Arabidopsis thaliana Atvsp is homologous to soybean VspA and VspB,genes encoding vegetative storage protein acid phosphatases,and is regulated similarly by methyl jasmonate,wounding, sugars,light and phosphate

The soybean vegetative storage proteins, VSP and VSP, are acid phosphatases that accumulate to very high levels in hypocotyls, young leaves and flowers and pods. The genes encoding the soybean VSP are activated by jasmonate, wounding, sugars and light and down regulated by phosphate and auxin. In this study, expression of an Arabidopsis thaliana gene (Atvsp) encoding a protein homologous to soybean Vsp and Vsp, was examined and compared to expression of the soybean Vsp genes. Atvsp mRNA was present at high levels in flowers and buds and at low levels in roots, stems, leaves and siliques. Expression of Atvsp in leaves could be induced by wounding or by treatment of illuminated plants with methyl jasmonate and sucrose. Roots of plants with wounded leaves also accumulated Atvsp mRNA indicating that this gene can be regulated by a transmissible wound signal. Phosphate partially inhibited expression of Atvsp. Arabidopsis proteins of 29 and 30 kDa crossreacted with antibodies against soybean VSP. These proteins were very abundant in flowers and the proteins accumulated in leaves and roots of plants treated with methyl jasmonate. The level of these proteins in flowers was similar to the levels of soybean VSP in young soybean leaves. Overall, these data indicate that Arabidopsis Atvsp and soybean VspA/B genes are regulated similarly and that in both plants, the gene products can accumulate to high levels. This suggests that genes homologous to VspA/B may be of greater general significance than previously recognized.     

A Rapid Increase in the Level of Binding Protein (BiP) is Accompanied by Synthesis and Degradation of Storage Proteins in Pumpkin Cotyledons

The binding protein (BiP) has been implicated in cotranslationalfolding of nascent polypeptides, and in the recognition anddisposal of aberrant polypeptides. To elucidate the involvementof BiP in the biosynthesis of vacuolar proteins, we have characterizedthe protein in pumpkin cotyledons during seed maturation andseedling growth. Isolated microsomes from maturing pumpkin cotyledonscontained a significant amount of BiP, protein-disulfide isomeraseand calreticulin. We have purified a 70-kDa protein; sequencesof the N-terminus and internal fragments of this protein exhibiteda high identity to the sequence of soybean BiP. Immunoblot analysiswith specific antibodies raised against the purified BiP showedthat the amount of BiP in a cotyledon increased markedly atthe middle stages and then decreased. The increase was accompaniedby the synthesis of storage proteins and the development ofthe endoplasmic reticulum in the cotyledons at the middle stageof seed maturation. Most of these storage proteins degradeddramatically between 2 and 5 days after seed germination, andthe degradation was also accompanied by a rapid increase inthe level of BiP. Subcellular fractionation of the 4-day-oldcotyledons showed a high accumulation of BiP in the endoplasmicreticulum. It is possible that BiP might be involved in thesynthesis of seed storage proteins during maturation and inthe synthesis of hydrolytic enzymes responsible for the degradationof the storage proteins during seed germination. (Received September 18, 1996; Accepted January 8, 1997)     

The phosphorylation state and expression of soybean BiP isoforms are differentially regulated following abiotic stresses

The mammalian BiP is regulated by phosphorylation, and it is generally accepted that its unmodified form constitutes the biologically active species. In fact, the glycosylation inhibitor tunicamycin induces dephosphorylation of mammalian BiP. The stress-induced phosphorylation state of plant BiP has not been examined. Here, we demonstrated that soybean BiP exists in interconvertible phosphorylated and nonphosphorylated forms, and the equilibrium can be shift to either direction in response to different stimuli. In contrast to tunicamycin treatment, water stress condition stimulated phosphorylation of BiP species in soybean cultured cells and stressed leaves. Despite their phosphorylation state, we demonstrated that BiP isoforms from water-stressed leaves exhibit protein binding activity, suggesting that plant BiP functional regulation may differ from other eukaryotic BiPs. We also compared the induction of the soybean BiP gene family, which consists of at least four members designated soyBiPA, soyBiPB, soyBiPC, and soyBiPD, by tunicamycin and osmotic stress. Although all soybean BiP genes were induced by tunicamycin, just the soyBiPA RNA was up-regulated by osmotic stress. In addition, these stresses promoted BiP induction with different kinetics and acted synergistically to increase BiP accumulation. These results suggest that the soybean BiP gene family is differentially regulated by abiotic stresses through distinct signaling pathways.     

Synthesis and degradation of a 28-kDa pod storage protein in French bean (Phaseolus vulgaris) plants

Pod storage protein (PSP) accumulated in developing pods of French bean (Phaseolus vulgaris L.) plants, and increasing the PSP mRNA level by pod removal resulted in the enhancement of PSP accumulation in pods that formed later. Pod storage protein was detected in flowers, young leaves and young stem internodes in addition to pods. Accumulation of PSP and its mRNA was induced by sink-removal in an organ-specific manner. In addition, wounding induced PSP accumulation systemically in leaves. Methyl jasmonate did not induce PSP synthesis but enhanced the synthesis that was induced by wounding. In senescing pods, PSP was degraded, and degradation products with molecular masses of 20 and 17 kDa were detected in the pods. The amount of 20-kDa degradation product was greater than that of the 17 kDa product. Received: 26 May 1999 / Accepted: 24 June 1999     

Differential Expression of Two Soybean (Glycine max L.) Proline-Rich Protein Genes after Wounding

We have investigated the wound-induced expression of two members of the soybean (Glycine max L.) proline-rich cell wall protein gene family and show that SbPRP1 and SbPRP2 exhibit unique patterns of expression after physical damage. SbPRP1 mRNA can be detected in the hook of soybean seedlings within 2 h after wounding and is present at high levels in the hook and elongating hypocotyl 20 h after wounding. In contrast, SbPRP2 mRNA increases transiently and rapidly throughout the soybean seedling after wounding. SbPRP2 is also induced by wounding in soybean leaves, but the pattern of mRNA accumulation in leaves is distinct from that seen in seedlings and reaches high levels of expression 20 h after physical damage. SbPRP2 mRNA levels were also found to increase in the mature hypocotyl and roots of seedlings in response to treatment with 10 [mu]M indoleacetic acid and naphthalene-1-acetic acid. These data indicate that the wound-induced expression of PRPs in soybean is tissue specific and that the regulation of these genes after physical damage may operate through different signal transduction pathways.     

Arabidopsis thaliana vegetative storage protein (VSP) genes: gene organization and tissue-specific expression

We have previously identified two cDNAs encoding vegetative storage proteins (VSPs) in Arabidopsis thaliana. Unlike soybean in which VSPs accumulate at high levels in leaves, A. thaliana VSP mRNAs are abundant in flowers. To understand tissue-specific expression and possible roles of VSPs on reproductive organ development, genes corresponding to VSPs (Vsp1 and Vsp2) and their putative promoters were characterized in this study. Genomic sequence analysis revealed that Vsp1 and Vsp2 resemble each other except in their introns, and that these two genes were organized in a tandem array with an interval of 6 kb in a region. The expression patterns of Vsp1 and Vsp2 were examined using transgenic A. thaliana plants carrying a promoter from Vsp1 or Vsp2 fused to a bacterial -glucuronidase (GUS) reporter gene. The promoter from Vsp1 expressed its effect in gynoecia, especially in styles, the basal and distal ends of ovaries and in siliques, whereas the promoter from Vsp2 showed its activity in vegetative shoots, petioles, peduncles and receptacles of floral organs. These results suggest that expression of Vsp1 and Vsp2 may be developmentally regulated in A. thaliana. In the transgenic plants, the GUS activity was induced by wounding in an area around the mid-rib of leaves. Therefore, Vsp1 and Vsp2 promoters appear to have elements required for both tissue specificity and wounding.     

Preferential Loss of an Abundant Storage Protein from Soybean Pods during Seed Development

A temporary vegetative storage protein, composed of similar 25 kilodalton and 27 kilodalton subunits, was found to be abundant in soybean (Glycine max (L.) Herr. var Hobbit) leaves, stems, pods, flower petals, germinated cotyledons, and less abundant in roots, nodules and seeds. Total pod protein was highest at 3 weeks after flowering and declined by 37% within 3 weeks during seed development. During this time the vegetative storage protein declined from 18% to 1.5% of the total pod protein and accounted for 45% of the protein lost from pods. This indicates that the vegetative storage protein makes a significant contribution to the pool of nutrients mobilized from pods for transport to developing seeds.     

Nitrogen accumulation and redistribution in soybean genotypes with variation in seed protein concentration

Breeding for high seed protein concentration in soybean [Glycine max (L.) Merrill] often results in lower yield, but the basis for this negative relationship is not well understood. To address this question, we evaluated the N acquisition characteristics of three high protein and three normal soybean genotypes in the field for 3 years. Plants were grown in 0.76 m rows following conventional cultural practices and water stress was minimized with sprinkler irrigation. We determined the mass and N concentration of leaves, petioles and stems at the beginning of seed filling (growth stage R5) and of stems at maturity. The N concentration of abscised leaves and petioles was also determined. There was significant variation among genotypes in total seed N (g m⁻²) at maturity (range from 14.7 to 24.4 g N m⁻²) as a result of variation in seed N concentration and yield. There was no evidence that the larger amounts of mature seed N were associated with a larger vegetative N reservoir at growth stage R5 as determined by vegetative mass at R5 or the concentration of N in vegetative tissues. Increasing seed N at maturity did not lower the N concentration in abscised leaves and petioles, or in the stems at maturity. The rate and timing of leaf senescence (loss of chlorophyll) was essentially the same for all genotypes. With no increase in the contribution from redistributed N, increases in N uptake or fixation during seed filling must have been responsible for the higher levels of seed N at maturity in high-protein genotypes. These data suggest that increasing total seed N at maturity by selecting for higher seed protein concentration or higher yield in soybean does not require, as some models suggest, a larger vegetative N reservoir at the beginning of seed filling or more rapid senescence.     

Coregulation of soybean vegetative storage protein gene expression by methyl jasmonate and soluble sugars

The soybean vegetative storage protein genes vspA and vspB are highly expressed in developing leaves, stems, flowers, and pods as compared with roots, seeds, and mature leaves and stems. In this paper, we report that physiological levels of methyl jasmonate (MeJA) and soluble sugars synergistically stimulate accumulation of vsp mRNAs. Treatment of excised mature soybean (Glycine max Merr. cv Williams) leaves with 0.2 molar sucrose and 10 micromolar MeJA caused a large accumulation of vsp mRNAs, whereas little accumulation occurred when these compounds were supplied separately. In soybean cell suspension cultures, the synergistic effect of sucrose and MeJA on the accumulation of vspB mRNA was maximal at 58 millimolar sucrose and was observed with fructose or glucose substituted for sucrose. In dark-grown soybean seedlings, the highest levels of vsp mRNAs occurred in the hypocotyl hook, which also contained high levels of MeJA and soluble sugars. Lower levels of vsp mRNAs, MeJA, and soluble sugars were found in the cotyledons, roots, and nongrowing regions of the stem. Wounding of mature soybean leaves induced a large accumulation of vsp mRNAs when wounded plants were incubated in the light. Wounded plants kept in the dark or illuminated plants sprayed with dichlorophenyldimethylurea, an inhibitor of photosynthetic electron transport, showed a greatly reduced accumulation of vsp mRNAs. The time courses for the accumulation of vsp mRNAs induced by wounding or sucrose/MeJA treatment were similar. These results strongly suggest that vsp expression is coregulated by endogenous levels of MeJA (or jasmonic acid) and soluble carbohydrate during normal vegetative development and in wounded leaves.     

Tissue specific and inducible expression of resveratrol synthase gene in peanut plants.

The expression of resveratrol synthase (RS) genes is induced by biotic and abiotic factors in peanut cell cultures. However, little is known about the regulation of the RS gene expression in peanut plants. The expression of RS genes was investigated in peanut plants with a peanut RS clone, pPRS3C, which encodes two polypeptides that show about a 96% amino acid sequence identity to peanut RS2 and RS3, respectively. A low level of RS mRNA was detected in the roots of peanut plants grown aseptically in vitro. In mature peanut plants that were grown in the field, however, RS mRNAs were present at relatively high levels in both the roots and pods, but at below the detection limit in leaves. RS mRNAs were abundant in young pods and decreased dramatically in mature pods. The RS mRNA expression was induced by yeast extract and UV in leaves and roots, and also by wounding in leaves. Stress hormones, such as ethylene, jasmonic acid, and salicylic acid, induced RS mRNA accumulation in leaves. These results indicate that the RS gene expression is induced by biotic and abiotic stresses through the stress hormones in peanut plants. The induction of the RS gene expression by biotic and abiotic stresses could provide peanut plants with protection from microbial infections through resveratrol synthesis. The RS gene expression in developing pods has significant implications in terms of the role of resveratrol as a phytochemical for human health.     

Methyl jasmonate treatment eliminates cell-specific expression of vegetative storage protein genes in soybean leaves

Soybean (Glycine max) plants accumulate a vacuolar glycoprotein in the parenchymal cells of leaves, petioles, stems, seed pods, and germinating cotyledons that acts in temporary nitrogen storage during vegetative growth. In situ immunolocalization of this vegetative storage protein (VSP) revealed that it accumulates in those parenchymal cells in close proximity to existing and developing vasculature, as well as in epidermal and cortical cells. The protein was more prevalent in younger, nitrogen-importing tissues before pod and seed development. Removal of actively growing seed pods greatly enhanced VSP accumulation, primarily in bundle sheath and paraveinal mesophyll cells. In situ hybridization of a VSP RNA probe to mRNA in leaf sections demonstrated that cell-specific mRNA accumulation corresponded with the pattern of protein localization. Treatment of leaf explants with 50 micromolar methyl jasmonate resulted in accumulation of VSP mRNA and protein in all cell types.     

Lipoxygenase gene expression is modulated in plants by water deficit, wounding, and methyl jasmonate

Summary Two classes of lipoxygenase (LOX) cDNAs, designated loxA and loxB, were isolated from soybean. A third lipoxygenase cDNA, loxP1, was isolated from pea. The deduced amino acid sequences of loxA and loxB show 61–74% identity with those of soybean seed LOXs. loxA and loxB mRNAs are abundant in roots and non-growing regions of seedling hypocotyls. Lower levels of these mRNAs are found in hypocotyl growing regions. Exposure of soybean seedlings to water deficit causes a rapid increase in loxA and loxB mRNAs in the elongating hypocotyl region. Similarly, loxP1 mRNA levels increase rapidly when pea plants are wilted. loxA and loxB mRNA levels also increase in wounded soybean leaves, and these mRNAs accumulate in soybean suspension cultures treated with 20 M methyl jasmonate. These results demonstrate that LOX gene expression is modulated in response to water deficit and wounding and suggest a role for lipoxygenase in plant responses to these stresses.     

Soybean vegetative storage protein structure and gene expression

Depodded soybean (Glycine max [L] Merr. cv Williams) plants accumulate high levels of a glycoprotein in their leaves that has many features of a storage protein. The protein is found in all vegetative tissues which have been examined but not in the seeds. Translation in vitro indicated that elevated mRNA levels were at least partially responsible for the specific increase in vegetative storage protein. cDNA clones were isolated and sequenced, and an amino acid sequence was predicted. Although the amino acid composition is similar to that of seed storage proteins, no sequence similarity could be detected. Northern blot hybridization confirmed a large increase in vegetative storage protein mRNA in leaves of depodded plants. The vegetative storage proteins are represented by about four gene copies in the haploid genome.     

BiP mRNA expression is upregulated by dehydration in vasopressin neurons in the hypothalamus in mice

The immunoglobulin heavy chain binding protein (BiP) is an endoplasmic reticulum (ER) chaperone that facilitates the proper folding of newly synthesized secretory and transmembrane proteins. Here we report that BiP mRNA was expressed in the supraoptic nucleus (SON) and paraventricular nucleus (PVN) of the hypothalamus in wild-type mice under basal conditions. Dual in situ hybridization in the SON and PVN demonstrated that BiP mRNA was expressed in almost all the neurons of arginine vasopressin (AVP), an antidiuretic hormone. BiP mRNA expression levels were increased in proportion to AVP mRNA expression in the SON and PVN under dehydration. These data suggest that BiP is involved in the homeostasis of ER function in the AVP neurons in the SON and PVN.     

The slow wound-response of<Emphasis Type="Italic"> γVPE</Emphasis> is regulated by endogenous salicylic acid in<Emphasis Type="Italic"> Arabidopsis</Emphasis>

Vacuolar processing enzyme (VPE) is a cysteine protease responsible for the maturation of various vacuolar proteins in higher plants. The Arabidopsis thaliana (L.) Heynh. VPE gene, encoding a VPE homologue, is slowly up-regulated in both local and systemic leaves in response to wounding. To clarify the activation mechanism of VPE, we examined the accumulation of VPE mRNA after hormone treatments or after wounding in wild-type and various mutant plants of Arabidopsis. Both ethylene and jasmonic acid (JA) are known as signal molecules that activate the wound-responsive genes. However, treatment with exogenous JA had little effect on the VPE response, although JA activated the vegetative storage protein (VSP) gene, a typical wound-responsive gene. Wounding activated VPE even in two ethylene-insensitive plants (etr1-1 and ein2-1). Thus, the wound-induced expression of VPE was independent of ethylene and JA. We found that the wound-induced expression of VPE was reduced in two SA-deficient plants (pad4-1 and NahG), while the wound-induced expression of VSP increased in these mutants. Appreciable accumulation of SA was not observed in either the local or systemic leaves after wounding. These results suggest that endogenous SA enhances the wound-induced expression of VPE and attenuates the wound-induced expression of VSP, although SA is not a wound-signal that directly activates these genes.Abbreviations ABA abscisic acid - GST glutathione S-transferase - INA 2,6-dichloroisonicotinic acid - JA jasmonic acid - MeJA methyl jasmonate - PR pathogenesis-related - RBCS Rubisco small subunit - SA salicylic acid - VPE vacuolar processing enzyme - VSP vegetative storage protein