indirect immunohistochemical methods is hampered by high background staining if the primary antibody is from the same species as the examined tissue. This high background can be eliminated in unfixed cryostat sections of mouse skeletal muscle by boiling sections in PBS, and several proteins including even the low abundant dystrophin protein can then be easily detected with murine monoclonal antibodies. However, not all antigens withstand the boiling procedure. Immunoreactivity of some of these antigens can be restored by subsequent washing in Triton X-100, whereas immunoreactivity of other proteins is not restored by this detergent treatment. When such thermolabile proteins are labeled with polyclonal primary antibodies followed by dichlorotriazinylaminofluorescein–conjugated secondary antibodies and boiled, the fluorescence signal persists, and sections can then be processed with a monoclonal antibody for double immunostaining of a protein unaffected by boiling. This stability of certain fluorochromes on heating can also be exploited for double immunofluorescence labeling of two different thermostable proteins with murine monoclonal antibodies as well as for combination with Y-chromosome fluorescence in situ hybridization. Our method should extend the range of monoclonal antibodies applicable to tissues derived from the same species as the monoclonal antibodies. (J Histochem Cytochem 56:969–975, 2008)     

Characterization and localization of dynein and myosins V and VI in the ovaries of queen bees

The presence of myosin and dynein in the ovaries of both Apis mellifera and Scaptotrigona postica was investigated in extracts and in histological sections. In the ovary extracts, motor proteins, myosins V, VI and dynein were detected by Western blot. In histological sections, they were detected by immunocytochemistry, using a mouse monoclonal antibody against the intermediary chain of dynein and a rabbit polyclonal antibody against the myosin V head domain. The myosin VI tail domain was recognized by a pig polyclonal antibody. The results show that these molecular motors are expressed in the ovaries of both bee species with few differences in location and intensity, in regions where movement of substances is expected during oogenesis. The fact that antibodies against vertebrate proteins recognize proteins of bee species indicates that the specific epitopes are evolutionarily well preserved.     

Pertussis Toxin-Sensitive G Protein α-Subunits: Production of Monoclonal Antibodies and Detection of Differential Increases on Differentiation of PC12 and LA-N-5 Cells

Abstract: Monoclonal antibodies were produced that are specific for the three major pertussis toxin-sensitive G protein α-subunits present in mammalian brain—αo, αi1, and αi2—using purified bovine brain G proteins, purified rat brain G proteins, and purified recombinant αi2, respectively. These monoclonal antibodies were used to monitor changes in the concentrations of the three G protein α-subunits during differentiation of PC12 cells and human neuroblastoma LA-N-5 cells. In PC12 cells, levels of αi1 but not αi2 increased during nerve growth factor-induced differentiation. In contrast, αi2 but not αi1 increased when LA-N-5 cells were differentiated with retinoic acid. The concentration of αo increased in both cell lines during differentiation. Electrophoretic resolution of αo subtypes revealed that although αo2 was the major subtype in undifferentiated cells, only the concentration of αo1 increased during differentiation of both PC12 and LA-N-5 cells. The level of 43-kDa growth-associated protein, a protein known to associate with αo, increased similarly to that of αo1. ADP-ribosylation of αo, αi1, and αi2 with pertussis toxin did not alter the reactivities of the monoclonal antibodies, but toxin treatment of cells reduced the concentrations of each protein after 24 h. There was no change in the concentration of αq, which is not ADP-ribosylated by pertussis toxin. Thus, these new monoclonal antibodies enabled the detection of differential increases in subtypes of αi and αo associated with neuronal differentiation.     

Characterization of the nucleolar protein, B-36, using monoclonal antibodies

A panel of nine monoclonal antibodies has been produced against a major nuclear protein, B-36, purified from the slime mold Physarum polycephalum. B-36, a 34 kD protein biochemically similar to the major structural proteins of mammalian hnRNP particles, was previously shown to be largely associated with the nucleolus. Eight of the monoclonal antibodies are specific for B-36 protein in Physarum and at least three different epitopes are represented among these eight. Using the monoclonal antibodies B-36 has been shown to be localized exclusively to the nucleolus in actively-growing Physarum cultures. The nucleolar localization of B-36 is dependent on the presence of intact RNA, but not DNA, supporting the hypothesis that B-36 is associated with nucleolar RNA, possibly in some analogous manner to the interaction of the related proteins within heterogeneous nuclear ribonucleoproteins (hnRNP) particles. B-36 is apparently a highly conserved nucleolar protein in eukaryotes as all eight of the monoclonal antibodies specific for B-36 in Physarum are also specific for a 34.5 kD nucleolar protein in rat liver. This indicates that a minimum of three distinct epitopes are conserved in B-36 protein from slime mold to rat.     

Characterization of monoclonal antibodies to glycodelin and recombinant glycodelin

Glycodelin-A belongs to the lipocalin superfamily. Although it is associated with normal endometrial growth during the menstrual cycle, fertilization and normal pregnancy in humans, the molecular mechanism of its biological action has not been elucidated. To undertake studies to understand the functional relevance of any molecule, obtaining large quantities of the protein becomes essential. With the ultimate aim of purifying glycodelin either from its natural sources (human amniotic fluid) or the recombinant glycodelin from bacterial recombinant lysates, we raised monoclonal antibodies to this protein. As immunogens, recombinant glycodelin expressed in E. coli and Pichia pastoris as well as glycodelin from amniotic fluid were used. The monoclonal antibodies generated were characterized with respect to binding to both the native as well as the recombinant proteins using ELISA, immunoblotting, and immunohistochemistry.     

Attempts to quantitate immunocytochemistry at the electron microscope level

Summary The ability to localize intracellular macromoleculesin situ by high resolution techniques has been made possible by the development of antibody labelling of thin sections obtained either from tissues embedded in an hydrophilic matrix, or by ultracryotomy or from conventional plastic embedded tissue. When particle-tagged immunological reagents are used to visualize intracellular antigens, quantitative information can be obtained by combining particle counts with morphometric estimations of compartment volume. Various detection systems have been used successfully for quantitation, which include ferritin-conjugated antibodies, biotin-avidin-ferritin complexes and, more recently, gold-protein A conjugates. Examples of the use of these techniques the localization of secretory proteins in pancreatic exocrine cells, opsin and a large membrane protein in photoreceptor cells of frog retina, and contractile proteins in skeletal muscle are given. Quantitative data obtained by morphometric analysis, both in bovine and rat pancreatic exocrine cells, are compared with values assessed by biochemical methods.     

M protein (M1) of influenza virus: antigenic analysis and intracellular localization with monoclonal antibodies.

A panel of 16 monoclonal antibodies recognizing M protein (M1) of influenza virus was generated. Competition analyses resulted in localization of 14 monoclonal antibodies to three antigenic sites. Three monoclonal antibodies localized to site 1B recognized a peptide synthesized to M1 (residues 220 to 236) with enzyme-linked immunosorbent assay titers equivalent to or greater than that seen with purified M1; therefore, site 1B is located near the C terminus of M1. Sites 2 and 3 localize to the N-terminal half of M1. Antigenic variation of M proteins was seen when the monoclonal antibodies were tested against 14 strains of type A influenza viruses. Several monoclonal antibodies showed specific recognition of A/PR/8/34 and A/USSR/90/77 M proteins and little or no reactivity for all other strains tested. Immunofluorescence analysis with the monoclonal antibodies showed migration of M protein to the nucleus during the replicative cycle and demonstrated association of M protein with actin filaments in the cytoplasm. Use of a vaccinia virus recombinant containing the M-protein gene demonstrated migration of M protein to the nucleus in the absence of synthesis of gene products from other influenza virus RNA segments.