Turnip vein clearing virus movement protein nuclear activity: Do Tobamovirus movement proteins play a role in immune response suppression?

Plant viruses'' cell-to-cell movement requires the function of virally encoded movement proteins (MPs). The Tobamovirus, Tobacco mosaic virus (TMV) has served as the model virus to study the activities of single MPs. However, since TMV does not infect the model plant Arabidopsis thaliana I have used a related Tobamovirus, Turnip vein-clearing virus (TVCV). I recently showed that, despite belonging to the same genus, the behavior of the 2 viruses MPs differ significantly during infection. Most notably, MP^TVCV, but not MP^TMV, targets the nucleus and induces the formation of F actin-containing filaments that associate with chromatin. Mutational analyses showed that nuclear localization of MP^TVCV was necessary for TVCV local and systemic infection in both Nicotiana benthamiana and Arabidopsis. In this addendum, I propose possible targets for the MP^TVCV nuclear activity, and suggest viewing MPs as viral effector-like proteins, playing a role in the inhibition of plant defense.     

Activation of Tm-22 resistance is mediated by a conserved cysteine essential for tobacco mosaic virus movement

The tomato Tm-2² gene was considered to be one of the most durable resistance genes in agriculture, protecting against viruses of the Tobamovirus genus, such as tomato mosaic virus (ToMV) and tobacco mosaic virus (TMV). However, an emerging tobamovirus, tomato brown rugose fruit virus (ToBRFV), has overcome Tm-2², damaging tomato production worldwide. Tm-2² encodes a nucleotide-binding leucine-rich repeat (NLR) class immune receptor that recognizes its effector, the tobamovirus movement protein (MP). Previously, we found that ToBRFV MP (MP^ToBRFV) enabled the virus to overcome Tm-2²-mediated resistance. Yet, it was unknown how Tm-2² remained durable against other tobamoviruses, such as TMV and ToMV, for over 60 years. Here, we show that a conserved cysteine (C68) in the MP of TMV (MP^TMV) plays a dual role in Tm-2² activation and viral movement. Substitution of MP^ToBRFV amino acid H67 with the corresponding amino acid in MP^TMV (C68) activated Tm-2²-mediated resistance. However, replacement of C68 in TMV and ToMV disabled the infectivity of both viruses. Phylogenetic and structural prediction analysis revealed that C68 is conserved among all Solanaceae-infecting tobamoviruses except ToBRFV and localizes to a predicted jelly-roll fold common to various MPs. Cell-to-cell and subcellular movement analysis showed that C68 is required for the movement of TMV by regulating the MP interaction with the endoplasmic reticulum and targeting it to plasmodesmata. The dual role of C68 in viral movement and Tm-2² immune activation could explain how TMV was unable to overcome this resistance for such a long period.     

Effects of salinity,temperature and nitrogen fertilization on growth and composition of Rhodes grass (Chloris gayana Kunth.)

The effects of salinity, temperature, and N-fertilization on growth and yield of Rhodes grass were investigated. High levels of all three factors had a negative effect on tillering and consequently on the total yield. Though high salt-stress lowered the yields, it also lowered the content of free-NO₃ ^– in the shoots, thus, raising the quality of the crops obtained.In partial fulfillment of the requirements for the degree of M.Sc. at The Tel Aviv University.In partial fulfillment of the requirements for the degree of M.Sc. at The Tel Aviv University.     

The Rubisco Small Subunit Is Involved in Tobamovirus Movement and Tm-22-Mediated Extreme Resistance

The multifunctional movement protein (MP) of Tomato mosaic tobamovirus (ToMV) is involved in viral cell-to-cell movement, symptom development, and resistance gene recognition. However, it remains to be elucidated how ToMV MP plays such diverse roles in plants. Here, we show that ToMV MP interacts with the Rubisco small subunit (RbCS) of Nicotiana benthamiana in vitro and in vivo. In susceptible N. benthamiana plants, silencing of NbRbCS enabled ToMV to induce necrosis in inoculated leaves, thus enhancing virus local infectivity. However, the development of systemic viral symptoms was delayed. In transgenic N. benthamiana plants harboring Tobacco mosaic virus resistance-2² (Tm-2²), which mediates extreme resistance to ToMV, silencing of NbRbCS compromised Tm-2²-dependent resistance. ToMV was able to establish efficient local infection but was not able to move systemically. These findings suggest that NbRbCS plays a vital role in tobamovirus movement and plant antiviral defenses.Plant viruses use at least one movement protein (MP) to facilitate viral spread between plant cells via plasmodesmata (PD; Lucas and Gilbertson, 1994; Ghoshroy et al., 1997). Among viral MPs, the MP of tobamoviruses, such as Tobacco mosaic virus (TMV) and its close relative Tomato mosaic virus (ToMV), is the best characterized. TMV MP specifically accumulates in PD and modifies the plasmodesmatal size exclusion limit in mature source leaves or tissues (Wolf et al., 1989; Deom et al., 1990; Ding et al., 1992). TMV MP and viral genomic RNA form a mobile ribonucleoprotein complex that is essential for cell-to-cell movement of viral infection (Watanabe et al., 1984; Deom et al., 1987; Citovsky et al., 1990, 1992; Kiselyova et al., 2001; Kawakami et al., 2004; Waigmann et al., 2007). TMV MP also enhances intercellular RNA silencing (Vogler et al., 2008) and affects viral symptom development, host range, and host susceptibility to virus (Dardick et al., 2000; Bazzini et al., 2007). Furthermore, ToMV MP is identified as an avirulence factor that is recognized by tomato (Solanum lycopersicum) resistance proteins Tobacco mosaic virus resistance-2 (Tm-2) and Tm-2² (Meshi et al., 1989; Lanfermeijer et al., 2004). Indeed, tomato Tm-2² confers extreme resistance against TMV and ToMV in tomato plants and even in heterologous tobacco (Nicotiana tabacum) plants (Lanfermeijer et al., 2003, 2004).To date, several host factors that interact with TMV MP have been identified. These TMV MP-binding host factors include cell wall-associated proteins such as pectin methylesterase (Chen et al., 2000), calreticulin (Meshi et al., 1989), ANK1 (Ueki et al., 2010), and the cellular DnaJ-like protein MPIP1 (Shimizu et al., 2009). Many cytoskeletal components such as actin filaments (McLean et al., 1995), microtubules (Heinlein et al., 1995), and the microtubule-associated proteins MPB2C (Kragler et al., 2003) and EB1a (Brandner et al., 2008) also interact with TMV MP. Most of these factors are involved in TMV cell-to-cell movement.Rubisco catalyzes the first step of CO₂ assimilation in photosynthesis and photorespiration. The Rubisco holoenzyme is a heteropolymer consisting of eight large subunits (RbCLs) and eight small subunits (RbCSs). RbCL was reported to interact with the coat protein of Potato virus Y (Feki et al., 2005). Both RbCS and RbCL were reported to interact with the P3 proteins encoded by several potyviruses, including Shallot yellow stripe virus, Onion yellow dwarf virus, Soybean mosaic virus, and Turnip mosaic virus (Lin et al., 2011). Proteomic analysis of the plant-virus interactome revealed that RbCS participates in the formation of virus complexes of Rice yellow mottle virus (Brizard et al., 2006). However, the biological function of Rubisco in viral infection remains unknown.In this study, we show that RbCS plays an essential role in virus movement, host susceptibility, and Tm-2²-mediated extreme resistance in the ToMV-host plant interaction.     

BOP‐OXy,BOP‐OBt,and BOP‐OAt: novel organophosphinic coupling reagents useful for solution and solid‐phase peptide synthesis

Stand‐alone coupling reagents derived from bis(2‐oxo‐3‐oxazolidinyl)phosphorodiamidic chloride show efficient performance in solution and SPPS. In particular, the Oxyma Pure (Luxembourg Biotech., Tel Aviv, Israel) derivative shows the additional advantage of being highly soluble in DMF and even fairly soluble in CH₃CN, which can extend its use for the synthesis of complex peptides. These new stand‐alone coupling reagents have the advantage of not bearing any counteranion such as PF₆ or BH₄, whose presence can jeopardize the purification of final peptides prepared in solution. Copyright © 2013 European Peptide Society and John Wiley & Sons, Ltd.     

Inter-relationships between Najas marina L. and three other species of aquatic macrophytes

The ability of Najas marina L. to thrive in the presence of the submerged hydrophytes (Myriophyllum spicatum L. and Potamogeton lucens L.) and of an emerged hygrophyte (Scirpus litoralis Schard.) was investigated in Tel Aviv, Israel. Najas plants were unaffected by the presence of Potamogeton lucens and Scirpus litoralis, but were significantly suppressed by Myriophyllum. Bilateral negative relationships exist between Najas and Myriophyllum and these seem to be of an allelophatic nature, depending more on the nature of the accompanying species rather than on their mass.     

Decomposition of leaf and root tissue of three perennial grass species grown at two levels of atmospheric CO2 and N supply

Leaf and root tissue of Lolium perenne L., Agrostis capillaris L. and Festuca ovina L. grown under ambient (350 μl l^-1 CO₂) and elevated (700 μl l^-1) CO₂ in a continuously ¹⁴C-labelled atmosphere and at two soil N levels, were incubated at 14°C for 222 days. Decomposition of leaf and root tissue grown in the low N treatment was not affected by elevated [CO₂], whereas decomposition in the high N treatment was significantly reduced by 7% after 222 days. Despite the increased C/N ratio (g g^-1) of tissue cultivated at elevated [CO₂] when compared with the corresponding ambient tissue, there was no significant correlation between initial C/N ratio and ¹⁴C respired. This finding suggests that the CO₂-induced changes in decomposition rates do not occur via CO₂-induced changes in C/N ratios of plant materials. We combined the decomposition data with data on ¹⁴C uptake and allocation for the same plants, and give evidence that elevated [CO₂] has the potential to increase soil C stores in grassland via increasing C uptake and shifting C allocation towards the roots, with an inherent slower decomposition rate than the leaves. An overall increase of 15% in ¹⁴C remaining after 222 days was estimated for the combined tissues, i.e., the whole plants; the leaves made a much smaller contribution to the C remaining (+6%) than the roots (+26%). This shows the importance of clarifying the contribution of roots and leaves with respect to the question whether grassland soils act as a sink or source for atmospheric CO₂. This revised version was published online in June 2006 with corrections to the Cover Date.     

Isolation of sensitive nisin-sensing GFP<Subscript>uv</Subscript> bioassay <Emphasis Type="Italic">Lactococcus lactis</Emphasis> strains using FACS

Fluorescence-activated cell sorting (FACS) was used to isolate mutants of Lactococcus lactis LAC275, an indicator strain in GFP_uv nisin bioassay. It harbors the GFP_uv encoding gene under the nisA promoter and the nisin signal transduction nisRK genes whereby nisin concentration can be correlated to GFP_uv fluorescence. The sorted L. lactis cells, which showed higher fluorescence intensities at low inducer concentration, were analysed for higher responsiveness to low concentration of nisin. Two strains showed lower detection limits (0.2 pg ml⁻¹) for nisin than the parent strain (10 pg ml⁻¹). This showed that mutants of LAC275 could successfully be isolated using FACS.     

Intermittency in the plankton: a multifractal analysis of zooplankton biomass variability

We present the first evidence that variability in zooplanktonbiomass can be characterized as a multifractal. An hourly tuneseries of vertically integrated acoustic biomass measurements,taken from a fixed mooring on the Atlantic coastline, providedthe data for our analysis. Two measures of variability wereanalyzed: the first difference squared and the squared differencefrom the mean. When integrated over time, these quantities provideestimates of biomass variability. The distribution in time ofthese measures of variability is highly intermittent. We showthat such intermittency is well described by the scaling propertiesof multifractals. In zooplankton ecology, potential applicationsof this analysis include comparing plankton variability distributionsto those of passive scalars and environmental variables, quantifyingspatial or temporal heterogeneity in intermittent quantities,and determining scales over which similar processes are operating. ¹Present address: University of Tel Aviv, Department of Zoology,Ramat Aviv, 69978 Tel Aviv, Israel     

Plasmodesmata transport of GFP and GFP fusions requires little energy and transitions during leaf expansion

Plasmodesmata (Pd) are symplastic channels between neighboring plant cells and are key in plant cell-cell signaling. Viruses of proteins, nucleic acids, and a wide range of signaling macromolecules move across Pd. Protein transport Pd is regulated by development and biotic signals. Recent investigations utilizing the Arrhenius equation or Coefficient of conductivity showed that fundamental energetic measurements used to describe transport of proteins across membrane pores or the nuclear pore can also apply to protein movement across Pd. As leaves continue to expand, Pd transport of proteins declines which may result from changes in cell volume, Pd density or Pd structure.Key words: plasmodesmata, diffusion, GFP, viral transport, PVX, triple gene blockResearchers have argued for the last decade that movement of proteins and other macromolecules across Pd is regulated by development, stress and biotic signals. There are four current models describing different mechanisms of Pd transport. First is the non cell autonomous protein (NCAP) pathway that carries ribonucleoprotein complexes across Pd. NCAPs often carry RNA in a ribonucleoprotein complex to the Pd.^1–4 This mode of transport involved targeted movement, meaning that a set of proteins must dock within the Pd to gate it open to enable transfer between cells. Proteins which are normally too large to move across Pd can gate open Pd to enable its own transfer into neighboring cells. This is contrasted by nontargetted movement, which is passive movement of proteins that are sufficiently small enough to pass between cells.^5,6 The green fluorescent protein (GFP) has been described as a protein whose movement is non-targeted, meaning that it can diffuse across Pd. Reasons that we do not see continuous movement of small proteins between cells include protein compartmentalization or subcellular targeting signals. For example proteins may be synthesized and modified via the ER and Golgi networks and then transferred into vesicles and transported within cells to their destination. These proteins would not be free in the cytosol for diffusion across Pd. Alternatively, proteins which have dominant subcellular targeting signals which direct them to certain organelles such as the nucleus, peroxisome, or other destination would not be free to move across Pd.^5,6 A third model represents proteins in the ER that move laterally along the membrane or through the ER lumen into neighboring cells. This transport is quite rapid and investigations are ongoing to determine how this is regulated.^7–11 Finally, there is vesicle transport which deliver cargo to Pd.^12,13 The origin of these vesicles is still under investigation. Much more research has been accomplished toward defining non-targeted movement and the NCAP pathway while the ER and vesicle transport pathways are only recently described and very little is known about the regulatory mechanisms underlying these pathways.Pd permeability is governed in part by architecture, but also by key regulatory factors that determine Pd conductivity. Factors such as mysoin VIII, actin and calreticulin were identified in Pd which likely regulate expansion and contraction.^14–19 In addition calcium, ATP and plant hormones can downregulate Pd permeability during development and stress.^20,21 The tools for measuring Pd permeability has been to study the transport of fluorescently tagged proteins, fluorescent dextran beads, GFP or GFP fusions following microinjection or biolistic delivery to the cytoplasm of one cell.^22–26 Then video imaging or captured still images at select time intervals are used to characterize Pd transport. Until recently researchers quantified movement by the frequency they observed a certain type of movement. Therefore our ability to describe Pd permeability has been limited.Evidence that ATP impacts Pd conductivity has led investigations to explore the energy requirements for macromolecular transport across Pd. By understanding the energy requirements for transport of various proteins and nucleic acids we can better characterize passive or active transport processes. Toward this end two recent studies detailed quantitative approaches that can be employed to describe the developmental and energy requirements cell-to-cell transport of cytosolic proteins. Both papers used biolistic bombardment to deliver plasmids expressing GFP or GFP fusions to tobacco leaf epidermal cells and then captured still images of GFP fluorescence in neighboring cells. We employed the Arrhenius equation to characterize transport of GFP or GFP fused to the Potato virus X (PVX) TGBp1 movement protein. PVX TGBp1 was selected to compare with GFP alone since it is known to gate open Pd and has ATPase activity.⁴⁵ We predicted that the abilities of GFP alone and GFP-TGBp1 to move across Pd might be different and were surprised to learn that the energy for transport of both proteins was similar. This project established the principle that GFP and GFP-TGBp1 transport is temperature dependent showing a linear relationship between protein movement and the temperatures at which leaves were incubated.Green fluorescent sites on bombarded leaves were scored for the movement or no movement. Movement is defined as evidence of fluorescence in 2 or more cells at 24 h and no movement is when fluorescence is in single cells. These were then presented as a percentage of the total. So by digitizing the representation of movement we were able to represent a linear relationship between movement and temperature. Representing movement in this way also enabled us to represent movement values on a logarithm scale necessary for a classic Arrhenius plot. The activation energy (Ea) was calculated by fitting the data to the Arrhenius equation:% movement = A exp(-Ea/RT); and the Ea for GFP and GFP-TGBp1 was approximately 38 kJ/mol and 29 kJ/mol. These low activation energies are comparable to the reported 30 kJ/mol calculated for temperature dependence of protein transport through the cytosol. Evidence that GFP movement across Pd requires slightly more energy than through the cytoplasm suggests there may be some resistance within the pore. The lower energy for GFP-TGBp1 suggests that movement is facilitated, which likely reflects Pd gating by TGBp1, enabling greater transfer between cells.Liarzi and Epel define a new coefficient of conductivity of Pd.⁴² This study also concluded that cell-to-cell transport of GFP in nontransgenic or transgenic N. benthamiana plants expressing the Tobacco mosaic virus (TMV) movement protein (MP) is temperature dependent. The method was to measure the exponential decay, which is a measure of the impedance to diffusion driven cell-to-cell movement of fluorescence. The exponential decay factor? was determined by calculating the ratio of GFP fluorescence in bombarded cell 0 and neighboring cells. This was presented as a measure of fluorescence transfer from cell 0 to cell 1 to cell 2. A coefficient for conductivity C(Pd), 1/? for GFP was reflective of diffusion. Interestingly the (TMV) MP did not increase conductivity of GFP between neighboring leaf epidermal cells indicating that movement was already maximal. Considering prior reports that the TMV MP shows preferential spread into mesophyll rather than epidermal tissues during virus infection, it is possible that preferential spread into mesophyll cells would prevent experimental efforts to achieve improved conductivity of GFP between epidermal cells.^27,28 In which case the absence of a trans effect of TMV MP on GFP conductivity in the epidermis may not be surprising. In fact, prior investigations of TMV MP gating activities were conducted in mesophyll cells.^29,30 The best explanation for the combined studies is that cytosolic GFP can diffuse across Pd , however viral proteins which gate Pd enable their own low energy transfer into neighboring cells without allowing other proteins to flood into neighboring cells. Therefore viral movement proteins, such as PVX TGBp1 and TMV MP, which gate Pd provide themselves with an energetic advantage for transport into neighboring cells which is essential for rapid dissemination of virus into further tissues.These studies provide an interesting contrast between PVX TGBp1 and TMV MP. Both proteins gate open Pd for virus cell-to-cell transport, but there seems to be differences in how these proteins function in epidermal cells. This is likely due to their different roles in promoting virus cell-to-cell movement. PVX TGBp1 protein is also a suppressor of RNA silencing. We recently proposed a model in which TGBp1 rapidly moves from cell-to-cell ahead of virus infection, to suppress the cell''s RNA degradation machinery, as a means to promote infection.³¹ The TMV MP on the other hand is reported to bind viral RNA for transfer into neighboring cells.^32,33 Therefore, the different observations of PVX TGBp1 and TMV MP transport between epidermal cells likely reflect their functional differences. Both proteins are required for virus cell-to-cell movement, but their exact roles in virus movement are not identical.As mentioned earlier, Pd permeability is downregulated during plant development. Research tracking GFP diffusion through Pd in embryonic cells, in young emerging leaves, and in fully expanded leaves showed that fluorescence is highly mobile between cells in young tissues but is restricted during maturation. Viral movement proteins such as Cucumber mosaic virus 3a, and PVX TGBp1 remain highly mobile in mature leaves because they gate open Pd under conditions that normally restrict movement of GFP.^34,35 Schoenknecht et al., undertook a straightforward investigation of leaf maturation describing Pd transport in relationship to leaf area expansion. The outcome of this study was evidence that GFP movement between cells declines as leaves expand.It is reasonable to consider that simultaneous changes in gene expression and physiology is reflected in a downward trend in Pd conductivity and an increased requirement for Pd gating to enable selected transport of macromolecules between cells. In Arabidopsis embryos there is an obvious transition between developmental stages which are also represented by a decline in the ability for GFP to diffuse across Pd.^36,37 A detailed analysis of Pd structure in source and sink tissues revealed that Pd are simple single channeled structures in sink tissues while source tissues contain predominantly “H” shaped branching Pd structures. The change in Pd structure has been correlated with changes in conductivity and is often correlated with changes in sink to source metabolism.^38,39 The sink-to-source transition in leaf development is typically monitored using phloem loading of carboxyfluorescein diacetate. Leaves where CF dye unloads are defined as sink leaves and leaves that were restricted in dye unloading were defined as source leaves. Then biolistic bombardment of GFP expressing plasmids to sink and source leaves revealed that GFP readily diffuses across Pd in sink leaves but is more often restricted in source leaves.^{26,34,40–42}Leaf development is typically defined as a transition from juvenile to adult which is represented by homeotic transformations as well as vegetative phase changes.^43,44 Source and sink regions of a leaf have been shown to correlate with changes in Pd structure and conductivity during leaf expansion. However, in our study we found that N. tabacum leaves identified as source during week 2 or 3 would continue to expand over an 8 week period to twice or three times the leaf area which provides a real indication that the source designation may not entirely reflect final leaf maturation or completion of leaf development.⁴⁵> For example, as cells transition from sink to source physiology it is suggested that the frequency of single channeled Pd declines while the frequency of branched Pd increases.³⁹ It is possible that even after leaves transition into photosynthetic sources that Pd architecture continues to change and there is a further decline in the proportion of single channel to branched channels. Therefore either the change in cell volume or Pd architecture or both can slow-down diffusion of GFP between cells.Researchers often point to the ER continuity between cells as a driving force for Pd formation and function. During cell division the cell wall is laid down and forms around the ER creating Pd channels.⁴⁶ However, it is also worth noting that the actin cytoskeleton is also present in Pd and is central to organ and reproductive development.^19,47 Actin and actin binding proteins are necessary for a number of plant processes determining the cell division plane, cell polarity, cell elongation, cytoplasmic streaming, transporting mRNAs and proteins, and defense.^48–51 Overexpression of ACT1 in Arabidopsis leaves can lead to changes in epidermal leaf shape and cause dwarfism in plants.⁵² Actin binding proteins are also necessary for organizing and remodeling the F-actin network which drives normal development of specific cell types and organs.⁵³ Actin filament bundling and remodeling are also seen in nonhost defense responses.⁵⁴ We do not know the effects of overexpressing certain actin homologues or actin remodeling on Pd formation or conductivity. Because the F-actin network is also central to Pd trafficking of proteins and macromolecules between cells it is worth considering F-actin as an early factor contributing to Pd formation which may be necessary to ensure cell-to-cell communication when cell polarity and elongation as well as defense machinery are being established.In summary, the novel quantitative tools developed for measuring protein movement across Pd reveal the temperature dependence of protein trafficking. Both the use of Arrhenius equation and C(Pd) provide new opportunities to measure the energy requirements for protein transport. These tools will enable researchers to quantify effects of environmental and developmental conditions on Pd conductivity, as well as comparing differences in Pd conductivity between plant species or induced by genetic mutations.     

The effect of source or sink temperature on photosynthesis and 14C-partitioning in and export from a source leaf of Alstroemeria

The influence of source and sink temperature on leaf net C exchange rate (NCER), export, and partitioning in the C₃ monocotyledon Alstroemeria sp. cv. Jacqueline were examined. Leaf (i.e. source) temperature was varied between 12 and 35°C while source leaves were exposed to photorespiratory and nonphotorespiratory conditions during a 2-h steady-state ¹⁴CO₂ labelling period. Between 12 and 20°C, at ambient CO₂ and O₂, leaf NCER and export were similar with maximum rates of 9.71 ± 0.51 and 3.06 ± 0.36 μmol C m^-2 s^-1, respectively. Both NCER and export decreased above 20°C. At 35°C NCER was 30% of the rate at 20°C, but export was totally inhibited. Between 12 and 35°C, at the end of the 2-h feeding period, ¹⁴C was partitioned in the leaf as ethanol insolubles (3–10%), H₂O solubles (88–92%), and chloroform solubles (2–8%). However, above 25°C, less ¹⁴C was recovered in the starch fraction and more in the sugar fractions. At all temperatures, 86 to 94% of the labelled sugars was ¹⁴C-sucrose. In nonphotorespiratory conditions (i.e. 1 800 μI I^-1 CO₂ and 2% O₂). NCER and export were higher than the rates obtained at ambient CO₂ and O₂ at each temperature. Carbon dioxide enrichment sustained high NCER and export rates even at 35°C, Although CO₂ enrichment increased partitioning of ¹⁴C into starch, starch synthesis at 35°C was markedly reduced. Cooling the root-zone mass (i.e. a dominant sink) to 10°C, which simulated the commercial practice used to induce flowering, had no significant effect on source leaf NCER and export rates either during a 2-h steady-state labelling period or subsequently during a 21-h light-dark chase period. Furthermore, partitioning of ¹⁴C among leaf products at the end of the feed-chase period was not affected. Additional pulse and chase experiments using ¹¹CO₂ fed to source leaves of control and root-cooled plants showed that there was no difference in the direction of movement of ¹¹C-assimilates towards the flower or the root zone as a consequence of root cooling. Together, the data indicate that changing source strength, by manipulating photosynthesis and photorespiration, by varying the leaf temperature had a more profound effect on leaf export than manipulating sink activity.     

Synthesis,Characterization, and Cytotoxicity Studies of a Novel Palladium(II) Complex and Evaluation of DNA-Binding Aspects

A new water-soluble palladium(II) complex, [Pd(bpy)(pyr-Ac]NO₃ in which bpy = 2,2′-bipyridine and pyr-Ac is 1-pyrrolacetato, has been synthesized and characterized by spectroscopic methods (¹H NMR, FT-IR, and UV-Vis), molar conductivity measurements, and elemental analysis. The results obtained from elemental analysis and conductivity measurements confirmed the stoichiometry of ligand and its complex while the characteristic peaks in UV-Vis and FT-IR and resonance peaks in ¹H NMR spectra confirmed the formation of ligand frameworks around the palladium ion. The 50% cytotoxic concentration (Ic₅₀) of new synthesized Pd(II) complex was determined by using MTT assay against human breast cancer cell line, T47D. The interaction between the Pd(II) complex with calf thymus DNA was studied at different temperatures by using absorption spectroscopy, fluorescence titration spectra, ethidium bromide displacement, and gel chromatography studies. The results obtained by absorption spectroscopy revealed that the Pd(II) complex can bind to DNA cooperatively at low concentrations. Several binding parameters in the above interaction were calculated by the fluorescence quenching method. The quenching mechanism was suggested to be the static quenching. The thermodynamic parameters: enthalpy change (ΔH °), entropy change (ΔS °), and Gibbs free energy (ΔG °), showed that van der Waals and hydrogen binding are predominant intermolecular forces between Pd(II) complex and DNA. These results were also consistent with the results obtained from Scatchard's plots.     

Hydraulic resistance to radial water flow in growing hypocotyl of soybean measured by a new pressure-perfusion technique

Hydraulic resistances to water flow have been determined in the cortex of hypocotyls of growing seedlings of soybean (Glycine max L. Merr. cv. Wayne). Data at the cell level (hydraulic conductivity, Lp; half-time of water exchange, T _1/2; elastic modulus, ; diffusivity for the cell-to-cell pathway, D _c) were obtained by the pressure probe, diffusivities for the tissue (D _t) by sorption experiments and the hydraulic conductivity of the entire cortex (Lp_r) by a new pressure-perfusion technique. For cortical cells in the elongating and mature regions of the hypocotyls T _1/2=0.4–15.1 s, Lp=0.2·10^-5–10.0·10^-5 cm s^-1 bar^-1 and D _c=0.1·10^-6–5.5·10^-6 cm² s^-1. Sorption kinetics yielded a tissue diffusivity D _t=0.2·10^-6–0.8·10^-6 cm² s^-1. The sorption kinetics include both cell-wall and cell-to-cell pathways for water transport. By comparing D _c and D _t, it was concluded that during swelling or shrinking of the tissue and during growth a substantial amount of water moves from cell to cell. The pressure-perfusion technique imposed hydrostatic gradients across the cortex either by manipulating the hydrostatic pressure in the xylem of hypocotyl segments or by forcing water from outside into the xylem. In segments with intact cuticle, the hydraulic conductance of the radial path (Lp_r) was a function of the rate of water flow and also of flow direction. In segments without cuticle, Lp_r was large (Lp_r=2·10^-5–20·10^-5 cm s^-1 bar^-1) and exceeded the corticla cell Lp. The results of the pressure-perfusion experiments are not compatible with a cell-to-cell transport and can only the explained by a preferred apoplasmic water movement. A tentative explanation for the differences found in the different types of experiments is that during hydrostatic perfusion the apoplasmic path dominates because of the high hydraulic conductivity of the cell wall or a preferred water movement by film flow in the intercellular space system. For shrinking and swelling experiments and during growth, the films are small and the cell-to-cell path dominates. This could lead to larger gradients in water potential in the tissue than expected from Lp_r. It is suggested that the reason for the preference of the cell-to-cell path during swelling and growth is that the solute contribution to the driving force in the apoplast is small, and tensions normally present in the wall prevent sufficiently thick water films from forming. The solute contribution is not very effective because the reflection coefficient of the cell-wall material should be very small for small solutes. The results demonstrate that in plant tissues the relative magnitude of cell-wall versus cell-to-cell transport could dependent on the physical nature of the driving forces (hydrostatic, osmotic) involved.Abbreviations and symbols D _c diffusivity of the cell-to-cell pathway - D _t diffusivity of the tissue - radial flow rate per cm² of segment surface - Lp hydraulic conductivity of plasma-membrane - Lp_r radial hydraulic conductance of the cortex - T _1/2 half-time of water exchange between cell and surroundings - volumetric elastic modulus     

Incorporation and uptake of thymidine and uridine by hela cells: Effect of DNA extracts prepared from normal human fibroblasts

Summary The incorporation and uptake of (³H) thymidine into HeLa cells markedly decreased in the presence of nuclear homogenates and DNA extracts that have been derived from normal diploid cell cultures. On the other hand, uridine uptake and incorporation were stimulated under the same conditions. The inhibition could be reversed immediately upon removal of the exogenous fraction from the culture medium. The inhibitory properties of the extracts are propagated by excreted cellular components as well as after DNAase treatment. The inhibitory factor is thermostable, resistant to pronase treatment, and seems to be related to nucleic acid. The material herein represents part of a dissertation presented by the senior author in partial fulfillment of the requirements for the degree of Doctor of Philosophy at the Tel Aviv University, Israel. This work was partially supported by a grant from the Israel Ministry of Health.     

The impact of Sharav weather conditions on airborne pollen in Jerusalem and Tel Aviv (Israel)

Pollen grains have been a major focus of research mostly in temperate regions due to their effects on human health, especially allergies and asthma. The current study investigates a subtropical region characterized by a Mediterranean climate where Sharav conditions are experienced during the spring and autumn. The aim of the current study was to investigate whether Sharav conditions impacted airborne pollen concentrations of allergenic Amaranthaceae, Poaceae, Morus, Pinus, and Quercus more than standard Warm days during the main pollen seasons in the years 2010–2014 in Tel Aviv and Jerusalem (Israel). Slight variation was observed between the main pollen seasons in Tel Aviv compared to Jerusalem resulting from differences in temperature and relative humidity percentages. Additionally, more Sharav conditions occurred in Jerusalem than in Tel Aviv during the study period. The highest pollen concentrations occurred during Sharav days for Amaranthaceae, Poaceae, and Pinus but not for Morus and Quercus. Therefore, individuals who are allergic to Amaranthaceae, Poaceae, and Pinus pollen, and exposed to high pollen concentrations during Sharav days, might suffer more allergy symptoms than on Warm days.     

Photosynthetic performance and resistance to photoinhibition of Zea mays L. leaves grown at sub-optimal temperature

The performance of the photosynthetic apparatus was examined in the third leaves of Zea mays L. seedlings grown at near-optimal (25 °C) or at suboptimal (15 °C) temperature by measuring chlorophyll (ChI) a fluorescence parameters and oxygen evolution in different temperature and light conditions. In leaf tissue grown at 25 and 15 °C, the quantum yield of PSII electron transport (ψ_PSII) and the rate of O₂ evolution decreased with decreasing temperature (from 25 to 4 °C) at a photon flux density of 125 μmol m^?2 s^?1. In leaves grown at 25 °C, the decrease of ψ_PSII correlated with a decrease of photochemical ChI fluorescence quenching (q_p), whereas in leaves crown at 15 °C q_p was largely insensitive to the temperature decrease. Compared with leaves grown at 25 °C, leaves grown at 15 °C were also able to maintain a higher fraction of oxidized to reduced Q_A (greater q_p) at high photon flux densities (up to 2000 μmol m^?2 s^?1), particularly when the measurements were performed at high temperature (25 °C). With decreasing temperature and/or increasing light intensity, leaves grown at 15 °C exhibited a substantial quenching of the dark level of fluorescence F₀ (q₀) whereas this type of quenching was virtually absent in leaves grown at 25 °C. Furthermore, leaves grown at 15 °C were able to recover faster from photo inhibition of photosynthesis after a photoinhibitory treatment (1200 μmol m^?2 s^?1 at 25, 15 or 6 °C for 8 h) than leaves grown at 25 °C. The results suggest that, in spite of having a low photosynthetic capacity, Z. mays leaves grown at sub optimal temperature possess efficient mechanisms of energy dissipation which enable them to cope better with photoinhibition than leaves grown at near-optimal temperature. It is suggested that the resistance of Z. mays leaves grown at 15 °C to photoinhibition is related to the higher content of carotenoids of the xanthophyll cycle (violaxanthin + antheraxanthin + zeaxanthin) measured in these leaves than in leaves grown at 25 °C.     

Interaction between cucumber green mottle mosaic virus MP and CP promotes virus systemic infection

The movement protein (MP) and coat protein (CP) of tobamoviruses play critical roles in viral cell-to-cell and long-distance movement, respectively. Cucumber green mottle mosaic virus (CGMMV) is a member of the genus Tobamovirus. The functions of CGMMV MP and CP during viral infection remain largely unclear. Here, we show that CGMMV MP can interact with CP in vivo, and the amino acids at positions 79–128 in MP are vital for the MP–CP interaction. To confirm this finding, we mutated five conserved residues within the residue 79–128 region and six other conserved residues flanking this region, followed by in vivo interaction assays. The results showed that the conserved threonine residue at the position 107 in MP (MP^T107) is important for the MP–CP interaction. Substitution of T107 with alanine (MP^T107A) delayed CGMMV systemic infection in Nicotiana benthamiana plants, but increased CGMMV local accumulation. Substitutions of another 10 conserved residues, not responsible for the MP–CP interaction, with alanine inhibited or abolished CGMMV systemic infection, suggesting that these 10 conserved residues are possibly required for the MP movement function through a CP-independent manner. Moreover, two movement function-associated point mutants (MP^F17A and MP^D97A) failed to cause systemic infection in plants without impacting on the MP–CP interaction. Furthermore, we have found that co-expression of CGMMV MP and CP increased CP accumulation independent of the interaction. MP and CP interaction inhibits the salicylic acid-associated defence response at an early infection stage. Taken together, we propose that the suppression of host antiviral defence through the MP–CP interaction facilitates virus systemic infection.     

Temperature effect on maintenance and growth respiration coefficients of young, field-grown hinoki cypress (Chamaecyparis obtusa)

Respiration measurements were made on the entire aboveground parts of young, field-grown hinoki cypress (Chamaecyparis obtusa) trees at monthly intervals over a 5-year period, to examine the effect of temperature on maintenance and growth respiration coefficients. The respiration rate of the trees was grouped on a monthly basis and then partitioned into maintenance and growth components. The maintenance respiration coefficient increased exponentially with air temperature. The maintenance respiration coefficient at a temperature of 0°C and itsQ ₁₀ value were 0.205 mmol CO₂ g⁻¹ d.w. month⁻¹ and 1.81, respectively. The growth respiration coefficient, which was virtually independent of temperature, had a mean value of 38.06±1.95 (SE) mmol CO₂g⁻¹ d.w. The growth rate increased exponentially with increasing temperature up to a peak at around 18°C, and thereafter declined, thereby resulting in the growth respiration rate being increasingly less sensitive to increasing air temperature. The reported decreases in theQ ₁₀ value of total respiration with increasing air temperature is due to the way in which the growth component of respiration responds to temperature.     

Photosystem 2 is more tolerant to high temperature in apple (<Emphasis Type="Italic">Malus domestica</Emphasis> Borkh.) leaves than in fruit peel

Tolerance of photosystem 2 (PS2) to high temperature in apple (Malus domestica Borkh. cv. Cortland) leaves and peel was investigated by chlorophyll a fluorescence (OJIP) transient after exposure to 25 (control), 40, 42, 44, and 46 °C in the dark for 30 min. The positive L-step was more pronounced in a peel than in leaves when exposed to 44 °C. Heat-induced K-step became less pronounced in leaves than in peel when exposed to 42 °C or higher temperature. Leaves had negative L-and K-steps relative to the peel. The decrease of oxygen-evolving complex (OEC) by heat stress was higher in the peel than in the leaves. OJIP transient from the 46 °C treated peel could not reach the maximum fluorescence (F_m). The striking thermoeffect was the big decrease in the relative variable fluorescence at 30 ms (V_I), especially in the leaves. Compared with the peel, the leaves had less decreased maximum PS2 quantum efficiency (F_v/F_m), photochemical rate constant (K_P), F_m and performance index (PI) on absorption basis (PI_abs) and less increased minimum fluorescence (F₀) and non-photochemical rate constant (K_N), but more increased reduction of end acceptors at PS1 electron acceptor side per cross section (RE₀/CS₀) and per reaction center (RE₀/RC₀), quantum yield of electron transport from Q_A ⁻ to the end acceptors (ϕ _R0) and total PI (PI_abs,total) when exposed to 44 °C. In conclusion, PS2 is more thermally labile than PS1. The reduction of PS2 activity by heat stress primarily results from an inactivation of OEC. PS2 was more tolerant to high temperature in the leaves than in the peel.     

Airborne fungal spores in the coastal plain of Israel: A preliminary survey

Airborne spores were monitored during the years 1993–1995 in three cities along the coastal plain of Israel: Ramat Gan, Tel Aviv (Ramat Aviv) and Haifa. Seasonal fluctuations in the concentration of airborne spores were recorded. The following genera of fungi were identified:Alternaria, Cladosporium, Coprinus, Curvularia, Drechslera. Diplococcum, Epicoccum, Fusarium, Leptosphaeria, Pithomyces, Puccinia, Sphacelotheca, Stemphylium andUstilago. Unidentified spores were very rare and in negligible numbers. The dominant airborne fungal spores wereCladosporium andAlternaria. The monthly variations in airborne spores, observed among the three cities, seem to be rather minor. The recorded levels of airborne spores were below the concentrations that are accepted as threshold levels for provocation of clinical responses.