Stress-induced Metabolic Changes Research Articles

Abstract 1027: Mechanical Stress Is A Non-canonical Regulator Of Inflammatory Metabolism In Immune Cells Via Netrin-1

Atherosclerotic cardiovascular disease (CVD) is characterized by chronic inflammation of the artery wall triggered by lipoprotein deposition. Maladaptive immune responses, primarily mediated by macrophages (Mø), promote disease progression including extracellular matrix (ECM) remodeling. Emerging evidence suggests a relationship between cellular mechanics and metabolic programming, yet the role of ECM-induced mechanical stress on Mø immunometabolism remains unexplored. We hypothesized that mechanical stress induces cytoskeletal-mediated rewiring of cellular metabolism that fuels inflammation in plaque macrophages. To investigate the role of matrix-induced mechanical stress on Mø, we used an in vitro system that reproduces the elasticity parameters of the atherosclerotic plaque environment. Compared to stiff matrices, Mø cultured on soft matrices showed marked morphological changes, accompanied by increased inflammation and decreased mitochondrial function as assessed by RNA sequencing and flow cytometry analyses. Notably, cytoskeletal changes were associated with profound mitochondrial network reorganization and increased ROS generation. RNA-seq and ligand-receptor pairing analysis identified the neuroimmune guidance molecule netrin-1 ( Ntn1 ) and its receptor Unc5b as most upregulated in reponse to mechanical stress. Loss-of-function studies showed that netrin-1-deficiency protects from mechanical stress-induced metabolic changes observed in WT Mø, as measured by mitochondrial network remodelling and higher mitochondrial respiration. Importantly, incubation with recombinant netrin-1 reversed the effects of genetic loss of Ntn1 , but not Unc5b , suggesting receptor dependency. Mechanistically, we showed that netrin-1 controls cytoskeletal reorganization via the Rho-associated kinase (ROCK) pathway to alter mitochondrial function, and that ROCK inhibition recapitulated the effect of Ntn1 silencing on mitochondrial potential. Collectively, our data link Ntn1-Uncb mediated changes in cytoskeletal rearrangement to alterations in mitochondrial metabolism that dictate Mø inflammation, and implicate the ECM as a non-canonical regulator of immunometabolism that perpetuates inflammation in CVD.

Role of Promising Secondary Metabolites to Confer Resistance Against Environmental Stresses in Crop Plants: Current Scenario and Future Perspectives.

Plants often face incompatible growing environments like drought, salinity, cold, frost, and elevated temperatures that affect plant growth and development leading to low yield and, in worse circumstances, plant death. The arsenal of versatile compounds for plant consumption and structure is called metabolites, which allows them to develop strategies to stop enemies, fight pathogens, replace their competitors and go beyond environmental restraints. These elements are formed under particular abiotic stresses like flooding, heat, drought, cold, etc., and biotic stress such as a pathogenic attack, thus associated with survival strategy of plants. Stress responses of plants are vigorous and include multifaceted crosstalk between different levels of regulation, including regulation of metabolism and expression of genes for morphological and physiological adaptation. To date, many of these compounds and their biosynthetic pathways have been found in the plant kingdom. Metabolites like amino acids, phenolics, hormones, polyamines, compatible solutes, antioxidants, pathogen related proteins (PR proteins), etc. are crucial for growth, stress tolerance, and plant defense. This review focuses on promising metabolites involved in stress tolerance under severe conditions and events signaling the mediation of stress-induced metabolic changes are presented.

Screening of NaCl salinity sensitivity across eight species of subterranean amphipod genus Niphargus

Secondary salinization of freshwater is becoming a growing environmental problem. Currently, there is few data available on the effects of salinisation on subterranean crustaceans that are vital for the maintenance of groundwater ecosystem functioning. In this study, the sensitivity of subterranean Niphargus amphipods to NaCl was investigated. We expected that cave-dwelling species would be more sensitive as surface-subterranean boundary species. Eight ecologically different Niphargus species were tested: four live at the boundary between the surface and subterranean ecosystems (N. timavi, N. krameri, N. sphagnicolus, N. spinulifemur), three live in cave streams (N. stygius, N. scopicauda, N. podpecanus), and one species (N. hebereri) lives in anchialine caves and wells. The organisms were exposed to five concentrations of NaCl for 96 h and afterwards the immobility, mortality, and electron transfer system (ETS) activity (a measure for metabolic rate of animals) were evaluated. As expected, the most tolerant species was N. hebereri dwelling in naturally high-salinity habitat. However, contrary to our expectations, the species collected at the surface-subterranean boundary were more sensitive as cave stream species when their immobility and mortality were assessed. Interestingly, the majority of Niphargus tested were more NaCl tolerant as can be deduced from currently available data for subterranean and surface crustaceans. We could not observe a clear trend in ETS activity changes between groups of surface-subterranean boundary and cave streams species after exposure to NaCl stress, but it appears that osmotic stress-induced metabolic rate changes are species-specific. This study shows that amphipods Niphargus can be a valuable subterranean environmental research model and further ecotoxicity research is of interest.

An untargeted metabolomic insight into the high-pressure stress effect on the germination of wholegrain Oryza sativa L.

High hydrostatic pressure (HHP) technique is used as a novel abiotic stress factor for efficiently enhancing the biosynthesis of selected bioactive phytochemicals in germinated wholegrain, but the information about HHP stress-induced metabolic changes remains rather limited. Thus, the current work employed an untargeted gas chromatography-mass spectrometry-based metabolomic approach combining with multivariate models to analyze the effect of mild HHP stress (30 MPa/5 min) on the overall metabolome shifts of wholegrain brown rice (WBR) during germination. Simultaneously, major phenolics in germinated WBR (GBR) were detected by ultra-performance liquid chromatography/quadrupole time-of-flight mass spectrometry, to explore the potential relationship between HHP stress-induced rice metabolome alternations and the biotransformation of bioactive components. The results demonstrated that the influence of HHP stress on GBR metabolite profiles was defined by germination durations, as revealed by the differentiation of the stressed grains from the naturally germinated grains at different germination points according to principal component analysis. This was further confirmed by the results of orthogonal projections to latent structures discriminant analysis, in which the discriminating metabolites between naturally germinated and HHP-stressed grains varied across the germination process. The metabolite signatures differentiating natural and HHP-stressed germination included glycerol-3-phosphate, monosaccharides, gamma-aminobutyric acid, 2,3-butanediol, glyceryl-glycoside, amino acids and myo-inositol. Besides, HHP stress led to the increase in ribose, arabinitol, salicylic acid, azelaic acid and gamma-aminobutyric acid, as well as the reduced phenolic acids. These results demonstrated that HHP stress before germination matched with appropriate process parameters could be used as a promising technology to tailor metabolic features of germinated products, thus exerting targeted nutrition and health implications.

Remodeling of Root Growth Under Combined Arsenic and Hypoxia Stress Is Linked to Nutrient Deprivation.

Root architecture responds to environmental stress. Stress-induced metabolic and nutritional changes affect the endogenous root development program. Transcriptional and translational changes realize the switch between stem cell proliferation and cell differentiation, lateral root or root hair formation and root functionality for stress acclimation. The current work explores the effects of stress combination of arsenic toxicity (As) and hypoxia (Hpx) on root development in Arabidopsis thaliana. As revealed previously, combined As and Hpx treatment leads to severe nutritional disorder evident from deregulation of root transcriptome and plant mineral contents. Both As and Hpx were identified to pose stress-specific constraints on root development that lead to unique root growth phenotype under their combination. Besides inhibition of root apical meristem (RAM) activity under all stresses, As induced lateral root growth while root hair density and lengths were strongly increased by Hpx and HpxAs-treatments.A dual stimulation of phosphate (Pi)-starvation response was observed for HpxAs-treated plant roots; however, the response under HpxAs aligned more with Hpx than As. Transcriptional evidence along with biochemical data suggests involvement of PHOSPHATE STARVATION RESPONSE 1; PHR1-dependent systemic signaling. Pi metabolism-related transcripts in close association with cellular iron homeostasis modulate root development under HpxAs. Early redox potential changes in meristematic cells, differential ROS accumulation in root hair zone cell layers and strong deregulation of NADPH oxidases, NADPH-dependent oxidoreductases and peroxidases signify a role of redox and ROS signaling in root architecture remodeling under HpxAs. Differential aquaporin expression suggests transmembrane ROS transport to regulate root hair induction and growth. Reorganization of energy metabolism through NO-dependent alternate oxidase, lactate fermentation, and phosphofructokinase seems crucial under HpxAs. TOR and SnRK-signaling network components were potentially involved in control of sustainable utilization of available energy reserves for root hair growth under combined stress as well as recovery on reaeration. Findings are discussed in context of combined stress-induced signaling in regulation of root development in contrast to As and Hpx alone.

Salt stress induces physiochemical alterations in rice grain composition and quality.

Salinity has drastic effects on plant growth and productivity and is one of the major factors responsible for crop yield losses throughout the agricultural soils of the world. The mechanisms of salinity tolerance in plants are regulated by a set of inherent multigenes and prevalent environmental factors, which bring about a myriad of metabolic changes in each plant part. The stress-induced metabolic changes in the rice plant have been intensively studied, but extensively in plant parts such as stem, leaf, and root. However, little information exists in the literature about such stress-induced architectural and physiological changes in rice grain, a premier staple food of a large proportion of human population. Thus, the current review comprehensively describes the effects of salinity stress on rice grain composition including changes in carbohydrate, protein, fat, and mineral contents. Elucidation of salinity induced changes in rice grain composition would help to understand whether or not a nutritious and healthy staple food is available to human population from rice grown under saline environments.

Exercise intensity regulates the effect of heat stress on substrate oxidation rates during exercise

Hyperthermia stimulates endogenous carbohydrate metabolism during exercise; however, it is not known if exercise intensity impacts the metabolic effect of heat stress. In the first study of this two-part investigation, endurance-trained male cyclists performed incremental exercise assessments in 18 and 35°C (60% rH). The stimulatory effect of heat stress on carbohydrate oxidation rates was greater at high vs. moderate vs. low relative intensity (P < 0.05). In agreement, no effects of heat stress on carbohydrate oxidation rates were observed during 60-min of subsequent low-intensity cycling. In study two, endurance-trained male cyclists performed 20-min of moderate-intensity (power at the first ventilatory threshold) and 5-min of high-intensity (power at the second ventilatory threshold) cycling in 18, 28, 34, and 40°C (60% rH). At moderate-intensity, carbohydrate oxidation rates were significantly elevated by heat stress in 40°C (P < 0.05), whereas at high-intensity carbohydrate oxidation rates were significantly elevated by heat stress in 34 and 40°C (P < 0.05). This exercise intensity-mediated regulation of the effect of heat stress on carbohydrate oxidation may be partially attributable to observed plasma adrenaline responses. Our data suggest that under moderate environmental heat stress (34–35°C, 60% rH), heat stress-induced changes in CHO oxidation rates are unlikely to occur unless the relative exercise intensity is high (81 ± 8%⩒O2max), whereas under more extreme environmental heat stress (40°C, 60% rH), these changes occur at lower relative intensities (69 ± 8%⩒O2max). This provides indication of when heat stress-induced metabolic changes during exercise are likely to occur.

FT-IR profiling reveals differential response of roots and leaves to salt stress in a halophyte Sesuvium portulacastrum (L.) L.

In a halophyte, Sesuvium portulacastrum (L.) L., we have applied Fourier Transform InfraRed (FT-IR) spectroscopy to detect the corresponding changes associated with salt-induced physiological changes under long- term treatment with 0, 100 and 500 mM NaCl. FT-IR profiles showed changes in chemical composition and functional groups of proteins, lipids and carbohydrates due to salt treatments, evident as differential FT-IR profiles in both roots and leaves specific to these metabolites. Further, the Principle Component Analysis (PCA) was applied to identify the main sources of variation in FT-IR data due to differential treatment. In PCA, the PC1 showed 85.55% and PC2 showed 18.18% variability in data and confirmed differential response of root and leaves to salt treatment in Sesuvium. The results suggest that FT-IR spectrometry can be used to study stress-induced metabolic changes in plants in relation to their salt tolerance.

Impact of pulsed UV-B stress exposure on plant performance: How recovery periods stimulate secondary metabolism while reducing adaptive growth attenuation.

Upon continuous stress exposure, plants display attenuated metabolic stress responses due to regulatory feedback loops. Here, we have tested the hypothesis that pulsed stress exposure with intervening recovery periods should affect these feedback loops, thereby causing increased accumulation of stress-induced metabolites. The response of Arabidopsis plantlets to continuous UV-B exposure (Cuv ) was compared with that of pulsed UV-B exposure (Puv ). The differential responses to Puv versus Cuv were monitored at the level of gene expression and metabolite accumulation, using wild type (WT) and different mutant lines. In comparison with Cuv , Puv increased sinapyl and flavonol (S+F) content, whereas adaptive growth attenuation was reduced. Furthermore, in a myb4 mutant (AtMYB4, repressor-type R2R3-MYB transcription factor), the S+F content was increased only for Cuv , but not beyond the level for Puv observed in WT. These observations and the ability of AtMYB4 to repress AtMYB12/AtMYB111-mediated activation of target gene promoters (pCHS and pFLS) indicate that the increase of S+F content after Puv observed in WT plants results from reduced feedback inhibition by AtMYB4. The results support the notion that stress-induced metabolic changes not necessarily cause a growth penalty. Furthermore, the observed Puv -induced increase in flavonol accumulation may stimulate reevaluation of commercial plant production practices.

Abscisic acid, cold and salt stimulate conserved metabolic regulation in the moss Physcomitrella patens.

Salt and cold are major abiotic stresses that have adverse effects on plant growth and development. To cope with these stresses and their detrimental effects plants have evolved several metabolic, biochemical and physiological processes that are mainly triggered and mediated by the plant hormone abscisic acid (ABA). To elucidate the metabolic responses of the moss Physcomitrella patens, which serves as a model plant for abiotic stress adaptation, we performed GC-MS-based metabolic profiling of plants challenged for 5 and 28h with either salt, cold or ABA. Our results indicate significant changes in the accumulation of several sugars including maltose, isomaltose and trehalose, amino acids including arginine, histidine, ornithine, tryptophan and tyrosine, and organic acids mainly citric acid and malonic acid. The metabolic responses provoked by ABA, cold and salt show considerable similarities. The accumulation of certain metabolites positively correlates with gene expression data whereas some metabolites do not show correlation with cognate transcript abundance. To place our results into an evolutionary context we compared the ABA- and stress-induced metabolic changes in moss to available metabolic profiles of the seed plant Arabidopsis thaliana. We detected considerable conservation between the species, indicating early evolution of stress-associated metabolic adaptations that probably occurred at the plant water-to-land transition.

The multiple adrenocorticotropic hormone injections significantly alters hepatic proteome in growing pigs

Currently, the effects of stress on the body metabolism are attracting more and more attentions. To better understand the probable stress-induced metabolic changes, the changes in plasma indices and hepatic proteome were investigated in pigs fitted with jugular venous catheters administered adrenocorticotropic hormone (ACTH), intramuscularly twice daily for 7 days. In particular, plasma hormones, blood cells and biochemical indicators were analyzed. In addition, the hepatic proteome was analyzed by two-dimensional electrophoresis and matrix-assisted laser desorption ionization time of flight mass spectrometry. The results revealed that after the initial ACTH injection, plasma ACTH, cortisol, triiodothyronine and tumor necrosis factor α increased (P ˂ 0.05). Additionally, lactic dehydrogenase activity increased (P < 0.05), and both leukocyte and lymphocyte count decreased (P < 0.05). In comparison, after the ACTH injection for 7 days, hepatic proteomics analysis identified 27 significantly changed proteins and most of these proteins (49%) are involved in metabolism, but plasma indices showed no obvious change. In conclusion, compared with the obvious changes in plasma indices after the initial ACTH injection, the multiple ACTH injections did not change plasma indices, yet the hepatic proteome profile was significantly altered. The results provide useful information for a better understanding of the effects of stress on metabolism.

Ultrastructural study of tumor-infiltrating СD4+ Т-lymphocytes in colon cancer.

e23074 Background: The purpose of the study was to assess stress-induced metabolic changes in СD4+ T-lymphocytes among tumor-infiltrating lymphocytes (TILs) according to ultrastructural morphometric parameters. Methods: Samples (n = 12) of colon adenocarcinoma, corresponding resection line tissues and blood of patients and healthy donors were studied. After grinding the samples and PBMC isolation using the density gradient, CD4+ T-lymphocytes separation with magnetic columns was performed using CD4 MicroBeads, human (MACS Miltenyi Biotech). The pellet obtained after centrifugation was embedded in agarose and prepared for transmission electron microscopy. Mitochondria images on ultrathin sections of Т-lymphocytes were randomly selected for the analysis. The total number of mitochondria studied were 71 (tumor), 78 (normal tissue), 78 (blood of patients), 80 (blood of healthy donors). For each image the unchanged cristae area was determined as a percentage of the total area of mitochondria cross section. Results: We found no differences in the structures of mitochondria of blood lymphocytes in patients and in healthy donors. Comparison of parameters of CD4+ Т-lymphocyte mitochondria in the colon unchanged tissues and in the blood of patients did not show significant differences indicating minimal damage during TILs` isolation from the tissues. Electron microscopy of TILs derived from tumor tissue showed more frequent apoptotic and necrotic death of lymphocytes, as well as some mitochondrial swelling with changes in the shape and the number of cristae compared to the norm. Statistical analysis revealed significant decrease in the relative area of unchanged cristae: 57% in tumor against 73% in the normal tissue (p &lt; 0.0001, χ2Test). Conclusions: The results suggest that stress-induced changes are developed in tumor-infiltrating CD4+ T-lymphocytes, and these changes apparently enhance their death as demonstrated by ultrastructural characteristics of mitochondria.

Temporary amygdala inhibition reduces stress effects in female mice

The current study investigated the effect of temporary inhibition of amygdala in response to metabolic changes caused by stress in female mice. Unilateral and bilateral amygdala cannulation was carried out, and after a week of recovery, 2% lidocaine hydrochloride was injected into the mice amygdalae five minutes before the induction of stress. A communication box was employed to induce stress for four consecutive days and plasma corticosterone, food and water intake, weight changes, and anorexia were measured as stress-induced metabolic changes. Results demonstrated that stress, increases stress, increased plasma corticosterone concentrations, weight, food, and water intake. Temporary inhibition of the amygdala slightly decreased plasma corticosterone concentrations, but did not fully reduce the effect of stress. The bilateral injection of lidocaine hydrochloride to the amygdala reduced the effect of stress and reduced water intake and weight. Unilateral injection of lidocaine hydrochloride into the left and right amygdala reduced food intake. In conclusion, the present study demonstrated that the left side and right side of amygdala nuclei play a different role in metabolic responses in stress.

Effect of Temporary Inactivation of Nucleus Accumbens on Chronic Stress Induced by Electric Shock to the Sole of the Foot in Female NMRI Mice

BACKGROUND AND OBJECTIVE: Activity changes in the neurons of nucleus accumbens during stress have been previously identified. However, the role of nucleus accumbens in diminishing stress-induced side-effects is not fully understood. In this study, we aimed to evaluate the effects of temporary inactivation of nucleus accumbens on stressinduced metabolic changes in female mice. METHODS: This experimental study was performed on 48 female NMRI mice with an average 27±3 g. The nucleus accumbens was unilaterally and bilaterally cannulated. After one week of recovery, 2% lidocaine or saline was administered in mice for four consecutive days (5 min per day) before inducing electric shock to the sole of the foot. Plasma corticosterone level, food and water intake, and delay in eating were assessed as stress-induced metabolic parameters. FINDINGS: Stress lonely, caused an increase in plasma corticosterone (17±0.8) compared with the control group (4.5±0.3) (p<0.001). It also, caused an increase delay in eating (%218±9.8, p<0.01) and, decrease water (%80±4.5) and food (%84±5.5) intake (p<0.05). Temporary inactivation of nucleus accumbens did not affect the stress-induced changes in plasma corticosterone, and it suppressed the effect of stress on the amount of water intake; inactivation of the left nucleus accumbens was more effective (%195±7.6, p<0.01). Temporary inactivation of nucleus accumbens neutralized the effect of stress on the amount of food intake. Temporary inactivation of the right nucleus accumbens augmented the effect of stress on delay in eating (%264±10.8, p<0.01), and inactivation of the left nucleus accumbens could suppress this effect. CONCLUSION: It seems that temporary inactivation of nucleus accumbens can be effective in diminishing stressinduced metabolic changes. However, this influence is indicative of asymmetry in the function of right and left nucleus

FT-Raman spectroscopy as a tool in evaluation the response of plants to drought stress

Abstract The aim of study was to evaluate the usefulness of FT-Raman spectroscopy in assessing stress-induced metabolic changes in plants. 20-d-old optimally watered plants of soybean were exposed to drought. Metabolic changes in optimally watered and drought-stressed plants were monitored using FT-Raman spectroscopy. In parallel, analyses were carried out of fatty acid composition and pigment content using analytical methods. These compounds are associated with the response of plants to environmental stress. While fatty acid assays in study were inconclusive, the pigment content analysis gave promising results. FT-Raman experiment demonstrated a decrease in carotenoid content in leaf, as a result of drought, which was confirmed by spectrophotometric analysis. In addition to the analysis of aforementioned compounds, FT-Raman spectroscopy allowed the simultaneous observation of a wider spectrum of compounds scattering the radiation in the leaves tested, and their subsequent comparative analysis. The impact of drought on metabolism of soybean was clearly visible on spectra and confirmed using cluster analysis. The technical problem of the influence of leaf water content on measurements, which appeared in studies, will be discussed. To conclude, FT-Raman spectroscopy may be a good complement to other non-invasive methods, e.g., fluorescent methods, in assessing the stress-induced damage of crops.

Fast responses of metabolites in Vicia faba L. to moderate NaCl stress

Salt stress impairs global agricultural crop production by reducing vegetative growth and yield. Despite this importance, a number of gaps exist in our knowledge about very early metabolic responses that ensue minutes after plants experience salt stress. Surprisingly, this early phase remains almost as a black box. Therefore, systematic studies focussing on very early plant physiological responses to salt stress (in this case NaCl) may enhance our understanding on strategies to develop crop plants with a better performance under saline conditions. In the present study, hydroponically grown Vicia faba L. plants were exposed to 90 min of NaCl stress, whereby every 15 min samples were taken for analyzing short-term physiologic responses. Gas chromatography–mass spectrometry-based metabolite profiles were analysed by calculating a principal component analysis followed by multiple contrast tests. Follow-up experiments were run to analyze downstream effects of the metabolic changes on the physiological level. The novelty of this study is the demonstration of complex stress-induced metabolic changes at the very beginning of a moderate salt stress in V. faba, information that are very scant for this early stage. This study reports for the first that the proline analogue trans-4-hydroxy-l-proline, known to inhibit cell elongation, was increasingly synthesized after NaCl-stress initiation. Leaf metabolites associated with the generation or scavenging of reactive oxygen species (ROS) were affected in leaves that showed a synchronized increase in ROS formation. A reduced glutamine synthetase activity indicated that disturbances in the nitrogen assimilation occur earlier than it was previously thought under salt stress.

Abstract 4335: A p53/HIF-1alpha-mediated metabolic response to stress

Abstract p53 is a key player in the cellular stress response. Apart from its canonical role in cell checkpoint functions, p53 also regulates cellular metabolism by blocking glycolysis and promoting oxidative phosphorylation. The hypoxia-inducible factor 1(HIF-1), on the other hand, is a master transcription factor promoting glycolysis. We describe a previously unrecognized metabolic response to low levels of stress, including low doses of ionizing radiation or arsenic. By using an integrated approach, we demonstrate that low-level stress induces a metabolic shift from oxidative phosphorylation to aerobic glycolysis leading to increased stress tolerance in both cell and animal models. Low-level stress-induced metabolic changes are mediated by a functional cooperation between p53 and HIF-1α. Our work provides a novel metabolic mechanism of the stress response. Citation Format: Suthakar Ganapathy, Zhi-Min Yuan. A p53/HIF-1alpha-mediated metabolic response to stress. [abstract]. In: Proceedings of the 105th Annual Meeting of the American Association for Cancer Research; 2014 Apr 5-9; San Diego, CA. Philadelphia (PA): AACR; Cancer Res 2014;74(19 Suppl):Abstract nr 4335. doi:10.1158/1538-7445.AM2014-4335

Stress-Induced Changes in Wheat Grain Composition and Quality

Abiotic stresses such as drought, salinity, waterlogging, and high temperature cause a myriad of changes in the metabolism of plants, and there is a lot of overlap in these changes in plants in response to different stresses such as drought and salinity. These stress-induced metabolic changes cause impaired crop growth thereby resulting in poor yield. The metabolic changes taking place in several plant species due to a particular abiotic stress have been revealed from the whole plant to the molecular level by researchers, but most studies have focused on organs such as leaf, stem, and root. Information on such stress-induced changes in seed or grains is infrequent in the literature. From the information that is available, it is now evident that abiotic stress can induce considerable changes in the composition and quality of cereal grains including those of wheat, the premier staple food crop in the world. Thus, the present review discusses how far different types of stresses, mainly salinity, drought, high temperature, and waterlogging, can alter the wheat grain composition and quality. By fully uncovering the stress-induced changes in the nutritional values of wheat grains it would be possible to establish whether balanced supplies of essential nutrients are available to the human population from the wheat crop grown on stress-affected areas.

Drought, salt, and temperature stress-induced metabolic rearrangements and regulatory networks.

Plants regularly face adverse growth conditions, such as drought, salinity, chilling, freezing, and high temperatures. These stresses can delay growth and development, reduce productivity, and, in extreme cases, cause plant death. Plant stress responses are dynamic and involve complex cross-talk between different regulatory levels, including adjustment of metabolism and gene expression for physiological and morphological adaptation. In this review, information about metabolic regulation in response to drought, extreme temperature, and salinity stress is summarized and the signalling events involved in mediating stress-induced metabolic changes are presented.

Characteristic properties of metabolism of the yeast Yarrowia lipolytica during the synthesis of α-ketoglutaric acid from ethanol

The study of free amino acid content in Yarrowia lipolytica cells grown on ethanol under thiamine deficiency showed that glutamate, alanine, and γ-aminobutyric acid (γ-ABA) occurred in the highest concentrations among the present 17 free amino acids. The culture liquid contained no amino acids. Analysis of the enzymes of oxidative metabolism in the yeast grown under these conditions showed that the cell-free homogenate contained substantial activity of glutamate decarboxylase, γ-ABA transaminase, and succinyl semialdehyde dehydrogenase. This result indicated the formation of succinate from glutamate in a reaction catalyzed by 4-aminobutyrate aminotransferase (γ-aminobutyrate bypass) under severe thiamine deficiency. These studies lead to the conclusion that cultivation of the yeast Y. lipolytica on ethanol under thiamine deficiency causes adaptive stress-induced metabolic changes. Increase of ammonium nitrogen consumption and excretion of α-ketoglutaric acid are indicative of physiological changes, the functioning of the γ-aminobutyrate bypass and high activity of malate dehydrogenase are manifestations of metabolic changes, and increased activities of the transamination reactions reflect the changes in nitrogen metabolism.