Expression of genes for cell-wall proteins in dividing and wounded tissues ofZea mays L.

Hydroxyproline-rich glycoproteins (HRGPs) fromZea mays have been immunolocalized in the cell wall of root tip cells using ultrathin sections and antibodies ellicited against the purified protein. The accumulation of mRNA corresponding to this protein was studied using the cDNA probe. Maximum accumulation of the mRNA was found in tissues with a high proportion of dividing cells such as those in the root tip of young maize seedlings and a close relationship with cellular division was also observed in in-vitro cultures. However, the level of the mRNA in elongating tissues was minimal, as shown by studies carried out on the elongation zones of root tips and coleoptiles. The mRNA was induced by stress conditions, particularly by wounding young leaves and coleoptiles. It is concluded that in maize this group of proline-rich cell-wall proteins accumulates during cell division and not during cell elongation or differentiation, and participates in the stress-response mechanisms of the plant.     

Plant response to touch affects the behaviour of aphids and ladybirds

Touching between leaves of the same plant and/or by neighbouring plants is one of the most common mechanical stimuli to which an individual plant has to respond on a daily basis. The possible ecological implications of a plant’s response to touch on plant–insect interactions have not been explicitly investigated. We examined whether plant response to 1 min daily touching over a period of 6 days affects host plant acceptance by the bird cherry-oat aphid Rhopalosiphum padi L. on maize and by the black bean aphid Aphis fabae Scop. on bean, as well as olfactory preference of an aphid predator, seven-spotted ladybird Coccinella septempunctata L. Maize plants responded to touch with significant reduction in plant height, total plant biomass, leaf weight, leaf surface, shoot/root ratio and specific leaf area (SLA), while bean plants responded with reduced stem height and reduced SLA. Both aphid species showed significantly reduced acceptance of touched plants compared with untouched plants. The two aphid species and male and female ladybirds preferred volatiles from untouched plants over those from touched plants. Volatiles in the headspace of touched and untouched plants were collected and identified. Stepwise discriminant analyses identified (E)-nerolidol and (E)-β-caryophyllene in maize and 6-methyl-5-hepten-2-one and an unidentified sesquiterpene in bean as the best discriminating compounds in the volatile profiles of touched plants. Our study suggests that touch-induced changes in plants can potentially affect host plant selection by aphids and habitat searching by ladybirds. Thus, touch-induced changes in plants may have significant effects at higher trophic levels.     

Expression of a dehydrin-like protein in maize seedlings germinated from seed exposed to freezing

Dehydrins are a family of heat-soluble, hydrophilic proteins that share a considerable degree of sequence homology. Their expression has been reported in numerous plant species in response to a multitude of environmental stresses including low temperature, freezing, and desiccation. It has also been established that exposing plant tissues to freezing temperatures generates desiccation stress. We observed differential accumulation of a dehydrin-like protein and corresponding mRNA in three-day-old maize (Zea mays L) seedlings germinated under favorable environmental conditions from seed that had been exposed to freezing temperatures during maturation. This represents the first documented situation in which a dehydrin-like protein differentially accumulates under favorable environmental conditions. We believe that the dehydrin-like protein and corresponding mRNA are synthesized de novo in seedlings that are germinated from seed that have been exposed to freezing in response to desiccation-like stress that persists under favorable environmental conditions resulting from freeze-induced damage sustained by the ungerminated embryo.     

Interactions between abscisic acid and cytokinins during water stress and subsequent rehydration

With the aim to contribute to elucidation of the role of phytohormones in plant responses to stresses the endogenous contents of abscisic acid (ABA) and cytokinins (CK) were followed in French bean, maize, sugar beet, and tobacco during water stress and subsequent rehydration. The effects of pre-treatments with exogenous ABA or benzyladenine (BA) before imposition of water stress were also evaluated. The content of ABA increased by water stress, and with the exception of bean plants increased content of ABA remained also after rehydration. In all plant species the ABA content was further increased by ABA pre-treatment, but in bean and maize it decreased by BA pre-treatment. The highest total content of CK was observed in bean and the lowest in maize during water stress. In their spectrum, the storage CK were dominant in bean, and inactive CK in tobacco while in sugar beet and maize all groups were present in comparable amounts. In all plant species, the contents of CK increased during water stress and with exception of bean they decreased back after rehydration. ABA pre-treatment further increased contents of CK in water-stressed bean and tobacco. BA pre-treatment increased contents of CK in sugar beet and tobacco after rehydration.     

An mRNA that specifically accumulates in maize roots delineates a novel subset of developing cortical cells

A near full-length cDNA clone (pZRP3) corresponding to an mRNA that accumulates specifically in roots of maize was isolated. The ZRP3 mRNA is ca. 600 nucleotides in length. The amino acid sequence of the predicted polypeptide is rich in leucine (16%), proline (11%), and cysteine (8.5%). The zrp3 gene appears to be expressed exclusively in roots, whereas other ZRP3-related genes are expressed in additional organs of the maize plant. In situ hybridization shows that ZRP3 mRNA accumulation is largely confined to the cells of the cortical ground meristem. Furthermore, accumulation of this mRNA occurs within a distinct subset of cortical cells, the inner three to four cell layers.Journal paper number J-14572 of the Iowa Agriculture and Home Economics Experiment Station, Ames, Iowa Project Number 2997.     

Plastic responses in the metabolome and functional traits of maize plants to temperature variations

Environmentally inducible phenotypic plasticity is a major player in plant responses to climate change. However, metabolic responses and their role in determining the phenotypic plasticity of plants that are subjected to temperature variations remain poorly understood. The metabolomic profiles and metabolite levels in the leaves of three maize inbred lines grown in different temperature conditions were examined with a nuclear magnetic resonance metabolomic technique. The relationship of functional traits to metabolome profiles and the metabolic mechanism underlying temperature variations were then explored. A comparative analysis showed that during heat and cold stress, maize plants shared common plastic responses in biomass accumulation, carbon, nitrogen, sugars, some amino acids and compatible solutes. We also found that the plastic response of maize plants to heat stress was different from that under cold stress, mainly involving biomass allocation, shikimate and its aromatic amino acid derivatives, and other non‐polar metabolites. The plastic responsiveness of functional traits of maize lines to temperature variations was low, while the metabolic responsiveness in plasticity was high, indicating that functional and metabolic plasticity may play different roles in maize plant adaptation to temperature variations. A linear regression analysis revealed that the maize lines could adapt to growth temperature variations through the interrelation of plastic responses in the metabolomes and functional traits, such as biomass allocation and the status of carbon and nitrogen. We provide valuable insight into the plastic response strategy of maize plants to temperature variations that will permit the optimisation of crop cultivation in an increasingly variable environment.     

Expression of a maize proteinase inhibitor gene is induced in response to wounding and fungal infection: systemic wound-response of a monocot gene

The isolation and characterization of cDNA and genomic clones encoding a proteinase inhibitor protein (MPI) in maize is reported. Accumulation of the MPI mRNA is induced in response to fungal infection in germinating maize embryos. The expression pattern of the MPI gene, in healthy and fungal infected maize tissues, was examined and compared with the expression pattern of a gene that codes for a pathogenesis-related protein (the PRms protein) from maize. These two genes are induced by fungal infection, however different signals trigger their activation. Accumulation of the proteinase inhibitor mRNA is more a consequence of the wound produced by the penetration and colonization of the host tissues by the pathogen, than the result of a direct molecular recognition of the pathogen by the plant, as is the case for the induction of the PRms gene. Wounding, or treatment with abscisic acid or methyl jasmonate, stimulate MPI mRNA accumulation, but not PRms mRNA accumulation. Local and systemic induction of the MPI gene expression in response to wounding occurs in maize plants. To the authors' knowledge, this is the first example of a gene from a monocotyledonous species that clearly shows a systemic wound response. The possible functional implications for the existence of different signal transduction pathways that simultaneously activate a battery of defense mechanisms against potential pathogens are discussed.     

A protein induced by NaCl in suspension cultures ofNicotiana tabacum accumulates in whole plant roots

Summary We have characterized a 26 000 dalton (26 000 D) protein which accumulates inNicotiana tabacum cuspension cells grown in media containing 10–25 g/l NaCl (7, 11, 17). Antibody was prepared against this protein and used to examine protein accumulation in both suspension cells and whole plants. Western blot analysis revealed that the 26 000 D protein also accumulates in suspension cells grown in the absence of NaCl as they approach stationary phase but the accumulation never reaches the level seen in the salt adapted cells. This protein also accumulates after treatment with other agents which lower the water potential, such as PEG and KCl, but no increase is seen after nonosmotic stresses such as heat shock and growth in cadmium chloride. The 26 000 D protein is found not only in whole tobacco plants but also in other members of the Solanaceae that were tested, as well as in alfalfa and green beans. The accumulation of the protein seems to be tissue specific as there is considerably more accumulation in roots than in stems or leaves of greenhouse grown plants. We have been unable to correlate accumlation of the 26 000 D protein with salt in wild tomato species but have demonstrated an increase in the accumulation of this protein with salt stress in hydroponically grown tomato plants. These results lead to speculation as to the role of this protein in responding to lowered water potential in the whole plant.     

Pyruvate accumulation during phosphate deficiency stress of bean roots

Culture of bean plants (Phaseolus vulgaris L. cv., Złota Saxa) for 16 d on phosphate-deficient nutrient medium resulted in an over twofold increase of pyruvate concentration in the root tissues. In a variety of plant tissues, the marked decline in cellular concentrations of adenylates and inorganic phosphate (Pi) influences the activity of pyruvate producing enzymes, which are dependent on the availability of ADP. In bean roots after 16 d of phosphate starvation pyruvate producing enzymes: phosphoenolpyruvate phosphatase (EC 3.1.3.2) and phosphoenolpyruvate carboxylase (EC 4.1.1.31) had higher activities compared to those of control plants. The observed decrease of alanine and ethanol concentration and also alcohol dehydrogenase (EC 1.1.1.1) activity in phosphate-deficient roots may be the effect of the restrictions in pyruvate utilizing pathways. The increased activity of mitochondrial NAD-malic enzyme (EC 1.1.1.40) as well as the lower consumption of pyruvate during respiration of phosphate-deficient roots indicate that pyruvate concentration in mitochondria may be elevated. It is proposed that pyruvate accumulation in phosphate-deficient roots and alternative oxidase participation in respiration are important aspects of plant metabolic adaptations to Pi limitation, and may play a role in reducing oxidative stress induced by phosphate deficiency.     

Role of sulphur availability on cadmium-induced changes of nitrogen and sulphur metabolism in maize (Zea mays L.) leaves

The interactions between sulphur nutrition and Cd exposure were investigated in maize (Zea mays L.) plants. Plants were grown for 12 days in nutrient solution with or without sulphate. Half of the plants of each treatment were then supplied with 100 microM Cd. Leaves were collected 0, 1, 2, 3, 4 and 5 days from the beginning of Cd application and used for chemical analysis and enzyme assays. Cd exposure produced symptoms of toxicity (leaf chlorosis, growth reduction) and induced a noticeable accumulation of non-protein SH compounds. As phytochelatins are glutamate- and cysteine-rich peptides, the effect of cadmium on some enzyme activities involved in N and S metabolism of maize leaves was studied in relation to the plant sulphur supply. In vivo Cd application to S-sufficient plants resulted in a drop of all measured enzyme activities. On the other hand, S-deficient plants showed a decrease in nitrate reductase (NR; EC 1.6.6.1) and glutamine synthetase (GS; EC 6.3.1.2) activity, and an increase in NAD-dependent glutamate dehydrogenase (GDH; EC 1.4.1.2) and phosphoenolpyruvate carboxylase (PEPc; EC 4.1.1.31) activity as a result of the Cd treatment. Furthermore, in the same plants ATP sulphurylase (ATPs; EC 2.7.7.4) and O-acetylserine sulphydrylase (OASs; EC 4.2.99.8) showed a particular pattern as both enzymes exhibited a transient maximum value of activity after 4 days from the beginning of Cd exposure. Results provide evidence that the increase of ATPs, OASs, GDH and PEPc activities, observed exclusively in S-deficient Cd-treated plants, may be part of the defence mechanism based on the production of phytochelatins.     

Accumulation of the ZRP3 mRNA in the root and coleorhiza of germinating maize (Zemays,Poaceae)

The evolutionary origin of the coleorhiza of species of Poaceae is unclear. The zrp3 gene, which codes for a protein of an as yet unknown function, is expressed in the roots of maize early in development. The sequence of zrp3 is similar to the sequences of three other genes isolated from dicot species. The pattern of accumulation of ZRP3 mRNA was examined in embryos of maize. No ZRP3 mRNA can be detected in the dry seeds; however, 1.5 d after inhibition, ZRP3 mRNA accumulated in both the roots and the coleorhiza of the embryo but not in other regions of the seed. In the roots, ZRP3 mRNA accumulates specifically in the cortical ground meristem and the pro-pith tissues. In the coleorhiza, ZRP3 mRNA accumulates in the parenchymal cells but not in the epidermal cells, thus distinguishing two tissue types in this organ. The accumulation of ZRP3 mRNA in the coleorhiza as well as in the root is molecular evidence consistent with the homology of these two organs.