Production of a T-Cell Clone Which Reacts with Membrane Proteins of Acholeplasma laidlawii

The role of cellular immunity in mycoplasma infection is not completely understood. In this study, we established mycoplasma-specific T-cell clones to evaluate cellular immunity in mycoplasma infection. We developed a T-cell clone (G-10) which was stimulated with Acholeplasma laidlawii. The T-cell clone G-10, CD4⁺ and T-cell receptor (TCR) αβ⁺ recognized the 42- and 65-kilodalton (kDa) membrane proteins of A. laidlawii and responded to A. hippikon. Hence, the application of mycoplasma-specific T cells such as G-10 in animal models may allow the assessment of cellular immune response to mycoplasma infection.     

Difference in Intensity of Ant Defense among Three Species of Macaranga Myrmecophytes in a Southeast Asian Dipterocarp Forest1

To examine interspecific variation in the intensity of ant defense among three sympatric species of obligate myrme‐cophytes of Macaranga (Euphorbiaceae), we measured the ratio of ant biomass to plant biomass, ant aggressiveness to artificial damage on host plants, and increase in herbivore damage on host plants when symbiont ants were removed. Increase in herbivore damage from two‐ and four‐week ant exclusion varied significantly among the three species. The decreasing order of vulnerability to herbivory was M. winkleri, M. trachyphylla, and M. beccariana. The antip/ant biomass ratio (= rate of the dry weight of whole ant colonies to the dry weight of whole aboveground plant parts) and ant agressiveness also varied significantly among the three species; the orders of both the ant/plant biomass ratio and ant aggressiveness were the same as in the herbivory increase. These results indicated that the intensity of ant defense differs predictably among sympatric species of obligate myrmecophytes on Macaranga. In addition to the interspecific difference in the total intensity of ant defense, when symbiont ants were excluded, both patterns of within‐plant variation in the amount of herbivore damage and compositions of herbivore species that caused the damage differed among species. This suggests that the three Macaranga species have different systems of ant defense with reference to what parts of plant tissue are protected and what herbivorous species are avoided by ant defense. Thus, it is important to consider the interspecific variation in ant defense among Macaranga species to understand the herbivore community on Macaranga plants and the mechanisms that promote the coexistence of multiple Macaranga myrmecophytes.     

Physiological Characterization of RNA-Binding Protein-Deficient Cells from Synechococcus sp. Strain PCC7942

The unicellular cyanobacteria, Synechococcus sp. strains PCC7942and PCC6301, have two small RNA-binding proteins, Rbp1 and Rbp2.In this study, native gel electrophoresis of the nuclease-treatedSynechococcus cell extracts showed that both Rbps are associatedin vivo with RNA but not with DNA. This indicates that theyare bona fide RNA-binding proteins. To address the functionof Rbps, we have characterized the mutants deficient in Rbp1or Rbp2. The Rbp1 deficient cells showed the same growth curve,cell color and cell viability as the wild-type strain at 30°C.The Rbp2-less mutant also grew well as wild-type but exhibiteda yellow-green color, and its cell viability was significantlyreduced. On exposure of the Rbp1-deficient mutant cells to atemperature of 10°C for one week, cell viability was completelylost. Western blot analysis showed that Rbp1 increases onlyin response to a temperature shift from 30 to 10°C, whereasRbp2 accumulates at a constant rate at cold temperature. Interestingly,translation elongation factor Tu was significantly decreasedin Rbp2-deficient cells but not in Rbp1-deficient cells. Thus,each Rbp appears to have a distinct role in cellular function. (Received June 28, 1999; Accepted September 24, 1999)     

Plant phenology-mediated indirect effects: The gall midge opens the phenological window wider for a leaf beetle

We examined whether larvae of the gall midge Rabdophaga rigidae (Diptera: Cecidomyiidae) can modify the seasonal dynamics of the density of a leaf beetle, Plagiodera versicolora (Coleoptera: Chrysomelidae), by modifying the leaf flushing phenology of its host willow species, Salix serissaefolia and Salix eriocarpa (Salicaceae). To test this, we conducted field observations and a laboratory experiment. The field observations demonstrated that the leaf flushing phenology of the willows and the seasonal dynamics of the beetle density differed between shoots with stem galls and shoots without them. On galled shoots of both willow species, secondary shoot growth and secondary leaf production were promoted; consequently, leaf production showed a bimodal pattern and leaf production periods were 1 to 2 months longer than on non‐galled shoots. The adult beetle density on galled shoots was thus enhanced late in the season, and was found to change seasonally, synchronizing with the production of new leaves on the host willow species. From the results of our laboratory experiment, we attributed this synchrony between adult beetle density and willow leaf flush to beetles’ preference to eat new leaves rather than old. Indeed, beetles consumed five times more of the young leaves when they were fed both young and old leaves. These results indicate that stem galls indirectly enhance the adult beetle density by enhancing food quality and quantity late in the beetle‐feeding season. We therefore conclude that midge galls widen the phenological window for leaf beetles by extending the willows’ leaf flush periods.     

Construction of a high-density linkage map of Italian ryegrass (Lolium multiflorum Lam) using restriction fragment length polymorphism, amplified fragment length polymorphism, and telomeric repeat associated sequence markers.

To construct a high-density molecular linkage map of Italian ryegrass (Lolium multiflorum Lam), we used a two-way pseudo-testcross F1 population consisting of 82 individuals to analyze three types of markers: restriction fragment length polymorphism markers, which we detected by using genomic probes from Italian ryegrass as well as heterologous anchor probes from other species belonging to the Poaceae family, amplified fragment length polymorphism markers, which we detected by using PstI/MseI primer combinations, and telomeric repeat associated sequence markers. Of the restriction fragment length polymorphism probes that we generated from a PstI genomic library, 74% (239 of 323) of randomly selected probes detected hybridization patterns consistent with single-copy or low-copy genetic locus status in the screening. The 385 (mostly restriction fragment length polymorphism) markers that we selected from the 1226 original markers were grouped into seven linkage groups. The maps cover 1244.4 cM, with an average of 3.7 cM between markers. This information will prove useful for gene targeting, quantitative trait loci mapping, and marker-assisted selection in Italian ryegrass.     

Deficiency of Starch Synthase IIIa and IVb Alters Starch Granule Morphology from Polyhedral to Spherical in Rice Endosperm

Starch granule morphology differs markedly among plant species. However, the mechanisms controlling starch granule morphology have not been elucidated. Rice (Oryza sativa) endosperm produces characteristic compound-type granules containing dozens of polyhedral starch granules within an amyloplast. Some other cereal species produce simple-type granules, in which only one starch granule is present per amyloplast. A double mutant rice deficient in the starch synthase (SS) genes SSIIIa and SSIVb (ss3a ss4b) produced spherical starch granules, whereas the parental single mutants produced polyhedral starch granules similar to the wild type. The ss3a ss4b amyloplasts contained compound-type starch granules during early developmental stages, and spherical granules were separated from each other during subsequent amyloplast development and seed dehydration. Analysis of glucan chain length distribution identified overlapping roles for SSIIIa and SSIVb in amylopectin chain synthesis, with a degree of polymerization of 42 or greater. Confocal fluorescence microscopy and immunoelectron microscopy of wild-type developing rice seeds revealed that the majority of SSIVb was localized between starch granules. Therefore, we propose that SSIIIa and SSIVb have crucial roles in determining starch granule morphology and in maintaining the amyloplast envelope structure. We present a model of spherical starch granule production.Starch is the most important carbohydrate storage material and contains the Glc polymers amylose and amylopectin. At least four classes of enzymes, ADP-Glc pyrophosphorylase (AGPase), starch synthase (SS), starch branching enzyme (BE), and starch debranching enzyme (DBE), are necessary for efficient starch biosynthesis in storage tissues.SSs (EC 2.4.1.21) play a central role in starch synthesis during α-glucan elongation by adding Glc residues from ADP-Glc to the nonreducing ends via α-1,4-glucosidic linkages. Rice (Oryza sativa) contains 11 SS genes that are grouped into six classes, SSI to SSV and granule-bound starch synthase (GBSS; Supplemental Fig. S1; Hirose and Terao, 2004; Ohdan et al., 2005). Every class contains multiple isozymes, except for SSI and SSV; SSI, SSIIa, SSIIIa, and GBSSI are highly expressed in developing rice endosperm (Hirose and Terao, 2004; Ohdan et al., 2005). SSI elongates short amylopectin chains with degree of polymerization (DP) from 6 or 7 to DP 8 to 12 (Fujita et al., 2006). SSIIa elongates amylopectin from DP 6 to 12 to DP 13 to 24 (Umemoto et al., 2002; Nakamura et al., 2005), and SSIIIa elongates long amylopectin chains with DP 33 or greater (Fujita et al., 2007). GBSSI synthesizes amylose and extra-long amylopectin chains (Sano, 1984; Takeda et al., 1987; Hizukuri, 1995). The functions of other SS isozymes, such as SSIIb, SSIIc, SSIIIb, SSIVa, SSIVb, SSV, and GBSSII, remain largely unknown due to the lack of respective mutant lines. It is not clear how SS isozymes contribute to starch granule formation.Rice endosperm amyloplasts produce characteristic compound-type starch granules, which consist of dozens of polyhedral, sharp-edged granules (Matsushima et al., 2010). Compound-type starch granules are the most common type in endosperm of Poaceae species (Tateoka, 1962; Grass Phylogeny Working Group, 2001; Prasad et al., 2011; Matsushima et al., 2013). Simple-type starch granules (one starch granule per amyloplast) are produced in some species of the Bambusoideae, Pooideae, Micrairoideae, Chloridoideae, and Panicoideae subfamilies. The taxonomic relationships in the Poaceae do not enable an accurate prediction of granule morphology (Tateoka 1962; Shapter et al., 2008; Matsushima et al., 2013).Two studies that changed starch granule shape from simple type to compound type have been reported (Suh et al., 2004; Myers et al., 2011). A hull-less cultivar of cv Betzes barley (Hordeum vulgare), cv Nubet, contains simple-type and bimodal starch granules, which are typical of wild-type barley. Chemical mutagenesis of cv Nubet produced a mutant called franubet, which contains compound-type starch granules (Suh et al., 2004). In the maize monogalactosyldiacylglycerol synthase-deficient mutant opaque5, simple-type granules are replaced by compound-type granules separated by a membranous structure (Myers et al., 2011). The molecular mechanisms that control starch granule morphology in cereal endosperm are largely unknown, although an alteration in membrane lipid synthesis may be involved (Myers et al., 2011).A structural model for the compound-type amyloplast is shown Figure 1. The amyloplast envelope contains an outer envelope membrane (OEM), inner envelope membrane (IEM), and intermembrane space (IMS). Each starch granule is enclosed by an IEM, and granules are separated by a septum-like structure (SLS; Yun and Kawagoe, 2010). In this model, the IMS and SLS are directly connected, and fluorescent proteins such as GFP and Cherry can move freely between the two (Fig. 1; Kawagoe, 2013). The chloroplast envelope membrane contains little protein compared with the thylakoid membrane (Heber and Heldt, 1981). The endosperm amyloplast envelope membrane contains even less protein. Low protein content could be a major reason why the amyloplast envelope in rice endosperm is difficult to observe using high-resolution electron microscopy. In transgenic rice, a fluorescent protein fused to an IEM protein, the ADP-Glc transporter BRITTLE1, visualized the amyloplast IEM (Yun and Kawagoe, 2010). Fluorescent proteins fused to the chloroplast OEM protein OEP7 visualized the amyloplast OEM in endosperm (Kawagoe, 2013). These studies revealed that the outermost membranes of rice amyloplasts are OEM and contain intraamyloplast compartments. Starch is synthesized within the amyloplast compartments and is ultimately formed as compound-type granules that are individually wrapped in IEM (Yun and Kawagoe, 2010; Kawagoe, 2013).Open in a separate windowFigure 1.Structural model of the wild-type amyloplast in developing rice endosperm. The OEM is in black, the IEM is in magenta, the IMS is in green, and the SLS is in blue. G, Starch granules.Confocal microscopy analyses of the rice IEM protein, BRITTLE1, revealed that an SLS, or cross wall, divides starch granules in the amyloplast (Yun and Kawagoe, 2010). A model for the synthesis of compound-type starch granules consisting of polyhedral, sharp-edged granules proposed that the SLS functions as a mold that casts growing granules into a characteristic shape (Yun and Kawagoe, 2010; Kawagoe, 2013). The model postulates a central role for the SLS in producing characteristic compound-type granules, although neither the SLS components nor the enzymes affecting its properties have been characterized.Arabidopsis (Arabidopsis thaliana) SS genes are grouped into six classes. Leaf transitory starch biosynthesis has been investigated in single mutants of SSI, SSII, SSIII, and SSIV and in various double and triple SS mutants (Ral et al., 2004; Delvallé et al., 2005; Zhang et al., 2005, 2008; Szydlowski et al., 2009, 2011). Starch granules in leaf chloroplasts are reduced in number but enlarged in the ssIV mutant (Roldán et al., 2007; Crumpton-Taylor et al., 2013) and in the ssIV double and triple mutants (Szydlowski et al., 2009). Immature ssIV leaves have no starch granules but accumulate the starch synthase substrate ADP-Glc at high concentrations. Starch granules are flattened and discoid in wild-type leaves but are rounded in mature leaves of ssIV, suggesting that SSIV is essential for coordinating granule formation with chloroplast division during leaf expansion (Crumpton-Taylor et al., 2013). The ssIII ssIV double mutant does not accumulate measurable amounts of starch in the leaves, despite the presence of SSI and SSII activity (Szydlowski et al., 2009), implying that Arabidopsis SSIII and SSIV are involved in the initiation of starch granule formation and that either SSIII or SSIV is sufficient. Overexpression of AtSSIV increases the starch level in Arabidopsis leaves and potato (Solanum tuberosum) tubers (Gámez-Arjona et al., 2011). In transgenic plants, the AtSSIV-GFP fusion protein is enriched in specific regions at the edge of granules in Arabidopsis chloroplasts and potato tuber amyloplasts. In rice, SSIVa and SSIVb are expressed in the endosperm and other organs at an early developmental stage (Hirose and Terao, 2004; Ohdan et al., 2005).In this study, two rice allelic SSIVb-deficient mutant lines (ss4b) were generated by insertion of the retrotransposon Tos17 and crossed with the SSIIIa null mutant (ss3a). Surprisingly, the ss3a ss4b endosperm produced spherical starch granules that were separated from each other within amyloplasts, whereas the single mutants produced compound-type polyhedral starch granules. The SSIVb and GBSSI enzymes were localized to distinct compartments in developing amyloplasts. We discuss the changes in rice starch structure due to the deficiency of both SSIIIa and SSIVb, the alteration in starch granule morphology, and possible unconventional functions of SSIIIa and SSIVb. We also present a model of how spherical granules are produced in ss3a ss4b rice endosperm.     

Interaction between a Domain of the Negative Regulator of the Ras-ERK Pathway,SPRED1 Protein,and the GTPase-activating Protein-related Domain of Neurofibromin Is Implicated in Legius Syndrome and Neurofibromatosis Type 1

Constitutional heterozygous loss-of-function mutations in the SPRED1 gene cause a phenotype known as Legius syndrome, which consists of symptoms of multiple café-au-lait macules, axillary freckling, learning disabilities, and macrocephaly. Legius syndrome resembles a mild neurofibromatosis type 1 (NF1) phenotype. It has been demonstrated that SPRED1 functions as a negative regulator of the Ras-ERK pathway and interacts with neurofibromin, the NF1 gene product. However, the molecular details of this interaction and the effects of the mutations identified in Legius syndrome and NF1 on this interaction have not yet been investigated. In this study, using a yeast two-hybrid system and an immunoprecipitation assay in HEK293 cells, we found that the SPRED1 EVH1 domain interacts with the N-terminal 16 amino acids and the C-terminal 20 amino acids of the GTPase-activating protein (GAP)-related domain (GRD) of neurofibromin, which form two crossing α-helix coils outside the GAP domain. These regions have been shown to be dispensable for GAP activity and are not present in p120^GAP. Several mutations in these N- and C-terminal regions of the GRD in NF1 patients and pathogenic missense mutations in the EVH1 domain of SPRED1 in Legius syndrome reduced the binding affinity between the EVH1 domain and the GRD. EVH1 domain mutations with reduced binding to the GRD also disrupted the ERK suppression activity of SPRED1. These data clearly demonstrate that SPRED1 inhibits the Ras-ERK pathway by recruiting neurofibromin to Ras through the EVH1-GRD interaction, and this study also provides molecular basis for the pathogenic mutations of NF1 and Legius syndrome.