Induction of swelling in pea internode tissue by ethylene

Ethylene inhibits polar cell expansion of etiolated pea (Pisum sativum) internode tissue and results in a radial cell expansion, swelling. A special gas-tight growth chamber was developed to monitor continuously the induction of cell expansion inhibition of excised internode segments in the presence of ethylene. Following a complex induction period which lasts about 3 hours, a low, but steady-state growth rate is achieved. Ethylene removal experiments indicate that the gas induces an irreversible change in the cell expansion mode. If the tissue was transferred to an ethylene-free chamber after the steady-state rate had been achieved, this rate continued in the absence of the gas. If the gas was removed during an intermediate phase, that intermediate rate of growth continued after removal. In other experiments, segments were incubated with intact apical hooks and the induction period was much shorter than with isolated segments. Changes in imino acid metabolism have been correlated with the induction of swelling. Although total proline and hydroxyproline levels were not affected by ethylene treatment, incorporation of [¹⁴C]proline into a wall-associated protein was inhibited during the period when swelling occurred. These results suggest that ethylene is affecting proline pool sizes.     

Cell Surfaces in Plant-Microorganism Interactions : III. In Vivo Effect of Ethylene on Hydroxyproline-Rich Glycoprotein Accumulation in the Cell Wall of Diseased Plants

Ethylene production and cell wall hydroxyproline-rich glycoprotein (HRGP) biosynthesis are greatly enhanced in melon (Cucumin melo cv. Cantaloup charentais) seedlings infected with Colletotrichum lagenarium. Short-term experiments performed in the presence of specific inhibitors of the ethylene pathway from methionine, namely l-canaline and amino-ethoxyvinylglycine, indicate that under non-toxic conditions, both ethylene and [¹⁴C]hydroxyproline deposition in the cell wall of infected tissues are significantly lowered. On the contrary, treatment of healthy tissues with 1-aminocyclopropane 1-carboxylic acid, a natural precursor of ethylene, stimulates both the production of the hormone and the incorporation of [¹⁴C]hydroxyproline into cell wall proteins.     

Massive synthesis of ribonucleic Acid and cellulase in the pea epicotyl in response to indoleacetic Acid, with and without concurrent cell division

Measurements were made over a 4-day period of the effect of added indoleacetic acid (IAA), puromycin, actinomycin D and 5-fluorodeoxyuridine (FUdR) on growth and the levels of total DNA, RNA, protein and cellulase in segments of tissue at the apex of decapitated etiolated epicotyls of Pisum sativum, L. var. Alaska.

The hormone induced swelling of parenchyma cells and cell division. By 3 days after IAA application, the amounts of DNA and protein were approximately double, RNA triple and cellulase 12 to 16 times the levels in controls. All of these changes were prevented by both puromycin and actinomycin D. FUdR prevented DNA synthesis and cell division but not swelling or synthesis of RNA, protein and cellulase.

It is concluded that IAA-induced RNA synthesis is required for cellulase synthesis and lateral cell expansion, whether or not cell division takes place.

     

Effects of ethylene on auxin transport

The effect of ethylene on the uptake, distribution and polar transport of C¹⁴ from indole-3-acetic acid-2-C¹⁴ and naphthalene acetic acid-1-C¹⁴ in tissue sections was studied. Test species were cotton (Gossypium hirsutum, L.) and cowpea (Vigna sinensis, Endl.). Generally, incubation of tissue or intact plants with ethylene reduced the degree of polar auxin transport. Ethylene inhibited the movement of both auxins in stem tissue and IAA in petiole tissue of cotton. The effect of ethylene on auxin movement in cow-peas was more complex. Ethylene apparently inhibited transport in younger petiole and stem tissue, but stimulated the process to a small but significant degree in basal petiole segments.

Ethylene, in some experiments, reduced C¹⁴ (auxin) uptake. This reduction was consistently smaller than the inhibition of transport. Effects upon transport were observed when uptake was not different. Differences in uptake declined as the period of incubation with auxin was lengthened, but transport was inhibited for up to 23 hours.

It is proposed that ethylene may, through its effect on transport, cause localized shortages and surpluses of auxin which in turn contribute to symptoms now associated with the response of sensitive species to ethylene.

     

Evidence for Extracellular ATP as a Stress Signal in a Single-Celled Organism

ATP is omnipresent in biology and acts as an extracellular signaling molecule in mammals. Information regarding the signaling function of extracellular ATP in single-celled eukaryotes is lacking. Here, we explore the role of extracellular ATP in cell volume recovery during osmotic swelling in the amoeba Dictyostelium. Release of micromolar ATP could be detected during cell swelling and regulatory cell volume decrease (RVD) phases during hypotonic challenge. Scavenging ATP with apyrase caused profound cell swelling and loss of RVD. Apyrase-induced swelling could be rescued by 100 μM βγ-imidoATP. N-Ethylmalemide (NEM), an inhibitor of vesicular exocytosis, caused heightened cell swelling, loss of RVD, and inhibition of ATP release. Amoebas with impaired contractile vacuole (CV) fusion (drainin knockout [KO] cells) displayed increased swelling but intact ATP release. One hundred micromolar Gd³⁺ caused cell swelling while blocking any recovery by βγ-imidoATP. ATP release was 4-fold higher in the presence of Gd³⁺. Cell swelling was associated with an increase in intracellular nitric oxide (NO), with NO-scavenging agents causing cell swelling. Swelling-induced NO production was inhibited by both apyrase and Gd³⁺, while NO donors rescued apyrase- and Gd³⁺-induced swelling. These data suggest extracellular ATP released during cell swelling is an important signal that elicits RVD. Though the cell surface receptor for ATP in Dictyostelium remains elusive, we suggest ATP operates through a Gd³⁺-sensitive receptor that is coupled with intracellular NO production.     

Abscission: role of cellulase

Cellulase (β-1,4-glucan-glucanohydrolase EC 3.2.1.4) activity increased during abscission and was localized in the cell separation layer of Phaseolus vulgaris L. cv. Red Kidney (bean), Gossypium hirsutum L. cv. Acala 4-42 (Cotton) and Coleus blumei Benth. Princeton strain (Coleus) abscission zone explants. Cellulase activity was optimum at pH 7, was reduced by one-half after heating to 55° for 10 min, and was associated with the soluble components of the cell. Explants treated with aging retardants (indoleacetic acid, ⁶N-benzyladenine, and coumarin), CO₂, actinomycin D or cycloheximide had less cellulase activity than untreated controls. Ethylene increased cellulase activity of aged explants after a 3-hr lag period but had no effect on cellulase activity of freshly excised explants. It was concluded that 1 of the roles of ethylene in abscission is to regulate the production of cellulase which in turn is required for cell separation.     

Enhancement of RNA synthesis, protein synthesis, and abscission by ethylene

Ethylene stimulated RNA and protein synthesis in bean (Phaseolus vulgaris L. var. Red Kidney) abscission zone explants prior to abscission. The effect of ethylene on RNA synthesis and abscission was blocked by actinomycin D. Carbon dioxide, which inhibits the effect of ethylene on abscission, also inhibited the influence of ethylene on protein synthesis. An aging period appears to be essential before bean explants respond to ethylene. Stimulation of protein synthesis by ethylene occurred only in receptive or senescent explants. Treatment of juvenile explants with ethylene, which has no effect on abscission also has no effect on protein synthesis. Evidence in favor of a hormonal role for ethylene during abscission is discussed.     

Regulation of soybean nodulation independent of ethylene signaling

Leguminous plants regulate the number of Bradyrhizobium- or Rhizobium-infected sites that develop into nitrogen-fixing root nodules. Ethylene has been implicated in the regulation of nodule formation in some species, but this role has remained in question for soybean (Glycine max). The present study used soybean mutants with decreased responsiveness to ethylene, soybean mutants with defective regulation of nodule number, and Ag⁺ inhibition of ethylene perception to examine the role of ethylene in the regulation of nodule number. Nodule numbers on ethylene-insensitive mutants and plants treated with Ag⁺ were similar to those on wild-type plants and untreated plants, respectively. Hypernodulating mutants displayed wild-type ethylene sensitivity. Suppression of nodule numbers by high nitrate was also similar between ethylene-insensitive plants, wild-type plants, and plants treated with Ag⁺. Ethylene insensitivity of the roots of etr1-1 mutants was confirmed using assays for sensitivity to 1-aminocyclopropane-1-carboxylic acid and for ethylene-stimulated root-hair formation. Additional phenotypes of etr1-1 roots were also characterized. Ethylene-dependent pathways regulate the number of nodules that form on species such as pea and Medicago truncatula, but our data indicate that ethylene is less significant in regulating the number of nodules that form on soybean.     

Mug28, a Meiosis-specific Protein of Schizosaccharomyces pombe,Regulates Spore Wall Formation

The meiosis-specific mug28⁺ gene of Schizosaccharomyces pombe encodes a putative RNA-binding protein with three RNA recognition motifs (RRMs). Live observations of meiotic cells that express Mug28 tagged with green fluorescent protein (GFP) revealed that Mug28 is localized in the cytoplasm, and accumulates around the nucleus from metaphase I to anaphase II. Disruption of mug28⁺ generated spores with low viability, due to the aberrant formation of the forespore membrane (FSM). Visualization of the FSM in living cells expressing GFP-tagged Psy1, an FSM protein, indicated that mug28Δ cells harbored abnormal FSMs that contained buds, and had a delayed disappearance of Meu14, a leading edge protein. Electron microscopic observation revealed that FSM formation was abnormal in mug28Δ cells, showing bifurcated spore walls that were thicker than the nonbifurcated spore walls of the wild type. Analysis of Mug28 mutants revealed that RRM3, in particular phenylalanin-466, is of primary importance for the proper localization of Mug28, spore viability, and FSM formation. Together, we conclude that Mug28 is essential for the proper maturation of the FSM and the spore wall.     

Mitochondrial Swelling Induced by Glutathione

Reduced glutathione, in concentrations approximating those occurring in intact rat liver, causes swelling of rat liver mitochondria in vitro which is different in kinetics and extent from that yielded by L-thyroxine. The effect is also given by cysteine, which is more active, and reduced coenzyme A, but not by L-ascorbate, cystine, or oxidized glutathione. The optimum pH is 6.5, whereas thyroxine-induced swelling is optimal at pH 7.5. The GSH-induced swelling is not inhibited by DNP or dicumarol, nor by high concentrations of sucrose, serum albumin, or polyvinylpyrrolidone, in contrast to thyroxine-induced swelling. ATP inhibits the GSH swelling, but ADP and AMP are ineffective. Mn^-+ is a very potent inhibitor, but Mg⁺⁺ is ineffective. Ethylenediaminetetraacetate is also an effective inhibitor of GSH-induced swelling. The respiratory inhibitors amytal and antimycin A do not inhibit the swelling action of GSH, but cyanide does; these findings are consistent with the view that the oxidation-reduction state of the respiratory chain between cytochrome c and oxygen is a determinant of GSH-induced swelling. Reversal of GSH-induced swelling by osmotic means or by ATP in KCl media could not be observed. Large losses of nucleotides and protein occur during the swelling by GSH, suggesting that the action is irreversible. The characteristically drastic swelling action of GSH could be prevented if L-thyroxine was also present in the medium.     

Ethylene-induced lateral expansion in etiolated pea stems : kinetics, cell wall synthesis, and osmotic potential

Treatment of etiolated pea (Pisum sativum L.) internode tissue with ethylene gas inhibits elongation and induces lateral expansion. Precise kinetics of the induction of this altered mode of growth of excised internode segments were recorded using a double laser optical monitoring device. Inhibition of elongation and promotion of lateral expansion began after about 1 hour of treatment and achieved a maximum by 3 hours. Similar induction kinetics were observed after treating internodes with colchicine and 2,6-dichlorobenzonitrile, an inhibitor of cellulose synthesis. In sealed flask experiments, ethylene had no detectable effect on incorporation of label from [¹⁴C]glucose into any of the classical pectin, hemicellulose, or cellulose wall fractions. Ethylene inhibited fresh weight increase (total cell expansion) of both excised internode segments (in sealed flasks) and intact seedlings. Ethylene treatment resulted in an increase in cell sap osmolality in those tissues (intact and excised) which are inhibited by the gas. A model for ethylene-induced inhibition of elongation and induction of lateral expansion is presented.     

SYNTHESIS OF PARAMECIUM SURFACE PROTEINS : I. Puromycin Insensitive Amino Acid Incorporation

The synthesis of a surface protein has been studied in Paramecium through double-labeling experiments using [¹⁴C]- and [³H]leucine-labeled bacteria as the source of radioactive amino acid. Over a 4–5 h incubation period, the turnover rate was found to be higher than that of overall cell protein. In addition, the initial label is apparently utilized during the chase period, being incorporated into protein via a puromycin insensitive pathway.     

Ion transport by heart mitochondria. XXII. Spontaneous, energy-linked accumulation of acetate and phosphate salts of monovalent cations

The accumulation of monovalent cations by isolated beef heart mitochondria has been studied by evaluating the efficiency of energy-dependent osmotic swelling. Extensive osmotic swelling occurs spontaneously when isolated heart mitochondria are suspended in 0.1 m acetate or phosphate salts. The swelling and ion uptake depend on either respiration or the presence of exogenous ATP, and the initial rate of swelling is proportional to the initial rate of respiration or ATP hydrolysis, respectively. The efficiency of the reaction varies somewhat from preparation to preparation but approaches a limit of about 2 cations accumulated per pair of electrons traversing a phosphorylation site. All monovalent cations tested support the reaction, but the most efficient energy-dependent swelling occurs with K⁺. Weak acid anions are required for the ion accumulation and swelling and the reaction appears to depend on the amount of free acid available in the suspension. Permeant strong acid anions, such as NO₃⁻, fail to support the swelling reaction in the presence of energy. Valinomycin increases both the amount and the efficiency of ion uptake under these conditions. Mg²⁺ decreases both of these values whereas p-chloromercuriphenyl sulfonate increases both. These responses are discussed in terms of current models of mitochondrial ion transport.     

Self-Protection against Cell Wall Hydrolysis in Streptococcus milleri NMSCC 061 and Analysis of the Millericin B Operon

Streptococcus milleri NMSCC 061 produces an endopeptidase, millericin B, which hydrolyzes the peptide moiety of susceptible cell wall peptidoglycan. The nucleotide sequence of a 4.9-kb chromosomal region showed three open reading frames (ORFs) and a putative tRNA^Leu sequence. The three ORFs encode a millericin B preprotein (MilB), a putative immunity protein (MilF), and a putative transporter protein (MilT). The milB gene encodes a 277-amino-acid preprotein with an 18-amino-acid signal peptide with a consensus IIGG cleavage motif. The predicted protein encoded by milT is homologous to ABC (ATP-binding cassette) transporters of several bacteriocin systems and to proteins implicated in the signal-sequence-independent export of Escherichia coli hemolysin A. These similarities strongly suggest that the milT gene product is involved in the translocation of millericin B. The gene milF encodes a protein of 302 amino acids that shows similarities to the FemA and FemB proteins of Staphylococcus aureus, which are involved in the addition of glycine to a pentapeptide peptidoglycan precursor. Comparisons of the cell wall mucopeptide of S. milleri NMSCC 061(resistant to lysis by millericin B) and S. milleri NMSCC 051(sensitive) showed a single amino acid difference. Serial growth of S. milleri NMSCC 051 in a cell wall minimal medium containing an increased concentration of leucine resulted in the in vivo substitution of leucine for threonine in the mucopeptide of the cell wall. A cell wall variant of S. milleri NMSCC 051 (sensitive) that contained an amino acid substitution (leucine for threonine) within its peptidoglycan cross bridge showed partial susceptibility to millericin B. The putative tRNA^Leu sequence located upstream of milB may be a cell wall-specific tRNA and could together with the milF protein, play a potential role in the addition of leucine to the pentapeptide peptidoglycan precursor and thereby, contributing to self-protection to millericin B in the producer strain.     

Cell Swelling Activates the K+ Conductance and Inhibits the Cl? Conductance of the Basolateral Membrane of Cells from a Leaky Epithelium

Necturus gallbladder epithelial cells bathed in 10 mM HCO₃/1% CO₂ display sizable basolateral membrane conductances for Cl⁻ (G_Cl ^b) and K ⁺ (G_K ^b). Lowering the osmolality of the apical bathing solution hyperpolarized both apical and basolateral membranes and increased the K ⁺/Cl⁻ selectivity of the basolateral membrane. Hyperosmotic solutions had the opposite effects. Intracellular free-calcium concentration ([Ca²⁺]_i) increased transiently during hyposmotic swelling (peak at ∼30 s, return to baseline within ∼90 s), but chelation of cell Ca²⁺ did not prevent the membrane hyperpolarization elicited by the hyposmotic solution. Cable analysis experiments showed that the electrical resistance of the basolateral membrane decreased during hyposmotic swelling and increased during hyperosmotic shrinkage, whereas the apical membrane resistance was unchanged in hyposmotic solution and decreased in hyperosmotic solution. We assessed changes in cell volume in the epithelium by measuring changes in the intracellular concentration of an impermeant cation (tetramethylammonium), and in isolated polarized cells measuring changes in intracellular calcein fluorescence, and observed that these epithelial cells do not undergo measurable volume regulation over 10–12 min after osmotic swelling. Depolarization of the basolateral membrane voltage (V_cs) produced a significant increase in the change in V_cs elicited by lowering basolateral solution [Cl⁻], whereas hyperpolarization of V_cs had the opposite effect. These results suggest that: (a) Hyposmotic swelling increases G_K ^b and decreases G _Cl ^b. These two effects appear to be linked, i.e., the increase in G _K ^b produces membrane hyperpolarization, which in turn reduces G _Cl ^b. ( b) Hyperosmotic shrinkage has the opposite effects on G_K ^b and G _Cl ^b. ( c) Cell swelling causes a transient increase in [Ca²⁺]_i, but this response may not be necessary for the increase in G_K ^b during cell swelling.     

Apoptosis Repressor with a CARD Domain (ARC) Restrains Bax-Mediated Pathogenesis in Dystrophic Skeletal Muscle

Myofiber wasting in muscular dystrophy has largely been ascribed to necrotic cell death, despite reports identifying apoptotic markers in dystrophic muscle. Here we set out to identify the contribution of canonical apoptotic pathways to skeletal muscle degeneration in muscular dystrophy by genetically deleting a known inhibitor of apoptosis, apoptosis repressor with a card domain (Arc), in dystrophic mouse models. Nol3 (Arc protein) genetic deletion in the dystrophic Sgcd or Lama2 null backgrounds showed exacerbated skeletal muscle pathology with decreased muscle performance compared with single null dystrophic littermate controls. The enhanced severity of the dystrophic phenotype associated with Nol3 deletion was caspase independent but dependent on the mitochondria permeability transition pore (MPTP), as the inhibitor Debio-025 partially rescued skeletal muscle pathology in Nol3 ^-/- Sgcd ^-/- double targeted mice. Mechanistically, Nol3 ^-/- Sgcd ^-/- mice showed elevated total and mitochondrial Bax protein levels, as well as greater mitochondrial swelling, suggesting that Arc normally restrains the cell death effects of Bax in skeletal muscle. Indeed, knockdown of Arc in mouse embryonic fibroblasts caused an increased sensitivity to cell death that was fully blocked in Bax Bak1 (genes encoding Bax and Bak) double null fibroblasts. Thus Arc deficiency in dystrophic muscle exacerbates disease pathogenesis due to a Bax-mediated sensitization of mitochondria-dependent death mechanisms.     

Spores of microorganisms

A pulse incorporation of radioactive precursors into the cells was used in studying the rate of RNA and protein synthesis during postgerminative development of spores ofBacillus cereus. It was found that the extractable pool of the spores can be enriched by these precursors during swelling and preelongation. During this period of differentiation of a spore to a primary cell,¹⁴C-uracil and to a smaller extent¹⁴C-adenine are more rapidly used for RNA synthesis. Labelled¹⁴C-leucine and³⁶S-methionine are found mostly in the extractable fraction of the cells. However, their rate of incorporation into proteins is not higher. Differences in utilization of precursors for the synthesis of macromolecules are apparently caused by different availability for the metabolic pool of the cell. Of the precursors tested¹⁴C-uracil seems to be selectively incorporated into RNA with a higher rate. This can be explained by a selective permeability into metabolic pool or by an increased need of uracil during preelongation period.     

Effect of Growth Rate and Starvation-Survival on Cellular DNA, RNA, and Protein of a Psychrophilic Marine Bacterium

DNA, RNA, and protein concentrations from starved ANT-300 cell populations grown at different growth rates fluctuated corresponding to the three stages of starvation-survival on total and viable cell bases. During stage 1 of starvation-survival, two to three peaks in the concentration levels for all three macromolecules were characteristic. During stage 2, DNA per total cell dropped to between 4.2 and 8.3% of the original amount for all of the cell populations examined, and it stabilized throughout stage 3. The decrease in DNA per cell was also observed in electron micrographs of cellular DNA in unstarved compared with starved cells. The fluctuations of RNA and protein per total cell concentrations observed during stage 2 coincided in all cases, except for the cells from dilution rate (D) = 0.015 h⁻¹. This ANT-300 cell population showed a decrease in RNA per total cell to only 29.2% and an increase in protein to 129.7% of the original amount after 98 days of starvation. During stage 3, DNA, RNA, and protein concentrations per total cell also stabilized to continuous levels. Cells from the faster-growth-rate cell populations of D = 0.170 h⁻¹ and batch culture had elevated protein per total cell concentrations, which remained primarily residual during the starvation period. Starved cells from D = 0.015 h⁻¹ had estimated nucleoid and cell volumes of 0.018 and 0.05 μm³, respectively, yielding a nucleoid volume/cell volume ratio of 0.40. We consider these data to indicate that slow-growth-rate cells are better adapted for starvation-survival than their faster-growth-rate counterparts.     

The Tyrosine Kinase p56lck Mediates Activation of Swelling-induced Chloride Channels in Lymphocytes

Osmotic cell swelling activates Cl⁻ channels to achieve anion efflux. In this study, we find that both the tyrosine kinase inhibitor herbimycin A and genetic knockout of p56^lck, a src-like tyrosine kinase, block regulatory volume decrease (RVD) in a human T cell line. Activation of a swelling-activated chloride current (I_Cl−swell) by osmotic swelling in whole-cell patch-clamp experiments is blocked by herbimycin A and lavendustin. Osmotic activation of I_Cl−swell is defective in p56^lck-deficient cells. Retransfection of p56^lck restores osmotic current activation. Furthermore, tyrosine kinase activity is sufficient for activation of I_Cl−swell. Addition of purified p56^lck to excised patches activates an outwardly rectifying chloride channel with 31 pS unitary conductance. Purified p56^lck washed into the cytoplasm activates I_Cl−swell in native and p56^lck-deficient cells even when hypotonic intracellular solutions lead to cell shrinkage. When whole-cell currents are activated either by swelling or by p56^lck, slow single-channel gating events can be observed revealing a unitary conductance of 25–28 pS. In accordance with our patch-clamp data, osmotic swelling increases activity of immunoprecipitated p56^lck. We conclude that osmotic swelling activates I_Cl−swell in lymphocytes via the tyrosine kinase p56^lck.