DNA strand breaks and DNA repair response in lymphocytes after chronic in vivo exposure to very low doses of ionizing radiation in mice

In contrast to the well-documented negative effects of high-dose oxidant exposure, accumulating evidence supports a positive, perhaps essential physiologic role for very low-level oxidant stress. For example, low-level oxidant exposure, within or below the physiologic range, has been reported to stimulate membrane signal transduction, proliferation, antioxidant defense and DNA repair. In the present study, we have examined whether whole-body exposure to low-dose radiation (LDR) results in an alteration in constitutive (steady state) levels of DNA-strand breaks and whether an adaptive increase in DNA-repair response is induced. C57B1/6J mice were exposed to 0.04 Gy (4 cGy) of gamma-radiation as a model of low level oxidant stress. End points measured after chronic in vivo LDR included: (1) constitutive expression of DNA-strand breaks in quiescent spleen cells; (2) sensitivity to DNA damage after high-dose radiation exposure in vitro; (3) repair of constitutive and radiation-induced DNA strand breaks after mitogen stimulation: (4) activity of the DNA-repair associated enzyme, poly(ADP-ribose)transferase (ADPRT) and its substrate, NAD. The results indicated that the constitutive expression of DNA-strand breaks is significantly decreased after chronic LDR; however, DNA-repair capacity after high-dose radiation exposure is not increased above that observed in sham-irradiated mice. Associated with the reduction in constitutive DNA-strand break accumulation was a decrease in resting levels of the DNA-repair-associated enzyme poly(ADP-ribose) transferase (ADPRT). These results are consistent with the interpretation that cumulative DNA damage and associated DNA-repair activity in unstimulated cells are both reduced after chronic LDR exposure.     

Integrated tolerance mechanisms: constitutive and adaptive plant responses to elevated metal concentrations in the environment

Isolation and study of metal tolerant and hypersensitive strains of higher plant (and yeast) species has greatly increased our knowledge of the individual pathways that are involved in tolerance. Plants have both constitutive (present in most phenotypes) and adaptive (present only in tolerant phenotypes) mechanisms for coping with elevated metal concentrations. Where studies on the mechanisms of tolerance fall down is in their failure to integrate tolerance mechanisms within cell or whole-plant function by not relating adaptive mechanisms to constitutive mechanisms. This failure often distorts the relative importance of a proposed tolerance mechanism, and indeed has confused the search for adaptive mechanisms. The fundamental goal of both constitutive and adaptive mechanisms is to limit the perturbation of cell homeostasis after exposure to metals so that normal or near-normal physiological function may take place. Consideration of the response to metals at a cellular rather than a biochemical level will lead to a greater understanding of mechanisms to withstand elevated levels of metals in both contaminated and uncontaminated environments. Recent advances in the study of Al, As, Cd, and Cu tolerance and hypersensitivity are reported with respect to the cellular response to toxic metals. The role of genetics in unravelling tolerance mechanisms is also considered.     

Transcriptional changes associated with ethanol tolerance in Saccharomyces cerevisiae

Saccharomyces spp. are widely used for ethanol production; however, fermentation productivity is negatively affected by the impact of ethanol accumulation on yeast metabolic rate and viability. This study used microarray and statistical two-way ANOVA analysis to compare and evaluate gene expression profiles of two previously generated ethanol-tolerant mutants, CM1 and SM1, with their parent, Saccharomyces cerevisiae W303-1A, in the presence and absence of ethanol stress. Although sharing the same parentage, the mutants were created differently: SM1 by adaptive evolution involving long-term exposure to ethanol stress and CM1 using chemical mutagenesis followed by adaptive evolution-based screening. Compared to the parent, differences in the expression levels of genes associated with a number of gene ontology categories in the mutants suggest that their improved ethanol stress response is a consequence of increased mitochondrial and NADH oxidation activities, stimulating glycolysis and other energy-yielding pathways. This leads to increased activity of energy-demanding processes associated with the production of proteins and plasma membrane components, which are necessary for acclimation to ethanol stress. It is suggested that a key function of the ethanol stress response is restoration of the NAD⁺/NADH redox balance, which increases glyceraldehyde-3-phosphate dehydrogenase activity, and higher glycolytic flux in the ethanol-stressed cell. Both mutants achieved this by a constitutive increase in carbon flux in the glycerol pathway as a means of increasing NADH oxidation.     

Repair of platinum-DNA lesions in E. coli by a pathway which does not recognize DNA damage caused by MNNG or UV light

The adaptive response is an inducible DNA-repair system which diminishes the mutagenic and toxic effects of alkylating agents. A mutant of E. coli constitutive for adaptative repair, BS21, has been isolated. A spontaneous revertant of this strain, BS23, lacks the adaptive response. When compared to its wild-type parent, mutant BS21 showed an increased resistance to the killing and mutagenic effects of a compound which is not a classical alkylating agent, the antitumor drug cis-diamminedichloroplatinum(II) (cis-DDP). However, this resistance to cis-DDP was also found in strain BS23 which lacks the adaptive response. cis-DDP bound to the DNA of all 3 strains with the same efficiency. In addition, we have investigated the effect of UV radiation and we failed to observe a significant difference in the survival and mutagenesis of these strains. This evidence suggests that the resistance of BS21 and BS23 strains to cis-DDP is not a consequence of the adaptive response or increased excision repair.     

Mouse splenic macrophage cell lines with different antigen-presenting activities for CD4+ helper T cell subsets and allogeneic CD8+ T cells.

A panel of seven mouse splenic macrophage cell lines, derived from cloned progenitors, was compared for their ability to present antigen to Th1 or Th2 helper T cell lines and hybridomas, as well as to naive T cells, and to provide accessory cell function for the synthesis of antibody from primed B cells. One of the cell lines expressed MHC class II molecules and was the only line with constitutive antigen-presenting activity for Th1 cells. It may represent a subset of splenic macrophages responsible for the activation of naive Th1 helper cells in situ. The remaining six cell lines responded to INF-gamma by up-regulating their class II expression and acquiring Th1 antigen-presenting activity. They may represent cells which, in situ, lack constitutive antigen-presenting activity but are promoted to presenting status by Th1-derived INF-gamma. Five of the cell lines provided accessory cell function to Th2 cells, as indicated by antibody synthesis in suspensions of spleen cells from primed mice depleted of their antigen-presenting cells. One of the cell lines lacking accessory cell activity had constitutive antigen-presenting activity for Th1 cells. This reciprocal expression of antigen-presenting activity supports the idea that Th1 and Th2 helper cells are activated by different antigen-presenting cells. Finally, the cell lines differed in their ability to constitutively induce an allogeneic response; a response that was limited to CD8+ T cells occurred in a CD4+ helper cell-independent manner and was unaffected by the addition of INF-gamma. The alloantigen-presenting macrophage cell lines also possessed the most efficient accessory cell activity for antibody synthesis. These cell lines, which represent a spectrum of antigen-presenting activities in the spleen afford models for defining the roles of macrophages in the induction of immune responses and for resolving issues concerning their development.     

The adaptive acid response in Mesorhizobium sp.

Mesorhizobium huakuii strain LL56 and Mesorhizobium sp. strain LL22, which nodulate Lotus glaber, developed an adaptive acid response during exponential growth upon exposure to sublethal acid conditions. The adaptive acid response was found to be dependent on the sublethal pH and the strain intrinsic acid tolerance: the lowest adaptation pH was 4.0 for strain LL56 and 5.7 for strain LL22, and the lowest pH values tolerated after adaptation were 3.0 and 4.0, respectively. Both complex and minimal medium allowed the development of the adaptive acid response, although in complex medium this response was more effective. Three low molecular weight polypeptides (LMWPs) showed increased expression in strain LL56 during the adaptation to pH 4.0. However, the adaptive acid tolerance was only partially dependent on de novo protein synthesis, and constitutive systems may play a significant role on the acid tolerance of Mesorhizobium huakuii strain LL56.     

Mutations in the Ca2+/H+ transporter CAX1 increase CBF/DREB1 expression and the cold-acclimation response in Arabidopsis

Transient increases in cytosolic free calcium concentration ([Ca2+]cyt) are essential for plant responses to a variety of environmental stimuli, including low temperature. Subsequent reestablishment of [Ca2+]cyt to resting levels by Ca2+ pumps and antiporters is required for the correct transduction of the signal [corrected]. C-repeat binding factor/dehydration responsive element binding factor 1 (Ca2+/H+) antiporters is required for the correct transduction of the signal. We have isolated a cDNA from Arabidopsis that corresponds to a new cold-inducible gene, rare cold inducible4 (RCI4), which was identical to calcium exchanger 1 (CAX1), a gene that encodes a vacuolar Ca2+/H+ antiporter involved in the regulation of intracellular Ca2+ levels. The expression of CAX1 was induced in response to low temperature through an abscisic acid-independent pathway. To determine the function of CAX1 in Arabidopsis stress tolerance, we identified two T-DNA insertion mutants, cax1-3 and cax1-4, that display reduced tonoplast Ca2+/H+ antiport activity. The mutants showed no significant differences with respect to the wild type when analyzed for dehydration, high-salt, chilling, or constitutive freezing tolerance. However, they exhibited increased freezing tolerance after cold acclimation, demonstrating that CAX1 plays an important role in this adaptive response. This phenotype correlates with the enhanced expression of CBF/DREB1 genes and their corresponding targets in response to low temperature. Our results indicate that CAX1 ensures the accurate development of the cold-acclimation response in Arabidopsis by controlling the induction of CBF/DREB1 and downstream genes.     

STIM1 holds a STING in its (N-terminal) tail

The Ca²⁺ sensor STIM1 is essential for adaptive immune responses, yet patients with hypomorphic STIM1 mutations develop both immunodeficiency and autoimmunity, implying that STIM1 also restrains immune responses. This study by Srikanth et al demonstrates that STIM1 tethers STING, a major inducer of the interferon (IFN) response, to the endoplasmic reticulum (ER) to prevent constitutive STING activation.     

MEKK1 is required for flg22-induced MPK4 activation in Arabidopsis plants

The Arabidopsis (Arabidopsis thaliana) gene MEKK1 encodes a mitogen-activated protein kinase kinase kinase that has been implicated in the activation of the map kinases MPK3 and MPK6 in response to the flagellin elicitor peptide flg22. In this study, analysis of plants carrying T-DNA knockout alleles indicated that MEKK1 is required for flg22-induced activation of MPK4 but not MPK3 or MPK6. Experiments performed using a kinase-impaired version of MEKK1 (K361M) showed that the kinase activity of MEKK1 may not be required for flg22-induced MPK4 activation or for other macroscopic FLS2-mediated responses. MEKK1 may play a structural role in signaling, independent of its protein kinase activity. mekk1 knockout mutants display a severe dwarf phenotype, constitutive callose deposition, and constitutive expression of pathogen response genes. This dwarf phenotype was largely rescued by introduction into mekk1 knockout plants of either the MEKK1 (K361M) construct or a nahG transgene that degrades salicylic acid. When treated with pathogenic bacteria, the K361M plants were slightly more susceptible to an avirulent strain of Pseudomonas syringae and showed a delayed hypersensitive response, suggesting a role for MEKK1 kinase activity in this aspect of plant disease resistance. Our results indicate that MEKK1 acts upstream of MPK4 as a negative regulator of pathogen response pathways, a function that may not require MEKK1's full kinase activity.     

Mitochondrial autophagy is an HIF-1-dependent adaptive metabolic response to hypoxia

Autophagy is a process by which cytoplasmic organelles can be catabolized either to remove defective structures or as a means of providing macromolecules for energy generation under conditions of nutrient starvation. In this study we demonstrate that mitochondrial autophagy is induced by hypoxia, that this process requires the hypoxia-dependent factor-1-dependent expression of BNIP3 and the constitutive expression of Beclin-1 and Atg5, and that in cells subjected to prolonged hypoxia, mitochondrial autophagy is an adaptive metabolic response which is necessary to prevent increased levels of reactive oxygen species and cell death.     

Intrinsic tyrosine kinase activity is required for vascular endothelial growth factor receptor 2 ubiquitination, sorting and degradation in endothelial cells

The human endothelial vascular endothelial growth factor receptor 2 (VEGFR2/kinase domain region, KDR/fetal liver kinase-1, Flk-1) tyrosine kinase receptor is essential for VEGF-mediated physiological responses including endothelial cell proliferation, migration and survival. How VEGFR2 kinase activation and trafficking are co-coordinated in response to VEGF-A is not known. Here, we elucidate a mechanism for endothelial VEGFR2 response to VEGF-A dependent on constitutive endocytosis co-ordinated with ligand-activated ubiquitination and proteolysis. The selective VEGFR kinase inhibitor, SU5416, blocked the endosomal sorting required for VEGFR2 trafficking and degradation. Inhibition of VEGFR2 tyrosine kinase activity did not block plasma membrane internalization but led to endosomal accumulation. Lysosomal protease activity was required for ligand-stimulated VEGFR2 degradation. Activated VEGFR2 codistributed with the endosomal hepatocyte growth factor-regulated tyrosine kinase substrate (Hrs)/signal-transducing adaptor molecule (STAM) complex in a ligand and time-dependent manner, implying a role for this factor in sorting of ubiquitinated VEGFR2. Increased tyrosine phosphorylation of the Hrs subunit in response to VEGF-A links VEGFR2 activation and Hrs/STAM function. In contrast, VEGFR2 in quiescent cells was present on both the endothelial plasma membrane and early endosomes, suggesting constitutive recycling between these two compartments. This pathway was clathrin-linked and dependent on the AP2 adaptor complex as the A23 tyrphostin inhibited VEGFR2 trafficking. We propose a mechanism whereby the transition of endothelial VEGFR2 from a constitutive recycling itinerary to a degradative pathway explains ligand-activated receptor degradation in endothelial cells. This study outlines a mechanism to control the VEGF-A-mediated response within the vascular system.     

A simplified approach to quasi-linear viscoelastic modeling

The fitting of quasi-linear viscoelastic (QLV) constitutive models to material data often involves somewhat cumbersome numerical convolution. A new approach to treating quasi-linearity in 1-D is described and applied to characterize the behavior of reconstituted collagen. This approach is based on a new principle for including nonlinearity and requires considerably less computation than other comparable models for both model calibration and response prediction, especially for smoothly applied stretching. Additionally, the approach allows relaxation to adapt with the strain history. The modeling approach is demonstrated through tests on pure reconstituted collagen. Sequences of "ramp-and-hold" stretching tests were applied to rectangular collagen specimens. The relaxation force data from the "hold" was used to calibrate a new "adaptive QLV model" and several models from literature, and the force data from the "ramp" was used to check the accuracy of model predictions. Additionally, the ability of the models to predict the force response on a reloading of the specimen was assessed. The "adaptive QLV model" based on this new approach predicts collagen behavior comparably to or better than existing models, with much less computation.     

Dealing with the genotype x environment interaction via a modelling approach: a comparison of QTLs of maize leaf length or width with QTLs of model parameters

Quantitative genetics of adaptive traits is made difficult by the genotypexenvironment interaction. A classical assumption is that QTLs identified in both stressed and control conditions correspond to constitutive traits whereas those identified only in stressed treatments are stress-specific and correspond to adaptive traits. This hypothesis was tested by comparing, in the same set of experiments, two ways of analysing the genetic variability of the responses of maize leaf growth to water deficit. One QTL detection was based on raw phenotypic traits (length and width of leaf 6) of 100 recombinant inbred lines (RILs) in four experiments with either well-watered or stressing conditions in the field or in the greenhouse. Another detection followed a method proposed recently which consists of analysing intrinsic responses of the same RILs to environmental conditions, determined jointly over several experiments. QTLs of three responses were considered: (i) leaf elongation rate per unit thermal time in the absence of stress, (ii) its response to evaporative demand in well-watered plants, and (iii) its response to soil water status in the absence of evaporative demand. The QTL of leaf length differed between experiments, but colocalized in seven cases out of 13 with QTLs of the intrinsic leaf elongation rate, even in experiments with stressing conditions. No colocalization was found between QTLs of leaf length under water deficit and QTLs of responses to air or soil water status. By contrast, QTLs of leaf width colocalized in all experiments, regardless of environmental conditions. The classical method of identifying the QTL of constitutive versus adaptive traits therefore did not apply to the experiments presented here. It is suggested that identification of the QTL of parameters of response curves provides a promising alternative for dealing with the genetic variability of adaptive traits.     

Heat shock modulates phosphorylation status and activity of nucleoside diphosphate kinase in cultured sugarcane cells

Nucleoside diphosphate kinase (NDPK) is involved in the regeneration of nucleoside triphosphates (NTPs) through its phosphotransferase activity via an autophosphorylating histidine residue. Additionally, autophosphorylation of serine and/or threonine residues is documented for NDPKs from various organisms. However, the metabolic significance of serine/threonine phosphorylation has not been well characterized. In this study we report the cloning and characterization of NDPKI from cultured sugarcane (Saccharum officinarum L. line H50-7209) cells, and modulation of serine autophosphorylation of NDPK1 in response to heat-shock (HS). Heat-shock treatment at 40°C for 2 h resulted in a 40% reduction in labeled phosphoserine in NDPK1. This dephosphorylation was accompanied by an increase in NDPK enzyme activity. In contrast, NDPK1 in cultured tobacco (cv. W-38) cells did not show changes in autophosphorylation or increased enzyme activity in response to HS. The mRNA or protein level of NDPK1 did not increase in response to HS. Sugarcane cells sustain the constitutive protein synthesis in addition to heat-shock protein synthesis during HS, while constitutive protein synthesis is significantly reduced in tobacco cells during HS. Thus, HS modulation of NDPK1 activity and serine dephosphorylation in sugarcane cells may represent an important physiological role in maintaining cellular metabolic functions during heat stress.