Unraveling Physiological and Metabolomic Responses Involved in Phlox subulata L. Tolerance to Drought Stress

Metabolic responses are important for plant adaptation to abiotic stress. To investigate the responses of Phlox subulata L. to drought stress, we analyzed its physiological and metabolic changes using gas chromatography-mass spectrometer. Based on the physiological indices, P. subulata L. has tolerance to drought to some degree. Our results showed that there were a total of 30 key metabolites induced by drought stress, including amino acids, organic acids, sugars and sugar alcohols, nucleic acid and its derivatives, and other organic compounds. The glutamic acid-mediated proline biosynthesis pathway is continuously upregulated under drought stress, which could regulate osmotic pressure and maintain intracellular environmental stability. More secondary metabolites are used to increase glycolysis and tricarboxylic acid cycle, to accelerate energy production and to enhance the glutamic acid-mediated proline biosynthesis pathway, which are necessary to increase osmotic regulation. Prolonged drought stress induced progressive accumulation of compatible osmolytes, such as proline and inositol, sugars, and amino acids. Therefore, drought caused systemic alterations in metabolic networks involving transamination, TCA cycle, gluconeogenesis/glycolysis, glutamate-mediated proline biosynthesis, shikimate-mediated secondary metabolisms, and the metabolism of pyrimidine. These data suggest that plants may utilize these physiological and metabolomic adjustments as adaptive responses in the early stages of drought stress. These results deepen our understanding of the mechanisms involved in P. subulata L. drought tolerance, which will help improve the understanding of drought’s effects on plant systems.

     

Regulation of proline utilization in Salmonella typhimurium: How do cells avoid a futile cycle?

Summary Salmonella typhimurium can degrade proline for use as a carbon, nitrogen, or energy source. To determine whether a futile cycle occurs which degrades the proline accumulated by proline biosynthesis, we studied the expression and enzymatic activity of the proline utilization (put) pathway under conditions which increase the concentration of the intracellular proline pools: catabolism of the dipeptide glycyl-proline, overproduction of proline due to a mutation which prevents feedback inhibition of proline biosynthesis, and accumulation of proline due to osmotic stress. The results indicate that: (i) internal proline induces the put genes, but only when accumulated to concentrations greater than the normal proline biosynthetic pool; and (ii) degradation of proline pools accumulated under high osmotic pressure is limited because proline oxidase is directly inhibited under these conditions.     

Effect of antisense L-Δ1-pyrroline-5-carboxylate reductase transgenic soybean plants subjected to osmotic and drought stress

The potential value of proline accumulation during environmental stressreveals a collection of controversial statements. Some argue that prolineaccumulation is beneficial to the plant, while others suggest the oppositeto be true. It is thus still unknown whether or not a constitutive higherlevel of proline accumulation enhances plant tolerance to environmentalstress. Since proline in plants is synthesised from both glutamic acid andornithine, we generated antisense soybean plants with an L-¹-pyrroline-5-carboxylate reductase (P5CR)gene, as it controls thecommon step of both pathways. The gene expression and consequentlyproline production was manipulated, with the use of an inducible heat shockpromoter (IHSP). The activation of the IHSP resulted in the inactivation ofthe P5CR gene, which resulted in decreased proline synthesis. Theantisense plants have provided us with insight into the correlation betweenproline accumulation, drought and osmotic stress. A mannitol stress at 32and 42 °C enhanced the accumulation of proline in control plants, incontrast to a significant decrease observed in the transformants. Theproline accumulation documented in this paper provides additional evidencethat the increase in proline levels during osmotic stress constitute anadaptive response by the plant. It was confirmed that there is anassociation between P5CR translation and proline accumulation, as theproline accumulation was markedly decreased by the activation of the heatinducible promoter and thus the antisense construct in transformed plants.A woodenbox screening indicated that proline plays a definite role insurvival of soybean plants under a drought stress, the transformantsfailed to survive a 6 day drought stress at 37 °C. This was in contrastwith the control plants which experienced the treatment only as a mildstress.     

Proline in the Osmoregulation of Brevibacterium lactofermentum

Osmoregulation in Brevibacterium lactofermentum was studied. Proline was accumulated up to approximately 35mg/g dry cell weight in the cells of a wild strain of the bacterium grown under osmotic stress. The osmotic tolerance of a proline auxotroph mutant obtained from the bacterium was lower than that in the wild strain. The activity of pyrroline-5-carboxylate reductase, one of the enzymes in the proline biosynthetic pathway, increased about 3-fold when the cells of B. lactofermentum were grown under osmotic stress. These data indicated that proline is important in osmoregulation in the bacterium.     

Nitrogen fixaton in Klebsiella pneumoniae during osmotic stress effect of exogenous proline or a proline overproducing plasmid

Osmotic stress, imposed by 0.5 M NaCl or other electrolytes and non-electrolytes, caused over a 100-fold reduction in the whole-cell nitrogen fixation activity in Klebsiella pneumoniae, wild-type strain M₅A₁. This reduction of nitrogen fixation activity could be reversed by the addition of proline to the culture medium at 0.5 mM concentration. With 0.5 M NaCl, in the presence of proline, nitrogenase activity was 47-fold greater than in the absence of proline. A mutation, originally isolated in Salmonella typhimurium, which resulted in proline over-production and enhanced osmotolerance, was transferred into K. pneumoniae by F′ conjugation. Intracellular proline, synthesized at high levels because of the mutation, had similar stimulatory effects on nitrogen fixation under osmotic stress as proline provided exogenously. In the overproducing strain, the cellular level of proline is elevated as much as 125-fold during stress over that seen in the control strain. To determine the mechanism of stimulation of nitrogen fixaton by proline during stress, the biosynthesis of nitrogenase polypeptides was studied. Net nitrogenase biosynthesis and the biosynthesis of other unidentified peptides, is strongly inhibited during osmotic stress; proline reverses the inhibition. The role of proline in enhancing nitrogen fixation during osmotic stress is discussed.     

Preferential Osmolyte Accumulation: a Mechanism of Osmotic Stress Adaptation in Diazotrophic Bacteria

A common cellular mechanism of osmotic-stress adaptation is the intracellular accumulation of organic solutes (osmolytes). We investigated the mechanism of osmotic adaptation in the diazotrophic bacteria Azotobacter chroococcum, Azospirillum brasilense, and Klebsiella pneumoniae, which are adversely affected by high osmotic strength (i.e., soil salinity and/or drought). We used natural-abundance ¹³C nuclear magnetic resonance spectroscopy to identify all the osmolytes accumulating in these strains during osmotic stress generated by 0.5 M NaCl. Evidence is presented for the accumulation of trehalose and glutamate in Azotobacter chroococcum ZSM4, proline and glutamate in Azospirillum brasilense SHS6, and trehalose and proline in K. pneumoniae. Glycine betaine was accumulated in all strains grown in culture media containing yeast extract as the sole nitrogen source. Alternative nitrogen sources (e.g., NH₄Cl or casamino acids) in the culture medium did not result in measurable glycine betaine accumulation. We suggest that the mechanism of osmotic adaptation in these organisms entails the accumulation of osmolytes in hyperosmotically stressed cells resulting from either enhanced uptake from the medium (of glycine betaine, proline, and glutamate) or increased net biosynthesis (of trehalose, proline, and glutamate) or both. The preferred osmolyte in Azotobacter chroococcum ZSM4 shifted from glutamate to trehalose as a consequence of a prolonged osmotic stress. Also, the dominant osmolyte in Azospirillum brasilense SHS6 shifted from glutamate to proline accumulation as the osmotic strength of the medium increased.