Miriam Hassidim

Sustained net CO2 evolution during photosynthesis by marine microorganism

BACKGROUND Many aquatic photosynthetic microorganisms possess an inorganic-carbon-concentrating mechanism that raises the CO2 concentration at the intracellular carboxylation sites, thus compensating for the relatively low affinity of the carboxylating enzyme for its substrate. In cyanobacteria, the concentrating mechanism involves the energy-dependent influx of inorganic carbon, the accumulation of this carbon--largely in the form of HCO3(-)-in the cytoplasm, and the generation of CO2 at carbonic anhydrase sites in close proximity to the carboxylation sites. RESULTS During measurements of inorganic carbon fluxes associated with the inorganic-carbon-concentrating mechanism, we observed the surprising fact that several marine photosynthetic microorganisms, including significant contributors to oceanic primary productivity, can serve as a source of CO2 rather than a sink during CO2 fixation. The phycoerythrin-possessing cyanobacterium Synechococcus sp. WH7803 evolved CO2 at a rate that increased with light intensity and attained a value approximately five-fold that for photosynthesis. The external CO2 concentration reached was significantly higher than that predicted for chemical equilibrium between HCO3- and CO2, as confirmed by the rapid decline in the CO2 concentration upon the addition of carbonic anhydrase. Measurements of oxygen exchange between water and CO2, by means of stable isotopes, demonstrated that the evolved CO2 originated from HCO3- taken up and converted intracellularly to CO2 in a light-dependent process. CONCLUSIONS We report net, sustained CO2 evolution during photosynthesis. The results have implications for energy balance and pH regulation of the cells, for carbon cycling between the cells and the marine environment, and for the observed fractionation of stable carbon isotopes.

Over-expression of CONSTANS-LIKE 5 can induce flowering in short-day grown Arabidopsis.

To ensure that the initiation of flowering occurs at the correct time of year, plants need to integrate a diverse range of external and internal signals. In Arabidopsis, the photoperiodic flowering pathway is controlled by a set of regulators that include CONSTANS (CO). In addition, Arabidopsis plants also have a family of genes with homologies to CO known as CO-LIKE (COL) about which relatively little is known. In this paper, we describe the regulation and interactions of a novel member of the family, COL5. The expression of COL5 is under circadian and diurnal regulation, but COL5 itself does not appear to affect circadian rhythms. COL5, like CO, is regulated by GIGANTEA. Furthermore, COL5 is expressed in the vascular tissue. Using COL5 over-expressing lines we show that, under short days, constitutive expression of COL5 affects flowering time and the expression of the floral integrator genes, FLOWERING LOCUS T and SUPPRESSOR OF OVEREXPRESSION OF CO 1. Constitutive expression of COL5 partially suppresses the late flowering phenotype of the co-mutant plants. However, plants with loss of COL5 function do not show altered flowering. Taken together, our results suggest that COL5 has COL activity, but may either not have a role in regulating flowering in wild-type plants or may act redundantly with other flowering regulators.

Posttranslational Regulation of CIRCADIAN CLOCK ASSOCIATED1 in the Circadian Oscillator of Arabidopsis

As an adaptation to life in a world with predictable daily changes, most eukaryotes and some prokaryotes have endogenous circadian (approximately 24 h) clocks. In plants, the circadian clock regulates a diverse range of cellular and physiological events from gene expression and protein phosphorylation to cellular calcium oscillations, hypocotyl growth, leaf movements, and photoperiod-dependent flowering. In Arabidopsis (Arabidopsis thaliana), as in other model organisms, such as Drosophila (Drosophila melanogaster) and mice, circadian rhythms are generated by molecular oscillators that consist of interlocking feedback loops involving a number of elements. CIRCADIAN CLOCK ASSOCIATED1 (CCA1) and LATE ELONGATED HYPOCOTYLS (LHY) are closely related single myb transcription factors that have been identified as key elements in the Arabidopsis oscillator. Research in other model organisms has shown that posttranslational regulation of oscillator components plays a critical role in the generation of the approximately 24-h cycles. To examine the role of posttranslational regulation of CCA1 and LHY in the Arabidopsis oscillator, we generated transgenic plants with tagged CCA1 and LHY under the control of their own promoters. We have shown that these tagged proteins are functional and can restore normal circadian rhythms to CCA1- and LHY-null plants. Using the tagged proteins, we demonstrate that CCA1 can form both homodimers and heterodimers with LHY. Furthermore, we also show that CCA1 is localized to the nucleus in vivo and that there is no significant delay between the translation of CCA1 and its translocation to the nucleus. We discuss our findings in the context of the functioning of the Arabidopsis oscillator.

Circadian Clock Associated1 transcript stability and the entrainment of the circadian clock in arabidopsis

The circadian clock is an endogenous mechanism that generates rhythms with an approximately 24-h period and enables plants to predict and adapt to daily and seasonal changes in their environment. These rhythms are generated by molecular oscillators that in Arabidopsis (Arabidopsis thaliana) have been shown to consist of interlocking feedback loops involving a number of elements. An important characteristic of circadian oscillators is that they can be entrained by daily environmental changes in light and temperature. Previous work has shown that one possible entrainment point for the Arabidopsis oscillator is the light-mediated regulation of expression of one of the oscillator genes, CIRCADIAN CLOCK ASSOCIATED1 (CCA1). In this article, we have used transgenic plants with constitutive CCA1 expression to show that light also regulates CCA1 transcript stability. Our experiments show that CCA1 messenger RNA is relatively stable in the dark and in far-red light but has a short half-life in red and blue light. Furthermore, using transgenic plants expressing chimeric CCA1 constructs, we demonstrate that the instability determinants in CCA1 transcripts are probably located in the coding region. We suggest that the combination of light regulation of CCA1 transcription and CCA1 messenger RNA degradation is important for ensuring that the Arabidopsis circadian oscillator is accurately entrained by environmental changes.

Cell autonomous and cell-type specific circadian rhythms in Arabidopsis.

The circadian system of plants regulates a wide range of rhythmic physiological and cellular output processes with a period of about 24 h. The rhythms are generated by an oscillator mechanism that, in Arabidopsis, consists of interlocking feedback loops of several components including CIRCADIAN CLOCK ASSOCIATED 1 (CCA1), LATE ELONGATED HYPOCOTYL (LHY), TIMING OF CAB EXPRESSION 1 (TOC1) and CCA1 HIKING EXPEDITION (CHE). Over recent years, researchers have gained a detailed picture of the clock mechanism at the resolution of the whole plant and several tissue types, but little information is known about the specificities of the clock mechanism at the level of individual cells. In this paper we have addressed the question of cell-type-specific differences in circadian systems. Using transgenic Arabidopsis plants with fluorescence-tagged CCA1 to measure rhythmicity in individual leaf cells in intact living plants, we showed that stomatal guard cells have a different period from surrounding epidermal and mesophyll leaf cells. By comparing transcript levels in guard cells with whole plants, we identified differences in the expression of some oscillator genes that may underlie cell-specific differences in clock properties. In addition, we demonstrated that the oscillators of individual cells in the leaf are robust, but become partially desynchronized in constant conditions. Taken together our results suggest that, at the level of individual cells, there are differences in the canonical oscillator mechanism that has been described for plants.

ACCLIMATION OF SYNECHOCOCCUS STRAIN WH7803 TO AMBIENT CO2 CONCENTRATION AND TO ELEVATED LIGHT INTENSITY1

A CO2 concentrating mechanism has been identified in the phycoerythrin‐possessing Synechococcus sp. WH7803 and has been observed to be severely inhibited by short exposure to elevated light intensities. A light treatment of 300–2000 μmol quanta·m−2·s−1 resulted in a considerable decay in the variable fluorescence of PSII with time, suggesting decreased efficiency of energy transfer from the phycobilisomes, direct damage to the reaction center II, or both. Measurements of the activity of PSII and changes in fluorescence emission spectra during a light treatment of 1000 μmol quanta·m−2·s−1 indicated considerable reduction in the energy flow from the phycocyanin to the phycobilisome terminal acceptor and chlorophyll a. Consequently, whereas the maximal photosynthetic rate, at saturating light and Co2 concentration, was hardly affected by a light treatment of 1000 μmol quanta·m−2·s−1 for 2 h, the light intensity required to reach that maximum increased with the duration of the light treatment.

Disruption of Nap14, a plastid‐localized non‐intrinsic ABC protein in Arabidopsis thaliana results in the over‐accumulation of transition metals and in aberrant chloroplast structures

Chloroplasts are the major sink for Fe in shoot tissues because of the requirements of the photosynthetic process and to storage in ferritins. Such requirements are common both to plastids and to their evolutionary progenitors, the cyanobacteria. Here, we examined whether iron transport mechanisms were conserved throughout the evolution of photosynthetic organisms. Comparison of the sequences of putative plastid transporters from Arabidopsis thaliana with those involved in cyanobacterial Fe transport identified two orthologs of the FutC protein, AtNAP11 and AtNAP14. To study their function, we analysed insertional mutants in the genes coding for these proteins. Both nap11/nap11 and nap14/nap14 plants exhibited severe growth defects. Significant changes in transition metal homeostasis were detected only in nap14/nap14. This mutant was found to contain approximately 18 times more Fe in the shoot tissue than in wild-type plants. The increased shoot transition metal content was accompanied by a specific loss of chloroplast structures and by a reduction in transcript levels of Fe homeostasis-related genes. Based on these results, we propose that AtNAP14 plays an important role in plastid transition metal homeostasis. One possibility is that AtNAP14 is part of a chloroplast transporter complex. Alternatively, AtNAP14 function may be in regulating transition metal homeostasis.

The Possible Role of Various Membrane Transport Mechanisms in Adaptation to Salinity

Peter Mitchell’s chemiosmotic hypothesis (Mitchell, 1986) has now dominated our thinking about membrane transport processes for nearly two decades. It envisages a relatively small number of primary energy transducers in the cell membranes, the “primary pumps”, which generate transmembrane ion gradients by transferring specific ions energetically uphill. These ions are the “working” ions — their return flux, downhill, can serve as the direct source of energy for the transmembrane flux of numerous other metabolites and ions if there are “porter” molecules in the membrane which couple the two fluxes, those of the “driving” and “driven” solute respectively (Fig. 1). These two fluxes may be in the same (symport) or opposing (antiport) direction, and in addition there may be “uniport” of ions, that is electrophoretic flux through specific channels, driven by the membrane potential (Δψ) generated by the electrogenic primary pump. The principal primary pump in the animal cell is the Na+K+ATPase which ejects Na+ from the cell and builds up an inwardly directed Na+ gradient. Its functional counterpart in the plant cell is the proton pump which is responsible for the electrogenic extrusion of protons, thus generating the “protonmotive force”, or pmf (ΔpH +Δψ).

CIRCADIAN CLOCK ASSOCIATED 1 (CCA1) and the circadian control of stomatal aperture

Stomatal guard cells are controlled by a modified circadian oscillator to ensure correct daylength-dependent regulation of stomatal aperture. The endogenous circadian (∼24 h) system allows plants to anticipate and adapt to daily environmental changes. Stomatal aperture is one of the many processes under circadian control; stomatal opening and closing occurs under constant conditions, even in the absence of environmental cues. To understand the significance of circadian-mediated anticipation in stomatal opening, we have generated SGC (specifically guard cell) Arabidopsis (Arabidopsis thaliana) plants in which the oscillator gene CIRCADIAN CLOCK ASSOCIATED1 (CCA1) was overexpressed under the control of the guard-cell-specific promoter, GC1. The SGC plants showed a loss of ability to open stomata in anticipation of daily dark-to-light changes and of circadian-mediated stomatal opening in constant light. We observed that under fully watered and mild drought conditions, SGC plants outperform wild type with larger leaf area and biomass. To investigate the molecular basis for circadian control of guard cell aperture, we used large-scale qRT-PCR to compare circadian oscillator gene expression in guard cells compared with the “average” whole-leaf oscillator and examined gene expression and stomatal aperture in several lines of plants with misexpressed CCA1. Our results show that the guard cell oscillator is different from the average plant oscillator. Moreover, the differences in guard cell oscillator function may be important for the correct regulation of photoperiod pathway genes that have previously been reported to control stomatal aperture. We conclude by showing that CONSTANS and FLOWERING LOCUS T, components of the photoperiod pathway that regulate flowering time, also control stomatal aperture in a daylength-dependent manner.

The Use of Fluorescent Proteins to Analyze Circadian Rhythms

Compared with luciferase which is widely used as a reporter for circadian rhythms in Arabidopsis thaliana, available fluorescent markers are generally too stable to allow circadian oscillations to be measured. However, we have developed a technique to use the nuclear localization of circadian-controlled transcription factors fused to a fluorescent reporter as a means of measuring circadian rhythms. This technique has the advantage of being suitable for analyzing rhythms at the level of individual cells and in living plants.