Action potentials and variation potentials in sunflower: An analysis of their relationships and distinguishing characteristics

Sunflower plants ( Helianthus annuus L.) were given an electrical stimulus to the stem or a heat (flame)‐wound to a single leaf or a cotyledon. The resulting electrical activity was monitored with extracellular electrodes. An electrical stimulus applied to the stem frequently evoked an action potential (AP), but never a variation potential (VP). In contrast, a heat‐wound applied to a leaf virtually always elicited a VP, which was often accompanied by one or more superimposed spikes (putative APs). The kinetic parameters of the AP and the VP were investigated. The AP appears to propagate without decrement in velocity or magnitude, whereas the VP parameters decrease significantly with distance. The heat stimulus triggered rapid alterations in stem elongation/contraction, which preceded changes in electrical potential, indicating the transmission of a hydraulic signal. Light‐off and light‐on stimuli evoked negative‐ and positive‐going changes in extracellular electrical potential, respectively, corresponding to de‐ and hyper‐polarization of the plasma membrane. Membrane depolarization (extracellularly manifested as a VP) evoked by both the light‐off and heat‐wounding stimuli was able to trigger one or more APs. We interpret these results to suggest that APs are "genuine" electrical signals involving voltage‐gated ion channels or pumps, which can be evoked directly by electrical stimulation or indirectly by changes in membrane potential occurring during the VP or after the light‐off stimulus. In contrast, VPs appear to be a local (non‐transmissible) electrical consequence of the passage of a rapidly transmitted hydraulic signal in the xylem, presumably acting on mechanosensitive ion channels or pumps in adjacent living cells.     

Electrical signals in higher plants: Mechanisms of generation and propagation

Local stimulation induces generation and propagation of electric signals in higher plants. Noninvasive stimulus induces an action potential and damaging influences lead to the variation potential. The mechanism of the generation of an action potential is rather complex in nature and is associated with both activation of ion channels (Ca²⁺, Cl^–, and K⁺) and transient change in the activity of the plasma membrane H⁺-ATPase. Generation of the variation potential, the duration of which is considerably longer than that of the action potential, is based on transient inactivation of the electrogenic pump; however, passive ion fluxes also contribute to such process, which causes qualitative similarity of the mechanisms of action potential and variation potential generation. Propagation of electrical signals mainly occurs in conducting bundles; thus, transfer of an action potential is associated with vascular parenchyma and sieve elements, while the variation potential is connected to the xylem vessels. The mechanism of the distribution the action potential is similar to nerve impulse transmission, while generation of the variation potential is induced by transfer of a chemical substance, whose propagation is accelerated by a hydraulic wave.     

Both action potentials and variation potentials induce proteinase inhibitor gene expression in tomato

Tomato plants (Lycopersicon esculentum) accumulate proteinase inhibitor 2 (pin2) mRNA in response to insect attack, crushing and flaming in leaves distant from those treated. Most earlier work suggests that the systemic wound signals are chemical; here we try to determine whether electrical or physical (hydraulic) signals can also evoke pin expression. We used a mild flame to evoke a systemic hydraulic signal and its local electrical aftermath, the variation potential (VP), and we used an electric stimulus to evoke a systemic electrical signal, the action potential (AP). We determined the kinetic parameters of both the VP and AP. Flame-wounded plants essentially always exhibited major electrical responses throughout the plant and a several-fold increase in pin2 mRNA within 1 h. Electrically stimulated plants that generated and transmitted a signal (AP) into the analyzed leaf exhibited similarly large, rapid increases in pin2 mRNA levels. Plants which generated no signal, or signals of just a few microvolts, had unchanged levels of pin2 mRNA. Since the AP and VP both arrived in the receiving leaf before accumulation of pin2 mRNA began, we conclude that, in addition to the previously shown chemical signals, both hydraulically induced VPs and electrically induced APs are capable of evoking pin2 gene expression.     

Surface potentials and hydraulic signals in wheat leaves following localized wounding by heat

Abstract. Localized burning of a leaf causes a rapid change in apoplastic electrical potential throughout the shoot of wheat seedlings ('variation potential'). It also causes marked increases in turgor pressure in epidermal cells of adjoining leaves. These turgor increases indicate rapid propagation throughout the seedling, of a hydraulic pressure wave from the site of wounding. Evidence is presented that this pressure wave is caused by relief of xylem tension, by water released from damaged cells in the wounded region. It is demonstrated that, in the absence of wounding, pressure waves imposed at the tip of one leaf can travel to neighbouring leaves, and can there induce change in apoplastic electrical potential similar to a 'variation potential'. This indicates that the hydraulic event produced by wounding is the signal responsible for systemic induction of the 'variation potential'. This signal has been termed 'Ricca's factor'. It is suggested that arrival of the hydraulic wave alters leaf water potential and thereby induces stomatal activity. Leaf surface potential may be dominated by electrogenic ion pumping or flux at stomatal cells, and the 'variation potential' may therefore be a reflection of stomatal activity induced by the hydraulic signal.     

Short Term Interactions between Flows of Photosynthate

Using radioactive tracers, interactions between flows of photosyntheticassimilate were observed in vivo with several species. Changesin translocation from one source (brought about by repeatedchilling and re-warming which stops and re-starts flow) cancause an immediate and partially compensating change in translocationfrom another source. The rapidity of response implies the transmissionof a physical rather than a chemical signal. The compensationcan be sustained for at least 90 min and involves a change inthe speed of sap flow rather than a change in its concentration.A change in the rate of loading in the source (lamina) is probablyinvolved, but this is not always the case, for it seems thatthe signal calling for extra assimilate is a lowering of sievetube pressure potential and this is transmitted over only rathershort distances of stem (though over quite long distances ofpetiole), because of entry of water and assimilate (loading)from stores in close proximity to the pathway. The responseis buffered therefore and becomes less evident as one movesaway from the site of treatment. Key words: Photosynthate translocation, Phloem loading     

Phosphorylation in vivo of a vaccinia-virus structural protein found associated with the ribosomes from infected cells.

When vaccinia-virus-infected cells were labeled with radioactive phosphate in the absence of viral gene expression an additional phosphoprotein, containing phosphoserine, was found specifically associated with the ribosomes. The phosphoprotein was removed from the ribosomes following a 0.5 M KCl washing or after EDTA treatment. This additional phosphoprotein was found in infected cells after either a long (3-4 h) or a short (30 min) labeling period; it was detected when the infected cells were incubated in the presence or absence of an inhibitor of RNA or protein synthesis. This phosphoprotein originated from the phosphorylation of vaccinia virion structural protein VP11b (Mr 11,000) at a specific site since only a single major phosphopeptide was obtained after trypsin digestion. This phosphoprotein was also present in purified vaccinia virions labeled with radioactive phosphate. VP11b protein was phosphorylated in vitro by the protein kinase associated with the cores. When the reaction was carried out at an alkaline pH the phosphorylation in vitro occurred at different sites in the protein; at neutral pH the phosphorylation of VP11b was more specific and, as judged by tryptic peptide analysis, occurred mainly at the same site as in the phosphorylation in vivo. A role for the involvement of phosphoprotein VP11b in the establishment of the shut off of host protein synthesis by vaccinia virus is suggested.     

The role of the intra- and extracellular protons in the photosynthetic response induced by the variation potential in pea seedlings

Local burning induces generation and propagation of variation potential (VP) in higher plants. VP induces transient inactivation of photosynthesis, which is possibly connected with proton signal in plant cell. Analysis of the role of changes in intracellular and extracellular pH in the VP-induced photosynthetic response in pea seedlings was the aim of this work. It was shown that local burning induced VP propagation, which was accompanied with a decrease of intracellular pH and increase of extracellular pH. VP induced photosynthesis inactivation that included an increase in the nonphotochemical fluorescence quenching and a decrease in the CO₂ assimilation rate. Analysis of photosynthetic responses under control and low external CO₂ concentration and changes in pH showed that there were two components in the responses. The first component appeared as a fast decrease of the CO₂ assimilation and increase of nonphotochemical quenching. It depended on the activity of the dark stage of photosynthesis and was connected with apoplast alkalization. The second component was presented as a slow increase of nonphotochemical quenching. It weakly depended on a dark stage and was connected with a decrease of intracellular pH.     

Retinal spreading depression and the extracellular milieu

We used isolated chick retina in vitro to study the participation of the extracellular milieu in the occurrence and propagation of spreading depression. The propagation was followed by visual observation or microphotometry and the ionic changes in the extracellular compartment were recorded with double-barreled ion-selective microelectrodes. The front of the spreading wave is accompanied by increased light scattering in the tissue and by decrease of Cl-, Na+, and Ca2+, increase of K+, and an alkaline-acid shift in the extracellular space, concomitant with the slow voltage changes characteristic of the wave. As the spread is related to the chemical steady-state of the extracellular milieu, the velocity of propagation is influenced by a balanced interplay of the chemical constituents of the superfusing solution, e.g., K+, HCO-3, and glucose facilitate, while Cl- and Mg2+ hinder the wave. Steady-state alterations induced by physical factors (temperature) or related to experimental conditions (speed and direction of superfusate flow) change markedly the velocity of propagation. Generally the procedures that cause increase of velocity augment the susceptibility of the preparation to the reaction and eventually may trigger it. Propagated spreading depression is considered as a chemical diffusion reaction pervading more intensively the inner plexiform layer of the retina.     

Temperature-dependent signal transmission in chloroplast accumulation response

Chloroplast photorelocation movement, well-characterized light-induced response found in various plant species from alga to higher plants, is an important phenomenon for plants to increase photosynthesis efficiency and avoid photodamage. The signal for chloroplast accumulation movement connecting the blue light receptor, phototropin, and chloroplasts remains to be identified, although the photoreceptors and the mechanism of movement via chloroplast actin filaments have now been revealed in land plants. The characteristics of the signal have been found; the speed of signal transfer is about 1 µm min^?1 and that the signal for the accumulation response has a longer life and is transferred a longer distance than that of the avoidance response. Here, to collect the clues of the unknown signal substances, we studied the effect of temperature on the speed of signal transmission using the fern Adiantum capillus-veneris and found the possibility that the mechanism of signal transfer was not dependent on the simple diffusion of a substance; thus, some chemical reaction must also be involved. We also found new insights of signaling substances, such that microtubules are not involved in the signal transmission, and that the signal could even be transmitted through the narrow space between chloroplasts and the plasma membrane.     

Effects of convective transport on chemical signal propagation in epithelia

We study effects of convective transport on a chemical front wave representing a signal propagation at a simple (single layer) epithelium by means of mathematical modeling. Plug flow and laminar flow regimes were considered. We observed a nonmonotonous dependence of the propagation velocity on the ligand receptor binding constant under influence of the convective transport. If the signal propagates downstream, the region of high velocities becomes much broader and spreads over several orders of magnitude of the binding constant. When the convective transport is oriented against the propagating signal, either velocity of the traveling front wave is slowed down or the traveling front wave can stop or reverse the direction of propagation. More importantly, chemical signal in epithelial systems influenced by the convective transport can propagate almost independently of the ligand-receptor binding constant in a broad range of this parameter. Furthermore, we found that the effects of the convective transport becomes more significant in systems where either the characteristic dimension of the extracellular space is larger/comparable with the spatial extent of the ligand diffusion trafficking or the ligand-receptor binding/ligand diffusion rate ratio is high.     

Crystal structure of a novel viral protease with a serine/lysine catalytic dyad mechanism

The blotched snakehead virus (BSNV), an aquatic birnavirus, encodes a polyprotein (NH2-pVP2-X-VP4-VP3-COOH) that is processed through the proteolytic activity of its own protease (VP4) to liberate itself and the viral proteins pVP2, X and VP3. The protein pVP2 is further processed by VP4 to give rise to the capsid protein VP2 and four structural peptides. We report here the crystal structure of a VP4 protease from BSNV, which displays a catalytic serine/lysine dyad in its active site. This is the first crystal structure of a birnavirus protease and the first crystal structure of a viral protease that utilizes a lysine general base in its catalytic mechanism. The topology of the VP4 substrate binding site is consistent with the enzymes substrate specificity and a nucleophilic attack from the si-face of the substrates scissile bond. Despite low levels of sequence identity, VP4 shows similarities in its active site to other characterized Ser/Lys proteases such as signal peptidase, LexA protease and Lon protease. Together, the structure of VP4 provides insights into the mechanism of a recently characterized clan of serine proteases that utilize a lysine general base and reveals the structure of potential targets for antiviral therapy, especially for other related and economically important viruses, such as infectious bursal disease virus in poultry and infectious pancreatic necrosis virus in aquaculture.     

ATMOSPHERIC AND UNDERWATER PROPAGATION OF BULLFROG VOCALIZATIONS

ABSTRACT

Male bullfrogs vocalize while partially submerged in shallow freshwater ponds. This imposes two potential propagation pathways, atmospheric and underwater, on transmission of their communication sounds. Propagation of pure tones, amplitude modulated (AM) broadband noise and natural calls was measured in air and underwater at three bullfrog breeding sites. In air, propagation losses were consistent with spherical spreading. No excess attenuation was observed for any tone frequency at any site. Both temporal envelope modulations and spectral cues are available to conspecific receivers at biologically realistic distances. The bullfrog's advertisement call is thus well adapted for transmission in air at the air/water interface. Underwater signal propagation differed at the three sites, consistent with substrate effects. Tone propagation showed the high-pass frequency window characteristic of shallow water. Broadband signals underwent propagation losses greater than expected by cylindrical spreading. Modulations of the envelope of natural calls remained discernible at distances where frequency-dependent propagation losses distorted the shape of the spectrum. Measurements of the propagation of the advertisement call emitted by a chorusing frog at the air/water interface confirm that periodicity cues embedded in the envelope are available to receivers both in air and underwater. High frequency cues available underwater overlap the maximal hearing sensitivity of larval conspecifics (tadpoles).     

Mechanisms of synthesis of virion proteins from the functionally bigenic late mRNAs of simian virus 40.

The late 19S RNAs of simian virus 40 (SV40) are functionally polycistronic, i.e., all encode both VP2 and VP3. The VP3-coding sequences are situated in the same reading frame as the VP2-coding sequences, within the carboxy-terminal two-thirds of the VP2-coding sequences. To test whether VP3 is produced by proteolytic processing of VP2, we introduced a variety of deletion and insertion mutations within the amino-terminal end of the VP2-coding sequences. Genetic and biochemical analysis of the proteins synthesized in cells transfected with these mutants indicated that VP2 and VP3 were synthesized independently of each other. A leaky scanning model for the synthesis of VP3 was tested by the insertion of a strong initiation signal (CCAACATGG) upstream of the VP3-coding sequences. When the signal was placed in the same reading frame as VP3, synthesis of VP3 was reduced by a factor of 10 to 20, whereas synthesis of the expected VP3-related fusion protein occurred at a rate similar to that observed for VP3 in cells transfected with wild-type SV40 DNA. Insertion of this strong initiation signal at the same site, but in a different reading frame, resulted in the synthesis of VP3 at one-third of the wild-type rate. Mutation of the VP2 initiator AUG resulted in a small but reproducible (1.6-fold) increase in VP3 accumulation. From these experiments we conclude that (i) VP3 is synthesized predominantly by independent initiation of translation via a leaky scanning mechanism, rather than by proteolytic processing of VP2 or direct internal initiation of translation; (ii) a strong initiation signal 5' of the VP3-coding sequences can significantly inhibit synthesis of VP3, but does not act as an absolute barrier to scanning ribosomes; (iii) approximately 70% of scanning ribosomes bypass the VP2 initiator AUG, which is present in a weak context (GGUCCAUGG), and initiate at the VP3 initiation signal located downstream; and (iv) reinitiation of translation appears to occur on the SV40 late 19S mRNAs at an efficiency of 25 to 50%.     

Is the 6 kDa tobacco etch viral protein a bona fide ERES marker?

The claim that the 6 kDa viral protein (VP) of Tobacco Etch Virus is a marker for ER exit sites (ERES) has been investigated. When transiently expressed as a CFP tagged fusion construct in tobacco mesophyll protoplasts, this integral membrane protein co-localizes with both the COPII coat protein YFP-SEC24 and the Golgi marker Man1-RFP. However, when over-expressed the VP locates to larger spherical structures which co-localize with neither ER nor Golgi markers. Nevertheless, deletion of the COPII interactive N-terminal D(X)E motif causes it to be broadly distributed throughout the ER, supporting the notion that this protein could be an ERES marker. Curiously, whereas brefeldin A (BFA) caused a typical Golgi-stack response (redistribution into the ER) of the VP in leaf epidermal cells, in protoplasts it resulted in the formation of structures identical to those formed by over-expression. However, anomalous results were obtained with protoplasts: when co-expressed with the non-cycling cis-Golgi marker Man1-RFP, a BFA-induced redistribution of the VP-CFP signal into the ER was observed, but, in the presence of the cycling Golgi marker ERD2-YFP, this did not occur. High resolution images of side-on views of Golgi stacks in epidermal cells showed that the 6 kDa VP-CFP signal overlapped considerably more with YFP-SEC24 than with Man1-RFP, indicating that the VP is proportionately more associated with ERES. However, based on a consideration of the structure of its cytoplasmic tail, the scenario that the VP collects at ERES and is transported to the cis-Golgi before being recycled back to the ER, is supported.     

A glycolytic marker test for individualizing the selection of chemical compounds for antitumor activity]

Based on literature data on effects of various preparations on the glycolysis in tumor and normal cells, a glycolytic molecular biochemical marker is proposed to screen chemical substances as potential antitumor drugs. A glycolytic specificity was noted in tumor cells which was regarded as a criterion for distinction of tumor cells from normal ones and among various histotypes of tumor cells as well as for the selective sensitivity of tumor cells to a substance. 17 of 38 substances tested were observed to inhibit glycolysis in tumor cells. The testing chemical substances for an antitumor activity with application of the glycolytic marker is recommended. A possibility is discussed of applying the marker for testing potential antitumor drugs, their individualization, and genetic typing.     

Synaptic vesicles in electromotoneurones. I. Axonal transport, site of transmitter uptake and processing of a core proteoglycan during maturation.

We were able by using an in vivo pulse-label technique to trace part of the life cycle of a secretory organelle, the acetylcholine-storing synaptic vesicle from electromotoneurones of Torpedo marmorata. This technique uses [35S]sulphate incorporation into the cell bodies of the electromotoneurones which results in radioactive labelling of a synaptic vesicle heparansulphate proteoglycan--a major core component. Vesicles are anterogradely transported in the axons at a fast rate as 'empty' organelles (VP0 population). In the nerve terminal, maturation of the granule to a population (VP1) fully charged with acetylcholine and ATP occurs. Finally after a longer time interval a change to a third population (VP2) is observed. This population is reduced in diameter as compared to VP0 and VP1 suggesting, in agreement with earlier reports, that it has undergone exo-endocytosis. The changes from VP0 to VP1 and VP2 are accompanied by a degradation of the core proteoglycan as measured by gel filtration of the 35S-labelled compound. The results show that vesicles are axonally transported as preformed organelles, exist in the neurone at least in three different populations and that the nerve terminal is the major site of transmitter uptake.