Studying Auxin’s Role in Ectopic Outgrowths’ Development on Leaves of the Arabidopsis thaliana taeniata Mutant

Russian Journal of Developmental Biology - Auxin is an important inductor of organogenesis. During leaf development, local sites with high auxin concentration initiate the formation of leaf...     

Photosynthetic Properties of Photosystem Ⅱ in Arabidopsis thaliana Ipa1 Mutant

In a previous study, we characterized a high chlorophyll fluorescence Ipal mutant of Arabidopsis thallana, in which approximately 20% photosystem （PS） Ⅱ protein is accumulated. In the present study, analysis of fluorescence decay kinetics and thermoluminescence profiles demonstrated that the electron transfer reaction on either the donor or acceptor side of PSII remained largely unaffected in the Ipa1 mutant. In the mutant, maximal photochemical efficiency （Fv/Fm, where Fm is the maximum fluorescence yield and Fv is variable fluorescence） decreased with increasing light intensity and remained almost unchanged in wildtype plants under different light conditions. The Fv/Fm values also increased when mutant plants were transferred from standard growth light to low light conditions. Analysis of PSll protein accumulation further confirmed that the amount of PSll reaction center protein is correlated with changes in Fv/Fm in Ipal plants. Thus, the assembled PSll in the mutant was functional and also showed increased photosensitivity compared with wild-type plants.     

Overaccumulation of γ-Glutamylcysteine in a Jasmonate-Hypersensitive Arabidopsis Mutant Causes Jasmonate-Dependent Growth Inhibition

Glutathione (GSH) is essential for many aspects of plant biology and is associated with jasmonate signaling in stress responses. We characterized an Arabidopsis (Arabidopsis thaliana) jasmonate-hypersensitive mutant (jah2) with seedling root growth 100-fold more sensitive to inhibition by the hormone jasmonyl-isoleucine than the wild type. Genetic mapping and genome sequencing determined that the mutation is in intron 6 of GLUTATHIONE SYNTHETASE2, encoding the enzyme that converts γ-glutamylcysteine (γ-EC) to GSH. The level of GSH in jah2 was 71% of the wild type, while the phytoalexin-deficient2-1 (pad2-1) mutant, defective in GSH1 and having only 27% of wild-type GSH level, was not jasmonate hypersensitive. Growth defects for jah2, but not pad2, were also seen in plants grown to maturity. Surprisingly, all phenotypes in the jah2 pad2-1 double mutant were weaker than in jah2. Quantification of γ-EC indicated these defects result from hyperaccumulation of this GSH precursor by 294- and 65-fold in jah2 and the double mutant, respectively. γ-EC reportedly partially substitutes for loss of GSH, but growth inhibition seen here was likely not due to an excess of total glutathione plus γ-EC because their sum in jah2 pad2-1 was only 16% greater than in the wild type. Further, the jah2 phenotypes were lost in a jasmonic acid biosynthesis mutant background, indicating the effect of γ-EC is mediated through jasmonate signaling and not as a direct result of perturbed redox status.Glutathione (GSH) is an essential thiol of most higher organisms, including plants. Primarily found in the reduced form, its roles in maintaining a reduced intracellular state are numerous and well characterized (Foyer and Noctor, 2011; Noctor et al., 2011). Additionally, GSH is involved in detoxifying reactive oxygen species, heavy metal detoxification through phytochelatins, elimination of xenobiotics, and signaling of plant development and stress responses (Rouhier et al., 2008).GSH is synthesized in two steps. The first links Cys to the γ-carboxyl group of Glu through an amide bond catalyzed by γ-glutamylcysteine (γ-EC) synthetase, encoded by the single gene GSH1 in Arabidopsis (Arabidopsis thaliana). Gly is then added by GSH synthetase (GSH-S), also encoded by a single gene (GSH2). GSH is typically present at millimolar levels in plants, and although γ-EC is normally present at only a few percent of this amount, there is evidence that γ-EC has redox activities in Arabidopsis (Pasternak et al., 2008).Insertional knockouts of GSH1 are embryo lethal, and rootmeristemless1, with only 5% of wild-type GSH level, lacks a root apical meristem due to cell cycle arrest (Vernoux et al., 2000; Cairns et al., 2006). Other mutants producing 25% to 50% of wild-type GSH levels grow normally but exhibit defects under various stress conditions. For example, phytoalexin-deficient2-1 (pad2-1) and cadmium sensitive2 mutants are susceptible to pathogens and hypersensitive to Cd, respectively, while regulator of axillary meristems1 causes elevated expression of ASCORBATE PEROXIDASE2 under non-photooxidative-stress conditions (Glazebrook and Ausubel, 1994; Cobbett et al., 1998; Ball et al., 2004).GSH2 null alleles (gsh2-1 and gsh2-2) are also lethal, although plants survive to the early seedling stage (Pasternak et al., 2008). Survival past the embryo stage was attributed to partial complementation of GSH activity by γ-EC, which accumulates to excessive levels in gsh2-1, and the mutant is partially rescued by GSH supplementation. Missense and nonsense GSH2 alleles of membrane trafficking mutants (gsh2-3–gsh2-5) disrupt endoplasmic reticulum (ER) organization and also arrest growth in early seedling development, while a weaker allele (gsh2-6) reached maturity but was smaller than the wild type (Au et al., 2012). A screen for reduced response to Cd also yielded a viable missense mutant of GSH2 (nonresponse or reduced response to Cd2) with approximately 75% of the wild-type GSH level (Jobe et al., 2012).Plant oxidative stress responses involve both redox signaling through GSH and jasmonate hormonal signaling, and gene expression studies have clearly linked these two signaling systems. GSH biosynthesis and metabolism genes are induced by jasmonate, while manipulating GSH level or redox status in various mutants alters expression of genes for jasmonate biosynthesis and signaling (Xiang and Oliver, 1998; Mhamdi et al., 2010; Han et al., 2013). GSH and jasmonate are also associated with protective glucosinolate production in response to insect feeding (Noctor et al., 2011). For example, pad2-1 is deficient in glucosinolates and more susceptible to insects, while several studies have shown jasmonate induces glucosinolates (Brader et al., 2001; Mikkelsen et al., 2003; Sasaki-Sekimoto et al., 2005; Schlaeppi et al., 2008). Liu et al. (2010) isolated jasmonic acid hypersensitive1 (jah1), an Arabidopsis mutant with greater inhibition of root growth than the wild type in the presence of jasmonic acid (JA). The affected gene encodes a cytochrome P450 (CYP82C3) involved in indole glucosinolate production, and this mutant was more susceptible to Botrytis cinerea.The basic mechanism of jasmonate signal transduction and some of the downstream responses emanating from it are now well understood (Browse, 2009; Wasternack and Hause, 2013). However, the mechanisms by which jasmonate and GSH coordinate their activities to mediate oxidative stress and other responses are not known. This study characterized, to our knowledge, a new jasmonate-hypersensitive mutant that accumulates excess γ-EC due to a defect in GSH2, but GSH is only modestly reduced. Results show that elevated γ-EC is deleterious to plant growth through a jasmonate-dependent mechanism.     

The Arabidopsis szl1 Mutant Reveals a Critical Role of β-Carotene in Photosystem I Photoprotection

Carotenes and their oxygenated derivatives, the xanthophylls, are structural determinants in both photosystems (PS) I and II. They bind and stabilize photosynthetic complexes, increase the light-harvesting capacity of chlorophyll-binding proteins, and have a major role in chloroplast photoprotection. Localization of carotenoid species within each PS is highly conserved: Core complexes bind carotenes, whereas peripheral light-harvesting systems bind xanthophylls. The specific functional role of each xanthophyll species has been recently described by genetic dissection, however the in vivo role of carotenes has not been similarly defined. Here, we have analyzed the function of carotenes in photosynthesis and photoprotection, distinct from that of xanthophylls, by characterizing the suppressor of zeaxanthin-less (szl) mutant of Arabidopsis (Arabidopsis thaliana) which, due to the decreased activity of the lycopene-β-cyclase, shows a lower carotene content than wild-type plants. When grown at room temperature, mutant plants showed a lower content in PSI light-harvesting complex I complex than the wild type, and a reduced capacity for chlorophyll fluorescence quenching, the rapidly reversible component of nonphotochemical quenching. When exposed to high light at chilling temperature, szl1 plants showed stronger photoxidation than wild-type plants. Both PSI and PSII from szl1 were similarly depleted in carotenes and yet PSI activity was more sensitive to light stress than PSII as shown by the stronger photoinhibition of PSI and increased rate of singlet oxygen release from isolated PSI light-harvesting complex I complexes of szl1 compared with the wild type. We conclude that carotene depletion in the core complexes impairs photoprotection of both PS under high light at chilling temperature, with PSI being far more affected than PSII.     

Alternations of Metabolic Profile and Kynurenine Metabolism in the Plasma of Parkinson’s Disease

The pathogenesis of Parkinson’s disease (PD) remains to be elucidated. Metabolomic analysis has the potential to identify biochemical pathways and metabolic profiles that are involved in PD pathogenesis. Here, we performed a targeted metabolomics to quantify the plasma levels of 184 metabolites in a discovery cohort including 82 PD patients and 82 normal controls (NCs) and found two up-regulated (dopamine, putrescine/ornithine ratio) and four down-regulated (octadecadienylcarnitine C18:2, asymmetric dimethylarginine, tryptophan, and kynurenine (KYN)) metabolites in the plasma of PD patients. We then measured the plasma levels of a panel of metabolic products of KYN pathway in an independent validation cohort including 118 PD patients, 22 Huntington’s disease (HD) patients, and 37 NCs. Lower kynurenic acid (KA)/KYN ratio, higher quinolinic acid (QA) level, and QA/KA ratio were observed in PD patients compared to HD patients and NCs. PD patients at advanced stage (Hoehn-Yahr stage >?2) showed lower KA and KA/KYN ratio, as well as higher QA and QA/KA ratio compared to PD patients at early stage (Hoehn-Yahr stage ≤?2) and NCs. Levels of KA and QA, as well as the ratios of KA/KYN and QA/KA between PD patients with and without psychiatric symptoms, dementia, or levodopa-induced dyskinesia in the advanced PD were similar. This metabolomic analyses demonstrate a number of plasma biomarker candidates for PD, suggesting a shift toward neurotoxic QA synthesis and away from neuroprotective KA production in KYN pathway.     

Does Speciation between Arabidopsis halleri and Arabidopsis lyrata Coincide with Major Changes in a Molecular Target of Adaptation?

Ever since Darwin proposed natural selection as the driving force for the origin of species, the role of adaptive processes in speciation has remained controversial. In particular, a largely unsolved issue is whether key divergent ecological adaptations are associated with speciation events or evolve secondarily within sister species after the split. The plant Arabidopsis halleri is one of the few species able to colonize soils highly enriched in zinc and cadmium. Recent advances in the molecular genetics of adaptation show that the physiology of this derived ecological trait involves copy number expansions of the AhHMA4 gene, for which orthologs are found in single copy in the closely related A. lyrata and the outgroup A. thaliana. To gain insight into the speciation process, we ask whether adaptive molecular changes at this candidate gene were contemporary with important stages of the speciation process. We first inferred the scenario and timescale of speciation by comparing patterns of variation across the genomic backgrounds of A. halleri and A. lyrata. Then, we estimated the timing of the first duplication of AhHMA4 in A. halleri. Our analysis suggests that the historical split between the two species closely coincides with major changes in this molecular target of adaptation in the A. halleri lineage. These results clearly indicate that these changes evolved in A. halleri well before industrial activities fostered the spread of Zn- and Cd-polluted areas, and suggest that adaptive processes related to heavy-metal homeostasis played a major role in the speciation process.     

Selective Abortion of Two Nonsister Nuclei in a Developing Ascus of the hfd1–1 Mutant in SACCHAROMYCES CEREVISIAE

A recessive mutation, hfd1–1, in strain SOS4 of Saccharomyces cerevisiae leads the mutant cells to produce predominantly two-spored asci. Light microscopical examination of Giemsa-stained cells revealed no significant differences in the meiotic figures between mutant and wild-type strains. However, only two of the four meiotic products in a developing ascus matured to ascospores in SOS4. Dyad analysis was carried out on an hfd1–1 mutant strain heterozygous for three markers, asp5, gal1 and arg4, which are closely linked to their centromeres, and for his4, which is loosely linked to its centromere. The twospored asci produced by the hfd1–1 mutant segregated dominant (+) and recessive (-) alleles of each marker in a 1:1 ratio; they generally contained one + and one - spore for any given marker. The occurrence of rare dyads with two + or two - spores can be explained quantitatively by recombination between the marker and its centromere. From the results of these cytological and genetical analyses, we infer that, in the mutant strain, one genome set is partitioned to each of the four second-meiotic division poles, but only two nonsister genomes are incorporated into mature spores. Thus, the hfd1–1 mutation in SOS4 blocks incorporation of two nonsister nuclei into mature ascospores, but does not block enclosure of the remaining two nonsister nuclei.     

Transformation of a Leu− Mutant of Rhizopus niveus with the leuA Gene of Mucor circinelloides

The 2287-bp cryptic plasmid, pMA1, from Microcystis aeruginosa f. aeruginosa Kützing, a unicellular cyanobacterium originally derived from Kasumigaura lake, was completely sequenced and analyzed. The predicted amino acid sequence (253 residues) of an open reading frame had identities of 47%, 48%, and 53% with replication-associated proteins of Bacillus amyloliquefaciens’s plasmid, pFTB14, B. subtilis BAA1’s pBAA1, and B. coagulans’s pBC1, respectively, when conservative amino acid substitutions were included. Such high-level identities were also shown with rep proteins and ori regions in a group of Gram-positive bacterial plasmids such as Lactococci and Staphylococci that are known to replicate via single-stranded intermediates. The pMA1 does hybridize with a plasmid, pUS1-3, derived from another unicellular cyanobacterium, Synechocystis sp. PCC 6803. Novel features of pMA1 are discussed.     

A Triple Mutant in the Ω-loop of TEM-1 β-Lactamase Changes the Substrate Profile via a Large Conformational Change and an Altered General Base for Catalysis

β-Lactamases are bacterial enzymes that hydrolyze β-lactam antibiotics. TEM-1 is a prevalent plasmid-encoded β-lactamase in Gram-negative bacteria that efficiently catalyzes the hydrolysis of penicillins and early cephalosporins but not oxyimino-cephalosporins. A previous random mutagenesis study identified a W165Y/E166Y/P167G triple mutant that displays greatly altered substrate specificity with increased activity for the oxyimino-cephalosporin, ceftazidime, and decreased activity toward all other β-lactams tested. Surprisingly, this mutant lacks the conserved Glu-166 residue critical for enzyme function. Ceftazidime contains a large, bulky side chain that does not fit optimally in the wild-type TEM-1 active site. Therefore, it was hypothesized that the substitutions in the mutant expand the binding site in the enzyme. To investigate structural changes and address whether there is an enlargement in the active site, the crystal structure of the triple mutant was solved to 1.44 Å. The structure reveals a large conformational change of the active site Ω-loop structure to create additional space for the ceftazidime side chain. The position of the hydroxyl group of Tyr-166 and an observed shift in the pH profile of the triple mutant suggests that Tyr-166 participates in the hydrolytic mechanism of the enzyme. These findings indicate that the highly conserved Glu-166 residue can be substituted in the mechanism of serine β-lactamases. The results reveal that the robustness of the overall β-lactamase fold coupled with the plasticity of an active site loop facilitates the evolution of enzyme specificity and mechanism.     

Is the Rate of Metabolic Ageing and Survival Determined by Basal Metabolic Rate in the Zebra Finch?

The relationship between energy metabolism and ageing is of great interest because aerobic metabolism is the primary source of reactive oxygen species which is believed to be of major importance in the ageing process. We conducted a longitudinal study on captive zebra finches where we tested the effect of age on basal metabolic rate (BMR), as well as the effect of BMR on the rate of metabolic ageing (decline in BMR with age) and survival. Basal metabolic rate declined with age in both sexes after controlling for the effect of body mass, indicating a loss of functionality with age. This loss of functionality could be due to accumulated oxidative damage, believed to increase with increasing metabolic rate, c.f. the free radical theory of ageing. If so, we would expect the rate of metabolic ageing to increase and survival to decrease with increasing BMR. However, we found no effect of BMR on the rate of metabolic ageing. Furthermore, survival was not affected by BMR in the males. In female zebra finches there was a tendency for survival to decrease with increasing BMR, but the effect did not reach significance (P<0.1). Thus, the effect of BMR on the rate of functional deterioration with age, if any, was not strong enough to influence neither the rate of metabolic ageing nor survival in the zebra finches.